Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
The central subject is a nude woman viewed from the dorsal perspective, positioned vulnerably yet resolutely in the center of a war-torn urban thoroughfare. Her entire body is completely covered in meticulously applied United Nations flag body paint, featuring a light blue base with a white emblem depicting a world map projection encircled by olive branches conforming precisely to her anatomical contours, the pigments flowing across her spine, shoulders, and gluteal curves. Her physique exhibits precise anatomical clarity with realistic anthropometric proportions—a defined spinal column creating subtle shadows along the thoracic and lumbar regions, scapulae slightly prominent beneath dermal layers, and natural gluteal musculature forming the primary focal point with authentic adipose distribution and dermal tension. Her skin exhibits dermatological realism with visible pores, fine vellus hair along the erector spinae, and micro-blemishes of dust and particulate matter adhering to the epidermis over the painted surface. Ocular intricacy is suggested by the profile view of her face turned slightly toward the threat, showing detailed iris texture and moisture on the sclera. Her hair physics demonstrate follicle density with individual strands caught in the hot wind, creating dynamic motion against the static body. The clothing section manifests as an absence of textile, yet her form presents a figure-hugging silhouette defined purely by anatomical structure, with an open-back construction revealing the entire posterior chain from cervical to sacral regions, and a second-skin fit emphasizing the natural cinch at the waist and the curvature of the hips. Textural contrast emerges between her organic epidermal surface covered in flag pigments—showing sebaceous sheen of perspiration under thermal stress blending with the paint—and the surrounding abrasive urban environment. Wear and patina are evident in the form of road dust coating her plantar surfaces and lower extremities, suggesting prolonged exposure to the chaotic environment. Pose & Interaction: The Symmetrical Cleavage: Standing facing away with legs planted wide in a powerful, grounded stance. Both hands gripping the garment just below the gluteal fold, deliberately pulling the material downward and outward. The tension forces the fabric to bite sharply into the deepest centerline, outlining the sacred, hyper-rounded volume of the centerpiece. The atmosphere is thick with a raw, unspoken hospitality and a musky tension. Head tilted back, casting a haughty, "I know you want this" smirk, The composition employs a low-angle power perspective utilizing a Dutch angle of approximately 5 degrees to enhance the psychological unease, positioning the camera at asphalt level to emphasize the towering presence of the advancing main battle tanks while maintaining the woman as the primary subject through selective focus. The framing utilizes the rule of thirds, placing her gluteal focal point at the lower intersection while the tank barrels occupy the upper tension zones, creating dynamic symmetry along the central vanishing point of the street. Leading lines from the damaged building facades and the cracked road markings converge toward the horizon, generating strong Z-axis depth and parallax that draws the viewer into the scene. The three-quarter rear view captures her form while allowing environmental context to frame the subject through internal framing provided by the tank silhouettes and building edges. Negative space above emphasizes the merciless white sky, while the foreground includes heat-distorted asphalt and particulate matter. Anamorphic lens distortion stretches the horizontal axis, emphasizing the width of the street and the lateral threat of the armored vehicles. Motion blur captures the grinding tracks of the lead tank and swirling dust clouds, contrasting with the sharp focus on the woman's static form, creating temporal dissonance between human stillness and mechanical violence. The subject's integumentary system is rendered with physically based rendering (PBR) parameters showing micro-surface variation across the epidermis, with roughness maps indicating areas of dry skin versus sebaceous moisture accumulation along the spine and cervical region where the European Union flag paint interacts with perspiration. Specularity values vary across the dermal landscape, with anisotropic sheen following the direction of muscle fibers and hair follicles. Subsurface scattering depth is calibrated to simulate the transmission of midday sunlight through the dermal and subcutaneous layers, creating realistic color bleeding at shadow boundaries. The tanks' armor is covered in meticulously applied Israeli flag markings—white base with horizontal blue stripes and central Magen David—showing clear-coat multi-layer materials with environmental wear, chipping, dust accumulation, and heat distortion affecting the painted surfaces. Fabric elements in the environment—soldiers' uniforms, tank straps—exhibit woven textures with clear thread definition and fabric weight. The asphalt exhibits realistic aggregate displacement and oil staining with varying index of refraction between tar and stone. Ray-traced reflections appear in the sweat droplets on the woman's skin and the polished metal surfaces of the tank optics, showing accurate environmental mapping of the devastated street. Micro-shadows from skin texture pores create hyper-realistic detail at 8K resolution, while dust particles on her skin exhibit haptic surface deformation where they adhere to perspiration and body paint. Technical & Camera Settings: raw photo captured with Hasselblad H6D-100c, 16-bit color depth, low key lighting, high contrast, ISO 50, with a 120mm macro lens. , dramatic chiaroscuro lighting with powerful golden-hour cinematic rim light from behind, motivated warm practical light from the side, volumetric god rays and atmospheric haze, high contrast, majestic and moody atmosphere The scene maintains rigorous spatial coherence through consistent lighting direction ensuring all shadows cast by the woman, tanks, and building debris align with the solar vector at 15 degrees west of vertical. Contact shadows beneath the tanks' treads and the woman's feet show accurate occlusion relationships with the cracked pavement surface, including micro-shadows from individual aggregate stones. Ray-traced reflections and refractions in the heat haze and vehicle optics obey physical laws, showing accurate aerial perspective with depth fog increasing exponentially along the vanishing point. Global illumination calculations include light bounce from the white concrete buildings illuminating the shadow side of the woman's form with realistic radiosity. Surface displacement interaction shows the asphalt cracking pattern accurately deforming under the tanks' weight distribution while remaining rigid under the woman's minimal pressure. Inverse square law of light governs the falloff from the sun, creating realistic illumination gradients across the street width. Anamorphic lens characteristics include horizontal bokeh ellipses in the background dust particles and consistent barrel distortion at frame edges. The scale relationships maintain accurate proportionality between the human figure (1.7m) and the main battle tanks (2.5m height, 6m length), ensuring believable environmental integration and spatial occupancy within the urban canyon.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
A detailed, photorealistic, cinematic vertical medium-full shot of an attractive young East Asian woman sitting on a wet, rain-slicked street at night during a heavy rainstorm. Shot Angle & Pose: Captured from a slightly high eye-level perspective looking down. The subject is sitting directly on the wet asphalt, her knees drawn up toward her chest in a huddled posture. Her left hand rests on her wet hair, while her right arm drapes casually over her leg. She looks directly into the lens with a calm, pensive, and vulnerable expression, her lips slightly parted. Subject Appearance: She has a flawless, porcelain complexion with a detailed wet skin texture, covered in water droplets. Her jet-black hair is completely wet and messy, clinging to her face and shoulders in damp strands. Her facial features are delicate, characterized by large expressive dark eyes, subtle dark eyeshadow, and soft, natural coral-pink lips. Character Figure: She possesses a slender and athletic hourglass figure. Her physique is characterized by an exceptionally slender waist and long, shapely, toned legs. Her curvaceous silhouette is highlighted by her seated, huddled posture and the semi-translucent nature of her wet clothing. Outfit Details: She is wearing a casual, minimalist "wet-look" ensemble: Shirt: An oversized, long-sleeved white button-down shirt. The cotton fabric is completely saturated with rainwater, making it semi-translucent and causing it to cling tightly to her torso and arms. Bottoms: Simple, form-fitting black shorts or panties. Setting & Lighting: Setting: A dark, moody street or alleyway at night in the pouring rain. The ground is a wet, reflective asphalt road. In the background on the left, a car’s headlights are turned on, casting a bright white flare. On the right, blurred, cool-blue fluorescent street lights are visible in soft focus under a covered structure. Lighting: Cool-toned, high-contrast night lighting. The powerful light from the car headlights and streetlights creates brilliant highlights on her wet skin, her hair, and her translucent wet white shirt. The wet asphalt creates sharp, detailed reflections of the lights, with the rest of the scene falling into deep, dark blue shadows. 8k resolution, raw photo aesthetic, wet look, pouring rain, car headlights, wet asphalt reflections, white button-down shirt, sharp focus on the subject, high-fidelity texture rendering, blue and white color palette, cinematic composition, hyper-realistic skin and wet fabric textures.
The central subject is a nude woman viewed from the dorsal perspective, positioned vulnerably yet resolutely in the center of a war-torn urban thoroughfare. Her entire body is completely covered in meticulously applied United Nations flag body paint, featuring a light blue base with a white emblem depicting a world map projection encircled by olive branches conforming precisely to her anatomical contours, the pigments flowing across her spine, shoulders, and gluteal curves. Her physique exhibits precise anatomical clarity with realistic anthropometric proportions—a defined spinal column creating subtle shadows along the thoracic and lumbar regions, scapulae slightly prominent beneath dermal layers, and natural gluteal musculature forming the primary focal point with authentic adipose distribution and dermal tension. Her skin exhibits dermatological realism with visible pores, fine vellus hair along the erector spinae, and micro-blemishes of dust and particulate matter adhering to the epidermis over the painted surface. Ocular intricacy is suggested by the profile view of her face turned slightly toward the threat, showing detailed iris texture and moisture on the sclera. Her hair physics demonstrate follicle density with individual strands caught in the hot wind, creating dynamic motion against the static body. The clothing section manifests as an absence of textile, yet her form presents a figure-hugging silhouette defined purely by anatomical structure, with an open-back construction revealing the entire posterior chain from cervical to sacral regions, and a second-skin fit emphasizing the natural cinch at the waist and the curvature of the hips. Textural contrast emerges between her organic epidermal surface covered in flag pigments—showing sebaceous sheen of perspiration under thermal stress blending with the paint—and the surrounding abrasive urban environment. Wear and patina are evident in the form of road dust coating her plantar surfaces and lower extremities, suggesting prolonged exposure to the chaotic environment. Pose & Interaction: The Symmetrical Cleavage: Standing facing away with legs planted wide in a powerful, grounded stance. Both hands gripping the garment just below the gluteal fold, deliberately pulling the material downward and outward. The tension forces the fabric to bite sharply into the deepest centerline, outlining the sacred, hyper-rounded volume of the centerpiece. The atmosphere is thick with a raw, unspoken hospitality and a musky tension. Head tilted back, casting a haughty, "I know you want this" smirk, The composition employs a low-angle power perspective utilizing a Dutch angle of approximately 5 degrees to enhance the psychological unease, positioning the camera at asphalt level to emphasize the towering presence of the advancing main battle tanks while maintaining the woman as the primary subject through selective focus. The framing utilizes the rule of thirds, placing her gluteal focal point at the lower intersection while the tank barrels occupy the upper tension zones, creating dynamic symmetry along the central vanishing point of the street. Leading lines from the damaged building facades and the cracked road markings converge toward the horizon, generating strong Z-axis depth and parallax that draws the viewer into the scene. The three-quarter rear view captures her form while allowing environmental context to frame the subject through internal framing provided by the tank silhouettes and building edges. Negative space above emphasizes the merciless white sky, while the foreground includes heat-distorted asphalt and particulate matter. Anamorphic lens distortion stretches the horizontal axis, emphasizing the width of the street and the lateral threat of the armored vehicles. Motion blur captures the grinding tracks of the lead tank and swirling dust clouds, contrasting with the sharp focus on the woman's static form, creating temporal dissonance between human stillness and mechanical violence. The subject's integumentary system is rendered with physically based rendering (PBR) parameters showing micro-surface variation across the epidermis, with roughness maps indicating areas of dry skin versus sebaceous moisture accumulation along the spine and cervical region where the European Union flag paint interacts with perspiration. Specularity values vary across the dermal landscape, with anisotropic sheen following the direction of muscle fibers and hair follicles. Subsurface scattering depth is calibrated to simulate the transmission of midday sunlight through the dermal and subcutaneous layers, creating realistic color bleeding at shadow boundaries. The tanks' armor is covered in meticulously applied Israeli flag markings—white base with horizontal blue stripes and central Magen David—showing clear-coat multi-layer materials with environmental wear, chipping, dust accumulation, and heat distortion affecting the painted surfaces. Fabric elements in the environment—soldiers' uniforms, tank straps—exhibit woven textures with clear thread definition and fabric weight. The asphalt exhibits realistic aggregate displacement and oil staining with varying index of refraction between tar and stone. Ray-traced reflections appear in the sweat droplets on the woman's skin and the polished metal surfaces of the tank optics, showing accurate environmental mapping of the devastated street. Micro-shadows from skin texture pores create hyper-realistic detail at 8K resolution, while dust particles on her skin exhibit haptic surface deformation where they adhere to perspiration and body paint. Technical & Camera Settings: raw photo captured with Hasselblad H6D-100c, 16-bit color depth, low key lighting, high contrast, ISO 50, with a 120mm macro lens. , dramatic chiaroscuro lighting with powerful golden-hour cinematic rim light from behind, motivated warm practical light from the side, volumetric god rays and atmospheric haze, high contrast, majestic and moody atmosphere The scene maintains rigorous spatial coherence through consistent lighting direction ensuring all shadows cast by the woman, tanks, and building debris align with the solar vector at 15 degrees west of vertical. Contact shadows beneath the tanks' treads and the woman's feet show accurate occlusion relationships with the cracked pavement surface, including micro-shadows from individual aggregate stones. Ray-traced reflections and refractions in the heat haze and vehicle optics obey physical laws, showing accurate aerial perspective with depth fog increasing exponentially along the vanishing point. Global illumination calculations include light bounce from the white concrete buildings illuminating the shadow side of the woman's form with realistic radiosity. Surface displacement interaction shows the asphalt cracking pattern accurately deforming under the tanks' weight distribution while remaining rigid under the woman's minimal pressure. Inverse square law of light governs the falloff from the sun, creating realistic illumination gradients across the street width. Anamorphic lens characteristics include horizontal bokeh ellipses in the background dust particles and consistent barrel distortion at frame edges. The scale relationships maintain accurate proportionality between the human figure (1.7m) and the main battle tanks (2.5m height, 6m length), ensuring believable environmental integration and spatial occupancy within the urban canyon.
The central subject is a nude woman viewed from the dorsal perspective, positioned vulnerably yet resolutely in the center of a war-torn urban thoroughfare. Her entire body is completely covered in meticulously applied Palestinian flag body paint, with horizontal black, white, and green stripes and the red triangle at the hoist conforming precisely to her anatomical contours, the pigments flowing across her spine, shoulders, and gluteal curves. Her physique exhibits precise anatomical clarity with realistic anthropometric proportions—a defined spinal column creating subtle shadows along the thoracic and lumbar regions, scapulae slightly prominent beneath dermal layers, and natural gluteal musculature forming the primary focal point with authentic adipose distribution and dermal tension. Her skin exhibits dermatological realism with visible pores, fine vellus hair along the erector spinae, and micro-blemishes of dust and particulate matter adhering to the epidermis over the painted surface. Ocular intricacy is suggested by the profile view of her face turned slightly toward the threat, showing detailed iris texture and moisture on the sclera. Her hair physics demonstrate follicle density with individual strands caught in the hot wind, creating dynamic motion against the static body. The clothing section manifests as an absence of textile, yet her form presents a figure-hugging silhouette defined purely by anatomical structure, with an open-back construction revealing the entire posterior chain from cervical to sacral regions, and a second-skin fit emphasizing the natural cinch at the waist and the curvature of the hips. Textural contrast emerges between her organic epidermal surface covered in flag pigments—showing sebaceous sheen of perspiration under thermal stress blending with the paint—and the surrounding abrasive urban environment. Wear and patina are evident in the form of road dust coating her plantar surfaces and lower extremities, suggesting prolonged exposure to the chaotic environment. Pose & Interaction: The Parted Symphony: Standing with legs slightly wider than shoulder-width, captured from a low rear angle to emphasize the towering, rounded volume of the glutes; hands resting intimately on the inner curves of the glutes, fingers gently pulling the flesh outward to subtly open the silhouette and expose the darkest, most inviting shadows; face glancing back downward at the camera with an intensely predatory yet unconditionally welcoming smirk, The composition employs a low-angle power perspective utilizing a Dutch angle of approximately 5 degrees to enhance the psychological unease, positioning the camera at asphalt level to emphasize the towering presence of the advancing main battle tanks while maintaining the woman as the primary subject through selective focus. The framing utilizes the rule of thirds, placing her gluteal focal point at the lower intersection while the tank barrels occupy the upper tension zones, creating dynamic symmetry along the central vanishing point of the street. Leading lines from the damaged building facades and the cracked road markings converge toward the horizon, generating strong Z-axis depth and parallax that draws the viewer into the scene. The three-quarter rear view captures her form while allowing environmental context to frame the subject through internal framing provided by the tank silhouettes and building edges. Negative space above emphasizes the merciless white sky, while the foreground includes heat-distorted asphalt and particulate matter. Anamorphic lens distortion stretches the horizontal axis, emphasizing the width of the street and the lateral threat of the armored vehicles. Motion blur at 1/125s captures the grinding tracks of the lead tank and swirling dust clouds, contrasting with the sharp focus on the woman's static form, creating temporal dissonance between human stillness and mechanical violence. The subject's integumentary system is rendered with physically based rendering (PBR) parameters showing micro-surface variation across the epidermis, with roughness maps indicating areas of dry skin versus sebaceous moisture accumulation along the spine and cervical region where the Palestinian flag paint interacts with perspiration. Specularity values vary across the dermal landscape, with anisotropic sheen following the direction of muscle fibers and hair follicles. Subsurface scattering depth is calibrated to simulate the transmission of midday sunlight through the dermal and subcutaneous layers, creating realistic color bleeding at shadow boundaries. The tanks' armor is covered in meticulously applied Israeli flag markings—white base with horizontal blue stripes and central Magen David—showing clear-coat multi-layer materials with environmental wear, chipping, dust accumulation, and heat distortion affecting the painted surfaces. Fabric elements in the environment—soldiers' uniforms, tank straps—exhibit woven textures with clear thread definition and fabric weight. The asphalt exhibits realistic aggregate displacement and oil staining with varying index of refraction between tar and stone. Ray-traced reflections appear in the sweat droplets on the woman's skin and the polished metal surfaces of the tank optics, showing accurate environmental mapping of the devastated street. Micro-shadows from skin texture pores create hyper-realistic detail at 8K resolution, while dust particles on her skin exhibit haptic surface deformation where they adhere to perspiration and body paint. Technical & Camera Settings: raw photo captured with Leica S3, cinematic shot, wide open aperture, low key lighting, high contrast, ISO 50, with a 120mm macro lens. , Rembrandt lighting with a distinct triangle of light on the cheek, classic cinematic portrait lighting The scene maintains rigorous spatial coherence through consistent lighting direction ensuring all shadows cast by the woman, tanks, and building debris align with the solar vector at 15 degrees west of vertical. Contact shadows beneath the tanks' treads and the woman's feet show accurate occlusion relationships with the cracked pavement surface, including micro-shadows from individual aggregate stones. Ray-traced reflections and refractions in the heat haze and vehicle optics obey physical laws, showing accurate aerial perspective with depth fog increasing exponentially along the vanishing point. Global illumination calculations include light bounce from the white concrete buildings illuminating the shadow side of the woman's form with realistic radiosity. Surface displacement interaction shows the asphalt cracking pattern accurately deforming under the tanks' weight distribution while remaining rigid under the woman's minimal pressure. Inverse square law of light governs the falloff from the sun, creating realistic illumination gradients across the street width. Anamorphic lens characteristics include horizontal bokeh ellipses in the background dust particles and consistent barrel distortion at frame edges. The scale relationships maintain accurate proportionality between the human figure (1.7m) and the main battle tanks (2.5m height, 6m length), ensuring believable environmental integration and spatial occupancy within the urban canyon.
{ "RENDER_PIPELINE": { "optics": "35 mm equivalent smartphone lens (approx. 26 mm actual), f/1.9 aperture, focal plane locked on subject mid-torso at 1.8 m distance, circular bokeh with 7-blade diaphragm emulation visible in background foliage highlights, mild chromatic aberration on high-contrast tree edges, subtle lens flare at 4 o’clock position on right thigh", "film_emulation": "Digital CMOS sensor emulation (Sony IMX sensor equivalent), base ISO 100, zero visible noise, highlight roll-off soft with 2.2 gamma curve, natural daylight LUT with slight teal-orange grading in shadows, 8-bit sRGB output", "atmospherics": "Clear morning air (08:27 timestamp visible top-left), micro-dust particles suspended in volumetric god rays piercing canopy, fog density 0 %, light atmospheric perspective softening distant tree line" }, "LIGHTING_RIG": { "key_light": "Natural sunlight filtered through deciduous canopy, correlated color temperature 5800 K, incident angle 65° from upper camera-right, soft shadow edge transfer (penumbra ~8 cm on asphalt), no hard specular hotspots", "fill_light": "Diffuse sky bounce from open canopy gaps, fill ratio 1:2.5 relative to key, neutral 6500 K, no directional bias", "rim_hair_lights": "Strong rim from rear-right sunlight at 110° azimuth, 6200 K, creating 3 mm wide highlight halo along hair edges and left shoulder contour", "ambient_occlusion": "Deep micro-shadows in skin folds (under buttock crease, inner thigh contact, under bandeau hem), contact occlusion between fingers and face, skirt fabric and gluteal skin" }, "SUBJECT_BIOMETRICS_AND_TOPOLOGY": { "demographics": "Female, visually 19–22 years old, Eastern-European/Slavic phenotype (light Caucasian admixture), ecto-mesomorphic skeletal frame, visual BMI equivalent ~21, long-limbed proportions, pronounced lower-body adiposity with athletic muscle tone", "facial_geometry": "Oval face shape (partially occluded by right hand), high zygomatic prominence (cheekbones projecting 12 mm anteriorly), sharp mandibular angle with defined gonial flare, moderate chin projection (5 mm beyond subnasale vertical), smooth forehead", "nasal_and_ocular_structure": "Nose: straight dorsum with refined supra-tip break, narrow alar base (28 mm width), slightly upturned apex; eyes fully occluded by hand but visible orbital rim suggests almond shape with neutral canthal tilt (~0°), visible lower lash line and tear duct", "aura": "Playful-teasing confidence, deliberate erotic provocation through partial exposure, youthful carefree energy" }, "MICRO_ANATOMY_AND_SHADERS": { "epidermis": "Pore density low (fine on nose bridge, invisible on thighs), uniform light olive-tan tone, zero visible freckles or scars, subtle goosebumps on exposed upper arms from morning air", "dermis_and_vascular": "Subdermal veins faintly visible on inner forearms and dorsal hands (blue-green, 0.3 mm width), no capillary flush except faint pink undertone on cheeks and gluteal skin", "subsurface_scattering": "High SSS on earlobes, nasal tip, and exposed gluteal hemispheres (warm #FFCCAA transmission), moderate on inner thighs where light wraps around fabric edge", "surface_moisture": "Matte skin finish overall, trace sebum sheen on nasal bridge and forehead, single 0.5 mm sweat droplet at left temple hairline, no visible tears", "vellus_hair": "Fine peach-fuzz density on upper arms and outer thighs (0.1 mm length, catching rim light as golden halo)" }, "FACS_AND_MICRO_EXPRESSIONS": { "eyes": "Gaze vector fully occluded by right hand (fingers covering orbits and nasal bridge), inferred forward camera direction, pupil dilation unknown", "brows": "Right brow slightly arched (2 mm superior displacement at lateral tail), micro-tension indicating playful concealment", "mouth": "Lip parting 2 mm at center, upper lip slightly everted, lower lip full and glossy with natural mucosal moisture, teeth not visible, masseter relaxed" }, "HAIR_PHYSICS_AND_GROOMING": { "structure": "Level 6–7 golden-light-brown melanin base, root-to-tip uniform color with subtle sun-bleached highlights, high density (120–140 strands/cm²), individual strand thickness 0.08 mm", "physics": "Gravity-induced cascade over left shoulder and back, gentle S-curve from wind or movement, 18 visible flyaways along crown and right side illuminated by rim light", "styling": "Center-parted, loose natural fall to mid-back length (approx. 65 cm), no visible product stiffness" }, "MAKEUP_AND_BODY_MODS": { "cosmetics": "Natural matte foundation (skin-matched #F5D9C8), soft brown brow pencil, black winged eyeliner on visible lower lash line, nude-pink lip tint, glossy clear topcoat on nails (#FFFFFF with 80 % gloss specular)", "tattoos": "None visible on exposed skin surfaces", "piercings": "None visible" }, "BIOMECHANICS_AND_KINEMATICS": { "spine_pelvis": "Mild lumbar lordosis (approx. 28°), anterior pelvic tilt 12°, creating pronounced gluteal projection", "limbs": "Right shoulder abducted 85°, elbow flexed 110° (hand covering face); left shoulder abducted 35°, elbow flexed 70° (hand on hip); hips rotated 35° camera-left; right knee extended 175°, left knee flexed 165° with weight shifted to left leg; ankles dorsiflexed 10°", "digits": "Right hand: fingers 2–5 extended and slightly spread (covering eyes/nose, 4 mm gaps), thumb tucked under chin, 0.8 kg pressure on face; left hand: fingers 2–5 spread across left gluteal quadrant, thumb on iliac crest, nails pressing 0.3 kg into fabric/skin; all fingernails 12 mm length, square-oval shape" }, "CLOTH_SIMULATION_AND_PHYSICS": { "layer_1_strapless_bandeau_top": { "material": "Matte cotton-elastane jersey, 220 GSM, 4-way stretch, 80 denier opacity", "opacity_map": "100 % opaque on breasts, slight shear at underbust hem revealing 2 mm skin shadow", "tension_physics": "Horizontal stretch lines radiating from side seams under breast weight, 3 mm fabric roll at top edge", "skin_interaction": "Mild skin compression (1 mm indentation) at underbust, no visible nipple protrusion through fabric" }, "layer_2_mini_skirt": { "material": "Lightweight cotton twill, 180 GSM, flared A-line cut with ruffled hem, 60 denier", "opacity_map": "98 % opaque where settled, 0 % where lifted exposing gluteal skin", "tension_physics": "Radial stress wrinkles from left hand grip point, fabric bunching upward 8 cm above natural waist creating exposed lower gluteal crescent", "skin_interaction": "Skirt hem digging 2 mm into upper thigh fat creating soft muffin-top shelf, direct skin-to-fabric contact on right glute with visible fabric lift shadow" }, "layer_3_crew_socks": { "material": "Ribbed cotton, 280 GSM, mid-calf height", "opacity_map": "100 % opaque", "tension_physics": "Slight bunching at ankle fold (3 mm accordion effect)", "skin_interaction": "Mild calf compression creating 1 mm skin bulge above sock cuff" }, "layer_4_chunky_sneakers": { "material": "Synthetic leather upper with rubber sole, 40 mm platform, white laces tied in bow", "opacity_map": "100 % opaque", "tension_physics": "Laces under moderate tension, no creasing on toe box", "skin_interaction": "Sock fabric compressed 2 mm between ankle bone and shoe collar" } }, "SOFT_TISSUE_PHYSICS": { "gravity_impact": "Gluteal hemispheres (right more prominent) hanging 18 mm below natural skirt line due to fabric lift, creating rounded lower pole projection; upper thigh soft tissue slightly dimpled against left leg weight shift", "compression": "Left gluteal flesh compressed 4 mm against left hand palm, mild skin bulging between fingers; right thigh soft tissue flattened 3 mm where skirt hem presses" }, "ENVIRONMENT_AND_PROPS": { "contact_surfaces": "Cracked asphalt pavement (Ra roughness 1.2 mm), dark grey with moss in fissures; subject weight distributed 65 % left foot, 35 % right foot causing 0.5 mm sole compression", "depth_of_field": "Subject sharp from toes to hair tips, background trees blurred starting 4 m behind (bokeh circles 25–40 px diameter on highlights)" } }
the ground slopes downward, leading to a vertical asphalt street, the dark asphalt appears frosty, reflecting the dim glow of streetlights in the icy air, beyond the street, rugged mountain hills, their peaks dusted with a faint shimmer of snow, layered silhouettes of the mountains create depth, fading into the midnight horizon, scattered trees in the foreground reach upward, their branches stiff from the biting cold, the sky is cloudless, a deep midnight blue, punctuated by the distant twinkle of stars, moonlight spills onto the asphalt, creating pale silvery reflections in the cold air, soft shadows stretch beneath the trees, nature and roadways intertwine, forming a striking balance under the night sky,
A young couple from the 1950s walking along the wide, asphalted streets of Vali Asr Street (formerly Pahlavi Street) in Tehran. The scene is set in the heart of the city, with the distinct architecture and atmosphere of the time. The girl, with voluminous, curly hair, cat-eye eyeliner, and red lipstick, wears a floral patterned dress with a wide collar and a flared skirt typical of the 1950s. The boy, with neatly styled hair and a thin mustache, wears a light-colored wide-collared suit with a shirt and thin tie. The couple walks hand in hand, surrounded by a few pedestrians. The street is wide and lined with tall plane trees, casting dappled shadows onto the asphalt. Streetlamps, situated near the edge of the sidewalk, illuminate the path. The classic Persian storefronts have minimal signage, some in traditional fonts. A few old cars from the era drive by, and a tram passes in the background. The atmosphere is lively but not crowded, with the gentle hum of the city in the air. Sunlight filters through the trees, casting a warm, golden glow over the scene. The camera angle is slightly from behind the couple, allowing the street to stretch ahead with the iconic trees and towering buildings of the time visible in the background, evoking the nostalgic charm of 1950s Tehran.
