Product Description
Oil Lubricated Screw Compressors FM07RS-FM75RS Series Variable Speed VSD
Efficient Compact Reliable
FM Series small air compressors are designed to provide you with excellent quality main engines imported from Germany, with simple and convenient after-sales maintenance design.
Design philosophy focused on details
• Hard pipe connection for both hard and soft pipelines
• Materials such as Teflon increase the stability of the overall unit running
Efficient, stable, customizable according to specific needs
• FM07-22: TEFC, with standard IP55 rating
• FM30-75: ODP, with IP23 / IP54 ratings optional
• (IP 54 400V / 50Hz optional)
Filtering system
Efficient, high-quality, micro-oil air quality
• With nanometer filter materials, filter accuracy of up to 1μ
• Improve air quality, oil content less than 2 ppm
• New pre-filtration system reduces the air filter load
• Increase the operating life of the overall unit under complex conditions
Compact design, imported main engine, high efficiency and energy saving
• The direct drive by air end and motor of FM30-75 realizes efficient conversion of high CHINAMFG torque that protects the air end from the impact of external forces, thereby enabling more efficient and more stable operation.
• The whole series can reach national Level I, or Level II energy efficiency.
Technical Data for FM07RS-FM75RS Series Variable Speed VSD
| Model Number | Pressure(Bar) | Power(kW) | FAD1 (m3/min) | Noise Level² dB(A) | Drive | Weight (kG) | Dimensions L x W x H (mm) |
| FM07RS-7A | 7 | 7.5 | 0.45-1.13 | 70 | Belt | 225 | 667×630×1050 |
| FM07RS-8A | 8 | 7.5 | 0.46-0.98 | 70 | Belt | 225 | 667×630×1050 |
| FM07RS-10A | 10 | 7.5 | 0.43-0.95 | 70 | Belt | 225 | 667×630×1050 |
| FM07RS-13A | 13 | 7.5 | 0.45-0.77 | 70 | Belt | 225 | 667×630×1050 |
| FM11RS-7A | 7 | 11 | 0.58-1.53 | 70 | Belt | 234 | 667×630×1050 |
| FM11RS-8A | 8 | 11 | 0.52-1.41 | 70 | Belt | 234 | 667×630×1050 |
| FM11RS-10A | 10 | 11 | 0.51-1.39 | 70 | Belt | 234 | 667×630×1050 |
| FM11RS-13A | 13 | 11 | 0.49-1.07 | 70 | Belt | 234 | 667×630×1050 |
| FM15RS-7A | 7 | 15 | 1.06-2.64 | 73 | Belt | 360 | 787×698×1202 |
| FM15RS-8A | 8 | 15 | 1.01-2.46 | 73 | Belt | 360 | 787×698×1202 |
| FM15RS-10A | 10 | 15 | 0.95-2.2 | 73 | Belt | 360 | 787×698×1202 |
| FM15RS-13A | 13 | 15 | 0.89-1.73 | 73 | Belt | 360 | 787×698×1202 |
| FM18RS-7A | 7 | 18.5 | 1.37-3.15 | 74 | Belt | 380 | 787×698×1202 |
| FM18RS-8A | 8 | 18.5 | 1.35-2.96 | 74 | Belt | 380 | 787×698×1202 |
| FM18RS-10A | 10 | 18.5 | 1.29-2.66 | 74 | Belt | 380 | 787×698×1202 |
| FM18RS-13A | 13 | 18.5 | 1.31-2.25 | 74 | Belt | 380 | 787×698×1202 |
| FM22RS-7A | 7 | 22 | 1.35-3.49 | 74 | Belt | 395 | 787×698×1202 |
| FM22RS-8A | 8 | 22 | 1.05-3.23 | 74 | Belt | 395 | 787×698×1202 |
| FM22RS-10A | 10 | 22 | 0.94-3.05 | 74 | Belt | 395 | 787×698×1202 |
| FM22RS-13A | 13 | 22 | 0.98-2.59 | 74 | Belt | 395 | 787×698×1202 |
| FM30RS-7A | 7 | 30 | 1.88-5.26 | 72 | Direct | 750 | 1554×894×1505 |
| FM30RS-8A | 8 | 30 | 1.85-5.23 | 72 | Direct | 750 | 1554×894×1505 |
| FM30RS-10A | 10 | 30 | 1.81-4.52 | 72 | Direct | 750 | 1554×894×1505 |
| FM37RS-7A | 7 | 37 | 1.84-6.24 | 72 | Direct | 830 | 1554×894×1505 |
| FM37RS-8A | 8 | 37 | 1.84-6.21 | 72 | Direct | 830 | 1554×894×1505 |
| FM37RS-10A | 10 | 37 | 1.75-5.01 | 72 | Direct | 830 | 1554×894×1505 |
| FM45RS-7A | 7 | 45 | 2.83-7.57 | 76 | Direct | 900 | 1554×894×1505 |
| FM45RS-8A | 8 | 45 | 3.73-7.51 | 76 | Direct | 900 | 1554×894×1505 |
| FM45RS-10A | 10 | 45 | 2.25-6.12 | 76 | Direct | 900 | 1554×894×1505 |
| FM55RS-7A | 7 | 55 | 2.44-10.34 | 75 | Direct | 1170 | 2004×1179×1605 |
| FM55RS-8A | 8 | 55 | 2.37-10.07 | 75 | Direct | 1170 | 2004×1179×1605 |
| FM55RS-10A | 10 | 55 | 2.24-9.14 | 75 | Direct | 1170 | 2004×1179×1605 |
| FM75RS-7A | 7 | 75 | 1.82-13.5 | 78 | Direct | 1220 | 2004×1179×1605 |
| FM75RS-8A | 8 | 75 | 1.76-12.9 | 78 | Direct | 1220 | 2004×1179×1605 |
| FM75RS-10A | 10 | 75 | 1.65-11.91 | 78 | Direct | 1220 | 2004×1179×1605 |
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| Lubrication Style: | Lubricated |
|---|---|
| Cooling System: | Air Cooling |
| Power Source: | AC Power |
| Cylinder Position: | Horizontal |
| Structure Type: | Closed Type |
| Installation Type: | Stationary Type |
