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Medium High Pressure Pet Bottle Blowing Plant Air Compressor
Description&Advantages
Product Descriptions:
High-pressure series compressors, medium-to-high pressure compressors for oil fields, general-purpose piston compressors, oil-free compressors of DW, VW, MZD, SF types, liquefied petroleum gas (LPG) circulation compressors, natural gas and gas bottle filling series compressors, and various types of pressure vessels. We can provide compressors with a discharge capacity ranging from 300 to 12000 nm³/h and discharge pressures from 0.2 to 45 MPa, suitable for compressing air, nitrogen, liquefied petroleum gas, coal gas, natural gas, carbon dioxide, propane, ethylene, ammonia, difluoroethane, and other mediem. With over 600 different models, our products are widely used in urban construction, petroleum, coal, geology, chemical, metallurgy, machinery manufacturing, medical, food and beverage, liquefied gas stations, natural gas stations, and other fields
ASC Compressor Factory are oil-free lubrication reciprocating piston compressors developed in collaboration with the German company CHINAMFG DEMAG. These models are known for their low energy consumption, minimal noise, reduced vibration, high reliability, and easy operation.
Each unit primarily consists of the compressor mainframe, electric motor, common base frame, air system, cooling system, lubrication system, instrument control system, drainage system, and electrical system. All components are generally installed on a single common base frame, which is then mounted on a concrete foundation, making it a fixed-type gas station. The connections between the equipment and the fixing points to the base are detachable, making transportation, installation, operation, and maintenance extremely convenient.
Advantages:
Our products, incorporating technology from Germany’s CHINAMFG Demag companies, exhibit high reliability. Wearable parts like gas valves and piston rings use products from Austria’s Hoerbiger company, with a lifespan exceeding 8000 hours. The system supports soft starting, allowing frequent start and stop cycles for the compressor. It features a wide intake range for broad adaptability. The overall skid-mounted structure results in low noise and is easy to install in urban areas, leading to investment savings.
It is equipped with a CHINAMFG PLC control system for high automation, ABB soft start (or variable frequency), and features automatic shutdown with audible and visual alarms in case of faults
Product Parameters
| Medium to High Compressor Parameter Sheet | ||||||||
| No | Model | Medium | Capacity | Inlet Pressure | Outlet Pressure | Rotation | Power | Cooling Method |
| nm3/h | MPa | MPa | r/min | KW | ||||
| 1 | DW-2.4/(18~25)-50 | Raw Gas | 2700 | 1.8~2.5 | 5 | 980 | 160 | Water |
| 2 | DW-5.5/(13-15)-26 | Nitrogen | 4500 | 1.3~1.5 | 2.6 | 740 | 160 | Water |
| 3 | VW-4.6/52 | BOG | 250 | Atmospheric Pressure | 5.2 | 740 | 75 | Closed loop |
| 4 | DWF-7/(2-4)-30 | Wellhead Gas | 2100 | 0.2~0.4 | 3 | 740 | 200 | Air |
| 5 | VWD-3.2/(0-0.2)-40 | Biogas | 200 | 0~0.02 | 4 | 740 | 45 | Closed loop |
| 6 | DW-4/5-41 | Exhaust Gas | 1200 | 0.5 | 4.1 | 980 | 160 | Water |
| 7 | VW-4.1/(36.8-44.7)- (39.9-49.9) |
Regenerated Gas | 8865 | 3.68~4.47 | 3.99~4.99 | 980 | 132 | Water |
| 8 | 2VW-18/0.05-90 | BOG | 1100 | 0.005 | 9 | 980 | 250 | Water |
| 9 | VW-4.8/48-54 | Natural Gas | 12000 | 4.8 | 5.4 | 980 | 132 | Water |
| 10 | VW-2/120 | Carbon Monoxide | 1200 | Atmospheric Pressure | 12 | 740 | 37 | Water |
| 11 | VW-2.5/120 | Carbon Monoxide | 1200 | Atmospheric Pressure | 12 | 740 | 45 | Water |
| High-Pressure Compressor (Pipeline Blowing) Specification Table | ||||||||
