Product Description
Reference Technical parameters and specifications
| NO. | MODEL | Compressed medium | Flow rate Nm³/h |
Inlet pressure MPa |
Outlet pressure MPa |
Rotating speed r/min |
Motor power KW |
Cooling mode | Overall dimension mm |
Weight Kg |
| 1 | DW-14/(0-0.2)-25 | Raw gas | 800 | 0-0.02 | 2.5 | 740 | 160 | Water cooled | 4800*3200*1915 | ~10000 |
| 2 | VW-8/18 | Vinylidene fluoride gas | 418 | Atmospheric pressure | 1.8 | 980 | 75 | Water cooled | 3700*2000*1700 | ~4500 |
| 3 | VWD-3.2/(0-0.2)-40 | Biogas | 230 | 0-0.2 | 4.0 | 740 | 45 | Water cooled | 6000*2500*2650 | ~8000 |
| 4 | VW-9/6 | Ethyl chloride gas | 470 | Atmospheric pressure | 0.6 | 980 | 55 | Water cooled | 2800*1720*1700 | ~3500 |
| 5 | DWF-12.4/(9-12)-14 | Carbon dioxide | 6400 | 0.9-1.2 | 1.4 | 740 | 185 | Air cooled | 6000*2700*2200 | ~10000 |
| 6 | VWF-2.86/5-16 | Nitrogen gas | 895 | 0.5 | 1.6 | 740 | 55 | Air cooled | 3200*2200*1750 | ~3500 |
| 7 | DW-2.4/(18-25)-50 | Raw gas | 2900 | 1.8-2.5 | 5.0 | 980 | 160 | Water cooled | 4300*3000*1540 | ~4500 |
| 8 | VW-5.6/(0-6)-6 | Isobutylene gas | 1650 | 0-0.6 | 0.6 | 740 | 45 | Water cooled | 2900X1900X1600 | ~3500 |
| 9 | VW-3.8/3.5 | Mixed gas | 200 | Atmospheric pressure | 0.35 | 980 | 18.5 | Water cooled | 2200*1945*1600 | ~2000 |
| 10 | ZW-1.7/3.5 | Vinyl chloride gas | 100 | Atmospheric pressure | 0.35 | 740 | 15 | Water cooled | 2700X1600X2068 | ~2000 |
| 11 | ZWF-0.96/5 | Hydrogen chloride gas | 55 | Atmospheric pressure | 0.5 | 740 | 11 | Air cooled | 2000*1500*2000 | ~1000 |
| 12 | VW-0.85/(0-14)-40 | Refrigerant gas | 300 | 0-1.4 | 4.0 | 740 | 55 | Water cooled | 4500*2300*1780 | ~5500 |
| 13 | DW-3.78/(8-13)-(16-24) | Ammonia gas | 2700 | 0.8-1.3 | 1.6-2.4 | 740 | 75 | Water cooled | 3200*2000*1700 | ~3500 |
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| Warranty: | 12 Months |
|---|---|
| Lubrication Style: | Customized |
| Cooling System: | Air/Water /Mixed Cooling |
| Cylinder Arrangement: | Balanced Opposed Arrangement |
| Cylinder Position: | Customized |
| Structure Type: | Open Type |
| Customization: |
Available
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What role do air dryers play in compressed air systems?
Air dryers play a crucial role in compressed air systems by removing moisture and contaminants from the compressed air. Compressed air, when generated, contains water vapor from the ambient air, which can condense and cause issues in the system and end-use applications. Here’s an overview of the role air dryers play in compressed air systems:
1. Moisture Removal:
Air dryers are primarily responsible for removing moisture from the compressed air. Moisture in compressed air can lead to problems such as corrosion in the system, damage to pneumatic tools and equipment, and compromised product quality in manufacturing processes. Air dryers utilize various techniques, such as refrigeration, adsorption, or membrane separation, to reduce the dew point of the compressed air and eliminate moisture.
2. Contaminant Removal:
In addition to moisture, compressed air can also contain contaminants like oil, dirt, and particles. Air dryers help in removing these contaminants to ensure clean and high-quality compressed air. Depending on the type of air dryer, additional filtration mechanisms may be incorporated to enhance the removal of oil, particulates, and other impurities from the compressed air stream.
3. Protection of Equipment and Processes:
By removing moisture and contaminants, air dryers help protect the downstream equipment and processes that rely on compressed air. Moisture and contaminants can negatively impact the performance, reliability, and lifespan of pneumatic tools, machinery, and instrumentation. Air dryers ensure that the compressed air supplied to these components is clean, dry, and free from harmful substances, minimizing the risk of damage and operational issues.
4. Improved Productivity and Efficiency:
Utilizing air dryers in compressed air systems can lead to improved productivity and efficiency. Dry and clean compressed air reduces the likelihood of equipment failures, downtime, and maintenance requirements. It also prevents issues such as clogging of air lines, malfunctioning of pneumatic components, and inconsistent performance of processes. By maintaining the quality of compressed air, air dryers contribute to uninterrupted operations, optimized productivity, and cost savings.