| Customization: |
Available
|
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|---|
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What are the differences between stationary and portable air compressors?
Stationary and portable air compressors are two common types of air compressors with distinct features and applications. Here are the key differences between them:
1. Mobility:
The primary difference between stationary and portable air compressors is their mobility. Stationary air compressors are designed to be permanently installed in a fixed location, such as a workshop or a factory. They are typically larger, heavier, and not easily movable. On the other hand, portable air compressors are smaller, lighter, and equipped with handles or wheels for easy transportation. They can be moved from one location to another, making them suitable for jobsites, construction sites, and other mobile applications.
2. Power Source:
Another difference lies in the power source used by stationary and portable air compressors. Stationary compressors are usually powered by electricity, as they are designed for continuous operation in a fixed location with access to power outlets. They are connected to the electrical grid or have dedicated wiring. In contrast, portable compressors are available in various power options, including electric, gasoline, and diesel engines. This versatility allows them to operate in remote areas or sites without readily available electricity.
3. Tank Capacity:
Tank capacity is also a distinguishing factor between stationary and portable air compressors. Stationary compressors often have larger storage tanks to store compressed air for extended periods. The larger tanks enable them to deliver a continuous and steady supply of compressed air for longer durations without the need for frequent cycling. Portable compressors, due to their compact size and portability, generally have smaller tank capacities, which may be sufficient for intermittent or smaller-scale applications.
4. Performance and Output:
The performance and output capabilities of stationary and portable air compressors can vary. Stationary compressors are typically designed for high-volume applications that require a consistent and continuous supply of compressed air. They often have higher horsepower ratings, larger motor sizes, and higher air delivery capacities. Portable compressors, while generally offering lower horsepower and air delivery compared to their stationary counterparts, are still capable of delivering sufficient air for a range of applications, including pneumatic tools, inflation tasks, and light-duty air-powered equipment.
5. Noise Level:
Noise level is an important consideration when comparing stationary and portable air compressors. Stationary compressors, being larger and built for industrial or commercial settings, are often equipped with noise-reducing features such as sound insulation and vibration dampening. They are designed to operate at lower noise levels, which is crucial for maintaining a comfortable working environment. Portable compressors, while efforts are made to reduce noise, may produce higher noise levels due to their compact size and portability.
6. Price and Cost:
Stationary and portable air compressors also differ in terms of price and cost. Stationary compressors are generally more expensive due to their larger size, higher power output, and industrial-grade construction. They often require professional installation and may involve additional costs such as electrical wiring and system setup. Portable compressors, being smaller and more versatile, tend to have a lower upfront cost. They are suitable for individual users, contractors, and small businesses with budget constraints or flexible air supply needs.
When selecting between stationary and portable air compressors, it is essential to consider the specific requirements of the intended application, such as mobility, power source availability, air demands, and noise considerations. Understanding these differences will help in choosing the appropriate type of air compressor for the intended use.
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How do you maintain proper air quality in compressed air systems?