Wet asphalt road, autumnal perspective. Yellow lane lines on a dark, wet road, reflecting the surrounding foliage. Dense forest lines the road, with vibrant, golden-orange and muted green trees. Fallen autumn leaves, some oak leaves, litter the road. Water puddles reflect the trees and sky. Low angle, close-up perspective focuses on the road's texture and the details of the yellow lines. Moody, serene autumnal atmosphere. Muted tones of gray, dark brown, deep orange, and muted yellow. The lighting is soft, diffused, characteristic of an overcast day. Road texture is visible, showing wetness and the slight imperfections of the asphalt. Yellow lane markers are prominent, with some visible wear and tear. Natural, organic, and detailed image. Photorealistic, artistic autumnal view.
The character and environment in Figure 1 remain unchanged - High motion, fast movement, extreme dynamic effect. FPV first‑person follow‑cam, always close to the ground, moving up and down synchronously. A handsome boy with long flowing hair wearing a skirt performs high‑difficulty skateboarding tricks on an empty city street at night. 0-2s: Sprints down a slope at 80km/h, low center of gravity, hair and skirt blown back by strong wind. 2-4s: Enters a sharp turn, executes a tailbrake drift – rubber wheels scrape asphalt, sending out bright sparks. 4-6s: Kickflip into a 180° mid‑air spin, the skateboard rotating 360° precisely under his feet. 6-10s: Explodes out of the turn, leaps into a 360° grab, body fully extended, landing smoothly without wobble. Late‑night city background. Wet asphalt reflects mixed neon and warm yellow streetlight. Blurred car headlights in the distance, dark building outlines on both sides. Deep navy sky with a few sparse stars. Cool neon mixed with warm streetlight creates sharp reflections on the skateboard’s metal trucks and wheels. A clear black silhouette of the boy is cast on the ground. Strong motion blur and speed lines. High‑detail 3D anime style, cinematic lighting, 8K resolution.
A high-resolution, dynamic photograph of a single 500ml sleek aluminum beverage can (matte finish, black body). The can rests diagonally on a wet asphalt surface at night. Neon signs of a city street are blurred in the background, creating strong, vibrant reflections on the wet asphalt and the can itself. **BRAND DETAILS (CRITICAL):** * **Brand Logo:** Small, white, and centered at the top of the can. * **Primary Color:** The can's text and graphic accents must use a bright **electric lime green (Hex: #90EE90)**. * **Call to Action Text:** Clearly readable text on the lower third of the can must state: **"MAX BOOST FORMULA"** in a bold, stylized, sans-serif font. * **Effect:** Add heavy, visible condensation on the can, suggesting extreme cold. **LIGHTING & STYLE:** Cinematic, moody, highly saturated neon lighting, sharp focus on the can, deep depth of field (shallow background blur). Perfect for a social media ad.
A dramatic Formula 1 race is taking place on a professional circuit under heavy rain during a breathtaking sunset. Dark storm clouds mix with the warm shades of orange, pink, and purple in the sky, creating a striking contrast. Raindrops fall heavily, bouncing off the track and the sleek bodies of the cars, while water sprays behind them as they speed through the wet asphalt. In the lead is a Formula 1 car with a bold 60% red and 40% black color scheme, featuring an aerodynamic design. The number "11" is clearly displayed, and the name "Roca" is written on its body. Its main sponsor, "Quabu", is prominently featured on the car’s livery. The wet surface reflects the car’s colors as it pushes forward, leaving a trail of water spray behind. Chasing closely behind is another Formula 1 car, painted entirely in a deep metallic green, with no other primary colors. This car bears the number "18", with the name "Alex" displayed on its body, also showcasing the "Quabu" sponsorship. The rain-soaked track glistens under the lights and sunset, while water splashes from the tires as the green car fights to close the gap. Both cars are locked in an intense battle as they navigate a sharp turn, their tires struggling for grip on the slippery asphalt. The red-and-black car, driven by "Roca", is slightly ahead, while the green car, driven by "Alex", is aggressively trying to overtake. The rain adds a dramatic element, with droplets streaking through the air and reflections shimmering on the wet surface. In the background, blurred grandstands full of cheering fans can be seen, their umbrellas raised as they watch the thrilling race unfold.
A young couple from the 1950s walking along the wide, asphalted streets of Vali Asr Street (formerly Pahlavi Street) in Tehran. The scene is set in the heart of the city, with the distinct architecture and atmosphere of the time. The girl, with voluminous, curly hair, cat-eye eyeliner, and red lipstick, wears a floral patterned dress with a wide collar and a flared skirt typical of the 1950s. The boy, with neatly styled hair and a thin mustache, wears a light-colored wide-collared suit with a shirt and thin tie. The couple walks hand in hand, surrounded by a few pedestrians. The street is wide and lined with tall plane trees, casting dappled shadows onto the asphalt. Streetlamps, situated near the edge of the sidewalk, illuminate the path. The classic Persian storefronts have minimal signage, some in traditional fonts. A few old cars from the era drive by, and a tram passes in the background. The atmosphere is lively but not crowded, with the gentle hum of the city in the air. Sunlight filters through the trees, casting a warm, golden glow over the scene. The camera angle is slightly from behind the couple, allowing the street to stretch ahead with the iconic trees and towering buildings of the time visible in the background, evoking the nostalgic charm of 1950s Tehran.
A young couple from the 1950s walking along the wide, asphalted streets of Vali Asr Street (formerly Pahlavi Street) in Tehran. The scene is set in the heart of the city, with the distinct architecture and atmosphere of the time. The girl, with voluminous, curly hair, cat-eye eyeliner, and red lipstick, wears a floral patterned dress with a wide collar and a flared skirt typical of the 1950s. The boy, with neatly styled hair and a thin mustache, wears a light-colored wide-collared suit with a shirt and thin tie. The couple walks hand in hand, surrounded by a few pedestrians. The street is wide and lined with tall plane trees, casting dappled shadows onto the asphalt. Streetlamps, situated near the edge of the sidewalk, illuminate the path. The classic Persian storefronts have minimal signage, some in traditional fonts. A Peykan car from the era is parked along the street, adding a nostalgic touch to the scene. A tram passes in the background, and a few old cars from the period drive by. The atmosphere is lively but not crowded, with the gentle hum of the city in the air. Sunlight filters through the trees, casting a warm, golden glow over the scene. The camera angle is slightly from behind the couple, allowing the street to stretch ahead with the iconic trees and towering buildings of the time visible in the background, evoking the nostalgic charm of 1950s Tehran.
A grotesquely obese, monstrous music industry executive stands in a dark, dystopian cityscape, his suit made of platinum records, his bloated belly hanging over his belt. His pants are half-down, revealing his obscene greed, while in front of him, a desperate indie hip-hop artist kneels, his expression filled with humiliation, pain, and frustration. His microphone dangles limply in his hand, his cracked 'wings of asphalt' barely holding him up. The industry giant smirks, holding a contract like a leash, tightening it around the rapper's neck. In the background, a carnival-like spectacle unfolds: faceless mainstream pop stars dance like puppets on strings, grotesque clowns with dollar-sign eyes throw fake awards into a roaring, soulless crowd. Neon billboards flash mindless slogans like 'STREAM OR DIE' and 'FAME FOR SALE.' The air is thick with smoke and despair, the city drowning in grey, the asphalt under the artist’s knees cracking under the weight of his broken dreams. The mood is dark, cold, and gritty—this is not a dream, but a nightmare of the music industry, where dignity is the price of exposure. --ar 16:9 --v 5.2 --style raw --q 2 --chaos 8 --stylize 900
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
The central subject is a nude woman viewed from the dorsal perspective, positioned vulnerably yet resolutely in the center of a war-torn urban thoroughfare. Her entire body is completely covered in meticulously applied United Nations flag body paint, featuring a light blue base with a white emblem depicting a world map projection encircled by olive branches conforming precisely to her anatomical contours, the pigments flowing across her spine, shoulders, and gluteal curves. Her physique exhibits precise anatomical clarity with realistic anthropometric proportions—a defined spinal column creating subtle shadows along the thoracic and lumbar regions, scapulae slightly prominent beneath dermal layers, and natural gluteal musculature forming the primary focal point with authentic adipose distribution and dermal tension. Her skin exhibits dermatological realism with visible pores, fine vellus hair along the erector spinae, and micro-blemishes of dust and particulate matter adhering to the epidermis over the painted surface. Ocular intricacy is suggested by the profile view of her face turned slightly toward the threat, showing detailed iris texture and moisture on the sclera. Her hair physics demonstrate follicle density with individual strands caught in the hot wind, creating dynamic motion against the static body. The clothing section manifests as an absence of textile, yet her form presents a figure-hugging silhouette defined purely by anatomical structure, with an open-back construction revealing the entire posterior chain from cervical to sacral regions, and a second-skin fit emphasizing the natural cinch at the waist and the curvature of the hips. Textural contrast emerges between her organic epidermal surface covered in flag pigments—showing sebaceous sheen of perspiration under thermal stress blending with the paint—and the surrounding abrasive urban environment. Wear and patina are evident in the form of road dust coating her plantar surfaces and lower extremities, suggesting prolonged exposure to the chaotic environment. Pose & Interaction: The Symmetrical Cleavage: Standing facing away with legs planted wide in a powerful, grounded stance. Both hands gripping the garment just below the gluteal fold, deliberately pulling the material downward and outward. The tension forces the fabric to bite sharply into the deepest centerline, outlining the sacred, hyper-rounded volume of the centerpiece. The atmosphere is thick with a raw, unspoken hospitality and a musky tension. Head tilted back, casting a haughty, "I know you want this" smirk, The composition employs a low-angle power perspective utilizing a Dutch angle of approximately 5 degrees to enhance the psychological unease, positioning the camera at asphalt level to emphasize the towering presence of the advancing main battle tanks while maintaining the woman as the primary subject through selective focus. The framing utilizes the rule of thirds, placing her gluteal focal point at the lower intersection while the tank barrels occupy the upper tension zones, creating dynamic symmetry along the central vanishing point of the street. Leading lines from the damaged building facades and the cracked road markings converge toward the horizon, generating strong Z-axis depth and parallax that draws the viewer into the scene. The three-quarter rear view captures her form while allowing environmental context to frame the subject through internal framing provided by the tank silhouettes and building edges. Negative space above emphasizes the merciless white sky, while the foreground includes heat-distorted asphalt and particulate matter. Anamorphic lens distortion stretches the horizontal axis, emphasizing the width of the street and the lateral threat of the armored vehicles. Motion blur captures the grinding tracks of the lead tank and swirling dust clouds, contrasting with the sharp focus on the woman's static form, creating temporal dissonance between human stillness and mechanical violence. The subject's integumentary system is rendered with physically based rendering (PBR) parameters showing micro-surface variation across the epidermis, with roughness maps indicating areas of dry skin versus sebaceous moisture accumulation along the spine and cervical region where the European Union flag paint interacts with perspiration. Specularity values vary across the dermal landscape, with anisotropic sheen following the direction of muscle fibers and hair follicles. Subsurface scattering depth is calibrated to simulate the transmission of midday sunlight through the dermal and subcutaneous layers, creating realistic color bleeding at shadow boundaries. The tanks' armor is covered in meticulously applied Israeli flag markings—white base with horizontal blue stripes and central Magen David—showing clear-coat multi-layer materials with environmental wear, chipping, dust accumulation, and heat distortion affecting the painted surfaces. Fabric elements in the environment—soldiers' uniforms, tank straps—exhibit woven textures with clear thread definition and fabric weight. The asphalt exhibits realistic aggregate displacement and oil staining with varying index of refraction between tar and stone. Ray-traced reflections appear in the sweat droplets on the woman's skin and the polished metal surfaces of the tank optics, showing accurate environmental mapping of the devastated street. Micro-shadows from skin texture pores create hyper-realistic detail at 8K resolution, while dust particles on her skin exhibit haptic surface deformation where they adhere to perspiration and body paint. Technical & Camera Settings: raw photo captured with Hasselblad H6D-100c, 16-bit color depth, low key lighting, high contrast, ISO 50, with a 120mm macro lens. , dramatic chiaroscuro lighting with powerful golden-hour cinematic rim light from behind, motivated warm practical light from the side, volumetric god rays and atmospheric haze, high contrast, majestic and moody atmosphere The scene maintains rigorous spatial coherence through consistent lighting direction ensuring all shadows cast by the woman, tanks, and building debris align with the solar vector at 15 degrees west of vertical. Contact shadows beneath the tanks' treads and the woman's feet show accurate occlusion relationships with the cracked pavement surface, including micro-shadows from individual aggregate stones. Ray-traced reflections and refractions in the heat haze and vehicle optics obey physical laws, showing accurate aerial perspective with depth fog increasing exponentially along the vanishing point. Global illumination calculations include light bounce from the white concrete buildings illuminating the shadow side of the woman's form with realistic radiosity. Surface displacement interaction shows the asphalt cracking pattern accurately deforming under the tanks' weight distribution while remaining rigid under the woman's minimal pressure. Inverse square law of light governs the falloff from the sun, creating realistic illumination gradients across the street width. Anamorphic lens characteristics include horizontal bokeh ellipses in the background dust particles and consistent barrel distortion at frame edges. The scale relationships maintain accurate proportionality between the human figure (1.7m) and the main battle tanks (2.5m height, 6m length), ensuring believable environmental integration and spatial occupancy within the urban canyon.
The central subject is a nude woman viewed from the dorsal perspective, positioned vulnerably yet resolutely in the center of a war-torn urban thoroughfare. Her entire body is completely covered in meticulously applied Palestinian flag body paint, with horizontal black, white, and green stripes and the red triangle at the hoist conforming precisely to her anatomical contours, the pigments flowing across her spine, shoulders, and gluteal curves. Her physique exhibits precise anatomical clarity with realistic anthropometric proportions—a defined spinal column creating subtle shadows along the thoracic and lumbar regions, scapulae slightly prominent beneath dermal layers, and natural gluteal musculature forming the primary focal point with authentic adipose distribution and dermal tension. Her skin exhibits dermatological realism with visible pores, fine vellus hair along the erector spinae, and micro-blemishes of dust and particulate matter adhering to the epidermis over the painted surface. Ocular intricacy is suggested by the profile view of her face turned slightly toward the threat, showing detailed iris texture and moisture on the sclera. Her hair physics demonstrate follicle density with individual strands caught in the hot wind, creating dynamic motion against the static body. The clothing section manifests as an absence of textile, yet her form presents a figure-hugging silhouette defined purely by anatomical structure, with an open-back construction revealing the entire posterior chain from cervical to sacral regions, and a second-skin fit emphasizing the natural cinch at the waist and the curvature of the hips. Textural contrast emerges between her organic epidermal surface covered in flag pigments—showing sebaceous sheen of perspiration under thermal stress blending with the paint—and the surrounding abrasive urban environment. Wear and patina are evident in the form of road dust coating her plantar surfaces and lower extremities, suggesting prolonged exposure to the chaotic environment. Pose & Interaction: The Parted Symphony: Standing with legs slightly wider than shoulder-width, captured from a low rear angle to emphasize the towering, rounded volume of the glutes; hands resting intimately on the inner curves of the glutes, fingers gently pulling the flesh outward to subtly open the silhouette and expose the darkest, most inviting shadows; face glancing back downward at the camera with an intensely predatory yet unconditionally welcoming smirk, The composition employs a low-angle power perspective utilizing a Dutch angle of approximately 5 degrees to enhance the psychological unease, positioning the camera at asphalt level to emphasize the towering presence of the advancing main battle tanks while maintaining the woman as the primary subject through selective focus. The framing utilizes the rule of thirds, placing her gluteal focal point at the lower intersection while the tank barrels occupy the upper tension zones, creating dynamic symmetry along the central vanishing point of the street. Leading lines from the damaged building facades and the cracked road markings converge toward the horizon, generating strong Z-axis depth and parallax that draws the viewer into the scene. The three-quarter rear view captures her form while allowing environmental context to frame the subject through internal framing provided by the tank silhouettes and building edges. Negative space above emphasizes the merciless white sky, while the foreground includes heat-distorted asphalt and particulate matter. Anamorphic lens distortion stretches the horizontal axis, emphasizing the width of the street and the lateral threat of the armored vehicles. Motion blur at 1/125s captures the grinding tracks of the lead tank and swirling dust clouds, contrasting with the sharp focus on the woman's static form, creating temporal dissonance between human stillness and mechanical violence. The subject's integumentary system is rendered with physically based rendering (PBR) parameters showing micro-surface variation across the epidermis, with roughness maps indicating areas of dry skin versus sebaceous moisture accumulation along the spine and cervical region where the Palestinian flag paint interacts with perspiration. Specularity values vary across the dermal landscape, with anisotropic sheen following the direction of muscle fibers and hair follicles. Subsurface scattering depth is calibrated to simulate the transmission of midday sunlight through the dermal and subcutaneous layers, creating realistic color bleeding at shadow boundaries. The tanks' armor is covered in meticulously applied Israeli flag markings—white base with horizontal blue stripes and central Magen David—showing clear-coat multi-layer materials with environmental wear, chipping, dust accumulation, and heat distortion affecting the painted surfaces. Fabric elements in the environment—soldiers' uniforms, tank straps—exhibit woven textures with clear thread definition and fabric weight. The asphalt exhibits realistic aggregate displacement and oil staining with varying index of refraction between tar and stone. Ray-traced reflections appear in the sweat droplets on the woman's skin and the polished metal surfaces of the tank optics, showing accurate environmental mapping of the devastated street. Micro-shadows from skin texture pores create hyper-realistic detail at 8K resolution, while dust particles on her skin exhibit haptic surface deformation where they adhere to perspiration and body paint. Technical & Camera Settings: raw photo captured with Leica S3, cinematic shot, wide open aperture, low key lighting, high contrast, ISO 50, with a 120mm macro lens. , Rembrandt lighting with a distinct triangle of light on the cheek, classic cinematic portrait lighting The scene maintains rigorous spatial coherence through consistent lighting direction ensuring all shadows cast by the woman, tanks, and building debris align with the solar vector at 15 degrees west of vertical. Contact shadows beneath the tanks' treads and the woman's feet show accurate occlusion relationships with the cracked pavement surface, including micro-shadows from individual aggregate stones. Ray-traced reflections and refractions in the heat haze and vehicle optics obey physical laws, showing accurate aerial perspective with depth fog increasing exponentially along the vanishing point. Global illumination calculations include light bounce from the white concrete buildings illuminating the shadow side of the woman's form with realistic radiosity. Surface displacement interaction shows the asphalt cracking pattern accurately deforming under the tanks' weight distribution while remaining rigid under the woman's minimal pressure. Inverse square law of light governs the falloff from the sun, creating realistic illumination gradients across the street width. Anamorphic lens characteristics include horizontal bokeh ellipses in the background dust particles and consistent barrel distortion at frame edges. The scale relationships maintain accurate proportionality between the human figure (1.7m) and the main battle tanks (2.5m height, 6m length), ensuring believable environmental integration and spatial occupancy within the urban canyon.
{ "RENDER_PIPELINE": { "optics": "35 mm equivalent smartphone lens (approx. 26 mm actual), f/1.9 aperture, focal plane locked on subject mid-torso at 1.8 m distance, circular bokeh with 7-blade diaphragm emulation visible in background foliage highlights, mild chromatic aberration on high-contrast tree edges, subtle lens flare at 4 o’clock position on right thigh", "film_emulation": "Digital CMOS sensor emulation (Sony IMX sensor equivalent), base ISO 100, zero visible noise, highlight roll-off soft with 2.2 gamma curve, natural daylight LUT with slight teal-orange grading in shadows, 8-bit sRGB output", "atmospherics": "Clear morning air (08:27 timestamp visible top-left), micro-dust particles suspended in volumetric god rays piercing canopy, fog density 0 %, light atmospheric perspective softening distant tree line" }, "LIGHTING_RIG": { "key_light": "Natural sunlight filtered through deciduous canopy, correlated color temperature 5800 K, incident angle 65° from upper camera-right, soft shadow edge transfer (penumbra ~8 cm on asphalt), no hard specular hotspots", "fill_light": "Diffuse sky bounce from open canopy gaps, fill ratio 1:2.5 relative to key, neutral 6500 K, no directional bias", "rim_hair_lights": "Strong rim from rear-right sunlight at 110° azimuth, 6200 K, creating 3 mm wide highlight halo along hair edges and left shoulder contour", "ambient_occlusion": "Deep micro-shadows in skin folds (under buttock crease, inner thigh contact, under bandeau hem), contact occlusion between fingers and face, skirt fabric and gluteal skin" }, "SUBJECT_BIOMETRICS_AND_TOPOLOGY": { "demographics": "Female, visually 19–22 years old, Eastern-European/Slavic phenotype (light Caucasian admixture), ecto-mesomorphic skeletal frame, visual BMI equivalent ~21, long-limbed proportions, pronounced lower-body adiposity with athletic muscle tone", "facial_geometry": "Oval face shape (partially occluded by right hand), high zygomatic prominence (cheekbones projecting 12 mm anteriorly), sharp mandibular angle with defined gonial flare, moderate chin projection (5 mm beyond subnasale vertical), smooth forehead", "nasal_and_ocular_structure": "Nose: straight dorsum with refined supra-tip break, narrow alar base (28 mm width), slightly upturned apex; eyes fully occluded by hand but visible orbital rim suggests almond shape with neutral canthal tilt (~0°), visible lower lash line and tear duct", "aura": "Playful-teasing confidence, deliberate erotic provocation through partial exposure, youthful carefree energy" }, "MICRO_ANATOMY_AND_SHADERS": { "epidermis": "Pore density low (fine on nose bridge, invisible on thighs), uniform light olive-tan tone, zero visible freckles or scars, subtle goosebumps on exposed upper arms from morning air", "dermis_and_vascular": "Subdermal veins faintly visible on inner forearms and dorsal hands (blue-green, 0.3 mm width), no capillary flush except faint pink undertone on cheeks and gluteal skin", "subsurface_scattering": "High SSS on earlobes, nasal tip, and exposed gluteal hemispheres (warm #FFCCAA transmission), moderate on inner thighs where light wraps around fabric edge", "surface_moisture": "Matte skin finish overall, trace sebum sheen on nasal bridge and forehead, single 0.5 mm sweat droplet at left temple hairline, no visible tears", "vellus_hair": "Fine peach-fuzz density on upper arms and outer thighs (0.1 mm length, catching rim light as golden halo)" }, "FACS_AND_MICRO_EXPRESSIONS": { "eyes": "Gaze vector fully occluded by right hand (fingers covering orbits and nasal bridge), inferred forward camera direction, pupil dilation unknown", "brows": "Right brow slightly arched (2 mm superior displacement at lateral tail), micro-tension indicating playful concealment", "mouth": "Lip parting 2 mm at center, upper lip slightly everted, lower lip full and glossy with natural mucosal moisture, teeth not visible, masseter relaxed" }, "HAIR_PHYSICS_AND_GROOMING": { "structure": "Level 6–7 golden-light-brown melanin base, root-to-tip uniform color with subtle sun-bleached highlights, high density (120–140 strands/cm²), individual strand thickness 0.08 mm", "physics": "Gravity-induced cascade over left shoulder and back, gentle S-curve from wind or movement, 18 visible flyaways along crown and right side illuminated by rim light", "styling": "Center-parted, loose natural fall to mid-back length (approx. 65 cm), no visible product stiffness" }, "MAKEUP_AND_BODY_MODS": { "cosmetics": "Natural matte foundation (skin-matched #F5D9C8), soft brown brow pencil, black winged eyeliner on visible lower lash line, nude-pink lip tint, glossy clear topcoat on nails (#FFFFFF with 80 % gloss specular)", "tattoos": "None visible on exposed skin surfaces", "piercings": "None visible" }, "BIOMECHANICS_AND_KINEMATICS": { "spine_pelvis": "Mild lumbar lordosis (approx. 28°), anterior pelvic tilt 12°, creating pronounced gluteal projection", "limbs": "Right shoulder abducted 85°, elbow flexed 110° (hand covering face); left shoulder abducted 35°, elbow flexed 70° (hand on hip); hips rotated 35° camera-left; right knee extended 175°, left knee flexed 165° with weight shifted to left leg; ankles dorsiflexed 10°", "digits": "Right hand: fingers 2–5 extended and slightly spread (covering eyes/nose, 4 mm gaps), thumb tucked under chin, 0.8 kg pressure on face; left hand: fingers 2–5 spread across left gluteal quadrant, thumb on iliac crest, nails pressing 0.3 kg into fabric/skin; all fingernails 12 mm length, square-oval shape" }, "CLOTH_SIMULATION_AND_PHYSICS": { "layer_1_strapless_bandeau_top": { "material": "Matte cotton-elastane jersey, 220 GSM, 4-way stretch, 80 denier opacity", "opacity_map": "100 % opaque on breasts, slight shear at underbust hem revealing 2 mm skin shadow", "tension_physics": "Horizontal stretch lines radiating from side seams under breast weight, 3 mm fabric roll at top edge", "skin_interaction": "Mild skin compression (1 mm indentation) at underbust, no visible nipple protrusion through fabric" }, "layer_2_mini_skirt": { "material": "Lightweight cotton twill, 180 GSM, flared A-line cut with ruffled hem, 60 denier", "opacity_map": "98 % opaque where settled, 0 % where lifted exposing gluteal skin", "tension_physics": "Radial stress wrinkles from left hand grip point, fabric bunching upward 8 cm above natural waist creating exposed lower gluteal crescent", "skin_interaction": "Skirt hem digging 2 mm into upper thigh fat creating soft muffin-top shelf, direct skin-to-fabric contact on right glute with visible fabric lift shadow" }, "layer_3_crew_socks": { "material": "Ribbed cotton, 280 GSM, mid-calf height", "opacity_map": "100 % opaque", "tension_physics": "Slight bunching at ankle fold (3 mm accordion effect)", "skin_interaction": "Mild calf compression creating 1 mm skin bulge above sock cuff" }, "layer_4_chunky_sneakers": { "material": "Synthetic leather upper with rubber sole, 40 mm platform, white laces tied in bow", "opacity_map": "100 % opaque", "tension_physics": "Laces under moderate tension, no creasing on toe box", "skin_interaction": "Sock fabric compressed 2 mm between ankle bone and shoe collar" } }, "SOFT_TISSUE_PHYSICS": { "gravity_impact": "Gluteal hemispheres (right more prominent) hanging 18 mm below natural skirt line due to fabric lift, creating rounded lower pole projection; upper thigh soft tissue slightly dimpled against left leg weight shift", "compression": "Left gluteal flesh compressed 4 mm against left hand palm, mild skin bulging between fingers; right thigh soft tissue flattened 3 mm where skirt hem presses" }, "ENVIRONMENT_AND_PROPS": { "contact_surfaces": "Cracked asphalt pavement (Ra roughness 1.2 mm), dark grey with moss in fissures; subject weight distributed 65 % left foot, 35 % right foot causing 0.5 mm sole compression", "depth_of_field": "Subject sharp from toes to hair tips, background trees blurred starting 4 m behind (bokeh circles 25–40 px diameter on highlights)" } }
the ground slopes downward, leading to a vertical asphalt street, the dark asphalt appears frosty, reflecting the dim glow of streetlights in the icy air, beyond the street, rugged mountain hills, their peaks dusted with a faint shimmer of snow, layered silhouettes of the mountains create depth, fading into the midnight horizon, scattered trees in the foreground reach upward, their branches stiff from the biting cold, the sky is cloudless, a deep midnight blue, punctuated by the distant twinkle of stars, moonlight spills onto the asphalt, creating pale silvery reflections in the cold air, soft shadows stretch beneath the trees, nature and roadways intertwine, forming a striking balance under the night sky,
Wet asphalt road, autumnal perspective. Yellow lane lines on a dark, wet road, reflecting the surrounding foliage. Dense forest lines the road, with vibrant, golden-orange and muted green trees. Fallen autumn leaves, some oak leaves, litter the road. Water puddles reflect the trees and sky. Low angle, close-up perspective focuses on the road's texture and the details of the yellow lines. Moody, serene autumnal atmosphere. Muted tones of gray, dark brown, deep orange, and muted yellow. The lighting is soft, diffused, characteristic of an overcast day. Road texture is visible, showing wetness and the slight imperfections of the asphalt. Yellow lane markers are prominent, with some visible wear and tear. Natural, organic, and detailed image. Photorealistic, artistic autumnal view.
A young couple from the 1950s walking along the wide, asphalted streets of Vali Asr Street (formerly Pahlavi Street) in Tehran. The scene is set in the heart of the city, with the distinct architecture and atmosphere of the time. The girl, with voluminous, curly hair, cat-eye eyeliner, and red lipstick, wears a floral patterned dress with a wide collar and a flared skirt typical of the 1950s. The boy, with neatly styled hair and a thin mustache, wears a light-colored wide-collared suit with a shirt and thin tie. The couple walks hand in hand, surrounded by a few pedestrians. The street is wide and lined with tall plane trees, casting dappled shadows onto the asphalt. Streetlamps, situated near the edge of the sidewalk, illuminate the path. The classic Persian storefronts have minimal signage, some in traditional fonts. A Peykan car from the era is parked along the street, adding a nostalgic touch to the scene. A tram passes in the background, and a few old cars from the period drive by. The atmosphere is lively but not crowded, with the gentle hum of the city in the air. Sunlight filters through the trees, casting a warm, golden glow over the scene. The camera angle is slightly from behind the couple, allowing the street to stretch ahead with the iconic trees and towering buildings of the time visible in the background, evoking the nostalgic charm of 1950s Tehran.