| No | Model | Medium | Capacity | Inlet Pressure | Outlet Pressure | Rotation | Power | Cooling Method |
| m3/h | MPa | MPa | r/min | W | ||||
| 1 | SF-10/250 | Air | 600 | Atm | 25 | 1330 | 258.5 (Diesel Motor) | Air |
| 2 | SF-10/150 | Air | 600 | Atm | 15 | 1330 | 258.5 (Diesel Motor) | |
| 3 | SF-7.5/250 | Air | 450 | Atm | 25 | 980 | 160 (Electric Motor) | |
| 4 | SF-7.5/150 | Air | 450 | Atm | 15 | 980 | 132 (Electric Motor) | |
| 5 | SF-8.5/250 | Air | 510 | Atm | 15 | 980 | 200 (Electric Motor) | |
| 6 | W-10/60 | Air | 600 | Atm | 6 | 1330 | 132 (Electric Motor) | |
| High-Pressure Compressor (Oilfield Membrane Nitrogen Generation) Parameter Table | |||||||
| Model | Flow Rate | Outlet Pressure | Air compressor form and series | Form and series of nitrogen booster compressor | Drive parameter | Power | Membrane Module Qty |
| nm3/h | MPa | KW | |||||
| MZD-300/250 | 300 | 25 | Screw type single-stage | V-type piston three-stage | 90KW+55KW | 300 | 4 |
| MZD-300/350 | 300 | 35 | Screw type single-stage | V-type piston four-stage | 90KW+55KW | 300 | 4 |
| MZD-300/250-C | 300 | 25 | Screw type single-stage | V-type piston three-stage | TBD234V6 | / | 4 |
| MZD-300/350-C | 300 | 35 | Screw type single-stage | V-type piston four-stage | TBD234V6 | / | 4 |
| MZD-600/250 | 600 | 25 | Screw type single-stage | V-type piston three-stage | 185KW+132KW | 500 | 8 |
| MZD-600/350 | 600 | 35 | Screw type single-stage | V-type piston four-stage | 185KW+132KW | 500 | 8 |
| MZD-600/250-C | 600 | 25 | Screw type single-stage | V-type piston three-stage | TBD234VB | / | 8 |
| MZD-600/350-C | 600 | 35 | Screw type single-stage | V-type piston four-stage | TBD234VB | / | 8 |
| MZD-900/250 | 900 | 25 | Screw type single-stage | V-type piston three-stage | 250KW+185KW | 800 | 12 |
| MZD-900/350 | 900 | 35 | Screw type single-stage | V-type piston four-stage | 250KW+185KW | 800 | 12 |
| MZD-1200/250 | 1200 | 25 | Screw type single-stage | V-type piston four-stage | 315KW+250KW | 880 | 16 |
| MZD-1200/350 | 1200 | 35 | Screw type single-stage | V-type piston four-stage | 315KW+250KW | 880 | 16 |
| MZD-1500/150 | 1200 | 15 | Screw type single-stage | V-type piston three-stage | 440KW+220KW | 880 | 20 |
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FAQ
Q:Are you a factory?
A:Yes, we are indeed a factory. We specialize in manufacturing high-quality Air/Gas Compressors and are proud to be a primary source for these products.
Q:How long is your delivery time?
A:It varies depending on the specific situation. For our standard configuration compressors, the delivery time is around 30 days. For customized compressors, it usually takes about 30-45 days.
Q:What technical support do you offer?
A:We offer comprehensive technical support to our clients, including remote assistance for installation and commissioning processes. Additionally, we have a team of seasoned engineers ready to be deployed to international client locations for meticulous on-site debugging, installation, and post-installation services.
Q:What is your warranty period?
A:Our warranty policy is valid for a period of 18 months from the date of commissioning at the end customer’s site or 21 months from the date of receipt by the purchaser, whichever comes first. This comprehensive coverage is designed to ensure total customer satisfaction and the reliability of our products
Q:How do you package the compressors?
A:For smaller compressors, we utilize robust plywood boxes that conform to export specifications.
For the larger units, we strategically place them in freight containers, implementing secure fastening methods to safeguard against any potential damage during the shipping process.
Q:What are your payment terms?