Maintaining proper air quality in compressed air systems is essential to ensure the reliability and performance of pneumatic equipment and the safety of downstream processes. Here are some key steps to maintain air quality:
1. Air Filtration:
Install appropriate air filters in the compressed air system to remove contaminants such as dust, dirt, oil, and water. Filters are typically placed at various points in the system, including the compressor intake, aftercoolers, and before point-of-use applications. Regularly inspect and replace filters to ensure their effectiveness.
2. Moisture Control:
Excessive moisture in compressed air can cause corrosion, equipment malfunction, and compromised product quality. Use moisture separators or dryers to remove moisture from the compressed air. Refrigerated dryers, desiccant dryers, or membrane dryers are commonly employed to achieve the desired level of dryness.
3. Oil Removal:
If the compressed air system utilizes oil-lubricated compressors, it is essential to incorporate proper oil removal mechanisms. This can include coalescing filters or adsorption filters to remove oil aerosols and vapors from the air. Oil-free compressors eliminate the need for oil removal.
4. Regular Maintenance:
Perform routine maintenance on the compressed air system, including inspections, cleaning, and servicing of equipment. This helps identify and address any potential issues that may affect air quality, such as leaks, clogged filters, or malfunctioning dryers.
5. Air Receiver Tank Maintenance:
Regularly drain and clean the air receiver tank to remove accumulated contaminants, including water and debris. Proper maintenance of the tank helps prevent contamination from being introduced into the compressed air system.
6. Air Quality Testing:
Periodically test the quality of the compressed air using appropriate instruments and methods. This can include measuring particle concentration, oil content, dew point, and microbial contamination. Air quality testing provides valuable information about the effectiveness of the filtration and drying processes and helps ensure compliance with industry standards.
7. Education and Training:
Educate personnel working with compressed air systems about the importance of air quality and the proper procedures for maintaining it. Provide training on the use and maintenance of filtration and drying equipment, as well as awareness of potential contaminants and their impact on downstream processes.
8. Documentation and Record-Keeping:
Maintain accurate records of maintenance activities, including filter replacements, drying system performance, and air quality test results. Documentation helps track the system’s performance over time and provides a reference for troubleshooting or compliance purposes.
By implementing these practices, compressed air systems can maintain proper air quality, minimize equipment damage, and ensure the integrity of processes that rely on compressed air.
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What is the role of air compressor tanks?
Air compressor tanks, also known as receiver tanks or air receivers, play a crucial role in the operation of air compressor systems. They serve several important functions:
1. Storage and Pressure Regulation: The primary role of an air compressor tank is to store compressed air. As the compressor pumps air into the tank, it accumulates and pressurizes the air. The tank acts as a reservoir, allowing the compressor to operate intermittently while providing a steady supply of compressed air during periods of high demand. It helps regulate and stabilize the pressure in the system, reducing pressure fluctuations and ensuring a consistent supply of air.
2. Condensation and Moisture Separation: Compressed air contains moisture, which can condense as the air cools down inside the tank. Air compressor tanks are equipped with moisture separators or drain valves to collect and remove this condensed moisture. The tank provides a space for the moisture to settle, allowing it to be drained out periodically. This helps prevent moisture-related issues such as corrosion, contamination, and damage to downstream equipment.
3. Heat Dissipation: During compression, air temperature increases. The air compressor tank provides a larger surface area for the compressed air to cool down and dissipate heat. This helps prevent overheating of the compressor and ensures efficient operation.
4. Pressure Surge Mitigation: Air compressor tanks act as buffers to absorb pressure surges or pulsations that may occur during compressor operation. These surges can be caused by variations in demand, sudden changes in airflow, or the cyclic nature of reciprocating compressors. The tank absorbs these pressure fluctuations, reducing stress on the compressor and other components, and providing a more stable and consistent supply of compressed air.
5. Energy Efficiency: Air compressor tanks contribute to energy efficiency by reducing the need for the compressor to run continuously. The compressor can fill the tank during periods of low demand and then shut off when the desired pressure is reached. This allows the compressor to operate in shorter cycles, reducing energy consumption and minimizing wear and tear on the compressor motor.
6. Emergency Air Supply: In the event of a power outage or compressor failure, the stored compressed air in the tank can serve as an emergency air supply. This can provide temporary air for critical operations, allowing time for maintenance or repairs to be carried out without disrupting the overall workflow.
Overall, air compressor tanks provide storage, pressure regulation, moisture separation, heat dissipation, pressure surge mitigation, energy efficiency, and emergency backup capabilities. They are vital components that enhance the performance, reliability, and longevity of air compressor systems in various industrial, commercial, and personal applications.
editor by CX 2024-01-03