A grotesquely obese, monstrous music industry executive stands in a dark, dystopian cityscape, his suit made of platinum records, his bloated belly hanging over his belt. His pants are half-down, revealing his obscene greed, while in front of him, a desperate indie hip-hop artist kneels, his expression filled with humiliation, pain, and frustration. His microphone dangles limply in his hand, his cracked 'wings of asphalt' barely holding him up. The industry giant smirks, holding a contract like a leash, tightening it around the rapper's neck. In the background, a carnival-like spectacle unfolds: faceless mainstream pop stars dance like puppets on strings, grotesque clowns with dollar-sign eyes throw fake awards into a roaring, soulless crowd. Neon billboards flash mindless slogans like 'STREAM OR DIE' and 'FAME FOR SALE.' The air is thick with smoke and despair, the city drowning in grey, the asphalt under the artist’s knees cracking under the weight of his broken dreams. The mood is dark, cold, and gritty—this is not a dream, but a nightmare of the music industry, where dignity is the price of exposure. --ar 16:9 --v 5.2 --style raw --q 2 --chaos 8 --stylize 900
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
The central subject is a nude woman viewed from the dorsal perspective, positioned vulnerably yet resolutely in the center of a war-torn urban thoroughfare. Her entire body is completely covered in meticulously applied United Nations flag body paint, featuring a light blue base with a white emblem depicting a world map projection encircled by olive branches conforming precisely to her anatomical contours, the pigments flowing across her spine, shoulders, and gluteal curves. Her physique exhibits precise anatomical clarity with realistic anthropometric proportions—a defined spinal column creating subtle shadows along the thoracic and lumbar regions, scapulae slightly prominent beneath dermal layers, and natural gluteal musculature forming the primary focal point with authentic adipose distribution and dermal tension. Her skin exhibits dermatological realism with visible pores, fine vellus hair along the erector spinae, and micro-blemishes of dust and particulate matter adhering to the epidermis over the painted surface. Ocular intricacy is suggested by the profile view of her face turned slightly toward the threat, showing detailed iris texture and moisture on the sclera. Her hair physics demonstrate follicle density with individual strands caught in the hot wind, creating dynamic motion against the static body. The clothing section manifests as an absence of textile, yet her form presents a figure-hugging silhouette defined purely by anatomical structure, with an open-back construction revealing the entire posterior chain from cervical to sacral regions, and a second-skin fit emphasizing the natural cinch at the waist and the curvature of the hips. Textural contrast emerges between her organic epidermal surface covered in flag pigments—showing sebaceous sheen of perspiration under thermal stress blending with the paint—and the surrounding abrasive urban environment. Wear and patina are evident in the form of road dust coating her plantar surfaces and lower extremities, suggesting prolonged exposure to the chaotic environment. Pose & Interaction: The Symmetrical Cleavage: Standing facing away with legs planted wide in a powerful, grounded stance. Both hands gripping the garment just below the gluteal fold, deliberately pulling the material downward and outward. The tension forces the fabric to bite sharply into the deepest centerline, outlining the sacred, hyper-rounded volume of the centerpiece. The atmosphere is thick with a raw, unspoken hospitality and a musky tension. Head tilted back, casting a haughty, "I know you want this" smirk, The composition employs a low-angle power perspective utilizing a Dutch angle of approximately 5 degrees to enhance the psychological unease, positioning the camera at asphalt level to emphasize the towering presence of the advancing main battle tanks while maintaining the woman as the primary subject through selective focus. The framing utilizes the rule of thirds, placing her gluteal focal point at the lower intersection while the tank barrels occupy the upper tension zones, creating dynamic symmetry along the central vanishing point of the street. Leading lines from the damaged building facades and the cracked road markings converge toward the horizon, generating strong Z-axis depth and parallax that draws the viewer into the scene. The three-quarter rear view captures her form while allowing environmental context to frame the subject through internal framing provided by the tank silhouettes and building edges. Negative space above emphasizes the merciless white sky, while the foreground includes heat-distorted asphalt and particulate matter. Anamorphic lens distortion stretches the horizontal axis, emphasizing the width of the street and the lateral threat of the armored vehicles. Motion blur captures the grinding tracks of the lead tank and swirling dust clouds, contrasting with the sharp focus on the woman's static form, creating temporal dissonance between human stillness and mechanical violence. The subject's integumentary system is rendered with physically based rendering (PBR) parameters showing micro-surface variation across the epidermis, with roughness maps indicating areas of dry skin versus sebaceous moisture accumulation along the spine and cervical region where the European Union flag paint interacts with perspiration. Specularity values vary across the dermal landscape, with anisotropic sheen following the direction of muscle fibers and hair follicles. Subsurface scattering depth is calibrated to simulate the transmission of midday sunlight through the dermal and subcutaneous layers, creating realistic color bleeding at shadow boundaries. The tanks' armor is covered in meticulously applied Israeli flag markings—white base with horizontal blue stripes and central Magen David—showing clear-coat multi-layer materials with environmental wear, chipping, dust accumulation, and heat distortion affecting the painted surfaces. Fabric elements in the environment—soldiers' uniforms, tank straps—exhibit woven textures with clear thread definition and fabric weight. The asphalt exhibits realistic aggregate displacement and oil staining with varying index of refraction between tar and stone. Ray-traced reflections appear in the sweat droplets on the woman's skin and the polished metal surfaces of the tank optics, showing accurate environmental mapping of the devastated street. Micro-shadows from skin texture pores create hyper-realistic detail at 8K resolution, while dust particles on her skin exhibit haptic surface deformation where they adhere to perspiration and body paint. Technical & Camera Settings: raw photo captured with Hasselblad H6D-100c, 16-bit color depth, low key lighting, high contrast, ISO 50, with a 120mm macro lens. , dramatic chiaroscuro lighting with powerful golden-hour cinematic rim light from behind, motivated warm practical light from the side, volumetric god rays and atmospheric haze, high contrast, majestic and moody atmosphere The scene maintains rigorous spatial coherence through consistent lighting direction ensuring all shadows cast by the woman, tanks, and building debris align with the solar vector at 15 degrees west of vertical. Contact shadows beneath the tanks' treads and the woman's feet show accurate occlusion relationships with the cracked pavement surface, including micro-shadows from individual aggregate stones. Ray-traced reflections and refractions in the heat haze and vehicle optics obey physical laws, showing accurate aerial perspective with depth fog increasing exponentially along the vanishing point. Global illumination calculations include light bounce from the white concrete buildings illuminating the shadow side of the woman's form with realistic radiosity. Surface displacement interaction shows the asphalt cracking pattern accurately deforming under the tanks' weight distribution while remaining rigid under the woman's minimal pressure. Inverse square law of light governs the falloff from the sun, creating realistic illumination gradients across the street width. Anamorphic lens characteristics include horizontal bokeh ellipses in the background dust particles and consistent barrel distortion at frame edges. The scale relationships maintain accurate proportionality between the human figure (1.7m) and the main battle tanks (2.5m height, 6m length), ensuring believable environmental integration and spatial occupancy within the urban canyon.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
A detailed, photorealistic, cinematic vertical medium-full shot of an attractive young East Asian woman sitting on a wet, rain-slicked street at night during a heavy rainstorm. Shot Angle & Pose: Captured from a slightly high eye-level perspective looking down. The subject is sitting directly on the wet asphalt, her knees drawn up toward her chest in a huddled posture. Her left hand rests on her wet hair, while her right arm drapes casually over her leg. She looks directly into the lens with a calm, pensive, and vulnerable expression, her lips slightly parted. Subject Appearance: She has a flawless, porcelain complexion with a detailed wet skin texture, covered in water droplets. Her jet-black hair is completely wet and messy, clinging to her face and shoulders in damp strands. Her facial features are delicate, characterized by large expressive dark eyes, subtle dark eyeshadow, and soft, natural coral-pink lips. Character Figure: She possesses a slender and athletic hourglass figure. Her physique is characterized by an exceptionally slender waist and long, shapely, toned legs. Her curvaceous silhouette is highlighted by her seated, huddled posture and the semi-translucent nature of her wet clothing. Outfit Details: She is wearing a casual, minimalist "wet-look" ensemble: Shirt: An oversized, long-sleeved white button-down shirt. The cotton fabric is completely saturated with rainwater, making it semi-translucent and causing it to cling tightly to her torso and arms. Bottoms: Simple, form-fitting black shorts or panties. Setting & Lighting: Setting: A dark, moody street or alleyway at night in the pouring rain. The ground is a wet, reflective asphalt road. In the background on the left, a car’s headlights are turned on, casting a bright white flare. On the right, blurred, cool-blue fluorescent street lights are visible in soft focus under a covered structure. Lighting: Cool-toned, high-contrast night lighting. The powerful light from the car headlights and streetlights creates brilliant highlights on her wet skin, her hair, and her translucent wet white shirt. The wet asphalt creates sharp, detailed reflections of the lights, with the rest of the scene falling into deep, dark blue shadows. 8k resolution, raw photo aesthetic, wet look, pouring rain, car headlights, wet asphalt reflections, white button-down shirt, sharp focus on the subject, high-fidelity texture rendering, blue and white color palette, cinematic composition, hyper-realistic skin and wet fabric textures.
A young couple from the 1950s walking along the wide, asphalted streets of Vali Asr Street (formerly Pahlavi Street) in Tehran. The scene is set in the heart of the city, with the distinct architecture and atmosphere of the time. The girl, with voluminous, curly hair, cat-eye eyeliner, and red lipstick, wears a floral patterned dress with a wide collar and a flared skirt typical of the 1950s. The boy, with neatly styled hair and a thin mustache, wears a light-colored wide-collared suit with a shirt and thin tie. The couple walks hand in hand, surrounded by a few pedestrians. The street is wide and lined with tall plane trees, casting dappled shadows onto the asphalt. Streetlamps, situated near the edge of the sidewalk, illuminate the path. The classic Persian storefronts have minimal signage, some in traditional fonts. A few old cars from the era drive by, and a tram passes in the background. The atmosphere is lively but not crowded, with the gentle hum of the city in the air. Sunlight filters through the trees, casting a warm, golden glow over the scene. The camera angle is slightly from behind the couple, allowing the street to stretch ahead with the iconic trees and towering buildings of the time visible in the background, evoking the nostalgic charm of 1950s Tehran.
The character and environment in Figure 1 remain unchanged - High motion, fast movement, extreme dynamic effect. FPV first‑person follow‑cam, always close to the ground, moving up and down synchronously. A handsome boy with long flowing hair wearing a skirt performs high‑difficulty skateboarding tricks on an empty city street at night. 0-2s: Sprints down a slope at 80km/h, low center of gravity, hair and skirt blown back by strong wind. 2-4s: Enters a sharp turn, executes a tailbrake drift – rubber wheels scrape asphalt, sending out bright sparks. 4-6s: Kickflip into a 180° mid‑air spin, the skateboard rotating 360° precisely under his feet. 6-10s: Explodes out of the turn, leaps into a 360° grab, body fully extended, landing smoothly without wobble. Late‑night city background. Wet asphalt reflects mixed neon and warm yellow streetlight. Blurred car headlights in the distance, dark building outlines on both sides. Deep navy sky with a few sparse stars. Cool neon mixed with warm streetlight creates sharp reflections on the skateboard’s metal trucks and wheels. A clear black silhouette of the boy is cast on the ground. Strong motion blur and speed lines. High‑detail 3D anime style, cinematic lighting, 8K resolution.
A high-resolution, dynamic photograph of a single 500ml sleek aluminum beverage can (matte finish, black body). The can rests diagonally on a wet asphalt surface at night. Neon signs of a city street are blurred in the background, creating strong, vibrant reflections on the wet asphalt and the can itself. **BRAND DETAILS (CRITICAL):** * **Brand Logo:** Small, white, and centered at the top of the can. * **Primary Color:** The can's text and graphic accents must use a bright **electric lime green (Hex: #90EE90)**. * **Call to Action Text:** Clearly readable text on the lower third of the can must state: **"MAX BOOST FORMULA"** in a bold, stylized, sans-serif font. * **Effect:** Add heavy, visible condensation on the can, suggesting extreme cold. **LIGHTING & STYLE:** Cinematic, moody, highly saturated neon lighting, sharp focus on the can, deep depth of field (shallow background blur). Perfect for a social media ad.
A dramatic Formula 1 race is taking place on a professional circuit under heavy rain during a breathtaking sunset. Dark storm clouds mix with the warm shades of orange, pink, and purple in the sky, creating a striking contrast. Raindrops fall heavily, bouncing off the track and the sleek bodies of the cars, while water sprays behind them as they speed through the wet asphalt. In the lead is a Formula 1 car with a bold 60% red and 40% black color scheme, featuring an aerodynamic design. The number "11" is clearly displayed, and the name "Roca" is written on its body. Its main sponsor, "Quabu", is prominently featured on the car’s livery. The wet surface reflects the car’s colors as it pushes forward, leaving a trail of water spray behind. Chasing closely behind is another Formula 1 car, painted entirely in a deep metallic green, with no other primary colors. This car bears the number "18", with the name "Alex" displayed on its body, also showcasing the "Quabu" sponsorship. The rain-soaked track glistens under the lights and sunset, while water splashes from the tires as the green car fights to close the gap. Both cars are locked in an intense battle as they navigate a sharp turn, their tires struggling for grip on the slippery asphalt. The red-and-black car, driven by "Roca", is slightly ahead, while the green car, driven by "Alex", is aggressively trying to overtake. The rain adds a dramatic element, with droplets streaking through the air and reflections shimmering on the wet surface. In the background, blurred grandstands full of cheering fans can be seen, their umbrellas raised as they watch the thrilling race unfold.
A young couple from the 1950s walking along the wide, asphalted streets of Vali Asr Street (formerly Pahlavi Street) in Tehran. The scene is set in the heart of the city, with the distinct architecture and atmosphere of the time. The girl, with voluminous, curly hair, cat-eye eyeliner, and red lipstick, wears a floral patterned dress with a wide collar and a flared skirt typical of the 1950s. The boy, with neatly styled hair and a thin mustache, wears a light-colored wide-collared suit with a shirt and thin tie. The couple walks hand in hand, surrounded by a few pedestrians. The street is wide and lined with tall plane trees, casting dappled shadows onto the asphalt. Streetlamps, situated near the edge of the sidewalk, illuminate the path. The classic Persian storefronts have minimal signage, some in traditional fonts. A few old cars from the era drive by, and a tram passes in the background. The atmosphere is lively but not crowded, with the gentle hum of the city in the air. Sunlight filters through the trees, casting a warm, golden glow over the scene. The camera angle is slightly from behind the couple, allowing the street to stretch ahead with the iconic trees and towering buildings of the time visible in the background, evoking the nostalgic charm of 1950s Tehran.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
The central subject is a nude woman viewed from the dorsal perspective, positioned vulnerably yet resolutely in the center of a war-torn urban thoroughfare. Her entire body is completely covered in meticulously applied United Nations flag body paint, featuring a light blue base with a white emblem depicting a world map projection encircled by olive branches conforming precisely to her anatomical contours, the pigments flowing across her spine, shoulders, and gluteal curves. Her physique exhibits precise anatomical clarity with realistic anthropometric proportions—a defined spinal column creating subtle shadows along the thoracic and lumbar regions, scapulae slightly prominent beneath dermal layers, and natural gluteal musculature forming the primary focal point with authentic adipose distribution and dermal tension. Her skin exhibits dermatological realism with visible pores, fine vellus hair along the erector spinae, and micro-blemishes of dust and particulate matter adhering to the epidermis over the painted surface. Ocular intricacy is suggested by the profile view of her face turned slightly toward the threat, showing detailed iris texture and moisture on the sclera. Her hair physics demonstrate follicle density with individual strands caught in the hot wind, creating dynamic motion against the static body. The clothing section manifests as an absence of textile, yet her form presents a figure-hugging silhouette defined purely by anatomical structure, with an open-back construction revealing the entire posterior chain from cervical to sacral regions, and a second-skin fit emphasizing the natural cinch at the waist and the curvature of the hips. Textural contrast emerges between her organic epidermal surface covered in flag pigments—showing sebaceous sheen of perspiration under thermal stress blending with the paint—and the surrounding abrasive urban environment. Wear and patina are evident in the form of road dust coating her plantar surfaces and lower extremities, suggesting prolonged exposure to the chaotic environment. Pose & Interaction: The Symmetrical Cleavage: Standing facing away with legs planted wide in a powerful, grounded stance. Both hands gripping the garment just below the gluteal fold, deliberately pulling the material downward and outward. The tension forces the fabric to bite sharply into the deepest centerline, outlining the sacred, hyper-rounded volume of the centerpiece. The atmosphere is thick with a raw, unspoken hospitality and a musky tension. Head tilted back, casting a haughty, "I know you want this" smirk, The composition employs a low-angle power perspective utilizing a Dutch angle of approximately 5 degrees to enhance the psychological unease, positioning the camera at asphalt level to emphasize the towering presence of the advancing main battle tanks while maintaining the woman as the primary subject through selective focus. The framing utilizes the rule of thirds, placing her gluteal focal point at the lower intersection while the tank barrels occupy the upper tension zones, creating dynamic symmetry along the central vanishing point of the street. Leading lines from the damaged building facades and the cracked road markings converge toward the horizon, generating strong Z-axis depth and parallax that draws the viewer into the scene. The three-quarter rear view captures her form while allowing environmental context to frame the subject through internal framing provided by the tank silhouettes and building edges. Negative space above emphasizes the merciless white sky, while the foreground includes heat-distorted asphalt and particulate matter. Anamorphic lens distortion stretches the horizontal axis, emphasizing the width of the street and the lateral threat of the armored vehicles. Motion blur captures the grinding tracks of the lead tank and swirling dust clouds, contrasting with the sharp focus on the woman's static form, creating temporal dissonance between human stillness and mechanical violence. The subject's integumentary system is rendered with physically based rendering (PBR) parameters showing micro-surface variation across the epidermis, with roughness maps indicating areas of dry skin versus sebaceous moisture accumulation along the spine and cervical region where the European Union flag paint interacts with perspiration. Specularity values vary across the dermal landscape, with anisotropic sheen following the direction of muscle fibers and hair follicles. Subsurface scattering depth is calibrated to simulate the transmission of midday sunlight through the dermal and subcutaneous layers, creating realistic color bleeding at shadow boundaries. The tanks' armor is covered in meticulously applied Israeli flag markings—white base with horizontal blue stripes and central Magen David—showing clear-coat multi-layer materials with environmental wear, chipping, dust accumulation, and heat distortion affecting the painted surfaces. Fabric elements in the environment—soldiers' uniforms, tank straps—exhibit woven textures with clear thread definition and fabric weight. The asphalt exhibits realistic aggregate displacement and oil staining with varying index of refraction between tar and stone. Ray-traced reflections appear in the sweat droplets on the woman's skin and the polished metal surfaces of the tank optics, showing accurate environmental mapping of the devastated street. Micro-shadows from skin texture pores create hyper-realistic detail at 8K resolution, while dust particles on her skin exhibit haptic surface deformation where they adhere to perspiration and body paint. Technical & Camera Settings: raw photo captured with Hasselblad H6D-100c, 16-bit color depth, low key lighting, high contrast, ISO 50, with a 120mm macro lens. , dramatic chiaroscuro lighting with powerful golden-hour cinematic rim light from behind, motivated warm practical light from the side, volumetric god rays and atmospheric haze, high contrast, majestic and moody atmosphere The scene maintains rigorous spatial coherence through consistent lighting direction ensuring all shadows cast by the woman, tanks, and building debris align with the solar vector at 15 degrees west of vertical. Contact shadows beneath the tanks' treads and the woman's feet show accurate occlusion relationships with the cracked pavement surface, including micro-shadows from individual aggregate stones. Ray-traced reflections and refractions in the heat haze and vehicle optics obey physical laws, showing accurate aerial perspective with depth fog increasing exponentially along the vanishing point. Global illumination calculations include light bounce from the white concrete buildings illuminating the shadow side of the woman's form with realistic radiosity. Surface displacement interaction shows the asphalt cracking pattern accurately deforming under the tanks' weight distribution while remaining rigid under the woman's minimal pressure. Inverse square law of light governs the falloff from the sun, creating realistic illumination gradients across the street width. Anamorphic lens characteristics include horizontal bokeh ellipses in the background dust particles and consistent barrel distortion at frame edges. The scale relationships maintain accurate proportionality between the human figure (1.7m) and the main battle tanks (2.5m height, 6m length), ensuring believable environmental integration and spatial occupancy within the urban canyon.
A detailed, photorealistic, cinematic vertical medium-full shot of an attractive young East Asian woman sitting on a wet, rain-slicked street at night during a heavy rainstorm. Shot Angle & Pose: Captured from a slightly high eye-level perspective looking down. The subject is sitting directly on the wet asphalt, her knees drawn up toward her chest in a huddled posture. Her left hand rests on her wet hair, while her right arm drapes casually over her leg. She looks directly into the lens with a calm, pensive, and vulnerable expression, her lips slightly parted. Subject Appearance: She has a flawless, porcelain complexion with a detailed wet skin texture, covered in water droplets. Her jet-black hair is completely wet and messy, clinging to her face and shoulders in damp strands. Her facial features are delicate, characterized by large expressive dark eyes, subtle dark eyeshadow, and soft, natural coral-pink lips. Character Figure: She possesses a slender and athletic hourglass figure. Her physique is characterized by an exceptionally slender waist and long, shapely, toned legs. Her curvaceous silhouette is highlighted by her seated, huddled posture and the semi-translucent nature of her wet clothing. Outfit Details: She is wearing a casual, minimalist "wet-look" ensemble: Shirt: An oversized, long-sleeved white button-down shirt. The cotton fabric is completely saturated with rainwater, making it semi-translucent and causing it to cling tightly to her torso and arms. Bottoms: Simple, form-fitting black shorts or panties. Setting & Lighting: Setting: A dark, moody street or alleyway at night in the pouring rain. The ground is a wet, reflective asphalt road. In the background on the left, a car’s headlights are turned on, casting a bright white flare. On the right, blurred, cool-blue fluorescent street lights are visible in soft focus under a covered structure. Lighting: Cool-toned, high-contrast night lighting. The powerful light from the car headlights and streetlights creates brilliant highlights on her wet skin, her hair, and her translucent wet white shirt. The wet asphalt creates sharp, detailed reflections of the lights, with the rest of the scene falling into deep, dark blue shadows. 8k resolution, raw photo aesthetic, wet look, pouring rain, car headlights, wet asphalt reflections, white button-down shirt, sharp focus on the subject, high-fidelity texture rendering, blue and white color palette, cinematic composition, hyper-realistic skin and wet fabric textures.
A young couple from the 1950s walking along the wide, asphalted streets of Vali Asr Street (formerly Pahlavi Street) in Tehran. The scene is set in the heart of the city, with the distinct architecture and atmosphere of the time. The girl, with voluminous, curly hair, cat-eye eyeliner, and red lipstick, wears a floral patterned dress with a wide collar and a flared skirt typical of the 1950s. The boy, with neatly styled hair and a thin mustache, wears a light-colored wide-collared suit with a shirt and thin tie. The couple walks hand in hand, surrounded by a few pedestrians. The street is wide and lined with tall plane trees, casting dappled shadows onto the asphalt. Streetlamps, situated near the edge of the sidewalk, illuminate the path. The classic Persian storefronts have minimal signage, some in traditional fonts. A few old cars from the era drive by, and a tram passes in the background. The atmosphere is lively but not crowded, with the gentle hum of the city in the air. Sunlight filters through the trees, casting a warm, golden glow over the scene. The camera angle is slightly from behind the couple, allowing the street to stretch ahead with the iconic trees and towering buildings of the time visible in the background, evoking the nostalgic charm of 1950s Tehran.
A high-resolution, dynamic photograph of a single 500ml sleek aluminum beverage can (matte finish, black body). The can rests diagonally on a wet asphalt surface at night. Neon signs of a city street are blurred in the background, creating strong, vibrant reflections on the wet asphalt and the can itself. **BRAND DETAILS (CRITICAL):** * **Brand Logo:** Small, white, and centered at the top of the can. * **Primary Color:** The can's text and graphic accents must use a bright **electric lime green (Hex: #90EE90)**. * **Call to Action Text:** Clearly readable text on the lower third of the can must state: **"MAX BOOST FORMULA"** in a bold, stylized, sans-serif font. * **Effect:** Add heavy, visible condensation on the can, suggesting extreme cold. **LIGHTING & STYLE:** Cinematic, moody, highly saturated neon lighting, sharp focus on the can, deep depth of field (shallow background blur). Perfect for a social media ad.
A young couple from the 1950s walking along the wide, asphalted streets of Vali Asr Street (formerly Pahlavi Street) in Tehran. The scene is set in the heart of the city, with the distinct architecture and atmosphere of the time. The girl, with voluminous, curly hair, cat-eye eyeliner, and red lipstick, wears a floral patterned dress with a wide collar and a flared skirt typical of the 1950s. The boy, with neatly styled hair and a thin mustache, wears a light-colored wide-collared suit with a shirt and thin tie. The couple walks hand in hand, surrounded by a few pedestrians. The street is wide and lined with tall plane trees, casting dappled shadows onto the asphalt. Streetlamps, situated near the edge of the sidewalk, illuminate the path. The classic Persian storefronts have minimal signage, some in traditional fonts. A Peykan car from the era is parked along the street, adding a nostalgic touch to the scene. A tram passes in the background, and a few old cars from the period drive by. The atmosphere is lively but not crowded, with the gentle hum of the city in the air. Sunlight filters through the trees, casting a warm, golden glow over the scene. The camera angle is slightly from behind the couple, allowing the street to stretch ahead with the iconic trees and towering buildings of the time visible in the background, evoking the nostalgic charm of 1950s Tehran.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
The central subject is a nude woman viewed from the dorsal perspective, positioned vulnerably yet resolutely in the center of a war-torn urban thoroughfare. Her entire body is completely covered in meticulously applied United Nations flag body paint, featuring a light blue base with a white emblem depicting a world map projection encircled by olive branches conforming precisely to her anatomical contours, the pigments flowing across her spine, shoulders, and gluteal curves. Her physique exhibits precise anatomical clarity with realistic anthropometric proportions—a defined spinal column creating subtle shadows along the thoracic and lumbar regions, scapulae slightly prominent beneath dermal layers, and natural gluteal musculature forming the primary focal point with authentic adipose distribution and dermal tension. Her skin exhibits dermatological realism with visible pores, fine vellus hair along the erector spinae, and micro-blemishes of dust and particulate matter adhering to the epidermis over the painted surface. Ocular intricacy is suggested by the profile view of her face turned slightly toward the threat, showing detailed iris texture and moisture on the sclera. Her hair physics demonstrate follicle density with individual strands caught in the hot wind, creating dynamic motion against the static body. The clothing section manifests as an absence of textile, yet her form presents a figure-hugging silhouette defined purely by anatomical structure, with an open-back construction revealing the entire posterior chain from cervical to sacral regions, and a second-skin fit emphasizing the natural cinch at the waist and the curvature of the hips. Textural contrast emerges between her organic epidermal surface covered in flag pigments—showing sebaceous sheen of perspiration under thermal stress blending with the paint—and the surrounding abrasive urban environment. Wear and patina are evident in the form of road dust coating her plantar surfaces and lower extremities, suggesting prolonged exposure to the chaotic environment. Pose & Interaction: The Symmetrical Cleavage: Standing facing away with legs planted wide in a powerful, grounded stance. Both hands gripping the garment just below the gluteal fold, deliberately pulling the material downward and outward. The tension forces the fabric to bite sharply into the deepest centerline, outlining the sacred, hyper-rounded volume of the centerpiece. The atmosphere is thick with a raw, unspoken hospitality and a musky tension. Head tilted back, casting a haughty, "I know you want this" smirk, The composition employs a low-angle power perspective utilizing a Dutch angle of approximately 5 degrees to enhance the psychological unease, positioning the camera at asphalt level to emphasize the towering presence of the advancing main battle tanks while maintaining the woman as the primary subject through selective focus. The framing utilizes the rule of thirds, placing her gluteal focal point at the lower intersection while the tank barrels occupy the upper tension zones, creating dynamic symmetry along the central vanishing point of the street. Leading lines from the damaged building facades and the cracked road markings converge toward the horizon, generating strong Z-axis depth and parallax that draws the viewer into the scene. The three-quarter rear view captures her form while allowing environmental context to frame the subject through internal framing provided by the tank silhouettes and building edges. Negative space above emphasizes the merciless white sky, while the foreground includes heat-distorted asphalt and particulate matter. Anamorphic lens distortion stretches the horizontal axis, emphasizing the width of the street and the lateral threat of the armored vehicles. Motion blur captures the grinding tracks of the lead tank and swirling dust clouds, contrasting with the sharp focus on the woman's static form, creating temporal dissonance between human stillness and mechanical violence. The subject's integumentary system is rendered with physically based rendering (PBR) parameters showing micro-surface variation across the epidermis, with roughness maps indicating areas of dry skin versus sebaceous moisture accumulation along the spine and cervical region where the European Union flag paint interacts with perspiration. Specularity values vary across the dermal landscape, with anisotropic sheen following the direction of muscle fibers and hair follicles. Subsurface scattering depth is calibrated to simulate the transmission of midday sunlight through the dermal and subcutaneous layers, creating realistic color bleeding at shadow boundaries. The tanks' armor is covered in meticulously applied Israeli flag markings—white base with horizontal blue stripes and central Magen David—showing clear-coat multi-layer materials with environmental wear, chipping, dust accumulation, and heat distortion affecting the painted surfaces. Fabric elements in the environment—soldiers' uniforms, tank straps—exhibit woven textures with clear thread definition and fabric weight. The asphalt exhibits realistic aggregate displacement and oil staining with varying index of refraction between tar and stone. Ray-traced reflections appear in the sweat droplets on the woman's skin and the polished metal surfaces of the tank optics, showing accurate environmental mapping of the devastated street. Micro-shadows from skin texture pores create hyper-realistic detail at 8K resolution, while dust particles on her skin exhibit haptic surface deformation where they adhere to perspiration and body paint. Technical & Camera Settings: raw photo captured with Hasselblad H6D-100c, 16-bit color depth, low key lighting, high contrast, ISO 50, with a 120mm macro lens. , dramatic chiaroscuro lighting with powerful golden-hour cinematic rim light from behind, motivated warm practical light from the side, volumetric god rays and atmospheric haze, high contrast, majestic and moody atmosphere The scene maintains rigorous spatial coherence through consistent lighting direction ensuring all shadows cast by the woman, tanks, and building debris align with the solar vector at 15 degrees west of vertical. Contact shadows beneath the tanks' treads and the woman's feet show accurate occlusion relationships with the cracked pavement surface, including micro-shadows from individual aggregate stones. Ray-traced reflections and refractions in the heat haze and vehicle optics obey physical laws, showing accurate aerial perspective with depth fog increasing exponentially along the vanishing point. Global illumination calculations include light bounce from the white concrete buildings illuminating the shadow side of the woman's form with realistic radiosity. Surface displacement interaction shows the asphalt cracking pattern accurately deforming under the tanks' weight distribution while remaining rigid under the woman's minimal pressure. Inverse square law of light governs the falloff from the sun, creating realistic illumination gradients across the street width. Anamorphic lens characteristics include horizontal bokeh ellipses in the background dust particles and consistent barrel distortion at frame edges. The scale relationships maintain accurate proportionality between the human figure (1.7m) and the main battle tanks (2.5m height, 6m length), ensuring believable environmental integration and spatial occupancy within the urban canyon.