A:Usually, the payment is made by T/T with a 30% down payment CHINAMFG confirmation of the Proforma Invoice (PI), and the balance is to be paid after inspection and before shipment. We accept both TT and L/C at sight.
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| After-sales Service: | Local Teams |
|---|---|
| Warranty: | 18 Months |
| Lubrication Style: | Customized |
| Cooling System: | Air Cooling/Water Cooling |
| Cylinder Arrangement: | Balanced Opposed Arrangement |
| Cylinder Position: | Customized |
| Samples: |
US$ 40000/Set
1 Set(Min.Order) | |
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| Customization: |
Available
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Can Water-Lubricated Air Compressors Be Used in Cold Climates?
Water-lubricated air compressors can be used in cold climates, but there are certain considerations and precautions to keep in mind. Here’s a detailed explanation of using water-lubricated air compressors in cold climates:
Freezing of Water:
- Potential for Freezing: In cold climates, the water used for lubrication in water-lubricated compressors can freeze, which can cause operational issues and damage to the equipment. Freezing can occur in the water supply lines, lubrication system, or water jackets if the temperature drops below the freezing point of water.
- Water Temperature: It is important to ensure that the water temperature remains above freezing throughout the compressor system. This can be achieved by using insulation, heat tracing, or heaters to maintain adequate water temperature. Monitoring the water temperature and implementing appropriate heating measures are crucial to prevent freezing-related problems.
Protection and Insulation:
- Protecting External Components: External components of water-lubricated compressors, such as valves, fittings, and pipes, may be exposed to cold temperatures. Insulating these components can help prevent freezing and ensure their proper functioning. Insulation materials, such as foam wraps or heat tapes, can be used to provide thermal protection.
- Water Supply Lines: Water supply lines that feed the compressor should be properly insulated and protected from freezing temperatures. Insulation can help maintain the water temperature and prevent freezing within the supply lines. Additionally, measures such as burying the supply lines below the frost line or using heat tracing cables can offer further protection against freezing.
Alternative Lubrication Methods:
- Oil-Lubricated Compressors: In extremely cold climates, where freezing is a significant concern, using oil-lubricated compressors instead of water-lubricated ones may be a more practical option. Oil-based lubrication systems are less prone to freezing and can provide reliable operation in colder temperatures. However, it is important to consider the specific requirements and limitations of oil-lubricated compressors for the intended application.
Manufacturer Recommendations:
- Consulting the Manufacturer: It is crucial to consult the manufacturer’s guidelines and recommendations regarding the use of water-lubricated compressors in cold climates. Manufacturers may provide specific instructions, modifications, or alternative solutions to ensure the safe and efficient operation of their equipment under cold weather conditions.
By implementing proper insulation, heating measures, and following the manufacturer’s guidance, water-lubricated air compressors can be used effectively in cold climates. It is important to assess the specific requirements of the application and consider the potential challenges associated with freezing temperatures to ensure the reliable and safe operation of the water-lubricated compressor system.
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How Do You Troubleshoot Common Problems with Water-Lubrication Systems?
When encountering common problems with water-lubrication systems, it is essential to follow a systematic troubleshooting approach. Here’s a detailed explanation of the steps involved in troubleshooting common issues with water-lubrication systems:
Step 1: Identify the Problem:
The first step is to identify the specific problem or symptom that is affecting the water-lubrication system. Common problems may include inadequate lubrication, water leaks, abnormal noises, or reduced system performance. Understanding the specific issue will help in determining the appropriate troubleshooting steps.
Step 2: Check Water Supply:
Verify that there is a proper water supply to the system. Ensure that the water source is connected and flowing adequately. Check for any obstructions or restrictions in the water lines that may be affecting the water flow to the lubrication system.
Step 3: Inspect Water Filters and Strainers:
Water filters and strainers are used in water-lubrication systems to remove debris and impurities from the water. Inspect these filters and strainers for clogs or blockages that may be hindering the water flow. Clean or replace the filters as necessary to ensure proper water filtration.
Step 4: Verify Water Pressure:
Check the water pressure within the system to ensure it falls within the recommended range. Low water pressure can result in inadequate lubrication, while high water pressure can cause leaks or damage to the system. Use a pressure gauge to measure the water pressure and adjust it if necessary according to the manufacturer’s guidelines.