5. Compliance with Standards and Specifications:
Many industries and applications have specific standards and specifications for the quality of compressed air. Air dryers play a vital role in meeting these requirements by ensuring that the compressed air meets the desired quality standards. This is particularly important in industries such as food and beverage, pharmaceuticals, electronics, and automotive, where clean and dry compressed air is essential for product integrity, safety, and regulatory compliance.
By incorporating air dryers into compressed air systems, users can effectively control moisture and contaminants, protect equipment and processes, enhance productivity, and meet the necessary quality standards for their specific applications.
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What are the environmental considerations when using air compressors?
When using air compressors, there are several environmental considerations to keep in mind. Here’s an in-depth look at some of the key factors:
Energy Efficiency:
Energy efficiency is a crucial environmental consideration when using air compressors. Compressing air requires a significant amount of energy, and inefficient compressors can consume excessive power, leading to higher energy consumption and increased greenhouse gas emissions. It is important to choose energy-efficient air compressors that incorporate features such as Variable Speed Drive (VSD) technology and efficient motor design, as they can help minimize energy waste and reduce the carbon footprint.
Air Leakage:
Air leakage is a common issue in compressed air systems and can contribute to energy waste and environmental impact. Leaks in the system result in the continuous release of compressed air, requiring the compressor to work harder and consume more energy to maintain the desired pressure. Regular inspection and maintenance of the compressed air system to detect and repair leaks can help reduce air loss and improve overall energy efficiency.
Noise Pollution:
Air compressors can generate significant noise levels during operation, which can contribute to noise pollution. Prolonged exposure to high noise levels can have detrimental effects on human health and well-being and can also impact the surrounding environment and wildlife. It is important to consider noise reduction measures such as sound insulation, proper equipment placement, and using quieter compressor models to mitigate the impact of noise pollution.
Emissions:
While air compressors do not directly emit pollutants, the electricity or fuel used to power them can have an environmental impact. If the electricity is generated from fossil fuels, the associated emissions from power plants contribute to air pollution and greenhouse gas emissions. Choosing energy sources with lower emissions, such as renewable energy, can help reduce the environmental impact of operating air compressors.
Proper Waste Management:
Proper waste management is essential when using air compressors. This includes the appropriate disposal of compressor lubricants, filters, and other maintenance-related materials. It is important to follow local regulations and guidelines for waste disposal to prevent contamination of soil, water, or air and minimize the environmental impact.
Sustainable Practices:
Adopting sustainable practices can further reduce the environmental impact of using air compressors. This can include implementing preventive maintenance programs to optimize performance, reducing idle time, and promoting responsible use of compressed air by avoiding overpressurization and optimizing system design.
By considering these environmental factors and taking appropriate measures, it is possible to minimize the environmental impact associated with the use of air compressors. Choosing energy-efficient models, addressing air leaks, managing waste properly, and adopting sustainable practices can contribute to a more environmentally friendly operation.
How do oil-lubricated and oil-free air compressors differ?
Oil-lubricated and oil-free air compressors differ in terms of their lubrication systems and the presence of oil in their operation. Here are the key differences:
Oil-Lubricated Air Compressors:
1. Lubrication: Oil-lubricated air compressors use oil for lubricating the moving parts, such as pistons, cylinders, and bearings. The oil forms a protective film that reduces friction and wear, enhancing the compressor’s efficiency and lifespan.
2. Performance: Oil-lubricated compressors are known for their smooth and quiet operation. The oil lubrication helps reduce noise levels and vibration, resulting in a more comfortable working environment.
3. Maintenance: These compressors require regular oil changes and maintenance to ensure the proper functioning of the lubrication system. The oil filter may need replacement, and the oil level should be regularly checked and topped up.
4. Applications: Oil-lubricated compressors are commonly used in applications that demand high air quality and continuous operation, such as industrial settings, workshops, and manufacturing facilities.
Oil-Free Air Compressors:
1. Lubrication: Oil-free air compressors do not use oil for lubrication. Instead, they utilize alternative materials, such as specialized coatings, self-lubricating materials, or water-based lubricants, to reduce friction and wear.
2. Performance: Oil-free compressors generally have a higher airflow capacity, making them suitable for applications where a large volume of compressed air is required. However, they may produce slightly more noise and vibration compared to oil-lubricated compressors.
3. Maintenance: Oil-free compressors typically require less maintenance compared to oil-lubricated ones. They do not need regular oil changes or oil filter replacements. However, it is still important to perform routine maintenance tasks such as air filter cleaning or replacement.
4. Applications: Oil-free compressors are commonly used in applications where air quality is crucial, such as medical and dental facilities, laboratories, electronics manufacturing, and painting applications. They are also favored for portable and consumer-grade compressors.
When selecting between oil-lubricated and oil-free air compressors, consider the specific requirements of your application, including air quality, noise levels, maintenance needs, and expected usage. It’s important to follow the manufacturer’s recommendations for maintenance and lubrication to ensure the optimal performance and longevity of the air compressor.
editor by CX 2023-12-23