{ "RENDER_PIPELINE": { "optics": "35 mm equivalent smartphone lens (approx. 26 mm actual), f/1.9 aperture, focal plane locked on subject mid-torso at 1.8 m distance, circular bokeh with 7-blade diaphragm emulation visible in background foliage highlights, mild chromatic aberration on high-contrast tree edges, subtle lens flare at 4 o’clock position on right thigh", "film_emulation": "Digital CMOS sensor emulation (Sony IMX sensor equivalent), base ISO 100, zero visible noise, highlight roll-off soft with 2.2 gamma curve, natural daylight LUT with slight teal-orange grading in shadows, 8-bit sRGB output", "atmospherics": "Clear morning air (08:27 timestamp visible top-left), micro-dust particles suspended in volumetric god rays piercing canopy, fog density 0 %, light atmospheric perspective softening distant tree line" }, "LIGHTING_RIG": { "key_light": "Natural sunlight filtered through deciduous canopy, correlated color temperature 5800 K, incident angle 65° from upper camera-right, soft shadow edge transfer (penumbra ~8 cm on asphalt), no hard specular hotspots", "fill_light": "Diffuse sky bounce from open canopy gaps, fill ratio 1:2.5 relative to key, neutral 6500 K, no directional bias", "rim_hair_lights": "Strong rim from rear-right sunlight at 110° azimuth, 6200 K, creating 3 mm wide highlight halo along hair edges and left shoulder contour", "ambient_occlusion": "Deep micro-shadows in skin folds (under buttock crease, inner thigh contact, under bandeau hem), contact occlusion between fingers and face, skirt fabric and gluteal skin" }, "SUBJECT_BIOMETRICS_AND_TOPOLOGY": { "demographics": "Female, visually 19–22 years old, Eastern-European/Slavic phenotype (light Caucasian admixture), ecto-mesomorphic skeletal frame, visual BMI equivalent ~21, long-limbed proportions, pronounced lower-body adiposity with athletic muscle tone", "facial_geometry": "Oval face shape (partially occluded by right hand), high zygomatic prominence (cheekbones projecting 12 mm anteriorly), sharp mandibular angle with defined gonial flare, moderate chin projection (5 mm beyond subnasale vertical), smooth forehead", "nasal_and_ocular_structure": "Nose: straight dorsum with refined supra-tip break, narrow alar base (28 mm width), slightly upturned apex; eyes fully occluded by hand but visible orbital rim suggests almond shape with neutral canthal tilt (~0°), visible lower lash line and tear duct", "aura": "Playful-teasing confidence, deliberate erotic provocation through partial exposure, youthful carefree energy" }, "MICRO_ANATOMY_AND_SHADERS": { "epidermis": "Pore density low (fine on nose bridge, invisible on thighs), uniform light olive-tan tone, zero visible freckles or scars, subtle goosebumps on exposed upper arms from morning air", "dermis_and_vascular": "Subdermal veins faintly visible on inner forearms and dorsal hands (blue-green, 0.3 mm width), no capillary flush except faint pink undertone on cheeks and gluteal skin", "subsurface_scattering": "High SSS on earlobes, nasal tip, and exposed gluteal hemispheres (warm #FFCCAA transmission), moderate on inner thighs where light wraps around fabric edge", "surface_moisture": "Matte skin finish overall, trace sebum sheen on nasal bridge and forehead, single 0.5 mm sweat droplet at left temple hairline, no visible tears", "vellus_hair": "Fine peach-fuzz density on upper arms and outer thighs (0.1 mm length, catching rim light as golden halo)" }, "FACS_AND_MICRO_EXPRESSIONS": { "eyes": "Gaze vector fully occluded by right hand (fingers covering orbits and nasal bridge), inferred forward camera direction, pupil dilation unknown", "brows": "Right brow slightly arched (2 mm superior displacement at lateral tail), micro-tension indicating playful concealment", "mouth": "Lip parting 2 mm at center, upper lip slightly everted, lower lip full and glossy with natural mucosal moisture, teeth not visible, masseter relaxed" }, "HAIR_PHYSICS_AND_GROOMING": { "structure": "Level 6–7 golden-light-brown melanin base, root-to-tip uniform color with subtle sun-bleached highlights, high density (120–140 strands/cm²), individual strand thickness 0.08 mm", "physics": "Gravity-induced cascade over left shoulder and back, gentle S-curve from wind or movement, 18 visible flyaways along crown and right side illuminated by rim light", "styling": "Center-parted, loose natural fall to mid-back length (approx. 65 cm), no visible product stiffness" }, "MAKEUP_AND_BODY_MODS": { "cosmetics": "Natural matte foundation (skin-matched #F5D9C8), soft brown brow pencil, black winged eyeliner on visible lower lash line, nude-pink lip tint, glossy clear topcoat on nails (#FFFFFF with 80 % gloss specular)", "tattoos": "None visible on exposed skin surfaces", "piercings": "None visible" }, "BIOMECHANICS_AND_KINEMATICS": { "spine_pelvis": "Mild lumbar lordosis (approx. 28°), anterior pelvic tilt 12°, creating pronounced gluteal projection", "limbs": "Right shoulder abducted 85°, elbow flexed 110° (hand covering face); left shoulder abducted 35°, elbow flexed 70° (hand on hip); hips rotated 35° camera-left; right knee extended 175°, left knee flexed 165° with weight shifted to left leg; ankles dorsiflexed 10°", "digits": "Right hand: fingers 2–5 extended and slightly spread (covering eyes/nose, 4 mm gaps), thumb tucked under chin, 0.8 kg pressure on face; left hand: fingers 2–5 spread across left gluteal quadrant, thumb on iliac crest, nails pressing 0.3 kg into fabric/skin; all fingernails 12 mm length, square-oval shape" }, "CLOTH_SIMULATION_AND_PHYSICS": { "layer_1_strapless_bandeau_top": { "material": "Matte cotton-elastane jersey, 220 GSM, 4-way stretch, 80 denier opacity", "opacity_map": "100 % opaque on breasts, slight shear at underbust hem revealing 2 mm skin shadow", "tension_physics": "Horizontal stretch lines radiating from side seams under breast weight, 3 mm fabric roll at top edge", "skin_interaction": "Mild skin compression (1 mm indentation) at underbust, no visible nipple protrusion through fabric" }, "layer_2_mini_skirt": { "material": "Lightweight cotton twill, 180 GSM, flared A-line cut with ruffled hem, 60 denier", "opacity_map": "98 % opaque where settled, 0 % where lifted exposing gluteal skin", "tension_physics": "Radial stress wrinkles from left hand grip point, fabric bunching upward 8 cm above natural waist creating exposed lower gluteal crescent", "skin_interaction": "Skirt hem digging 2 mm into upper thigh fat creating soft muffin-top shelf, direct skin-to-fabric contact on right glute with visible fabric lift shadow" }, "layer_3_crew_socks": { "material": "Ribbed cotton, 280 GSM, mid-calf height", "opacity_map": "100 % opaque", "tension_physics": "Slight bunching at ankle fold (3 mm accordion effect)", "skin_interaction": "Mild calf compression creating 1 mm skin bulge above sock cuff" }, "layer_4_chunky_sneakers": { "material": "Synthetic leather upper with rubber sole, 40 mm platform, white laces tied in bow", "opacity_map": "100 % opaque", "tension_physics": "Laces under moderate tension, no creasing on toe box", "skin_interaction": "Sock fabric compressed 2 mm between ankle bone and shoe collar" } }, "SOFT_TISSUE_PHYSICS": { "gravity_impact": "Gluteal hemispheres (right more prominent) hanging 18 mm below natural skirt line due to fabric lift, creating rounded lower pole projection; upper thigh soft tissue slightly dimpled against left leg weight shift", "compression": "Left gluteal flesh compressed 4 mm against left hand palm, mild skin bulging between fingers; right thigh soft tissue flattened 3 mm where skirt hem presses" }, "ENVIRONMENT_AND_PROPS": { "contact_surfaces": "Cracked asphalt pavement (Ra roughness 1.2 mm), dark grey with moss in fissures; subject weight distributed 65 % left foot, 35 % right foot causing 0.5 mm sole compression", "depth_of_field": "Subject sharp from toes to hair tips, background trees blurred starting 4 m behind (bokeh circles 25–40 px diameter on highlights)" } }
Wet asphalt road, autumnal perspective. Yellow lane lines on a dark, wet road, reflecting the surrounding foliage. Dense forest lines the road, with vibrant, golden-orange and muted green trees. Fallen autumn leaves, some oak leaves, litter the road. Water puddles reflect the trees and sky. Low angle, close-up perspective focuses on the road's texture and the details of the yellow lines. Moody, serene autumnal atmosphere. Muted tones of gray, dark brown, deep orange, and muted yellow. The lighting is soft, diffused, characteristic of an overcast day. Road texture is visible, showing wetness and the slight imperfections of the asphalt. Yellow lane markers are prominent, with some visible wear and tear. Natural, organic, and detailed image. Photorealistic, artistic autumnal view.
A grotesquely obese, monstrous music industry executive stands in a dark, dystopian cityscape, his suit made of platinum records, his bloated belly hanging over his belt. His pants are half-down, revealing his obscene greed, while in front of him, a desperate indie hip-hop artist kneels, his expression filled with humiliation, pain, and frustration. His microphone dangles limply in his hand, his cracked 'wings of asphalt' barely holding him up. The industry giant smirks, holding a contract like a leash, tightening it around the rapper's neck. In the background, a carnival-like spectacle unfolds: faceless mainstream pop stars dance like puppets on strings, grotesque clowns with dollar-sign eyes throw fake awards into a roaring, soulless crowd. Neon billboards flash mindless slogans like 'STREAM OR DIE' and 'FAME FOR SALE.' The air is thick with smoke and despair, the city drowning in grey, the asphalt under the artist’s knees cracking under the weight of his broken dreams. The mood is dark, cold, and gritty—this is not a dream, but a nightmare of the music industry, where dignity is the price of exposure. --ar 16:9 --v 5.2 --style raw --q 2 --chaos 8 --stylize 900
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
The central subject is a nude woman viewed from the dorsal perspective, positioned vulnerably yet resolutely in the center of a war-torn urban thoroughfare. Her entire body is completely covered in meticulously applied Palestinian flag body paint, with horizontal black, white, and green stripes and the red triangle at the hoist conforming precisely to her anatomical contours, the pigments flowing across her spine, shoulders, and gluteal curves. Her physique exhibits precise anatomical clarity with realistic anthropometric proportions—a defined spinal column creating subtle shadows along the thoracic and lumbar regions, scapulae slightly prominent beneath dermal layers, and natural gluteal musculature forming the primary focal point with authentic adipose distribution and dermal tension. Her skin exhibits dermatological realism with visible pores, fine vellus hair along the erector spinae, and micro-blemishes of dust and particulate matter adhering to the epidermis over the painted surface. Ocular intricacy is suggested by the profile view of her face turned slightly toward the threat, showing detailed iris texture and moisture on the sclera. Her hair physics demonstrate follicle density with individual strands caught in the hot wind, creating dynamic motion against the static body. The clothing section manifests as an absence of textile, yet her form presents a figure-hugging silhouette defined purely by anatomical structure, with an open-back construction revealing the entire posterior chain from cervical to sacral regions, and a second-skin fit emphasizing the natural cinch at the waist and the curvature of the hips. Textural contrast emerges between her organic epidermal surface covered in flag pigments—showing sebaceous sheen of perspiration under thermal stress blending with the paint—and the surrounding abrasive urban environment. Wear and patina are evident in the form of road dust coating her plantar surfaces and lower extremities, suggesting prolonged exposure to the chaotic environment. Pose & Interaction: The Parted Symphony: Standing with legs slightly wider than shoulder-width, captured from a low rear angle to emphasize the towering, rounded volume of the glutes; hands resting intimately on the inner curves of the glutes, fingers gently pulling the flesh outward to subtly open the silhouette and expose the darkest, most inviting shadows; face glancing back downward at the camera with an intensely predatory yet unconditionally welcoming smirk, The composition employs a low-angle power perspective utilizing a Dutch angle of approximately 5 degrees to enhance the psychological unease, positioning the camera at asphalt level to emphasize the towering presence of the advancing main battle tanks while maintaining the woman as the primary subject through selective focus. The framing utilizes the rule of thirds, placing her gluteal focal point at the lower intersection while the tank barrels occupy the upper tension zones, creating dynamic symmetry along the central vanishing point of the street. Leading lines from the damaged building facades and the cracked road markings converge toward the horizon, generating strong Z-axis depth and parallax that draws the viewer into the scene. The three-quarter rear view captures her form while allowing environmental context to frame the subject through internal framing provided by the tank silhouettes and building edges. Negative space above emphasizes the merciless white sky, while the foreground includes heat-distorted asphalt and particulate matter. Anamorphic lens distortion stretches the horizontal axis, emphasizing the width of the street and the lateral threat of the armored vehicles. Motion blur at 1/125s captures the grinding tracks of the lead tank and swirling dust clouds, contrasting with the sharp focus on the woman's static form, creating temporal dissonance between human stillness and mechanical violence. The subject's integumentary system is rendered with physically based rendering (PBR) parameters showing micro-surface variation across the epidermis, with roughness maps indicating areas of dry skin versus sebaceous moisture accumulation along the spine and cervical region where the Palestinian flag paint interacts with perspiration. Specularity values vary across the dermal landscape, with anisotropic sheen following the direction of muscle fibers and hair follicles. Subsurface scattering depth is calibrated to simulate the transmission of midday sunlight through the dermal and subcutaneous layers, creating realistic color bleeding at shadow boundaries. The tanks' armor is covered in meticulously applied Israeli flag markings—white base with horizontal blue stripes and central Magen David—showing clear-coat multi-layer materials with environmental wear, chipping, dust accumulation, and heat distortion affecting the painted surfaces. Fabric elements in the environment—soldiers' uniforms, tank straps—exhibit woven textures with clear thread definition and fabric weight. The asphalt exhibits realistic aggregate displacement and oil staining with varying index of refraction between tar and stone. Ray-traced reflections appear in the sweat droplets on the woman's skin and the polished metal surfaces of the tank optics, showing accurate environmental mapping of the devastated street. Micro-shadows from skin texture pores create hyper-realistic detail at 8K resolution, while dust particles on her skin exhibit haptic surface deformation where they adhere to perspiration and body paint. Technical & Camera Settings: raw photo captured with Leica S3, cinematic shot, wide open aperture, low key lighting, high contrast, ISO 50, with a 120mm macro lens. , Rembrandt lighting with a distinct triangle of light on the cheek, classic cinematic portrait lighting The scene maintains rigorous spatial coherence through consistent lighting direction ensuring all shadows cast by the woman, tanks, and building debris align with the solar vector at 15 degrees west of vertical. Contact shadows beneath the tanks' treads and the woman's feet show accurate occlusion relationships with the cracked pavement surface, including micro-shadows from individual aggregate stones. Ray-traced reflections and refractions in the heat haze and vehicle optics obey physical laws, showing accurate aerial perspective with depth fog increasing exponentially along the vanishing point. Global illumination calculations include light bounce from the white concrete buildings illuminating the shadow side of the woman's form with realistic radiosity. Surface displacement interaction shows the asphalt cracking pattern accurately deforming under the tanks' weight distribution while remaining rigid under the woman's minimal pressure. Inverse square law of light governs the falloff from the sun, creating realistic illumination gradients across the street width. Anamorphic lens characteristics include horizontal bokeh ellipses in the background dust particles and consistent barrel distortion at frame edges. The scale relationships maintain accurate proportionality between the human figure (1.7m) and the main battle tanks (2.5m height, 6m length), ensuring believable environmental integration and spatial occupancy within the urban canyon.
the ground slopes downward, leading to a vertical asphalt street, the dark asphalt appears frosty, reflecting the dim glow of streetlights in the icy air, beyond the street, rugged mountain hills, their peaks dusted with a faint shimmer of snow, layered silhouettes of the mountains create depth, fading into the midnight horizon, scattered trees in the foreground reach upward, their branches stiff from the biting cold, the sky is cloudless, a deep midnight blue, punctuated by the distant twinkle of stars, moonlight spills onto the asphalt, creating pale silvery reflections in the cold air, soft shadows stretch beneath the trees, nature and roadways intertwine, forming a striking balance under the night sky,
The character and environment in Figure 1 remain unchanged - High motion, fast movement, extreme dynamic effect. FPV first‑person follow‑cam, always close to the ground, moving up and down synchronously. A handsome boy with long flowing hair wearing a skirt performs high‑difficulty skateboarding tricks on an empty city street at night. 0-2s: Sprints down a slope at 80km/h, low center of gravity, hair and skirt blown back by strong wind. 2-4s: Enters a sharp turn, executes a tailbrake drift – rubber wheels scrape asphalt, sending out bright sparks. 4-6s: Kickflip into a 180° mid‑air spin, the skateboard rotating 360° precisely under his feet. 6-10s: Explodes out of the turn, leaps into a 360° grab, body fully extended, landing smoothly without wobble. Late‑night city background. Wet asphalt reflects mixed neon and warm yellow streetlight. Blurred car headlights in the distance, dark building outlines on both sides. Deep navy sky with a few sparse stars. Cool neon mixed with warm streetlight creates sharp reflections on the skateboard’s metal trucks and wheels. A clear black silhouette of the boy is cast on the ground. Strong motion blur and speed lines. High‑detail 3D anime style, cinematic lighting, 8K resolution.
A dramatic Formula 1 race is taking place on a professional circuit under heavy rain during a breathtaking sunset. Dark storm clouds mix with the warm shades of orange, pink, and purple in the sky, creating a striking contrast. Raindrops fall heavily, bouncing off the track and the sleek bodies of the cars, while water sprays behind them as they speed through the wet asphalt. In the lead is a Formula 1 car with a bold 60% red and 40% black color scheme, featuring an aerodynamic design. The number "11" is clearly displayed, and the name "Roca" is written on its body. Its main sponsor, "Quabu", is prominently featured on the car’s livery. The wet surface reflects the car’s colors as it pushes forward, leaving a trail of water spray behind. Chasing closely behind is another Formula 1 car, painted entirely in a deep metallic green, with no other primary colors. This car bears the number "18", with the name "Alex" displayed on its body, also showcasing the "Quabu" sponsorship. The rain-soaked track glistens under the lights and sunset, while water splashes from the tires as the green car fights to close the gap. Both cars are locked in an intense battle as they navigate a sharp turn, their tires struggling for grip on the slippery asphalt. The red-and-black car, driven by "Roca", is slightly ahead, while the green car, driven by "Alex", is aggressively trying to overtake. The rain adds a dramatic element, with droplets streaking through the air and reflections shimmering on the wet surface. In the background, blurred grandstands full of cheering fans can be seen, their umbrellas raised as they watch the thrilling race unfold.
A young couple from the 1950s walking along the wide, asphalted streets of Vali Asr Street (formerly Pahlavi Street) in Tehran. The scene is set in the heart of the city, with the distinct architecture and atmosphere of the time. The girl, with voluminous, curly hair, cat-eye eyeliner, and red lipstick, wears a floral patterned dress with a wide collar and a flared skirt typical of the 1950s. The boy, with neatly styled hair and a thin mustache, wears a light-colored wide-collared suit with a shirt and thin tie. The couple walks hand in hand, surrounded by a few pedestrians. The street is wide and lined with tall plane trees, casting dappled shadows onto the asphalt. Streetlamps, situated near the edge of the sidewalk, illuminate the path. The classic Persian storefronts have minimal signage, some in traditional fonts. A few old cars from the era drive by, and a tram passes in the background. The atmosphere is lively but not crowded, with the gentle hum of the city in the air. Sunlight filters through the trees, casting a warm, golden glow over the scene. The camera angle is slightly from behind the couple, allowing the street to stretch ahead with the iconic trees and towering buildings of the time visible in the background, evoking the nostalgic charm of 1950s Tehran.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
Wet asphalt road, autumnal perspective. Yellow lane lines on a dark, wet road, reflecting the surrounding foliage. Dense forest lines the road, with vibrant, golden-orange and muted green trees. Fallen autumn leaves, some oak leaves, litter the road. Water puddles reflect the trees and sky. Low angle, close-up perspective focuses on the road's texture and the details of the yellow lines. Moody, serene autumnal atmosphere. Muted tones of gray, dark brown, deep orange, and muted yellow. The lighting is soft, diffused, characteristic of an overcast day. Road texture is visible, showing wetness and the slight imperfections of the asphalt. Yellow lane markers are prominent, with some visible wear and tear. Natural, organic, and detailed image. Photorealistic, artistic autumnal view.
A young couple from the 1950s walking along the wide, asphalted streets of Vali Asr Street (formerly Pahlavi Street) in Tehran. The scene is set in the heart of the city, with the distinct architecture and atmosphere of the time. The girl, with voluminous, curly hair, cat-eye eyeliner, and red lipstick, wears a floral patterned dress with a wide collar and a flared skirt typical of the 1950s. The boy, with neatly styled hair and a thin mustache, wears a light-colored wide-collared suit with a shirt and thin tie. The couple walks hand in hand, surrounded by a few pedestrians. The street is wide and lined with tall plane trees, casting dappled shadows onto the asphalt. Streetlamps, situated near the edge of the sidewalk, illuminate the path. The classic Persian storefronts have minimal signage, some in traditional fonts. A Peykan car from the era is parked along the street, adding a nostalgic touch to the scene. A tram passes in the background, and a few old cars from the period drive by. The atmosphere is lively but not crowded, with the gentle hum of the city in the air. Sunlight filters through the trees, casting a warm, golden glow over the scene. The camera angle is slightly from behind the couple, allowing the street to stretch ahead with the iconic trees and towering buildings of the time visible in the background, evoking the nostalgic charm of 1950s Tehran.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
A detailed, photorealistic, cinematic vertical medium-full shot of an attractive young East Asian woman sitting on a wet, rain-slicked street at night during a heavy rainstorm. Shot Angle & Pose: Captured from a slightly high eye-level perspective looking down. The subject is sitting directly on the wet asphalt, her knees drawn up toward her chest in a huddled posture. Her left hand rests on her wet hair, while her right arm drapes casually over her leg. She looks directly into the lens with a calm, pensive, and vulnerable expression, her lips slightly parted. Subject Appearance: She has a flawless, porcelain complexion with a detailed wet skin texture, covered in water droplets. Her jet-black hair is completely wet and messy, clinging to her face and shoulders in damp strands. Her facial features are delicate, characterized by large expressive dark eyes, subtle dark eyeshadow, and soft, natural coral-pink lips. Character Figure: She possesses a slender and athletic hourglass figure. Her physique is characterized by an exceptionally slender waist and long, shapely, toned legs. Her curvaceous silhouette is highlighted by her seated, huddled posture and the semi-translucent nature of her wet clothing. Outfit Details: She is wearing a casual, minimalist "wet-look" ensemble: Shirt: An oversized, long-sleeved white button-down shirt. The cotton fabric is completely saturated with rainwater, making it semi-translucent and causing it to cling tightly to her torso and arms. Bottoms: Simple, form-fitting black shorts or panties. Setting & Lighting: Setting: A dark, moody street or alleyway at night in the pouring rain. The ground is a wet, reflective asphalt road. In the background on the left, a car’s headlights are turned on, casting a bright white flare. On the right, blurred, cool-blue fluorescent street lights are visible in soft focus under a covered structure. Lighting: Cool-toned, high-contrast night lighting. The powerful light from the car headlights and streetlights creates brilliant highlights on her wet skin, her hair, and her translucent wet white shirt. The wet asphalt creates sharp, detailed reflections of the lights, with the rest of the scene falling into deep, dark blue shadows. 8k resolution, raw photo aesthetic, wet look, pouring rain, car headlights, wet asphalt reflections, white button-down shirt, sharp focus on the subject, high-fidelity texture rendering, blue and white color palette, cinematic composition, hyper-realistic skin and wet fabric textures.
the ground slopes downward, leading to a vertical asphalt street, the dark asphalt appears frosty, reflecting the dim glow of streetlights in the icy air, beyond the street, rugged mountain hills, their peaks dusted with a faint shimmer of snow, layered silhouettes of the mountains create depth, fading into the midnight horizon, scattered trees in the foreground reach upward, their branches stiff from the biting cold, the sky is cloudless, a deep midnight blue, punctuated by the distant twinkle of stars, moonlight spills onto the asphalt, creating pale silvery reflections in the cold air, soft shadows stretch beneath the trees, nature and roadways intertwine, forming a striking balance under the night sky,
A grotesquely obese, monstrous music industry executive stands in a dark, dystopian cityscape, his suit made of platinum records, his bloated belly hanging over his belt. His pants are half-down, revealing his obscene greed, while in front of him, a desperate indie hip-hop artist kneels, his expression filled with humiliation, pain, and frustration. His microphone dangles limply in his hand, his cracked 'wings of asphalt' barely holding him up. The industry giant smirks, holding a contract like a leash, tightening it around the rapper's neck. In the background, a carnival-like spectacle unfolds: faceless mainstream pop stars dance like puppets on strings, grotesque clowns with dollar-sign eyes throw fake awards into a roaring, soulless crowd. Neon billboards flash mindless slogans like 'STREAM OR DIE' and 'FAME FOR SALE.' The air is thick with smoke and despair, the city drowning in grey, the asphalt under the artist’s knees cracking under the weight of his broken dreams. The mood is dark, cold, and gritty—this is not a dream, but a nightmare of the music industry, where dignity is the price of exposure. --ar 16:9 --v 5.2 --style raw --q 2 --chaos 8 --stylize 900
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
The central subject is a nude woman viewed from the dorsal perspective, positioned vulnerably yet resolutely in the center of a war-torn urban thoroughfare. Her entire body is completely covered in meticulously applied United Nations flag body paint, featuring a light blue base with a white emblem depicting a world map projection encircled by olive branches conforming precisely to her anatomical contours, the pigments flowing across her spine, shoulders, and gluteal curves. Her physique exhibits precise anatomical clarity with realistic anthropometric proportions—a defined spinal column creating subtle shadows along the thoracic and lumbar regions, scapulae slightly prominent beneath dermal layers, and natural gluteal musculature forming the primary focal point with authentic adipose distribution and dermal tension. Her skin exhibits dermatological realism with visible pores, fine vellus hair along the erector spinae, and micro-blemishes of dust and particulate matter adhering to the epidermis over the painted surface. Ocular intricacy is suggested by the profile view of her face turned slightly toward the threat, showing detailed iris texture and moisture on the sclera. Her hair physics demonstrate follicle density with individual strands caught in the hot wind, creating dynamic motion against the static body. The clothing section manifests as an absence of textile, yet her form presents a figure-hugging silhouette defined purely by anatomical structure, with an open-back construction revealing the entire posterior chain from cervical to sacral regions, and a second-skin fit emphasizing the natural cinch at the waist and the curvature of the hips. Textural contrast emerges between her organic epidermal surface covered in flag pigments—showing sebaceous sheen of perspiration under thermal stress blending with the paint—and the surrounding abrasive urban environment. Wear and patina are evident in the form of road dust coating her plantar surfaces and lower extremities, suggesting prolonged exposure to the chaotic environment. Pose & Interaction: The Symmetrical Cleavage: Standing facing away with legs planted wide in a powerful, grounded stance. Both hands gripping the garment just below the gluteal fold, deliberately pulling the material downward and outward. The tension forces the fabric to bite sharply into the deepest centerline, outlining the sacred, hyper-rounded volume of the centerpiece. The atmosphere is thick with a raw, unspoken hospitality and a musky tension. Head tilted back, casting a haughty, "I know you want this" smirk, The composition employs a low-angle power perspective utilizing a Dutch angle of approximately 5 degrees to enhance the psychological unease, positioning the camera at asphalt level to emphasize the towering presence of the advancing main battle tanks while maintaining the woman as the primary subject through selective focus. The framing utilizes the rule of thirds, placing her gluteal focal point at the lower intersection while the tank barrels occupy the upper tension zones, creating dynamic symmetry along the central vanishing point of the street. Leading lines from the damaged building facades and the cracked road markings converge toward the horizon, generating strong Z-axis depth and parallax that draws the viewer into the scene. The three-quarter rear view captures her form while allowing environmental context to frame the subject through internal framing provided by the tank silhouettes and building edges. Negative space above emphasizes the merciless white sky, while the foreground includes heat-distorted asphalt and particulate matter. Anamorphic lens distortion stretches the horizontal axis, emphasizing the width of the street and the lateral threat of the armored vehicles. Motion blur captures the grinding tracks of the lead tank and swirling dust clouds, contrasting with the sharp focus on the woman's static form, creating temporal dissonance between human stillness and mechanical violence. The subject's integumentary system is rendered with physically based rendering (PBR) parameters showing micro-surface variation across the epidermis, with roughness maps indicating areas of dry skin versus sebaceous moisture accumulation along the spine and cervical region where the European Union flag paint interacts with perspiration. Specularity values vary across the dermal landscape, with anisotropic sheen following the direction of muscle fibers and hair follicles. Subsurface scattering depth is calibrated to simulate the transmission of midday sunlight through the dermal and subcutaneous layers, creating realistic color bleeding at shadow boundaries. The tanks' armor is covered in meticulously applied Israeli flag markings—white base with horizontal blue stripes and central Magen David—showing clear-coat multi-layer materials with environmental wear, chipping, dust accumulation, and heat distortion affecting the painted surfaces. Fabric elements in the environment—soldiers' uniforms, tank straps—exhibit woven textures with clear thread definition and fabric weight. The asphalt exhibits realistic aggregate displacement and oil staining with varying index of refraction between tar and stone. Ray-traced reflections appear in the sweat droplets on the woman's skin and the polished metal surfaces of the tank optics, showing accurate environmental mapping of the devastated street. Micro-shadows from skin texture pores create hyper-realistic detail at 8K resolution, while dust particles on her skin exhibit haptic surface deformation where they adhere to perspiration and body paint. Technical & Camera Settings: raw photo captured with Hasselblad H6D-100c, 16-bit color depth, low key lighting, high contrast, ISO 50, with a 120mm macro lens. , dramatic chiaroscuro lighting with powerful golden-hour cinematic rim light from behind, motivated warm practical light from the side, volumetric god rays and atmospheric haze, high contrast, majestic and moody atmosphere The scene maintains rigorous spatial coherence through consistent lighting direction ensuring all shadows cast by the woman, tanks, and building debris align with the solar vector at 15 degrees west of vertical. Contact shadows beneath the tanks' treads and the woman's feet show accurate occlusion relationships with the cracked pavement surface, including micro-shadows from individual aggregate stones. Ray-traced reflections and refractions in the heat haze and vehicle optics obey physical laws, showing accurate aerial perspective with depth fog increasing exponentially along the vanishing point. Global illumination calculations include light bounce from the white concrete buildings illuminating the shadow side of the woman's form with realistic radiosity. Surface displacement interaction shows the asphalt cracking pattern accurately deforming under the tanks' weight distribution while remaining rigid under the woman's minimal pressure. Inverse square law of light governs the falloff from the sun, creating realistic illumination gradients across the street width. Anamorphic lens characteristics include horizontal bokeh ellipses in the background dust particles and consistent barrel distortion at frame edges. The scale relationships maintain accurate proportionality between the human figure (1.7m) and the main battle tanks (2.5m height, 6m length), ensuring believable environmental integration and spatial occupancy within the urban canyon.