Step 5: Examine Water-Lubrication Components:
Closely inspect the various components of the water-lubrication system, including the water pump, distribution lines, lubrication points, and seals. Look for signs of wear, damage, or misalignment that may be contributing to the problem. Tighten loose connections and replace any damaged or worn-out components as needed.
Step 6: Check for Air in the System:
Air trapped within the water-lubrication system can affect its performance. Bleed the system to remove any trapped air. Follow the manufacturer’s instructions for bleeding air from the system, which typically involves opening specific valves or vents until a steady flow of water is achieved.
Step 7: Inspect Cooling Mechanisms:
Water-lubrication systems often incorporate cooling mechanisms, such as heat exchangers or radiators, to dissipate excess heat. Inspect these cooling components for blockages, corrosion, or leaks that may be compromising their effectiveness. Clean or repair the cooling mechanisms as necessary to ensure proper heat dissipation.
Step 8: Consult Manufacturer Documentation:
If the troubleshooting steps above do not resolve the problem, refer to the manufacturer’s documentation, such as the user manual or technical specifications. These resources may provide specific troubleshooting guidelines, diagnostics, or additional maintenance procedures for the water-lubrication system.
Step 9: Seek Professional Assistance:
If the problem persists or if the troubleshooting steps are beyond your expertise, it is advisable to seek professional assistance. Contact the manufacturer’s technical support or consult a qualified technician with experience in water-lubrication systems. They can provide expert guidance and assistance in resolving complex issues.
By following these troubleshooting steps, you can effectively identify and address common problems encountered in water-lubrication systems, ensuring optimal performance and reliability.
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How Do Water-Lubricated Air Compressors Compare to Oil-Lubricated Ones?
Water-lubricated air compressors and oil-lubricated air compressors have distinct differences in terms of lubrication method, performance, maintenance, and environmental impact. Here is a detailed comparison between the two:
| Water-Lubricated Air Compressors | Oil-Lubricated Air Compressors | |
|---|---|---|
| Lubrication Method | Water is used as the lubricant in water-lubricated compressors. It provides lubrication and heat dissipation. | Oil is used as the lubricant in oil-lubricated compressors. It provides lubrication, sealing, and heat dissipation. |
| Performance | Water lubrication offers efficient heat dissipation and cooling properties. It can effectively remove heat generated during compressor operation, preventing overheating and prolonging the compressor’s lifespan. Water lubrication can be suitable for applications where high heat generation is a concern. | Oil lubrication provides excellent lubrication properties, ensuring smooth operation and reduced friction. It offers good sealing capabilities, preventing air leakage. Oil-lubricated compressors are often preferred for heavy-duty applications that require high pressure and continuous operation. |
| Maintenance | Water lubrication generally requires less maintenance compared to oil lubrication. Water does not leave sticky residues or deposits, simplifying the cleaning process and reducing the frequency of lubricant changes. However, water lubrication may require additional measures to prevent corrosion and ensure proper water quality. | Oil lubrication typically requires more maintenance. Regular oil changes, filter replacements, and monitoring of oil levels are necessary. Contaminants, such as dirt or moisture, can adversely affect oil lubrication and require more frequent maintenance tasks. |
| Environmental Impact | Water lubrication is more environmentally friendly compared to oil lubrication. Water is non-toxic, biodegradable, and does not contribute to air or water pollution. It has a lower environmental impact and reduces the risk of contamination in case of leaks or spills. | Oil lubrication can have environmental implications. Oil leaks or spills can contaminate the environment, including air, soil, and water sources. Used oil disposal requires proper handling to prevent pollution. Oil-lubricated compressors also release volatile organic compounds (VOCs) into the air, contributing to air pollution. |
In summary, water-lubricated air compressors excel in efficient heat dissipation, require less maintenance, and have a lower environmental impact. On the other hand, oil-lubricated air compressors offer excellent lubrication properties and are suitable for heavy-duty applications. The choice between water and oil lubrication depends on specific requirements, operating conditions, and environmental considerations.
editor by CX 2024-02-01