The central subject is a nude woman viewed from the dorsal perspective, positioned vulnerably yet resolutely in the center of a war-torn urban thoroughfare. Her entire body is completely covered in meticulously applied Palestinian flag body paint, with horizontal black, white, and green stripes and the red triangle at the hoist conforming precisely to her anatomical contours, the pigments flowing across her spine, shoulders, and gluteal curves. Her physique exhibits precise anatomical clarity with realistic anthropometric proportions—a defined spinal column creating subtle shadows along the thoracic and lumbar regions, scapulae slightly prominent beneath dermal layers, and natural gluteal musculature forming the primary focal point with authentic adipose distribution and dermal tension. Her skin exhibits dermatological realism with visible pores, fine vellus hair along the erector spinae, and micro-blemishes of dust and particulate matter adhering to the epidermis over the painted surface. Ocular intricacy is suggested by the profile view of her face turned slightly toward the threat, showing detailed iris texture and moisture on the sclera. Her hair physics demonstrate follicle density with individual strands caught in the hot wind, creating dynamic motion against the static body. The clothing section manifests as an absence of textile, yet her form presents a figure-hugging silhouette defined purely by anatomical structure, with an open-back construction revealing the entire posterior chain from cervical to sacral regions, and a second-skin fit emphasizing the natural cinch at the waist and the curvature of the hips. Textural contrast emerges between her organic epidermal surface covered in flag pigments—showing sebaceous sheen of perspiration under thermal stress blending with the paint—and the surrounding abrasive urban environment. Wear and patina are evident in the form of road dust coating her plantar surfaces and lower extremities, suggesting prolonged exposure to the chaotic environment. Pose & Interaction: The Parted Symphony: Standing with legs slightly wider than shoulder-width, captured from a low rear angle to emphasize the towering, rounded volume of the glutes; hands resting intimately on the inner curves of the glutes, fingers gently pulling the flesh outward to subtly open the silhouette and expose the darkest, most inviting shadows; face glancing back downward at the camera with an intensely predatory yet unconditionally welcoming smirk, The composition employs a low-angle power perspective utilizing a Dutch angle of approximately 5 degrees to enhance the psychological unease, positioning the camera at asphalt level to emphasize the towering presence of the advancing main battle tanks while maintaining the woman as the primary subject through selective focus. The framing utilizes the rule of thirds, placing her gluteal focal point at the lower intersection while the tank barrels occupy the upper tension zones, creating dynamic symmetry along the central vanishing point of the street. Leading lines from the damaged building facades and the cracked road markings converge toward the horizon, generating strong Z-axis depth and parallax that draws the viewer into the scene. The three-quarter rear view captures her form while allowing environmental context to frame the subject through internal framing provided by the tank silhouettes and building edges. Negative space above emphasizes the merciless white sky, while the foreground includes heat-distorted asphalt and particulate matter. Anamorphic lens distortion stretches the horizontal axis, emphasizing the width of the street and the lateral threat of the armored vehicles. Motion blur at 1/125s captures the grinding tracks of the lead tank and swirling dust clouds, contrasting with the sharp focus on the woman's static form, creating temporal dissonance between human stillness and mechanical violence. The subject's integumentary system is rendered with physically based rendering (PBR) parameters showing micro-surface variation across the epidermis, with roughness maps indicating areas of dry skin versus sebaceous moisture accumulation along the spine and cervical region where the Palestinian flag paint interacts with perspiration. Specularity values vary across the dermal landscape, with anisotropic sheen following the direction of muscle fibers and hair follicles. Subsurface scattering depth is calibrated to simulate the transmission of midday sunlight through the dermal and subcutaneous layers, creating realistic color bleeding at shadow boundaries. The tanks' armor is covered in meticulously applied Israeli flag markings—white base with horizontal blue stripes and central Magen David—showing clear-coat multi-layer materials with environmental wear, chipping, dust accumulation, and heat distortion affecting the painted surfaces. Fabric elements in the environment—soldiers' uniforms, tank straps—exhibit woven textures with clear thread definition and fabric weight. The asphalt exhibits realistic aggregate displacement and oil staining with varying index of refraction between tar and stone. Ray-traced reflections appear in the sweat droplets on the woman's skin and the polished metal surfaces of the tank optics, showing accurate environmental mapping of the devastated street. Micro-shadows from skin texture pores create hyper-realistic detail at 8K resolution, while dust particles on her skin exhibit haptic surface deformation where they adhere to perspiration and body paint. Technical & Camera Settings: raw photo captured with Leica S3, cinematic shot, wide open aperture, low key lighting, high contrast, ISO 50, with a 120mm macro lens. , Rembrandt lighting with a distinct triangle of light on the cheek, classic cinematic portrait lighting The scene maintains rigorous spatial coherence through consistent lighting direction ensuring all shadows cast by the woman, tanks, and building debris align with the solar vector at 15 degrees west of vertical. Contact shadows beneath the tanks' treads and the woman's feet show accurate occlusion relationships with the cracked pavement surface, including micro-shadows from individual aggregate stones. Ray-traced reflections and refractions in the heat haze and vehicle optics obey physical laws, showing accurate aerial perspective with depth fog increasing exponentially along the vanishing point. Global illumination calculations include light bounce from the white concrete buildings illuminating the shadow side of the woman's form with realistic radiosity. Surface displacement interaction shows the asphalt cracking pattern accurately deforming under the tanks' weight distribution while remaining rigid under the woman's minimal pressure. Inverse square law of light governs the falloff from the sun, creating realistic illumination gradients across the street width. Anamorphic lens characteristics include horizontal bokeh ellipses in the background dust particles and consistent barrel distortion at frame edges. The scale relationships maintain accurate proportionality between the human figure (1.7m) and the main battle tanks (2.5m height, 6m length), ensuring believable environmental integration and spatial occupancy within the urban canyon.
A young couple from the 1950s walking along the wide, asphalted streets of Vali Asr Street (formerly Pahlavi Street) in Tehran. The scene is set in the heart of the city, with the distinct architecture and atmosphere of the time. The girl, with voluminous, curly hair, cat-eye eyeliner, and red lipstick, wears a floral patterned dress with a wide collar and a flared skirt typical of the 1950s. The boy, with neatly styled hair and a thin mustache, wears a light-colored wide-collared suit with a shirt and thin tie. The couple walks hand in hand, surrounded by a few pedestrians. The street is wide and lined with tall plane trees, casting dappled shadows onto the asphalt. Streetlamps, situated near the edge of the sidewalk, illuminate the path. The classic Persian storefronts have minimal signage, some in traditional fonts. A few old cars from the era drive by, and a tram passes in the background. The atmosphere is lively but not crowded, with the gentle hum of the city in the air. Sunlight filters through the trees, casting a warm, golden glow over the scene. The camera angle is slightly from behind the couple, allowing the street to stretch ahead with the iconic trees and towering buildings of the time visible in the background, evoking the nostalgic charm of 1950s Tehran.
A dramatic Formula 1 race is taking place on a professional circuit under heavy rain during a breathtaking sunset. Dark storm clouds mix with the warm shades of orange, pink, and purple in the sky, creating a striking contrast. Raindrops fall heavily, bouncing off the track and the sleek bodies of the cars, while water sprays behind them as they speed through the wet asphalt. In the lead is a Formula 1 car with a bold 60% red and 40% black color scheme, featuring an aerodynamic design. The number "11" is clearly displayed, and the name "Roca" is written on its body. Its main sponsor, "Quabu", is prominently featured on the car’s livery. The wet surface reflects the car’s colors as it pushes forward, leaving a trail of water spray behind. Chasing closely behind is another Formula 1 car, painted entirely in a deep metallic green, with no other primary colors. This car bears the number "18", with the name "Alex" displayed on its body, also showcasing the "Quabu" sponsorship. The rain-soaked track glistens under the lights and sunset, while water splashes from the tires as the green car fights to close the gap. Both cars are locked in an intense battle as they navigate a sharp turn, their tires struggling for grip on the slippery asphalt. The red-and-black car, driven by "Roca", is slightly ahead, while the green car, driven by "Alex", is aggressively trying to overtake. The rain adds a dramatic element, with droplets streaking through the air and reflections shimmering on the wet surface. In the background, blurred grandstands full of cheering fans can be seen, their umbrellas raised as they watch the thrilling race unfold.
The central subject is a nude woman viewed from the dorsal perspective, positioned vulnerably yet resolutely in the center of a war-torn urban thoroughfare. Her entire body is completely covered in meticulously applied United Nations flag body paint, featuring a light blue base with a white emblem depicting a world map projection encircled by olive branches conforming precisely to her anatomical contours, the pigments flowing across her spine, shoulders, and gluteal curves. Her physique exhibits precise anatomical clarity with realistic anthropometric proportions—a defined spinal column creating subtle shadows along the thoracic and lumbar regions, scapulae slightly prominent beneath dermal layers, and natural gluteal musculature forming the primary focal point with authentic adipose distribution and dermal tension. Her skin exhibits dermatological realism with visible pores, fine vellus hair along the erector spinae, and micro-blemishes of dust and particulate matter adhering to the epidermis over the painted surface. Ocular intricacy is suggested by the profile view of her face turned slightly toward the threat, showing detailed iris texture and moisture on the sclera. Her hair physics demonstrate follicle density with individual strands caught in the hot wind, creating dynamic motion against the static body. The clothing section manifests as an absence of textile, yet her form presents a figure-hugging silhouette defined purely by anatomical structure, with an open-back construction revealing the entire posterior chain from cervical to sacral regions, and a second-skin fit emphasizing the natural cinch at the waist and the curvature of the hips. Textural contrast emerges between her organic epidermal surface covered in flag pigments—showing sebaceous sheen of perspiration under thermal stress blending with the paint—and the surrounding abrasive urban environment. Wear and patina are evident in the form of road dust coating her plantar surfaces and lower extremities, suggesting prolonged exposure to the chaotic environment. Pose & Interaction: The Symmetrical Cleavage: Standing facing away with legs planted wide in a powerful, grounded stance. Both hands gripping the garment just below the gluteal fold, deliberately pulling the material downward and outward. The tension forces the fabric to bite sharply into the deepest centerline, outlining the sacred, hyper-rounded volume of the centerpiece. The atmosphere is thick with a raw, unspoken hospitality and a musky tension. Head tilted back, casting a haughty, "I know you want this" smirk, The composition employs a low-angle power perspective utilizing a Dutch angle of approximately 5 degrees to enhance the psychological unease, positioning the camera at asphalt level to emphasize the towering presence of the advancing main battle tanks while maintaining the woman as the primary subject through selective focus. The framing utilizes the rule of thirds, placing her gluteal focal point at the lower intersection while the tank barrels occupy the upper tension zones, creating dynamic symmetry along the central vanishing point of the street. Leading lines from the damaged building facades and the cracked road markings converge toward the horizon, generating strong Z-axis depth and parallax that draws the viewer into the scene. The three-quarter rear view captures her form while allowing environmental context to frame the subject through internal framing provided by the tank silhouettes and building edges. Negative space above emphasizes the merciless white sky, while the foreground includes heat-distorted asphalt and particulate matter. Anamorphic lens distortion stretches the horizontal axis, emphasizing the width of the street and the lateral threat of the armored vehicles. Motion blur captures the grinding tracks of the lead tank and swirling dust clouds, contrasting with the sharp focus on the woman's static form, creating temporal dissonance between human stillness and mechanical violence. The subject's integumentary system is rendered with physically based rendering (PBR) parameters showing micro-surface variation across the epidermis, with roughness maps indicating areas of dry skin versus sebaceous moisture accumulation along the spine and cervical region where the European Union flag paint interacts with perspiration. Specularity values vary across the dermal landscape, with anisotropic sheen following the direction of muscle fibers and hair follicles. Subsurface scattering depth is calibrated to simulate the transmission of midday sunlight through the dermal and subcutaneous layers, creating realistic color bleeding at shadow boundaries. The tanks' armor is covered in meticulously applied Israeli flag markings—white base with horizontal blue stripes and central Magen David—showing clear-coat multi-layer materials with environmental wear, chipping, dust accumulation, and heat distortion affecting the painted surfaces. Fabric elements in the environment—soldiers' uniforms, tank straps—exhibit woven textures with clear thread definition and fabric weight. The asphalt exhibits realistic aggregate displacement and oil staining with varying index of refraction between tar and stone. Ray-traced reflections appear in the sweat droplets on the woman's skin and the polished metal surfaces of the tank optics, showing accurate environmental mapping of the devastated street. Micro-shadows from skin texture pores create hyper-realistic detail at 8K resolution, while dust particles on her skin exhibit haptic surface deformation where they adhere to perspiration and body paint. Technical & Camera Settings: raw photo captured with Hasselblad H6D-100c, 16-bit color depth, low key lighting, high contrast, ISO 50, with a 120mm macro lens. , dramatic chiaroscuro lighting with powerful golden-hour cinematic rim light from behind, motivated warm practical light from the side, volumetric god rays and atmospheric haze, high contrast, majestic and moody atmosphere The scene maintains rigorous spatial coherence through consistent lighting direction ensuring all shadows cast by the woman, tanks, and building debris align with the solar vector at 15 degrees west of vertical. Contact shadows beneath the tanks' treads and the woman's feet show accurate occlusion relationships with the cracked pavement surface, including micro-shadows from individual aggregate stones. Ray-traced reflections and refractions in the heat haze and vehicle optics obey physical laws, showing accurate aerial perspective with depth fog increasing exponentially along the vanishing point. Global illumination calculations include light bounce from the white concrete buildings illuminating the shadow side of the woman's form with realistic radiosity. Surface displacement interaction shows the asphalt cracking pattern accurately deforming under the tanks' weight distribution while remaining rigid under the woman's minimal pressure. Inverse square law of light governs the falloff from the sun, creating realistic illumination gradients across the street width. Anamorphic lens characteristics include horizontal bokeh ellipses in the background dust particles and consistent barrel distortion at frame edges. The scale relationships maintain accurate proportionality between the human figure (1.7m) and the main battle tanks (2.5m height, 6m length), ensuring believable environmental integration and spatial occupancy within the urban canyon.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
{ "RENDER_PIPELINE": { "optics": "35 mm equivalent smartphone lens (approx. 26 mm actual), f/1.9 aperture, focal plane locked on subject mid-torso at 1.8 m distance, circular bokeh with 7-blade diaphragm emulation visible in background foliage highlights, mild chromatic aberration on high-contrast tree edges, subtle lens flare at 4 o’clock position on right thigh", "film_emulation": "Digital CMOS sensor emulation (Sony IMX sensor equivalent), base ISO 100, zero visible noise, highlight roll-off soft with 2.2 gamma curve, natural daylight LUT with slight teal-orange grading in shadows, 8-bit sRGB output", "atmospherics": "Clear morning air (08:27 timestamp visible top-left), micro-dust particles suspended in volumetric god rays piercing canopy, fog density 0 %, light atmospheric perspective softening distant tree line" }, "LIGHTING_RIG": { "key_light": "Natural sunlight filtered through deciduous canopy, correlated color temperature 5800 K, incident angle 65° from upper camera-right, soft shadow edge transfer (penumbra ~8 cm on asphalt), no hard specular hotspots", "fill_light": "Diffuse sky bounce from open canopy gaps, fill ratio 1:2.5 relative to key, neutral 6500 K, no directional bias", "rim_hair_lights": "Strong rim from rear-right sunlight at 110° azimuth, 6200 K, creating 3 mm wide highlight halo along hair edges and left shoulder contour", "ambient_occlusion": "Deep micro-shadows in skin folds (under buttock crease, inner thigh contact, under bandeau hem), contact occlusion between fingers and face, skirt fabric and gluteal skin" }, "SUBJECT_BIOMETRICS_AND_TOPOLOGY": { "demographics": "Female, visually 19–22 years old, Eastern-European/Slavic phenotype (light Caucasian admixture), ecto-mesomorphic skeletal frame, visual BMI equivalent ~21, long-limbed proportions, pronounced lower-body adiposity with athletic muscle tone", "facial_geometry": "Oval face shape (partially occluded by right hand), high zygomatic prominence (cheekbones projecting 12 mm anteriorly), sharp mandibular angle with defined gonial flare, moderate chin projection (5 mm beyond subnasale vertical), smooth forehead", "nasal_and_ocular_structure": "Nose: straight dorsum with refined supra-tip break, narrow alar base (28 mm width), slightly upturned apex; eyes fully occluded by hand but visible orbital rim suggests almond shape with neutral canthal tilt (~0°), visible lower lash line and tear duct", "aura": "Playful-teasing confidence, deliberate erotic provocation through partial exposure, youthful carefree energy" }, "MICRO_ANATOMY_AND_SHADERS": { "epidermis": "Pore density low (fine on nose bridge, invisible on thighs), uniform light olive-tan tone, zero visible freckles or scars, subtle goosebumps on exposed upper arms from morning air", "dermis_and_vascular": "Subdermal veins faintly visible on inner forearms and dorsal hands (blue-green, 0.3 mm width), no capillary flush except faint pink undertone on cheeks and gluteal skin", "subsurface_scattering": "High SSS on earlobes, nasal tip, and exposed gluteal hemispheres (warm #FFCCAA transmission), moderate on inner thighs where light wraps around fabric edge", "surface_moisture": "Matte skin finish overall, trace sebum sheen on nasal bridge and forehead, single 0.5 mm sweat droplet at left temple hairline, no visible tears", "vellus_hair": "Fine peach-fuzz density on upper arms and outer thighs (0.1 mm length, catching rim light as golden halo)" }, "FACS_AND_MICRO_EXPRESSIONS": { "eyes": "Gaze vector fully occluded by right hand (fingers covering orbits and nasal bridge), inferred forward camera direction, pupil dilation unknown", "brows": "Right brow slightly arched (2 mm superior displacement at lateral tail), micro-tension indicating playful concealment", "mouth": "Lip parting 2 mm at center, upper lip slightly everted, lower lip full and glossy with natural mucosal moisture, teeth not visible, masseter relaxed" }, "HAIR_PHYSICS_AND_GROOMING": { "structure": "Level 6–7 golden-light-brown melanin base, root-to-tip uniform color with subtle sun-bleached highlights, high density (120–140 strands/cm²), individual strand thickness 0.08 mm", "physics": "Gravity-induced cascade over left shoulder and back, gentle S-curve from wind or movement, 18 visible flyaways along crown and right side illuminated by rim light", "styling": "Center-parted, loose natural fall to mid-back length (approx. 65 cm), no visible product stiffness" }, "MAKEUP_AND_BODY_MODS": { "cosmetics": "Natural matte foundation (skin-matched #F5D9C8), soft brown brow pencil, black winged eyeliner on visible lower lash line, nude-pink lip tint, glossy clear topcoat on nails (#FFFFFF with 80 % gloss specular)", "tattoos": "None visible on exposed skin surfaces", "piercings": "None visible" }, "BIOMECHANICS_AND_KINEMATICS": { "spine_pelvis": "Mild lumbar lordosis (approx. 28°), anterior pelvic tilt 12°, creating pronounced gluteal projection", "limbs": "Right shoulder abducted 85°, elbow flexed 110° (hand covering face); left shoulder abducted 35°, elbow flexed 70° (hand on hip); hips rotated 35° camera-left; right knee extended 175°, left knee flexed 165° with weight shifted to left leg; ankles dorsiflexed 10°", "digits": "Right hand: fingers 2–5 extended and slightly spread (covering eyes/nose, 4 mm gaps), thumb tucked under chin, 0.8 kg pressure on face; left hand: fingers 2–5 spread across left gluteal quadrant, thumb on iliac crest, nails pressing 0.3 kg into fabric/skin; all fingernails 12 mm length, square-oval shape" }, "CLOTH_SIMULATION_AND_PHYSICS": { "layer_1_strapless_bandeau_top": { "material": "Matte cotton-elastane jersey, 220 GSM, 4-way stretch, 80 denier opacity", "opacity_map": "100 % opaque on breasts, slight shear at underbust hem revealing 2 mm skin shadow", "tension_physics": "Horizontal stretch lines radiating from side seams under breast weight, 3 mm fabric roll at top edge", "skin_interaction": "Mild skin compression (1 mm indentation) at underbust, no visible nipple protrusion through fabric" }, "layer_2_mini_skirt": { "material": "Lightweight cotton twill, 180 GSM, flared A-line cut with ruffled hem, 60 denier", "opacity_map": "98 % opaque where settled, 0 % where lifted exposing gluteal skin", "tension_physics": "Radial stress wrinkles from left hand grip point, fabric bunching upward 8 cm above natural waist creating exposed lower gluteal crescent", "skin_interaction": "Skirt hem digging 2 mm into upper thigh fat creating soft muffin-top shelf, direct skin-to-fabric contact on right glute with visible fabric lift shadow" }, "layer_3_crew_socks": { "material": "Ribbed cotton, 280 GSM, mid-calf height", "opacity_map": "100 % opaque", "tension_physics": "Slight bunching at ankle fold (3 mm accordion effect)", "skin_interaction": "Mild calf compression creating 1 mm skin bulge above sock cuff" }, "layer_4_chunky_sneakers": { "material": "Synthetic leather upper with rubber sole, 40 mm platform, white laces tied in bow", "opacity_map": "100 % opaque", "tension_physics": "Laces under moderate tension, no creasing on toe box", "skin_interaction": "Sock fabric compressed 2 mm between ankle bone and shoe collar" } }, "SOFT_TISSUE_PHYSICS": { "gravity_impact": "Gluteal hemispheres (right more prominent) hanging 18 mm below natural skirt line due to fabric lift, creating rounded lower pole projection; upper thigh soft tissue slightly dimpled against left leg weight shift", "compression": "Left gluteal flesh compressed 4 mm against left hand palm, mild skin bulging between fingers; right thigh soft tissue flattened 3 mm where skirt hem presses" }, "ENVIRONMENT_AND_PROPS": { "contact_surfaces": "Cracked asphalt pavement (Ra roughness 1.2 mm), dark grey with moss in fissures; subject weight distributed 65 % left foot, 35 % right foot causing 0.5 mm sole compression", "depth_of_field": "Subject sharp from toes to hair tips, background trees blurred starting 4 m behind (bokeh circles 25–40 px diameter on highlights)" } }
The character and environment in Figure 1 remain unchanged - High motion, fast movement, extreme dynamic effect. FPV first‑person follow‑cam, always close to the ground, moving up and down synchronously. A handsome boy with long flowing hair wearing a skirt performs high‑difficulty skateboarding tricks on an empty city street at night. 0-2s: Sprints down a slope at 80km/h, low center of gravity, hair and skirt blown back by strong wind. 2-4s: Enters a sharp turn, executes a tailbrake drift – rubber wheels scrape asphalt, sending out bright sparks. 4-6s: Kickflip into a 180° mid‑air spin, the skateboard rotating 360° precisely under his feet. 6-10s: Explodes out of the turn, leaps into a 360° grab, body fully extended, landing smoothly without wobble. Late‑night city background. Wet asphalt reflects mixed neon and warm yellow streetlight. Blurred car headlights in the distance, dark building outlines on both sides. Deep navy sky with a few sparse stars. Cool neon mixed with warm streetlight creates sharp reflections on the skateboard’s metal trucks and wheels. A clear black silhouette of the boy is cast on the ground. Strong motion blur and speed lines. High‑detail 3D anime style, cinematic lighting, 8K resolution.
A high-resolution, dynamic photograph of a single 500ml sleek aluminum beverage can (matte finish, black body). The can rests diagonally on a wet asphalt surface at night. Neon signs of a city street are blurred in the background, creating strong, vibrant reflections on the wet asphalt and the can itself. **BRAND DETAILS (CRITICAL):** * **Brand Logo:** Small, white, and centered at the top of the can. * **Primary Color:** The can's text and graphic accents must use a bright **electric lime green (Hex: #90EE90)**. * **Call to Action Text:** Clearly readable text on the lower third of the can must state: **"MAX BOOST FORMULA"** in a bold, stylized, sans-serif font. * **Effect:** Add heavy, visible condensation on the can, suggesting extreme cold. **LIGHTING & STYLE:** Cinematic, moody, highly saturated neon lighting, sharp focus on the can, deep depth of field (shallow background blur). Perfect for a social media ad.
A young couple from the 1950s walking along the wide, asphalted streets of Vali Asr Street (formerly Pahlavi Street) in Tehran. The scene is set in the heart of the city, with the distinct architecture and atmosphere of the time. The girl, with voluminous, curly hair, cat-eye eyeliner, and red lipstick, wears a floral patterned dress with a wide collar and a flared skirt typical of the 1950s. The boy, with neatly styled hair and a thin mustache, wears a light-colored wide-collared suit with a shirt and thin tie. The couple walks hand in hand, surrounded by a few pedestrians. The street is wide and lined with tall plane trees, casting dappled shadows onto the asphalt. Streetlamps, situated near the edge of the sidewalk, illuminate the path. The classic Persian storefronts have minimal signage, some in traditional fonts. A few old cars from the era drive by, and a tram passes in the background. The atmosphere is lively but not crowded, with the gentle hum of the city in the air. Sunlight filters through the trees, casting a warm, golden glow over the scene. The camera angle is slightly from behind the couple, allowing the street to stretch ahead with the iconic trees and towering buildings of the time visible in the background, evoking the nostalgic charm of 1950s Tehran.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
A detailed, photorealistic, cinematic vertical medium-full shot of an attractive young East Asian woman sitting on a wet, rain-slicked street at night during a heavy rainstorm. Shot Angle & Pose: Captured from a slightly high eye-level perspective looking down. The subject is sitting directly on the wet asphalt, her knees drawn up toward her chest in a huddled posture. Her left hand rests on her wet hair, while her right arm drapes casually over her leg. She looks directly into the lens with a calm, pensive, and vulnerable expression, her lips slightly parted. Subject Appearance: She has a flawless, porcelain complexion with a detailed wet skin texture, covered in water droplets. Her jet-black hair is completely wet and messy, clinging to her face and shoulders in damp strands. Her facial features are delicate, characterized by large expressive dark eyes, subtle dark eyeshadow, and soft, natural coral-pink lips. Character Figure: She possesses a slender and athletic hourglass figure. Her physique is characterized by an exceptionally slender waist and long, shapely, toned legs. Her curvaceous silhouette is highlighted by her seated, huddled posture and the semi-translucent nature of her wet clothing. Outfit Details: She is wearing a casual, minimalist "wet-look" ensemble: Shirt: An oversized, long-sleeved white button-down shirt. The cotton fabric is completely saturated with rainwater, making it semi-translucent and causing it to cling tightly to her torso and arms. Bottoms: Simple, form-fitting black shorts or panties. Setting & Lighting: Setting: A dark, moody street or alleyway at night in the pouring rain. The ground is a wet, reflective asphalt road. In the background on the left, a car’s headlights are turned on, casting a bright white flare. On the right, blurred, cool-blue fluorescent street lights are visible in soft focus under a covered structure. Lighting: Cool-toned, high-contrast night lighting. The powerful light from the car headlights and streetlights creates brilliant highlights on her wet skin, her hair, and her translucent wet white shirt. The wet asphalt creates sharp, detailed reflections of the lights, with the rest of the scene falling into deep, dark blue shadows. 8k resolution, raw photo aesthetic, wet look, pouring rain, car headlights, wet asphalt reflections, white button-down shirt, sharp focus on the subject, high-fidelity texture rendering, blue and white color palette, cinematic composition, hyper-realistic skin and wet fabric textures.
The character and environment in Figure 1 remain unchanged - High motion, fast movement, extreme dynamic effect. FPV first‑person follow‑cam, always close to the ground, moving up and down synchronously. A handsome boy with long flowing hair wearing a skirt performs high‑difficulty skateboarding tricks on an empty city street at night. 0-2s: Sprints down a slope at 80km/h, low center of gravity, hair and skirt blown back by strong wind. 2-4s: Enters a sharp turn, executes a tailbrake drift – rubber wheels scrape asphalt, sending out bright sparks. 4-6s: Kickflip into a 180° mid‑air spin, the skateboard rotating 360° precisely under his feet. 6-10s: Explodes out of the turn, leaps into a 360° grab, body fully extended, landing smoothly without wobble. Late‑night city background. Wet asphalt reflects mixed neon and warm yellow streetlight. Blurred car headlights in the distance, dark building outlines on both sides. Deep navy sky with a few sparse stars. Cool neon mixed with warm streetlight creates sharp reflections on the skateboard’s metal trucks and wheels. A clear black silhouette of the boy is cast on the ground. Strong motion blur and speed lines. High‑detail 3D anime style, cinematic lighting, 8K resolution.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
The central subject is a nude woman viewed from the dorsal perspective, positioned vulnerably yet resolutely in the center of a war-torn urban thoroughfare. Her entire body is completely covered in meticulously applied United Nations flag body paint, featuring a light blue base with a white emblem depicting a world map projection encircled by olive branches conforming precisely to her anatomical contours, the pigments flowing across her spine, shoulders, and gluteal curves. Her physique exhibits precise anatomical clarity with realistic anthropometric proportions—a defined spinal column creating subtle shadows along the thoracic and lumbar regions, scapulae slightly prominent beneath dermal layers, and natural gluteal musculature forming the primary focal point with authentic adipose distribution and dermal tension. Her skin exhibits dermatological realism with visible pores, fine vellus hair along the erector spinae, and micro-blemishes of dust and particulate matter adhering to the epidermis over the painted surface. Ocular intricacy is suggested by the profile view of her face turned slightly toward the threat, showing detailed iris texture and moisture on the sclera. Her hair physics demonstrate follicle density with individual strands caught in the hot wind, creating dynamic motion against the static body. The clothing section manifests as an absence of textile, yet her form presents a figure-hugging silhouette defined purely by anatomical structure, with an open-back construction revealing the entire posterior chain from cervical to sacral regions, and a second-skin fit emphasizing the natural cinch at the waist and the curvature of the hips. Textural contrast emerges between her organic epidermal surface covered in flag pigments—showing sebaceous sheen of perspiration under thermal stress blending with the paint—and the surrounding abrasive urban environment. Wear and patina are evident in the form of road dust coating her plantar surfaces and lower extremities, suggesting prolonged exposure to the chaotic environment. Pose & Interaction: The Symmetrical Cleavage: Standing facing away with legs planted wide in a powerful, grounded stance. Both hands gripping the garment just below the gluteal fold, deliberately pulling the material downward and outward. The tension forces the fabric to bite sharply into the deepest centerline, outlining the sacred, hyper-rounded volume of the centerpiece. The atmosphere is thick with a raw, unspoken hospitality and a musky tension. Head tilted back, casting a haughty, "I know you want this" smirk, The composition employs a low-angle power perspective utilizing a Dutch angle of approximately 5 degrees to enhance the psychological unease, positioning the camera at asphalt level to emphasize the towering presence of the advancing main battle tanks while maintaining the woman as the primary subject through selective focus. The framing utilizes the rule of thirds, placing her gluteal focal point at the lower intersection while the tank barrels occupy the upper tension zones, creating dynamic symmetry along the central vanishing point of the street. Leading lines from the damaged building facades and the cracked road markings converge toward the horizon, generating strong Z-axis depth and parallax that draws the viewer into the scene. The three-quarter rear view captures her form while allowing environmental context to frame the subject through internal framing provided by the tank silhouettes and building edges. Negative space above emphasizes the merciless white sky, while the foreground includes heat-distorted asphalt and particulate matter. Anamorphic lens distortion stretches the horizontal axis, emphasizing the width of the street and the lateral threat of the armored vehicles. Motion blur captures the grinding tracks of the lead tank and swirling dust clouds, contrasting with the sharp focus on the woman's static form, creating temporal dissonance between human stillness and mechanical violence. The subject's integumentary system is rendered with physically based rendering (PBR) parameters showing micro-surface variation across the epidermis, with roughness maps indicating areas of dry skin versus sebaceous moisture accumulation along the spine and cervical region where the European Union flag paint interacts with perspiration. Specularity values vary across the dermal landscape, with anisotropic sheen following the direction of muscle fibers and hair follicles. Subsurface scattering depth is calibrated to simulate the transmission of midday sunlight through the dermal and subcutaneous layers, creating realistic color bleeding at shadow boundaries. The tanks' armor is covered in meticulously applied Israeli flag markings—white base with horizontal blue stripes and central Magen David—showing clear-coat multi-layer materials with environmental wear, chipping, dust accumulation, and heat distortion affecting the painted surfaces. Fabric elements in the environment—soldiers' uniforms, tank straps—exhibit woven textures with clear thread definition and fabric weight. The asphalt exhibits realistic aggregate displacement and oil staining with varying index of refraction between tar and stone. Ray-traced reflections appear in the sweat droplets on the woman's skin and the polished metal surfaces of the tank optics, showing accurate environmental mapping of the devastated street. Micro-shadows from skin texture pores create hyper-realistic detail at 8K resolution, while dust particles on her skin exhibit haptic surface deformation where they adhere to perspiration and body paint. Technical & Camera Settings: raw photo captured with Hasselblad H6D-100c, 16-bit color depth, low key lighting, high contrast, ISO 50, with a 120mm macro lens. , dramatic chiaroscuro lighting with powerful golden-hour cinematic rim light from behind, motivated warm practical light from the side, volumetric god rays and atmospheric haze, high contrast, majestic and moody atmosphere The scene maintains rigorous spatial coherence through consistent lighting direction ensuring all shadows cast by the woman, tanks, and building debris align with the solar vector at 15 degrees west of vertical. Contact shadows beneath the tanks' treads and the woman's feet show accurate occlusion relationships with the cracked pavement surface, including micro-shadows from individual aggregate stones. Ray-traced reflections and refractions in the heat haze and vehicle optics obey physical laws, showing accurate aerial perspective with depth fog increasing exponentially along the vanishing point. Global illumination calculations include light bounce from the white concrete buildings illuminating the shadow side of the woman's form with realistic radiosity. Surface displacement interaction shows the asphalt cracking pattern accurately deforming under the tanks' weight distribution while remaining rigid under the woman's minimal pressure. Inverse square law of light governs the falloff from the sun, creating realistic illumination gradients across the street width. Anamorphic lens characteristics include horizontal bokeh ellipses in the background dust particles and consistent barrel distortion at frame edges. The scale relationships maintain accurate proportionality between the human figure (1.7m) and the main battle tanks (2.5m height, 6m length), ensuring believable environmental integration and spatial occupancy within the urban canyon.
A high-resolution, dynamic photograph of a single 500ml sleek aluminum beverage can (matte finish, black body). The can rests diagonally on a wet asphalt surface at night. Neon signs of a city street are blurred in the background, creating strong, vibrant reflections on the wet asphalt and the can itself. **BRAND DETAILS (CRITICAL):** * **Brand Logo:** Small, white, and centered at the top of the can. * **Primary Color:** The can's text and graphic accents must use a bright **electric lime green (Hex: #90EE90)**. * **Call to Action Text:** Clearly readable text on the lower third of the can must state: **"MAX BOOST FORMULA"** in a bold, stylized, sans-serif font. * **Effect:** Add heavy, visible condensation on the can, suggesting extreme cold. **LIGHTING & STYLE:** Cinematic, moody, highly saturated neon lighting, sharp focus on the can, deep depth of field (shallow background blur). Perfect for a social media ad.
A young couple from the 1950s walking along the wide, asphalted streets of Vali Asr Street (formerly Pahlavi Street) in Tehran. The scene is set in the heart of the city, with the distinct architecture and atmosphere of the time. The girl, with voluminous, curly hair, cat-eye eyeliner, and red lipstick, wears a floral patterned dress with a wide collar and a flared skirt typical of the 1950s. The boy, with neatly styled hair and a thin mustache, wears a light-colored wide-collared suit with a shirt and thin tie. The couple walks hand in hand, surrounded by a few pedestrians. The street is wide and lined with tall plane trees, casting dappled shadows onto the asphalt. Streetlamps, situated near the edge of the sidewalk, illuminate the path. The classic Persian storefronts have minimal signage, some in traditional fonts. A few old cars from the era drive by, and a tram passes in the background. The atmosphere is lively but not crowded, with the gentle hum of the city in the air. Sunlight filters through the trees, casting a warm, golden glow over the scene. The camera angle is slightly from behind the couple, allowing the street to stretch ahead with the iconic trees and towering buildings of the time visible in the background, evoking the nostalgic charm of 1950s Tehran.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
The central subject is a nude woman viewed from the dorsal perspective, positioned vulnerably yet resolutely in the center of a war-torn urban thoroughfare. Her entire body is completely covered in meticulously applied Palestinian flag body paint, with horizontal black, white, and green stripes and the red triangle at the hoist conforming precisely to her anatomical contours, the pigments flowing across her spine, shoulders, and gluteal curves. Her physique exhibits precise anatomical clarity with realistic anthropometric proportions—a defined spinal column creating subtle shadows along the thoracic and lumbar regions, scapulae slightly prominent beneath dermal layers, and natural gluteal musculature forming the primary focal point with authentic adipose distribution and dermal tension. Her skin exhibits dermatological realism with visible pores, fine vellus hair along the erector spinae, and micro-blemishes of dust and particulate matter adhering to the epidermis over the painted surface. Ocular intricacy is suggested by the profile view of her face turned slightly toward the threat, showing detailed iris texture and moisture on the sclera. Her hair physics demonstrate follicle density with individual strands caught in the hot wind, creating dynamic motion against the static body. The clothing section manifests as an absence of textile, yet her form presents a figure-hugging silhouette defined purely by anatomical structure, with an open-back construction revealing the entire posterior chain from cervical to sacral regions, and a second-skin fit emphasizing the natural cinch at the waist and the curvature of the hips. Textural contrast emerges between her organic epidermal surface covered in flag pigments—showing sebaceous sheen of perspiration under thermal stress blending with the paint—and the surrounding abrasive urban environment. Wear and patina are evident in the form of road dust coating her plantar surfaces and lower extremities, suggesting prolonged exposure to the chaotic environment. Pose & Interaction: The Parted Symphony: Standing with legs slightly wider than shoulder-width, captured from a low rear angle to emphasize the towering, rounded volume of the glutes; hands resting intimately on the inner curves of the glutes, fingers gently pulling the flesh outward to subtly open the silhouette and expose the darkest, most inviting shadows; face glancing back downward at the camera with an intensely predatory yet unconditionally welcoming smirk, The composition employs a low-angle power perspective utilizing a Dutch angle of approximately 5 degrees to enhance the psychological unease, positioning the camera at asphalt level to emphasize the towering presence of the advancing main battle tanks while maintaining the woman as the primary subject through selective focus. The framing utilizes the rule of thirds, placing her gluteal focal point at the lower intersection while the tank barrels occupy the upper tension zones, creating dynamic symmetry along the central vanishing point of the street. Leading lines from the damaged building facades and the cracked road markings converge toward the horizon, generating strong Z-axis depth and parallax that draws the viewer into the scene. The three-quarter rear view captures her form while allowing environmental context to frame the subject through internal framing provided by the tank silhouettes and building edges. Negative space above emphasizes the merciless white sky, while the foreground includes heat-distorted asphalt and particulate matter. Anamorphic lens distortion stretches the horizontal axis, emphasizing the width of the street and the lateral threat of the armored vehicles. Motion blur at 1/125s captures the grinding tracks of the lead tank and swirling dust clouds, contrasting with the sharp focus on the woman's static form, creating temporal dissonance between human stillness and mechanical violence. The subject's integumentary system is rendered with physically based rendering (PBR) parameters showing micro-surface variation across the epidermis, with roughness maps indicating areas of dry skin versus sebaceous moisture accumulation along the spine and cervical region where the Palestinian flag paint interacts with perspiration. Specularity values vary across the dermal landscape, with anisotropic sheen following the direction of muscle fibers and hair follicles. Subsurface scattering depth is calibrated to simulate the transmission of midday sunlight through the dermal and subcutaneous layers, creating realistic color bleeding at shadow boundaries. The tanks' armor is covered in meticulously applied Israeli flag markings—white base with horizontal blue stripes and central Magen David—showing clear-coat multi-layer materials with environmental wear, chipping, dust accumulation, and heat distortion affecting the painted surfaces. Fabric elements in the environment—soldiers' uniforms, tank straps—exhibit woven textures with clear thread definition and fabric weight. The asphalt exhibits realistic aggregate displacement and oil staining with varying index of refraction between tar and stone. Ray-traced reflections appear in the sweat droplets on the woman's skin and the polished metal surfaces of the tank optics, showing accurate environmental mapping of the devastated street. Micro-shadows from skin texture pores create hyper-realistic detail at 8K resolution, while dust particles on her skin exhibit haptic surface deformation where they adhere to perspiration and body paint. Technical & Camera Settings: raw photo captured with Leica S3, cinematic shot, wide open aperture, low key lighting, high contrast, ISO 50, with a 120mm macro lens. , Rembrandt lighting with a distinct triangle of light on the cheek, classic cinematic portrait lighting The scene maintains rigorous spatial coherence through consistent lighting direction ensuring all shadows cast by the woman, tanks, and building debris align with the solar vector at 15 degrees west of vertical. Contact shadows beneath the tanks' treads and the woman's feet show accurate occlusion relationships with the cracked pavement surface, including micro-shadows from individual aggregate stones. Ray-traced reflections and refractions in the heat haze and vehicle optics obey physical laws, showing accurate aerial perspective with depth fog increasing exponentially along the vanishing point. Global illumination calculations include light bounce from the white concrete buildings illuminating the shadow side of the woman's form with realistic radiosity. Surface displacement interaction shows the asphalt cracking pattern accurately deforming under the tanks' weight distribution while remaining rigid under the woman's minimal pressure. Inverse square law of light governs the falloff from the sun, creating realistic illumination gradients across the street width. Anamorphic lens characteristics include horizontal bokeh ellipses in the background dust particles and consistent barrel distortion at frame edges. The scale relationships maintain accurate proportionality between the human figure (1.7m) and the main battle tanks (2.5m height, 6m length), ensuring believable environmental integration and spatial occupancy within the urban canyon.
A young couple from the 1950s walking along the wide, asphalted streets of Vali Asr Street (formerly Pahlavi Street) in Tehran. The scene is set in the heart of the city, with the distinct architecture and atmosphere of the time. The girl, with voluminous, curly hair, cat-eye eyeliner, and red lipstick, wears a floral patterned dress with a wide collar and a flared skirt typical of the 1950s. The boy, with neatly styled hair and a thin mustache, wears a light-colored wide-collared suit with a shirt and thin tie. The couple walks hand in hand, surrounded by a few pedestrians. The street is wide and lined with tall plane trees, casting dappled shadows onto the asphalt. Streetlamps, situated near the edge of the sidewalk, illuminate the path. The classic Persian storefronts have minimal signage, some in traditional fonts. A few old cars from the era drive by, and a tram passes in the background. The atmosphere is lively but not crowded, with the gentle hum of the city in the air. Sunlight filters through the trees, casting a warm, golden glow over the scene. The camera angle is slightly from behind the couple, allowing the street to stretch ahead with the iconic trees and towering buildings of the time visible in the background, evoking the nostalgic charm of 1950s Tehran.
A young couple from the 1950s walking along the wide, asphalted streets of Vali Asr Street (formerly Pahlavi Street) in Tehran. The scene is set in the heart of the city, with the distinct architecture and atmosphere of the time. The girl, with voluminous, curly hair, cat-eye eyeliner, and red lipstick, wears a floral patterned dress with a wide collar and a flared skirt typical of the 1950s. The boy, with neatly styled hair and a thin mustache, wears a light-colored wide-collared suit with a shirt and thin tie. The couple walks hand in hand, surrounded by a few pedestrians. The street is wide and lined with tall plane trees, casting dappled shadows onto the asphalt. Streetlamps, situated near the edge of the sidewalk, illuminate the path. The classic Persian storefronts have minimal signage, some in traditional fonts. A Peykan car from the era is parked along the street, adding a nostalgic touch to the scene. A tram passes in the background, and a few old cars from the period drive by. The atmosphere is lively but not crowded, with the gentle hum of the city in the air. Sunlight filters through the trees, casting a warm, golden glow over the scene. The camera angle is slightly from behind the couple, allowing the street to stretch ahead with the iconic trees and towering buildings of the time visible in the background, evoking the nostalgic charm of 1950s Tehran.
The central subject is a nude woman viewed from the dorsal perspective, positioned vulnerably yet resolutely in the center of a war-torn urban thoroughfare. Her entire body is completely covered in meticulously applied United Nations flag body paint, featuring a light blue base with a white emblem depicting a world map projection encircled by olive branches conforming precisely to her anatomical contours, the pigments flowing across her spine, shoulders, and gluteal curves. Her physique exhibits precise anatomical clarity with realistic anthropometric proportions—a defined spinal column creating subtle shadows along the thoracic and lumbar regions, scapulae slightly prominent beneath dermal layers, and natural gluteal musculature forming the primary focal point with authentic adipose distribution and dermal tension. Her skin exhibits dermatological realism with visible pores, fine vellus hair along the erector spinae, and micro-blemishes of dust and particulate matter adhering to the epidermis over the painted surface. Ocular intricacy is suggested by the profile view of her face turned slightly toward the threat, showing detailed iris texture and moisture on the sclera. Her hair physics demonstrate follicle density with individual strands caught in the hot wind, creating dynamic motion against the static body. The clothing section manifests as an absence of textile, yet her form presents a figure-hugging silhouette defined purely by anatomical structure, with an open-back construction revealing the entire posterior chain from cervical to sacral regions, and a second-skin fit emphasizing the natural cinch at the waist and the curvature of the hips. Textural contrast emerges between her organic epidermal surface covered in flag pigments—showing sebaceous sheen of perspiration under thermal stress blending with the paint—and the surrounding abrasive urban environment. Wear and patina are evident in the form of road dust coating her plantar surfaces and lower extremities, suggesting prolonged exposure to the chaotic environment. Pose & Interaction: The Symmetrical Cleavage: Standing facing away with legs planted wide in a powerful, grounded stance. Both hands gripping the garment just below the gluteal fold, deliberately pulling the material downward and outward. The tension forces the fabric to bite sharply into the deepest centerline, outlining the sacred, hyper-rounded volume of the centerpiece. The atmosphere is thick with a raw, unspoken hospitality and a musky tension. Head tilted back, casting a haughty, "I know you want this" smirk, The composition employs a low-angle power perspective utilizing a Dutch angle of approximately 5 degrees to enhance the psychological unease, positioning the camera at asphalt level to emphasize the towering presence of the advancing main battle tanks while maintaining the woman as the primary subject through selective focus. The framing utilizes the rule of thirds, placing her gluteal focal point at the lower intersection while the tank barrels occupy the upper tension zones, creating dynamic symmetry along the central vanishing point of the street. Leading lines from the damaged building facades and the cracked road markings converge toward the horizon, generating strong Z-axis depth and parallax that draws the viewer into the scene. The three-quarter rear view captures her form while allowing environmental context to frame the subject through internal framing provided by the tank silhouettes and building edges. Negative space above emphasizes the merciless white sky, while the foreground includes heat-distorted asphalt and particulate matter. Anamorphic lens distortion stretches the horizontal axis, emphasizing the width of the street and the lateral threat of the armored vehicles. Motion blur captures the grinding tracks of the lead tank and swirling dust clouds, contrasting with the sharp focus on the woman's static form, creating temporal dissonance between human stillness and mechanical violence. The subject's integumentary system is rendered with physically based rendering (PBR) parameters showing micro-surface variation across the epidermis, with roughness maps indicating areas of dry skin versus sebaceous moisture accumulation along the spine and cervical region where the European Union flag paint interacts with perspiration. Specularity values vary across the dermal landscape, with anisotropic sheen following the direction of muscle fibers and hair follicles. Subsurface scattering depth is calibrated to simulate the transmission of midday sunlight through the dermal and subcutaneous layers, creating realistic color bleeding at shadow boundaries. The tanks' armor is covered in meticulously applied Israeli flag markings—white base with horizontal blue stripes and central Magen David—showing clear-coat multi-layer materials with environmental wear, chipping, dust accumulation, and heat distortion affecting the painted surfaces. Fabric elements in the environment—soldiers' uniforms, tank straps—exhibit woven textures with clear thread definition and fabric weight. The asphalt exhibits realistic aggregate displacement and oil staining with varying index of refraction between tar and stone. Ray-traced reflections appear in the sweat droplets on the woman's skin and the polished metal surfaces of the tank optics, showing accurate environmental mapping of the devastated street. Micro-shadows from skin texture pores create hyper-realistic detail at 8K resolution, while dust particles on her skin exhibit haptic surface deformation where they adhere to perspiration and body paint. Technical & Camera Settings: raw photo captured with Hasselblad H6D-100c, 16-bit color depth, low key lighting, high contrast, ISO 50, with a 120mm macro lens. , dramatic chiaroscuro lighting with powerful golden-hour cinematic rim light from behind, motivated warm practical light from the side, volumetric god rays and atmospheric haze, high contrast, majestic and moody atmosphere The scene maintains rigorous spatial coherence through consistent lighting direction ensuring all shadows cast by the woman, tanks, and building debris align with the solar vector at 15 degrees west of vertical. Contact shadows beneath the tanks' treads and the woman's feet show accurate occlusion relationships with the cracked pavement surface, including micro-shadows from individual aggregate stones. Ray-traced reflections and refractions in the heat haze and vehicle optics obey physical laws, showing accurate aerial perspective with depth fog increasing exponentially along the vanishing point. Global illumination calculations include light bounce from the white concrete buildings illuminating the shadow side of the woman's form with realistic radiosity. Surface displacement interaction shows the asphalt cracking pattern accurately deforming under the tanks' weight distribution while remaining rigid under the woman's minimal pressure. Inverse square law of light governs the falloff from the sun, creating realistic illumination gradients across the street width. Anamorphic lens characteristics include horizontal bokeh ellipses in the background dust particles and consistent barrel distortion at frame edges. The scale relationships maintain accurate proportionality between the human figure (1.7m) and the main battle tanks (2.5m height, 6m length), ensuring believable environmental integration and spatial occupancy within the urban canyon.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
the ground slopes downward, leading to a vertical asphalt street, the dark asphalt appears frosty, reflecting the dim glow of streetlights in the icy air, beyond the street, rugged mountain hills, their peaks dusted with a faint shimmer of snow, layered silhouettes of the mountains create depth, fading into the midnight horizon, scattered trees in the foreground reach upward, their branches stiff from the biting cold, the sky is cloudless, a deep midnight blue, punctuated by the distant twinkle of stars, moonlight spills onto the asphalt, creating pale silvery reflections in the cold air, soft shadows stretch beneath the trees, nature and roadways intertwine, forming a striking balance under the night sky,
Wet asphalt road, autumnal perspective. Yellow lane lines on a dark, wet road, reflecting the surrounding foliage. Dense forest lines the road, with vibrant, golden-orange and muted green trees. Fallen autumn leaves, some oak leaves, litter the road. Water puddles reflect the trees and sky. Low angle, close-up perspective focuses on the road's texture and the details of the yellow lines. Moody, serene autumnal atmosphere. Muted tones of gray, dark brown, deep orange, and muted yellow. The lighting is soft, diffused, characteristic of an overcast day. Road texture is visible, showing wetness and the slight imperfections of the asphalt. Yellow lane markers are prominent, with some visible wear and tear. Natural, organic, and detailed image. Photorealistic, artistic autumnal view.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
{ "RENDER_PIPELINE": { "optics": "35 mm equivalent smartphone lens (approx. 26 mm actual), f/1.9 aperture, focal plane locked on subject mid-torso at 1.8 m distance, circular bokeh with 7-blade diaphragm emulation visible in background foliage highlights, mild chromatic aberration on high-contrast tree edges, subtle lens flare at 4 o’clock position on right thigh", "film_emulation": "Digital CMOS sensor emulation (Sony IMX sensor equivalent), base ISO 100, zero visible noise, highlight roll-off soft with 2.2 gamma curve, natural daylight LUT with slight teal-orange grading in shadows, 8-bit sRGB output", "atmospherics": "Clear morning air (08:27 timestamp visible top-left), micro-dust particles suspended in volumetric god rays piercing canopy, fog density 0 %, light atmospheric perspective softening distant tree line" }, "LIGHTING_RIG": { "key_light": "Natural sunlight filtered through deciduous canopy, correlated color temperature 5800 K, incident angle 65° from upper camera-right, soft shadow edge transfer (penumbra ~8 cm on asphalt), no hard specular hotspots", "fill_light": "Diffuse sky bounce from open canopy gaps, fill ratio 1:2.5 relative to key, neutral 6500 K, no directional bias", "rim_hair_lights": "Strong rim from rear-right sunlight at 110° azimuth, 6200 K, creating 3 mm wide highlight halo along hair edges and left shoulder contour", "ambient_occlusion": "Deep micro-shadows in skin folds (under buttock crease, inner thigh contact, under bandeau hem), contact occlusion between fingers and face, skirt fabric and gluteal skin" }, "SUBJECT_BIOMETRICS_AND_TOPOLOGY": { "demographics": "Female, visually 19–22 years old, Eastern-European/Slavic phenotype (light Caucasian admixture), ecto-mesomorphic skeletal frame, visual BMI equivalent ~21, long-limbed proportions, pronounced lower-body adiposity with athletic muscle tone", "facial_geometry": "Oval face shape (partially occluded by right hand), high zygomatic prominence (cheekbones projecting 12 mm anteriorly), sharp mandibular angle with defined gonial flare, moderate chin projection (5 mm beyond subnasale vertical), smooth forehead", "nasal_and_ocular_structure": "Nose: straight dorsum with refined supra-tip break, narrow alar base (28 mm width), slightly upturned apex; eyes fully occluded by hand but visible orbital rim suggests almond shape with neutral canthal tilt (~0°), visible lower lash line and tear duct", "aura": "Playful-teasing confidence, deliberate erotic provocation through partial exposure, youthful carefree energy" }, "MICRO_ANATOMY_AND_SHADERS": { "epidermis": "Pore density low (fine on nose bridge, invisible on thighs), uniform light olive-tan tone, zero visible freckles or scars, subtle goosebumps on exposed upper arms from morning air", "dermis_and_vascular": "Subdermal veins faintly visible on inner forearms and dorsal hands (blue-green, 0.3 mm width), no capillary flush except faint pink undertone on cheeks and gluteal skin", "subsurface_scattering": "High SSS on earlobes, nasal tip, and exposed gluteal hemispheres (warm #FFCCAA transmission), moderate on inner thighs where light wraps around fabric edge", "surface_moisture": "Matte skin finish overall, trace sebum sheen on nasal bridge and forehead, single 0.5 mm sweat droplet at left temple hairline, no visible tears", "vellus_hair": "Fine peach-fuzz density on upper arms and outer thighs (0.1 mm length, catching rim light as golden halo)" }, "FACS_AND_MICRO_EXPRESSIONS": { "eyes": "Gaze vector fully occluded by right hand (fingers covering orbits and nasal bridge), inferred forward camera direction, pupil dilation unknown", "brows": "Right brow slightly arched (2 mm superior displacement at lateral tail), micro-tension indicating playful concealment", "mouth": "Lip parting 2 mm at center, upper lip slightly everted, lower lip full and glossy with natural mucosal moisture, teeth not visible, masseter relaxed" }, "HAIR_PHYSICS_AND_GROOMING": { "structure": "Level 6–7 golden-light-brown melanin base, root-to-tip uniform color with subtle sun-bleached highlights, high density (120–140 strands/cm²), individual strand thickness 0.08 mm", "physics": "Gravity-induced cascade over left shoulder and back, gentle S-curve from wind or movement, 18 visible flyaways along crown and right side illuminated by rim light", "styling": "Center-parted, loose natural fall to mid-back length (approx. 65 cm), no visible product stiffness" }, "MAKEUP_AND_BODY_MODS": { "cosmetics": "Natural matte foundation (skin-matched #F5D9C8), soft brown brow pencil, black winged eyeliner on visible lower lash line, nude-pink lip tint, glossy clear topcoat on nails (#FFFFFF with 80 % gloss specular)", "tattoos": "None visible on exposed skin surfaces", "piercings": "None visible" }, "BIOMECHANICS_AND_KINEMATICS": { "spine_pelvis": "Mild lumbar lordosis (approx. 28°), anterior pelvic tilt 12°, creating pronounced gluteal projection", "limbs": "Right shoulder abducted 85°, elbow flexed 110° (hand covering face); left shoulder abducted 35°, elbow flexed 70° (hand on hip); hips rotated 35° camera-left; right knee extended 175°, left knee flexed 165° with weight shifted to left leg; ankles dorsiflexed 10°", "digits": "Right hand: fingers 2–5 extended and slightly spread (covering eyes/nose, 4 mm gaps), thumb tucked under chin, 0.8 kg pressure on face; left hand: fingers 2–5 spread across left gluteal quadrant, thumb on iliac crest, nails pressing 0.3 kg into fabric/skin; all fingernails 12 mm length, square-oval shape" }, "CLOTH_SIMULATION_AND_PHYSICS": { "layer_1_strapless_bandeau_top": { "material": "Matte cotton-elastane jersey, 220 GSM, 4-way stretch, 80 denier opacity", "opacity_map": "100 % opaque on breasts, slight shear at underbust hem revealing 2 mm skin shadow", "tension_physics": "Horizontal stretch lines radiating from side seams under breast weight, 3 mm fabric roll at top edge", "skin_interaction": "Mild skin compression (1 mm indentation) at underbust, no visible nipple protrusion through fabric" }, "layer_2_mini_skirt": { "material": "Lightweight cotton twill, 180 GSM, flared A-line cut with ruffled hem, 60 denier", "opacity_map": "98 % opaque where settled, 0 % where lifted exposing gluteal skin", "tension_physics": "Radial stress wrinkles from left hand grip point, fabric bunching upward 8 cm above natural waist creating exposed lower gluteal crescent", "skin_interaction": "Skirt hem digging 2 mm into upper thigh fat creating soft muffin-top shelf, direct skin-to-fabric contact on right glute with visible fabric lift shadow" }, "layer_3_crew_socks": { "material": "Ribbed cotton, 280 GSM, mid-calf height", "opacity_map": "100 % opaque", "tension_physics": "Slight bunching at ankle fold (3 mm accordion effect)", "skin_interaction": "Mild calf compression creating 1 mm skin bulge above sock cuff" }, "layer_4_chunky_sneakers": { "material": "Synthetic leather upper with rubber sole, 40 mm platform, white laces tied in bow", "opacity_map": "100 % opaque", "tension_physics": "Laces under moderate tension, no creasing on toe box", "skin_interaction": "Sock fabric compressed 2 mm between ankle bone and shoe collar" } }, "SOFT_TISSUE_PHYSICS": { "gravity_impact": "Gluteal hemispheres (right more prominent) hanging 18 mm below natural skirt line due to fabric lift, creating rounded lower pole projection; upper thigh soft tissue slightly dimpled against left leg weight shift", "compression": "Left gluteal flesh compressed 4 mm against left hand palm, mild skin bulging between fingers; right thigh soft tissue flattened 3 mm where skirt hem presses" }, "ENVIRONMENT_AND_PROPS": { "contact_surfaces": "Cracked asphalt pavement (Ra roughness 1.2 mm), dark grey with moss in fissures; subject weight distributed 65 % left foot, 35 % right foot causing 0.5 mm sole compression", "depth_of_field": "Subject sharp from toes to hair tips, background trees blurred starting 4 m behind (bokeh circles 25–40 px diameter on highlights)" } }
A dramatic Formula 1 race is taking place on a professional circuit under heavy rain during a breathtaking sunset. Dark storm clouds mix with the warm shades of orange, pink, and purple in the sky, creating a striking contrast. Raindrops fall heavily, bouncing off the track and the sleek bodies of the cars, while water sprays behind them as they speed through the wet asphalt. In the lead is a Formula 1 car with a bold 60% red and 40% black color scheme, featuring an aerodynamic design. The number "11" is clearly displayed, and the name "Roca" is written on its body. Its main sponsor, "Quabu", is prominently featured on the car’s livery. The wet surface reflects the car’s colors as it pushes forward, leaving a trail of water spray behind. Chasing closely behind is another Formula 1 car, painted entirely in a deep metallic green, with no other primary colors. This car bears the number "18", with the name "Alex" displayed on its body, also showcasing the "Quabu" sponsorship. The rain-soaked track glistens under the lights and sunset, while water splashes from the tires as the green car fights to close the gap. Both cars are locked in an intense battle as they navigate a sharp turn, their tires struggling for grip on the slippery asphalt. The red-and-black car, driven by "Roca", is slightly ahead, while the green car, driven by "Alex", is aggressively trying to overtake. The rain adds a dramatic element, with droplets streaking through the air and reflections shimmering on the wet surface. In the background, blurred grandstands full of cheering fans can be seen, their umbrellas raised as they watch the thrilling race unfold.
A grotesquely obese, monstrous music industry executive stands in a dark, dystopian cityscape, his suit made of platinum records, his bloated belly hanging over his belt. His pants are half-down, revealing his obscene greed, while in front of him, a desperate indie hip-hop artist kneels, his expression filled with humiliation, pain, and frustration. His microphone dangles limply in his hand, his cracked 'wings of asphalt' barely holding him up. The industry giant smirks, holding a contract like a leash, tightening it around the rapper's neck. In the background, a carnival-like spectacle unfolds: faceless mainstream pop stars dance like puppets on strings, grotesque clowns with dollar-sign eyes throw fake awards into a roaring, soulless crowd. Neon billboards flash mindless slogans like 'STREAM OR DIE' and 'FAME FOR SALE.' The air is thick with smoke and despair, the city drowning in grey, the asphalt under the artist’s knees cracking under the weight of his broken dreams. The mood is dark, cold, and gritty—this is not a dream, but a nightmare of the music industry, where dignity is the price of exposure. --ar 16:9 --v 5.2 --style raw --q 2 --chaos 8 --stylize 900
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
The central subject is a nude woman viewed from the dorsal perspective, positioned vulnerably yet resolutely in the center of a war-torn urban thoroughfare. Her entire body is completely covered in meticulously applied United Nations flag body paint, featuring a light blue base with a white emblem depicting a world map projection encircled by olive branches conforming precisely to her anatomical contours, the pigments flowing across her spine, shoulders, and gluteal curves. Her physique exhibits precise anatomical clarity with realistic anthropometric proportions—a defined spinal column creating subtle shadows along the thoracic and lumbar regions, scapulae slightly prominent beneath dermal layers, and natural gluteal musculature forming the primary focal point with authentic adipose distribution and dermal tension. Her skin exhibits dermatological realism with visible pores, fine vellus hair along the erector spinae, and micro-blemishes of dust and particulate matter adhering to the epidermis over the painted surface. Ocular intricacy is suggested by the profile view of her face turned slightly toward the threat, showing detailed iris texture and moisture on the sclera. Her hair physics demonstrate follicle density with individual strands caught in the hot wind, creating dynamic motion against the static body. The clothing section manifests as an absence of textile, yet her form presents a figure-hugging silhouette defined purely by anatomical structure, with an open-back construction revealing the entire posterior chain from cervical to sacral regions, and a second-skin fit emphasizing the natural cinch at the waist and the curvature of the hips. Textural contrast emerges between her organic epidermal surface covered in flag pigments—showing sebaceous sheen of perspiration under thermal stress blending with the paint—and the surrounding abrasive urban environment. Wear and patina are evident in the form of road dust coating her plantar surfaces and lower extremities, suggesting prolonged exposure to the chaotic environment. Pose & Interaction: The Symmetrical Cleavage: Standing facing away with legs planted wide in a powerful, grounded stance. Both hands gripping the garment just below the gluteal fold, deliberately pulling the material downward and outward. The tension forces the fabric to bite sharply into the deepest centerline, outlining the sacred, hyper-rounded volume of the centerpiece. The atmosphere is thick with a raw, unspoken hospitality and a musky tension. Head tilted back, casting a haughty, "I know you want this" smirk, The composition employs a low-angle power perspective utilizing a Dutch angle of approximately 5 degrees to enhance the psychological unease, positioning the camera at asphalt level to emphasize the towering presence of the advancing main battle tanks while maintaining the woman as the primary subject through selective focus. The framing utilizes the rule of thirds, placing her gluteal focal point at the lower intersection while the tank barrels occupy the upper tension zones, creating dynamic symmetry along the central vanishing point of the street. Leading lines from the damaged building facades and the cracked road markings converge toward the horizon, generating strong Z-axis depth and parallax that draws the viewer into the scene. The three-quarter rear view captures her form while allowing environmental context to frame the subject through internal framing provided by the tank silhouettes and building edges. Negative space above emphasizes the merciless white sky, while the foreground includes heat-distorted asphalt and particulate matter. Anamorphic lens distortion stretches the horizontal axis, emphasizing the width of the street and the lateral threat of the armored vehicles. Motion blur captures the grinding tracks of the lead tank and swirling dust clouds, contrasting with the sharp focus on the woman's static form, creating temporal dissonance between human stillness and mechanical violence. The subject's integumentary system is rendered with physically based rendering (PBR) parameters showing micro-surface variation across the epidermis, with roughness maps indicating areas of dry skin versus sebaceous moisture accumulation along the spine and cervical region where the European Union flag paint interacts with perspiration. Specularity values vary across the dermal landscape, with anisotropic sheen following the direction of muscle fibers and hair follicles. Subsurface scattering depth is calibrated to simulate the transmission of midday sunlight through the dermal and subcutaneous layers, creating realistic color bleeding at shadow boundaries. The tanks' armor is covered in meticulously applied Israeli flag markings—white base with horizontal blue stripes and central Magen David—showing clear-coat multi-layer materials with environmental wear, chipping, dust accumulation, and heat distortion affecting the painted surfaces. Fabric elements in the environment—soldiers' uniforms, tank straps—exhibit woven textures with clear thread definition and fabric weight. The asphalt exhibits realistic aggregate displacement and oil staining with varying index of refraction between tar and stone. Ray-traced reflections appear in the sweat droplets on the woman's skin and the polished metal surfaces of the tank optics, showing accurate environmental mapping of the devastated street. Micro-shadows from skin texture pores create hyper-realistic detail at 8K resolution, while dust particles on her skin exhibit haptic surface deformation where they adhere to perspiration and body paint. Technical & Camera Settings: raw photo captured with Hasselblad H6D-100c, 16-bit color depth, low key lighting, high contrast, ISO 50, with a 120mm macro lens. , dramatic chiaroscuro lighting with powerful golden-hour cinematic rim light from behind, motivated warm practical light from the side, volumetric god rays and atmospheric haze, high contrast, majestic and moody atmosphere The scene maintains rigorous spatial coherence through consistent lighting direction ensuring all shadows cast by the woman, tanks, and building debris align with the solar vector at 15 degrees west of vertical. Contact shadows beneath the tanks' treads and the woman's feet show accurate occlusion relationships with the cracked pavement surface, including micro-shadows from individual aggregate stones. Ray-traced reflections and refractions in the heat haze and vehicle optics obey physical laws, showing accurate aerial perspective with depth fog increasing exponentially along the vanishing point. Global illumination calculations include light bounce from the white concrete buildings illuminating the shadow side of the woman's form with realistic radiosity. Surface displacement interaction shows the asphalt cracking pattern accurately deforming under the tanks' weight distribution while remaining rigid under the woman's minimal pressure. Inverse square law of light governs the falloff from the sun, creating realistic illumination gradients across the street width. Anamorphic lens characteristics include horizontal bokeh ellipses in the background dust particles and consistent barrel distortion at frame edges. The scale relationships maintain accurate proportionality between the human figure (1.7m) and the main battle tanks (2.5m height, 6m length), ensuring believable environmental integration and spatial occupancy within the urban canyon.
the ground slopes downward, leading to a vertical asphalt street, the dark asphalt appears frosty, reflecting the dim glow of streetlights in the icy air, beyond the street, rugged mountain hills, their peaks dusted with a faint shimmer of snow, layered silhouettes of the mountains create depth, fading into the midnight horizon, scattered trees in the foreground reach upward, their branches stiff from the biting cold, the sky is cloudless, a deep midnight blue, punctuated by the distant twinkle of stars, moonlight spills onto the asphalt, creating pale silvery reflections in the cold air, soft shadows stretch beneath the trees, nature and roadways intertwine, forming a striking balance under the night sky,
A high-resolution, dynamic photograph of a single 500ml sleek aluminum beverage can (matte finish, black body). The can rests diagonally on a wet asphalt surface at night. Neon signs of a city street are blurred in the background, creating strong, vibrant reflections on the wet asphalt and the can itself. **BRAND DETAILS (CRITICAL):** * **Brand Logo:** Small, white, and centered at the top of the can. * **Primary Color:** The can's text and graphic accents must use a bright **electric lime green (Hex: #90EE90)**. * **Call to Action Text:** Clearly readable text on the lower third of the can must state: **"MAX BOOST FORMULA"** in a bold, stylized, sans-serif font. * **Effect:** Add heavy, visible condensation on the can, suggesting extreme cold. **LIGHTING & STYLE:** Cinematic, moody, highly saturated neon lighting, sharp focus on the can, deep depth of field (shallow background blur). Perfect for a social media ad.
A grotesquely obese, monstrous music industry executive stands in a dark, dystopian cityscape, his suit made of platinum records, his bloated belly hanging over his belt. His pants are half-down, revealing his obscene greed, while in front of him, a desperate indie hip-hop artist kneels, his expression filled with humiliation, pain, and frustration. His microphone dangles limply in his hand, his cracked 'wings of asphalt' barely holding him up. The industry giant smirks, holding a contract like a leash, tightening it around the rapper's neck. In the background, a carnival-like spectacle unfolds: faceless mainstream pop stars dance like puppets on strings, grotesque clowns with dollar-sign eyes throw fake awards into a roaring, soulless crowd. Neon billboards flash mindless slogans like 'STREAM OR DIE' and 'FAME FOR SALE.' The air is thick with smoke and despair, the city drowning in grey, the asphalt under the artist’s knees cracking under the weight of his broken dreams. The mood is dark, cold, and gritty—this is not a dream, but a nightmare of the music industry, where dignity is the price of exposure. --ar 16:9 --v 5.2 --style raw --q 2 --chaos 8 --stylize 900
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
The central subject is a nude woman viewed from the dorsal perspective, positioned vulnerably yet resolutely in the center of a war-torn urban thoroughfare. Her entire body is completely covered in meticulously applied Palestinian flag body paint, with horizontal black, white, and green stripes and the red triangle at the hoist conforming precisely to her anatomical contours, the pigments flowing across her spine, shoulders, and gluteal curves. Her physique exhibits precise anatomical clarity with realistic anthropometric proportions—a defined spinal column creating subtle shadows along the thoracic and lumbar regions, scapulae slightly prominent beneath dermal layers, and natural gluteal musculature forming the primary focal point with authentic adipose distribution and dermal tension. Her skin exhibits dermatological realism with visible pores, fine vellus hair along the erector spinae, and micro-blemishes of dust and particulate matter adhering to the epidermis over the painted surface. Ocular intricacy is suggested by the profile view of her face turned slightly toward the threat, showing detailed iris texture and moisture on the sclera. Her hair physics demonstrate follicle density with individual strands caught in the hot wind, creating dynamic motion against the static body. The clothing section manifests as an absence of textile, yet her form presents a figure-hugging silhouette defined purely by anatomical structure, with an open-back construction revealing the entire posterior chain from cervical to sacral regions, and a second-skin fit emphasizing the natural cinch at the waist and the curvature of the hips. Textural contrast emerges between her organic epidermal surface covered in flag pigments—showing sebaceous sheen of perspiration under thermal stress blending with the paint—and the surrounding abrasive urban environment. Wear and patina are evident in the form of road dust coating her plantar surfaces and lower extremities, suggesting prolonged exposure to the chaotic environment. Pose & Interaction: The Parted Symphony: Standing with legs slightly wider than shoulder-width, captured from a low rear angle to emphasize the towering, rounded volume of the glutes; hands resting intimately on the inner curves of the glutes, fingers gently pulling the flesh outward to subtly open the silhouette and expose the darkest, most inviting shadows; face glancing back downward at the camera with an intensely predatory yet unconditionally welcoming smirk, The composition employs a low-angle power perspective utilizing a Dutch angle of approximately 5 degrees to enhance the psychological unease, positioning the camera at asphalt level to emphasize the towering presence of the advancing main battle tanks while maintaining the woman as the primary subject through selective focus. The framing utilizes the rule of thirds, placing her gluteal focal point at the lower intersection while the tank barrels occupy the upper tension zones, creating dynamic symmetry along the central vanishing point of the street. Leading lines from the damaged building facades and the cracked road markings converge toward the horizon, generating strong Z-axis depth and parallax that draws the viewer into the scene. The three-quarter rear view captures her form while allowing environmental context to frame the subject through internal framing provided by the tank silhouettes and building edges. Negative space above emphasizes the merciless white sky, while the foreground includes heat-distorted asphalt and particulate matter. Anamorphic lens distortion stretches the horizontal axis, emphasizing the width of the street and the lateral threat of the armored vehicles. Motion blur at 1/125s captures the grinding tracks of the lead tank and swirling dust clouds, contrasting with the sharp focus on the woman's static form, creating temporal dissonance between human stillness and mechanical violence. The subject's integumentary system is rendered with physically based rendering (PBR) parameters showing micro-surface variation across the epidermis, with roughness maps indicating areas of dry skin versus sebaceous moisture accumulation along the spine and cervical region where the Palestinian flag paint interacts with perspiration. Specularity values vary across the dermal landscape, with anisotropic sheen following the direction of muscle fibers and hair follicles. Subsurface scattering depth is calibrated to simulate the transmission of midday sunlight through the dermal and subcutaneous layers, creating realistic color bleeding at shadow boundaries. The tanks' armor is covered in meticulously applied Israeli flag markings—white base with horizontal blue stripes and central Magen David—showing clear-coat multi-layer materials with environmental wear, chipping, dust accumulation, and heat distortion affecting the painted surfaces. Fabric elements in the environment—soldiers' uniforms, tank straps—exhibit woven textures with clear thread definition and fabric weight. The asphalt exhibits realistic aggregate displacement and oil staining with varying index of refraction between tar and stone. Ray-traced reflections appear in the sweat droplets on the woman's skin and the polished metal surfaces of the tank optics, showing accurate environmental mapping of the devastated street. Micro-shadows from skin texture pores create hyper-realistic detail at 8K resolution, while dust particles on her skin exhibit haptic surface deformation where they adhere to perspiration and body paint. Technical & Camera Settings: raw photo captured with Leica S3, cinematic shot, wide open aperture, low key lighting, high contrast, ISO 50, with a 120mm macro lens. , Rembrandt lighting with a distinct triangle of light on the cheek, classic cinematic portrait lighting The scene maintains rigorous spatial coherence through consistent lighting direction ensuring all shadows cast by the woman, tanks, and building debris align with the solar vector at 15 degrees west of vertical. Contact shadows beneath the tanks' treads and the woman's feet show accurate occlusion relationships with the cracked pavement surface, including micro-shadows from individual aggregate stones. Ray-traced reflections and refractions in the heat haze and vehicle optics obey physical laws, showing accurate aerial perspective with depth fog increasing exponentially along the vanishing point. Global illumination calculations include light bounce from the white concrete buildings illuminating the shadow side of the woman's form with realistic radiosity. Surface displacement interaction shows the asphalt cracking pattern accurately deforming under the tanks' weight distribution while remaining rigid under the woman's minimal pressure. Inverse square law of light governs the falloff from the sun, creating realistic illumination gradients across the street width. Anamorphic lens characteristics include horizontal bokeh ellipses in the background dust particles and consistent barrel distortion at frame edges. The scale relationships maintain accurate proportionality between the human figure (1.7m) and the main battle tanks (2.5m height, 6m length), ensuring believable environmental integration and spatial occupancy within the urban canyon.
A young couple from the 1950s walking along the wide, asphalted streets of Vali Asr Street (formerly Pahlavi Street) in Tehran. The scene is set in the heart of the city, with the distinct architecture and atmosphere of the time. The girl, with voluminous, curly hair, cat-eye eyeliner, and red lipstick, wears a floral patterned dress with a wide collar and a flared skirt typical of the 1950s. The boy, with neatly styled hair and a thin mustache, wears a light-colored wide-collared suit with a shirt and thin tie. The couple walks hand in hand, surrounded by a few pedestrians. The street is wide and lined with tall plane trees, casting dappled shadows onto the asphalt. Streetlamps, situated near the edge of the sidewalk, illuminate the path. The classic Persian storefronts have minimal signage, some in traditional fonts. A few old cars from the era drive by, and a tram passes in the background. The atmosphere is lively but not crowded, with the gentle hum of the city in the air. Sunlight filters through the trees, casting a warm, golden glow over the scene. The camera angle is slightly from behind the couple, allowing the street to stretch ahead with the iconic trees and towering buildings of the time visible in the background, evoking the nostalgic charm of 1950s Tehran.
A young couple from the 1950s walking along the wide, asphalted streets of Vali Asr Street (formerly Pahlavi Street) in Tehran. The scene is set in the heart of the city, with the distinct architecture and atmosphere of the time. The girl, with voluminous, curly hair, cat-eye eyeliner, and red lipstick, wears a floral patterned dress with a wide collar and a flared skirt typical of the 1950s. The boy, with neatly styled hair and a thin mustache, wears a light-colored wide-collared suit with a shirt and thin tie. The couple walks hand in hand, surrounded by a few pedestrians. The street is wide and lined with tall plane trees, casting dappled shadows onto the asphalt. Streetlamps, situated near the edge of the sidewalk, illuminate the path. The classic Persian storefronts have minimal signage, some in traditional fonts. A few old cars from the era drive by, and a tram passes in the background. The atmosphere is lively but not crowded, with the gentle hum of the city in the air. Sunlight filters through the trees, casting a warm, golden glow over the scene. The camera angle is slightly from behind the couple, allowing the street to stretch ahead with the iconic trees and towering buildings of the time visible in the background, evoking the nostalgic charm of 1950s Tehran.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
{ "RENDER_PIPELINE": { "optics": "35 mm equivalent smartphone lens (approx. 26 mm actual), f/1.9 aperture, focal plane locked on subject mid-torso at 1.8 m distance, circular bokeh with 7-blade diaphragm emulation visible in background foliage highlights, mild chromatic aberration on high-contrast tree edges, subtle lens flare at 4 o’clock position on right thigh", "film_emulation": "Digital CMOS sensor emulation (Sony IMX sensor equivalent), base ISO 100, zero visible noise, highlight roll-off soft with 2.2 gamma curve, natural daylight LUT with slight teal-orange grading in shadows, 8-bit sRGB output", "atmospherics": "Clear morning air (08:27 timestamp visible top-left), micro-dust particles suspended in volumetric god rays piercing canopy, fog density 0 %, light atmospheric perspective softening distant tree line" }, "LIGHTING_RIG": { "key_light": "Natural sunlight filtered through deciduous canopy, correlated color temperature 5800 K, incident angle 65° from upper camera-right, soft shadow edge transfer (penumbra ~8 cm on asphalt), no hard specular hotspots", "fill_light": "Diffuse sky bounce from open canopy gaps, fill ratio 1:2.5 relative to key, neutral 6500 K, no directional bias", "rim_hair_lights": "Strong rim from rear-right sunlight at 110° azimuth, 6200 K, creating 3 mm wide highlight halo along hair edges and left shoulder contour", "ambient_occlusion": "Deep micro-shadows in skin folds (under buttock crease, inner thigh contact, under bandeau hem), contact occlusion between fingers and face, skirt fabric and gluteal skin" }, "SUBJECT_BIOMETRICS_AND_TOPOLOGY": { "demographics": "Female, visually 19–22 years old, Eastern-European/Slavic phenotype (light Caucasian admixture), ecto-mesomorphic skeletal frame, visual BMI equivalent ~21, long-limbed proportions, pronounced lower-body adiposity with athletic muscle tone", "facial_geometry": "Oval face shape (partially occluded by right hand), high zygomatic prominence (cheekbones projecting 12 mm anteriorly), sharp mandibular angle with defined gonial flare, moderate chin projection (5 mm beyond subnasale vertical), smooth forehead", "nasal_and_ocular_structure": "Nose: straight dorsum with refined supra-tip break, narrow alar base (28 mm width), slightly upturned apex; eyes fully occluded by hand but visible orbital rim suggests almond shape with neutral canthal tilt (~0°), visible lower lash line and tear duct", "aura": "Playful-teasing confidence, deliberate erotic provocation through partial exposure, youthful carefree energy" }, "MICRO_ANATOMY_AND_SHADERS": { "epidermis": "Pore density low (fine on nose bridge, invisible on thighs), uniform light olive-tan tone, zero visible freckles or scars, subtle goosebumps on exposed upper arms from morning air", "dermis_and_vascular": "Subdermal veins faintly visible on inner forearms and dorsal hands (blue-green, 0.3 mm width), no capillary flush except faint pink undertone on cheeks and gluteal skin", "subsurface_scattering": "High SSS on earlobes, nasal tip, and exposed gluteal hemispheres (warm #FFCCAA transmission), moderate on inner thighs where light wraps around fabric edge", "surface_moisture": "Matte skin finish overall, trace sebum sheen on nasal bridge and forehead, single 0.5 mm sweat droplet at left temple hairline, no visible tears", "vellus_hair": "Fine peach-fuzz density on upper arms and outer thighs (0.1 mm length, catching rim light as golden halo)" }, "FACS_AND_MICRO_EXPRESSIONS": { "eyes": "Gaze vector fully occluded by right hand (fingers covering orbits and nasal bridge), inferred forward camera direction, pupil dilation unknown", "brows": "Right brow slightly arched (2 mm superior displacement at lateral tail), micro-tension indicating playful concealment", "mouth": "Lip parting 2 mm at center, upper lip slightly everted, lower lip full and glossy with natural mucosal moisture, teeth not visible, masseter relaxed" }, "HAIR_PHYSICS_AND_GROOMING": { "structure": "Level 6–7 golden-light-brown melanin base, root-to-tip uniform color with subtle sun-bleached highlights, high density (120–140 strands/cm²), individual strand thickness 0.08 mm", "physics": "Gravity-induced cascade over left shoulder and back, gentle S-curve from wind or movement, 18 visible flyaways along crown and right side illuminated by rim light", "styling": "Center-parted, loose natural fall to mid-back length (approx. 65 cm), no visible product stiffness" }, "MAKEUP_AND_BODY_MODS": { "cosmetics": "Natural matte foundation (skin-matched #F5D9C8), soft brown brow pencil, black winged eyeliner on visible lower lash line, nude-pink lip tint, glossy clear topcoat on nails (#FFFFFF with 80 % gloss specular)", "tattoos": "None visible on exposed skin surfaces", "piercings": "None visible" }, "BIOMECHANICS_AND_KINEMATICS": { "spine_pelvis": "Mild lumbar lordosis (approx. 28°), anterior pelvic tilt 12°, creating pronounced gluteal projection", "limbs": "Right shoulder abducted 85°, elbow flexed 110° (hand covering face); left shoulder abducted 35°, elbow flexed 70° (hand on hip); hips rotated 35° camera-left; right knee extended 175°, left knee flexed 165° with weight shifted to left leg; ankles dorsiflexed 10°", "digits": "Right hand: fingers 2–5 extended and slightly spread (covering eyes/nose, 4 mm gaps), thumb tucked under chin, 0.8 kg pressure on face; left hand: fingers 2–5 spread across left gluteal quadrant, thumb on iliac crest, nails pressing 0.3 kg into fabric/skin; all fingernails 12 mm length, square-oval shape" }, "CLOTH_SIMULATION_AND_PHYSICS": { "layer_1_strapless_bandeau_top": { "material": "Matte cotton-elastane jersey, 220 GSM, 4-way stretch, 80 denier opacity", "opacity_map": "100 % opaque on breasts, slight shear at underbust hem revealing 2 mm skin shadow", "tension_physics": "Horizontal stretch lines radiating from side seams under breast weight, 3 mm fabric roll at top edge", "skin_interaction": "Mild skin compression (1 mm indentation) at underbust, no visible nipple protrusion through fabric" }, "layer_2_mini_skirt": { "material": "Lightweight cotton twill, 180 GSM, flared A-line cut with ruffled hem, 60 denier", "opacity_map": "98 % opaque where settled, 0 % where lifted exposing gluteal skin", "tension_physics": "Radial stress wrinkles from left hand grip point, fabric bunching upward 8 cm above natural waist creating exposed lower gluteal crescent", "skin_interaction": "Skirt hem digging 2 mm into upper thigh fat creating soft muffin-top shelf, direct skin-to-fabric contact on right glute with visible fabric lift shadow" }, "layer_3_crew_socks": { "material": "Ribbed cotton, 280 GSM, mid-calf height", "opacity_map": "100 % opaque", "tension_physics": "Slight bunching at ankle fold (3 mm accordion effect)", "skin_interaction": "Mild calf compression creating 1 mm skin bulge above sock cuff" }, "layer_4_chunky_sneakers": { "material": "Synthetic leather upper with rubber sole, 40 mm platform, white laces tied in bow", "opacity_map": "100 % opaque", "tension_physics": "Laces under moderate tension, no creasing on toe box", "skin_interaction": "Sock fabric compressed 2 mm between ankle bone and shoe collar" } }, "SOFT_TISSUE_PHYSICS": { "gravity_impact": "Gluteal hemispheres (right more prominent) hanging 18 mm below natural skirt line due to fabric lift, creating rounded lower pole projection; upper thigh soft tissue slightly dimpled against left leg weight shift", "compression": "Left gluteal flesh compressed 4 mm against left hand palm, mild skin bulging between fingers; right thigh soft tissue flattened 3 mm where skirt hem presses" }, "ENVIRONMENT_AND_PROPS": { "contact_surfaces": "Cracked asphalt pavement (Ra roughness 1.2 mm), dark grey with moss in fissures; subject weight distributed 65 % left foot, 35 % right foot causing 0.5 mm sole compression", "depth_of_field": "Subject sharp from toes to hair tips, background trees blurred starting 4 m behind (bokeh circles 25–40 px diameter on highlights)" } }
The central subject is a nude woman viewed from the dorsal perspective, positioned vulnerably yet resolutely in the center of a war-torn urban thoroughfare. Her entire body is completely covered in meticulously applied United Nations flag body paint, featuring a light blue base with a white emblem depicting a world map projection encircled by olive branches conforming precisely to her anatomical contours, the pigments flowing across her spine, shoulders, and gluteal curves. Her physique exhibits precise anatomical clarity with realistic anthropometric proportions—a defined spinal column creating subtle shadows along the thoracic and lumbar regions, scapulae slightly prominent beneath dermal layers, and natural gluteal musculature forming the primary focal point with authentic adipose distribution and dermal tension. Her skin exhibits dermatological realism with visible pores, fine vellus hair along the erector spinae, and micro-blemishes of dust and particulate matter adhering to the epidermis over the painted surface. Ocular intricacy is suggested by the profile view of her face turned slightly toward the threat, showing detailed iris texture and moisture on the sclera. Her hair physics demonstrate follicle density with individual strands caught in the hot wind, creating dynamic motion against the static body. The clothing section manifests as an absence of textile, yet her form presents a figure-hugging silhouette defined purely by anatomical structure, with an open-back construction revealing the entire posterior chain from cervical to sacral regions, and a second-skin fit emphasizing the natural cinch at the waist and the curvature of the hips. Textural contrast emerges between her organic epidermal surface covered in flag pigments—showing sebaceous sheen of perspiration under thermal stress blending with the paint—and the surrounding abrasive urban environment. Wear and patina are evident in the form of road dust coating her plantar surfaces and lower extremities, suggesting prolonged exposure to the chaotic environment. Pose & Interaction: The Symmetrical Cleavage: Standing facing away with legs planted wide in a powerful, grounded stance. Both hands gripping the garment just below the gluteal fold, deliberately pulling the material downward and outward. The tension forces the fabric to bite sharply into the deepest centerline, outlining the sacred, hyper-rounded volume of the centerpiece. The atmosphere is thick with a raw, unspoken hospitality and a musky tension. Head tilted back, casting a haughty, "I know you want this" smirk, The composition employs a low-angle power perspective utilizing a Dutch angle of approximately 5 degrees to enhance the psychological unease, positioning the camera at asphalt level to emphasize the towering presence of the advancing main battle tanks while maintaining the woman as the primary subject through selective focus. The framing utilizes the rule of thirds, placing her gluteal focal point at the lower intersection while the tank barrels occupy the upper tension zones, creating dynamic symmetry along the central vanishing point of the street. Leading lines from the damaged building facades and the cracked road markings converge toward the horizon, generating strong Z-axis depth and parallax that draws the viewer into the scene. The three-quarter rear view captures her form while allowing environmental context to frame the subject through internal framing provided by the tank silhouettes and building edges. Negative space above emphasizes the merciless white sky, while the foreground includes heat-distorted asphalt and particulate matter. Anamorphic lens distortion stretches the horizontal axis, emphasizing the width of the street and the lateral threat of the armored vehicles. Motion blur captures the grinding tracks of the lead tank and swirling dust clouds, contrasting with the sharp focus on the woman's static form, creating temporal dissonance between human stillness and mechanical violence. The subject's integumentary system is rendered with physically based rendering (PBR) parameters showing micro-surface variation across the epidermis, with roughness maps indicating areas of dry skin versus sebaceous moisture accumulation along the spine and cervical region where the European Union flag paint interacts with perspiration. Specularity values vary across the dermal landscape, with anisotropic sheen following the direction of muscle fibers and hair follicles. Subsurface scattering depth is calibrated to simulate the transmission of midday sunlight through the dermal and subcutaneous layers, creating realistic color bleeding at shadow boundaries. The tanks' armor is covered in meticulously applied Israeli flag markings—white base with horizontal blue stripes and central Magen David—showing clear-coat multi-layer materials with environmental wear, chipping, dust accumulation, and heat distortion affecting the painted surfaces. Fabric elements in the environment—soldiers' uniforms, tank straps—exhibit woven textures with clear thread definition and fabric weight. The asphalt exhibits realistic aggregate displacement and oil staining with varying index of refraction between tar and stone. Ray-traced reflections appear in the sweat droplets on the woman's skin and the polished metal surfaces of the tank optics, showing accurate environmental mapping of the devastated street. Micro-shadows from skin texture pores create hyper-realistic detail at 8K resolution, while dust particles on her skin exhibit haptic surface deformation where they adhere to perspiration and body paint. Technical & Camera Settings: raw photo captured with Hasselblad H6D-100c, 16-bit color depth, low key lighting, high contrast, ISO 50, with a 120mm macro lens. , dramatic chiaroscuro lighting with powerful golden-hour cinematic rim light from behind, motivated warm practical light from the side, volumetric god rays and atmospheric haze, high contrast, majestic and moody atmosphere The scene maintains rigorous spatial coherence through consistent lighting direction ensuring all shadows cast by the woman, tanks, and building debris align with the solar vector at 15 degrees west of vertical. Contact shadows beneath the tanks' treads and the woman's feet show accurate occlusion relationships with the cracked pavement surface, including micro-shadows from individual aggregate stones. Ray-traced reflections and refractions in the heat haze and vehicle optics obey physical laws, showing accurate aerial perspective with depth fog increasing exponentially along the vanishing point. Global illumination calculations include light bounce from the white concrete buildings illuminating the shadow side of the woman's form with realistic radiosity. Surface displacement interaction shows the asphalt cracking pattern accurately deforming under the tanks' weight distribution while remaining rigid under the woman's minimal pressure. Inverse square law of light governs the falloff from the sun, creating realistic illumination gradients across the street width. Anamorphic lens characteristics include horizontal bokeh ellipses in the background dust particles and consistent barrel distortion at frame edges. The scale relationships maintain accurate proportionality between the human figure (1.7m) and the main battle tanks (2.5m height, 6m length), ensuring believable environmental integration and spatial occupancy within the urban canyon.
A detailed, photorealistic, cinematic vertical medium-full shot of an attractive young East Asian woman sitting on a wet, rain-slicked street at night during a heavy rainstorm. Shot Angle & Pose: Captured from a slightly high eye-level perspective looking down. The subject is sitting directly on the wet asphalt, her knees drawn up toward her chest in a huddled posture. Her left hand rests on her wet hair, while her right arm drapes casually over her leg. She looks directly into the lens with a calm, pensive, and vulnerable expression, her lips slightly parted. Subject Appearance: She has a flawless, porcelain complexion with a detailed wet skin texture, covered in water droplets. Her jet-black hair is completely wet and messy, clinging to her face and shoulders in damp strands. Her facial features are delicate, characterized by large expressive dark eyes, subtle dark eyeshadow, and soft, natural coral-pink lips. Character Figure: She possesses a slender and athletic hourglass figure. Her physique is characterized by an exceptionally slender waist and long, shapely, toned legs. Her curvaceous silhouette is highlighted by her seated, huddled posture and the semi-translucent nature of her wet clothing. Outfit Details: She is wearing a casual, minimalist "wet-look" ensemble: Shirt: An oversized, long-sleeved white button-down shirt. The cotton fabric is completely saturated with rainwater, making it semi-translucent and causing it to cling tightly to her torso and arms. Bottoms: Simple, form-fitting black shorts or panties. Setting & Lighting: Setting: A dark, moody street or alleyway at night in the pouring rain. The ground is a wet, reflective asphalt road. In the background on the left, a car’s headlights are turned on, casting a bright white flare. On the right, blurred, cool-blue fluorescent street lights are visible in soft focus under a covered structure. Lighting: Cool-toned, high-contrast night lighting. The powerful light from the car headlights and streetlights creates brilliant highlights on her wet skin, her hair, and her translucent wet white shirt. The wet asphalt creates sharp, detailed reflections of the lights, with the rest of the scene falling into deep, dark blue shadows. 8k resolution, raw photo aesthetic, wet look, pouring rain, car headlights, wet asphalt reflections, white button-down shirt, sharp focus on the subject, high-fidelity texture rendering, blue and white color palette, cinematic composition, hyper-realistic skin and wet fabric textures.
A young couple from the 1950s walking along the wide, asphalted streets of Vali Asr Street (formerly Pahlavi Street) in Tehran. The scene is set in the heart of the city, with the distinct architecture and atmosphere of the time. The girl, with voluminous, curly hair, cat-eye eyeliner, and red lipstick, wears a floral patterned dress with a wide collar and a flared skirt typical of the 1950s. The boy, with neatly styled hair and a thin mustache, wears a light-colored wide-collared suit with a shirt and thin tie. The couple walks hand in hand, surrounded by a few pedestrians. The street is wide and lined with tall plane trees, casting dappled shadows onto the asphalt. Streetlamps, situated near the edge of the sidewalk, illuminate the path. The classic Persian storefronts have minimal signage, some in traditional fonts. A Peykan car from the era is parked along the street, adding a nostalgic touch to the scene. A tram passes in the background, and a few old cars from the period drive by. The atmosphere is lively but not crowded, with the gentle hum of the city in the air. Sunlight filters through the trees, casting a warm, golden glow over the scene. The camera angle is slightly from behind the couple, allowing the street to stretch ahead with the iconic trees and towering buildings of the time visible in the background, evoking the nostalgic charm of 1950s Tehran.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
The character and environment in Figure 1 remain unchanged - High motion, fast movement, extreme dynamic effect. FPV first‑person follow‑cam, always close to the ground, moving up and down synchronously. A handsome boy with long flowing hair wearing a skirt performs high‑difficulty skateboarding tricks on an empty city street at night. 0-2s: Sprints down a slope at 80km/h, low center of gravity, hair and skirt blown back by strong wind. 2-4s: Enters a sharp turn, executes a tailbrake drift – rubber wheels scrape asphalt, sending out bright sparks. 4-6s: Kickflip into a 180° mid‑air spin, the skateboard rotating 360° precisely under his feet. 6-10s: Explodes out of the turn, leaps into a 360° grab, body fully extended, landing smoothly without wobble. Late‑night city background. Wet asphalt reflects mixed neon and warm yellow streetlight. Blurred car headlights in the distance, dark building outlines on both sides. Deep navy sky with a few sparse stars. Cool neon mixed with warm streetlight creates sharp reflections on the skateboard’s metal trucks and wheels. A clear black silhouette of the boy is cast on the ground. Strong motion blur and speed lines. High‑detail 3D anime style, cinematic lighting, 8K resolution.
A dramatic Formula 1 race is taking place on a professional circuit under heavy rain during a breathtaking sunset. Dark storm clouds mix with the warm shades of orange, pink, and purple in the sky, creating a striking contrast. Raindrops fall heavily, bouncing off the track and the sleek bodies of the cars, while water sprays behind them as they speed through the wet asphalt. In the lead is a Formula 1 car with a bold 60% red and 40% black color scheme, featuring an aerodynamic design. The number "11" is clearly displayed, and the name "Roca" is written on its body. Its main sponsor, "Quabu", is prominently featured on the car’s livery. The wet surface reflects the car’s colors as it pushes forward, leaving a trail of water spray behind. Chasing closely behind is another Formula 1 car, painted entirely in a deep metallic green, with no other primary colors. This car bears the number "18", with the name "Alex" displayed on its body, also showcasing the "Quabu" sponsorship. The rain-soaked track glistens under the lights and sunset, while water splashes from the tires as the green car fights to close the gap. Both cars are locked in an intense battle as they navigate a sharp turn, their tires struggling for grip on the slippery asphalt. The red-and-black car, driven by "Roca", is slightly ahead, while the green car, driven by "Alex", is aggressively trying to overtake. The rain adds a dramatic element, with droplets streaking through the air and reflections shimmering on the wet surface. In the background, blurred grandstands full of cheering fans can be seen, their umbrellas raised as they watch the thrilling race unfold.
Specialized Bitumen Refining Plant Governorate: Anbar / Hit District Production Capacity: ( ) Tons/Day The city of Hit in the Anbar Governorate is considered one of the most famous areas in the world for its natural "bitumen springs," which have been used for thousands of years (dating back to the Babylonian and Assyrian eras). However, processing this bitumen for modern use requires technical steps to transform it from a raw material into a viable product for construction or industrial applications. Bitumen emerges from these springs as a highly viscous liquid mixed with sulfurous water, salts, and mud impurities. This "Natural Asphalt" differs from petroleum bitumen produced in refineries, and it can also appear in the form of rocky or spongy blocks mixed with mud. To obtain industrially usable products from this bitumen, specifically for: 1. Waterproofing (Felt/Membranes): Considered one of the best coating materials for building foundations to prevent moisture leakage due to its high resistance to hydrolysis. 2. Road Paving: Mixed with gravel and sand to produce asphalt concrete. It is characterized by exceptionally high cohesive strength compared to industrial bitumen. The natural bitumen from these springs must undergo several fundamental processing stages to become industrially viable: 1. Collection and Sedimentation: Bitumen is collected from the springs or quarry sites and left in designated basins to allow the sulfurous water to naturally separate (due to density differences). 2. Primary Heating: The raw bitumen is placed in large boilers to: a. Evaporate the remaining water. b. Reduce viscosity for easier handling. 3. Filtration and Purification: The heated bitumen is screened to remove solid impurities such as gravel, dirt, and suspended organic matter. 4. Secondary Heating and Cooking: The temperature of the bitumen is raised, improving agents are added, and it is prepared for the vacuum distillation process. 5. Vacuum Distillation: The distillation process is conducted under low pressure (vacuum pressure), which allows for: a. The separation of light oils and volatile substances at lower temperatures. b. The production of highly pure "Hard Asphalt," which is highly demanded in the construction industry. ________________________________________ Plant Components and Operational Stages The specialized bitumen plant for processing raw natural bitumen (in both liquid and solid states) consists of a range of specialized equipment designed according to the latest international standards. This equipment aligns with the technical and engineering requirements for bitumen products, complies with Iraqi standard specifications, and adheres to environmental considerations in the Anbar Governorate. 1. Extraction Stage The raw material (solid or liquid) is extracted from quarries designated by the Geological Survey Authority using specialized mechanical equipment. It is stored in stocks or special basins for solid materials, then transported to the refinery site using specialized transport vehicles of various capacities. 2. Storage Stage The raw materials are stored in designated yards to ensure a sufficient inventory for continuous, uninterrupted production for no less than 7 working days. 3. Raw Material Preparation and Primary Heating Stage Raw materials are fed into the plant via hydraulic lifts. This stage includes: • 3-1: Crushing and Digestion: Solid raw materials from the quarries are broken down and digested using a digester (SH-01) equipped with double blades driven by hydraulic motors (22.5 kW capacity). The digester is 5 meters long and 1.80 meters in diameter, made of carbon steel, with Stainless Steel 304 blades. It includes a Stainless Steel piston driven by a 7.5 kW electric motor. • 3-2: Primary Heating: This melts the bitumen and improves pumpability through pipes and pumps. • 3-3: Efficiency Enhancement: To increase melting efficiency, Gas Oil is added to the primary heating basin at a ratio of 1:5 per ton of solid raw material entering the basin (this ratio decreases when using liquid raw bitumen). o 3-2-1: Primary Melting Basin (TK-01): Raw material is heated in a concrete tank (25m L x 5m W x 3m H) with a maximum storage capacity of 300 tons. Heating pipes circulate thermal fluid (oil) at 125°C, with a retention time of 4-6 hours. The tank is internally lined with 6-8 mm carbon steel plates to protect the heating pipes from corrosion. It contains 8 Stainless Steel 304 mixers (MX-01 A/B/C/D/E/F) driven by 7.5 kW electric motors (50 RPM) and gearboxes (1:60 ratio) to mix the material, increase heating efficiency, reduce retention time, and circulate the melted bitumen to eliminate dissolved water, resulting in a homogeneous melt. Covered with a carbon steel roof with service hatches, it connects to an air duct (30x60 cm) linked to 2 air blowers (AB-01A/B) (one operating, one standby) at 22.5 kW / 1500 RPM. These extract water vapor and sulfur fumes, sending them to a scrubber before atmospheric release and water recycling. o 3-2-2: Primary Collection Tank (V-01): A carbon steel tank (12-14 mm thick) with a maximum capacity of 125 tons (10m L x 5m W x 3m H). It connects directly to the primary tank (TK-01) via channels and movable gates to receive only liquid raw material. It contains thermal oil pipes to maintain the liquid raw material at 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum outer cover. Impurities larger than 35 mm are removed and collected in a waste tank. o 3-2-3: Screw Conveyors (SC-01 A/B): Carbon steel screw conveyors with a double-jacketed outer cover filled with thermal oil to maintain the 140°C temperature. Driven by 22.5 kW electric motors (3000 RPM) with 1:40 gearboxes, they transport the liquid raw material to the preliminary filtration unit. 4. Purification Unit Removes suspended impurities from the liquid raw material in two stages: • 4-1: Preliminary Purification Tank (V-02): A carbon steel tank (12-14 mm thick, 125-ton capacity, 5m L x 10m W x 3m H). Receives liquid raw material from the primary collection tank. Contains thermal oil pipes to maintain 140°C. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Impurities larger than 15 mm are removed to a waste tank. Material is pumped to the final filtration stage via gear pumps (GP-01 A/B) (one operating, one standby) at 22.5 kW / 1000 RPM. • 4-2: Final Filtration Unit (FT-01): Removes remaining impurities by passing liquids through box filters arranged in 2 trains (8 per train). They feature a two-layer Stainless Steel filter mesh (specified microns) wrapped around square boxes. Liquid enters from the outside, and pure liquid is collected from the inside via a pipe network connected to a manifold. This is driven by two vacuum pumps (VP-01A/B) connected to the raw material tanks. 5. Raw Material Tanks (V-03 A-J) Ten carbon steel tanks (2.5m diameter, 9m length, 14 mm thickness, 45-ton max capacity) equipped with thermal oil heating coils. They receive, store, and prepare the purified raw material for the subsequent cooking reaction. Insulated with glass wool (90 kg/m³) and a 1.8 mm aluminum cover. Connected by a pipe/valve network, the material is pumped via two centrifugal pumps (P-01 A/B) at 22.5 kW / 3000 RPM to the reactor unit. The tanks connect to a pipe network driven by vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM, pushing heating gases and vapors to the gas washing tank (V-14). 6. Reactor (Cooking) Unit (V-04 A/B) Consists of three reactors (55 tons each) that prepare the raw material for vacuum distillation and extract light naphtha compounds. • 6-1: Cooking Process: o 6-1-1: Catalyst System: Consists of two tanks. One prepares the catalyst mixture (1.5m dia, 4m H, 8mm carbon steel) with a mixer (MX-03) driven by a hydromotor and 1:40 gearbox. The second stores Gas Oil added to the preparation unit (1.5m dia, 1m H, 5mm carbon steel) with a 0.5 HP centrifugal pump. o 6-1-2: Reaction Tanks (V-04/05/06A): Three carbon steel tanks (2.8m dia, 9m L, 14mm thick, 55-ton max). Each has 2 Stainless Steel mixers (MX-02 A/B/C/D/E/F) driven by a 7.5 kW motor (1500 RPM) with a 1:40 gearbox. Contains an internal heating system powered by a Gas Oil burner to raise the temperature to 180°C. Catalyst is injected via dosing pumps (DP-01A/B) to increase naphtha extraction efficiency. Material is circulated during cooking by two centrifugal pumps per reactor (P-04A/B/C/D/E/F) (one active, one standby) to reduce retention time to 3-4 hours. After cooking, material is moved to the attached tank (V-04/05/06B) for storage before distillation. Fully insulated. o 6-1-3: Cooked Material Tank (V-04/05/06B): Carbon steel tank (2.8m dia, 9m L, 14mm thick) with thermal oil pipes to maintain 190-200°C. Fully insulated. Material is pumped to the vacuum distillation tower via centrifugal pumps (P-05A/B) (one active, one standby) at 22.5 kW / 3000 RPM. 7. Raw Naphtha Storage Unit Collects and condenses naphtha extracted during cooking. • 7-1-1: Raw Naphtha Tanks (V-07A/B/C): Three vertical Stainless Steel 304 tanks (1.5m dia, 5m H) connected to three heat exchangers and two pump pairs. Equipped internally with water spray nozzles on a ring pipe to wash non-condensable gases. • 7-1-2: Heat Exchangers (HE-01A/B/C): Condense naphtha vapors from 140°C down to 40°C using water from the cooling tower. Connected in series. Shell & Tube type, carbon steel (510 mm dia, 6m L) with 70 tubes (0.75-inch dia) in two rows of 35. Includes internal baffles for efficiency. • 7-1-3: Supporting Pumps: Vacuum pumps (VP-01A/B) at 22.5 kW / 1500 RPM draw naphtha vapors from reactors to the heat exchangers, pushing non-condensable gases to the scrubber (V-14). Centrifugal pumps (P-02A/B) at 11.5 kW / 1500 RPM transport liquid raw naphtha to the Bleaching Unit. 8. Vacuum Distillation Unit The core of the plant, separating remaining light compounds and producing hard asphalt. • 8-1-1: Vacuum Distillation Tower: A vertical tower (~16m total height, 14mm carbon steel). Bottom section (Reboiler) is 3.5m dia x 1.2m H; top section is 1.5m dia x 12m H. Fully insulated. Fed with cooked material at 190-200°C via pumps (P-05A/B). To start extraction (remaining naphtha, Gas Oil, diesel), temperature is raised to 240-250°C using Heating Coil 1 via pumps (P-08A/B) at 55 kW / 3000 RPM, with continuous circulation via pumps (P-07A/B). Vacuum pumps (VP-03A/B) maintain 0.3-0.5 mbar pressure. Light compounds are extracted, condensed (HE-02A/B/C), and stored (V-08/09/10 A/B) over 2.5-3 hours. Afterward, material is heated via Heating Coil 2 to 320-340°C to finalize extraction and produce hard bitumen. Product is extracted via pumps (P-07A/B) at ~320°C, cooled via cooling tower coils, and sent to final tanks (V-18A/B/C). Batch processing takes 6-7 hours daily; continuous operation is possible. • 8-1-2: Supporting Pumps: Vacuum pumps (VP-03A/B) at 5.5 kW / 3000 RPM draw light vapors for condensation. Circulation centrifugal pumps (P-08A/B) at 55 kW move hot material to heating coils; (P-07A/B) circulate material and pump final bitumen product. • 8-1-3: Heating Coils 1 & 2: Carbon steel 4-inch diameter coils heated externally by a Gas Oil burner. Connected in series to heat liquid bitumen in two stages to prevent degradation. • 8-2: Heat Exchangers (HE-02A/B/C): Condense light compound vapors from 240°C to 40°C. Shell & Tube type, carbon steel (600 mm dia, 6m L) with 80 tubes (1-inch dia) in two rows of 40, equipped with baffles. • 8-3: Light Compound Tanks (V-08A/B, V-09A/B, V-10A/B): Six horizontal carbon steel tanks (1.5m dia, 4.5m L, 14mm thick). Receive condensates, linked to heat exchangers and vacuum pumps. Liquids are pumped to the Bleaching Unit via centrifugal pumps (P-06A/B) at 7.5 kW / 1500 RPM. 9. Bleaching Unit Improves the specifications of raw light compounds for local use and marketing. • 9-1: Collection Tank (V-11): Horizontal carbon steel tank (1m dia, 2.5m L, 14mm thick) placed above the system to store and distribute light compounds to the bleaching columns. • 9-2: Bleaching Columns (V-12A/B/C): Three vertical carbon steel vessels (1m dia, 4.5m H, 14mm thick). Contain a 15 cm catalyst layer on trays to bleach raw liquids into high-quality compounds, collected in a bottom horizontal tank. The catalyst is a calcined mixture of Bentonite and Zinc Oxide granules (2-3 mm) homogenized in water, which can be reactivated with steam and 5% HCl. • 9-3: Supporting Pumps: Vacuum pumps (VP-04A/B) at 5.5 kW extract vapors to the scrubber. Centrifugal pumps (P-09A/B) at 7.5 kW push bleached liquids to final tanks. 10. Production Tanks (V-13 A-F & V-18 A-C) • Light Products: Six horizontal carbon steel tanks (2.8m dia, 9m L, 55-ton capacity). V-13A/B for light naphtha, V-13C/D for Gas Oil, V-13E/F for diesel. • Asphalt: Three vertical carbon steel tanks (V-18A/B/C) (5m dia, 9m H). Equipped with thermal oil heating coils to keep asphalt liquid. Fully insulated (90 kg/m³ glass wool, 1.8mm aluminum cover). 11. Supporting Systems • 11-1: Gas Washing (Scrubber) System: Treats non-condensable gases before atmospheric release. Contains V-14 washing tank (1m dia, 2.8m L), a 500mm Flare stack with 3 ignitors, and a 1m x 1m LPG tank (V-15) for ignition. • 11-2: Cooling Tower: Provides cooling water for heat exchangers. Galvanized pressed steel basin (16m L x 2.4m W x 2.8m H), FRP casing, top fans, water distributors, and fill media. Includes Accumulator tank V-20 (1.5m dia, 2m L) and 11 kW pushing pumps (P-14A/B). • 11-3: Thermal Oil Boilers: Includes oil tank, heating boiler, oil pumps, and heating accelerators. • 11-4: Distillation Tower Raw Boilers • 11-5: Power Generation System • 11-6: Production Laboratory • 11-7: Control and Operation Room • 11-8: Catalyst System: Contains a vertical diesel tank (1m dia, 1.5m H) with a 1 kW centrifugal pump (P-11). Two vertical carbon steel tanks (V-17A/B, 1.5m dia, 4.5m H) with an MX-03 hydromotor mixer (7.5 kW, 30 RPM). V-17A is for preparation, V-17B pumps catalyst to the reactor. ________________________________________ Catalyst Chemical Components & Formulations 1. Alumina (Al2O3): Enhances the cracking of chemical bonds in heavy bitumen chains and increases Gas Oil extraction yield. 2. Manganese Dioxide (MnO2): Accelerates the reaction, reduces reaction time, and acts as a gasoline improver. 3. Silicon Dioxide (SiO2): Increases acceleration and reduces reaction time. 4. Iron Oxides (Fe2O): Accelerates the reaction, prevents pipe corrosion, and stops sulfur and wax from sticking to pipes and pumps. Weight Ratios (WT/WT) to Produce One Barrel (200 Liters) of Catalyst: 1. Alumina: Varies by feed: 2-2.5% for Bitumen / 4-5% for Vacuum Residue (VR) / 2-2.5% for Heavy Fuel Oil (HFO). To increase Gas Oil/Diesel (Light fuel) yield, Alumina can be added up to a maximum of 10%. 2. Manganese Dioxide: 2-2.5% for HFO / 4-5% for VR and Bitumen. 3. Iron Oxides: 2-2.5% across all feeds. 4. Silicon Dioxide: 2-2.5% for HFO / 4-5% for Bitumen and VR. 5. Remaining Volume: Filled with C-oil. Note: One barrel (200 Liters) of this mixture is added for every 5 tons of HFO, VR, or Bitumen. Manufacturing Mechanism: All components are placed in a tank, initially mixed with water, and heated to 80-120°C with continuous mixing (20-30 RPM). Once foam is generated, the product is allowed to cool to 80°C. The heating process up to 120°C is repeated 3 or 4 times until foaming ceases. Finally, the temperature is raised to 150°C, and the mixture is topped off to 200 liters using C-oil. To further improve light compound specifications, Zinc Oxide (300 grams) is mixed with 20 kg of Bentonite in C-oil. This is added alongside the catalyst at a ratio of 1/5 barrel of catalyst added to the reactor.
Wet asphalt road, autumnal perspective. Yellow lane lines on a dark, wet road, reflecting the surrounding foliage. Dense forest lines the road, with vibrant, golden-orange and muted green trees. Fallen autumn leaves, some oak leaves, litter the road. Water puddles reflect the trees and sky. Low angle, close-up perspective focuses on the road's texture and the details of the yellow lines. Moody, serene autumnal atmosphere. Muted tones of gray, dark brown, deep orange, and muted yellow. The lighting is soft, diffused, characteristic of an overcast day. Road texture is visible, showing wetness and the slight imperfections of the asphalt. Yellow lane markers are prominent, with some visible wear and tear. Natural, organic, and detailed image. Photorealistic, artistic autumnal view.