Product Description
Oil free compressed air: in accordance with ISO 8573-1:2001 grade 0, which specifies the food and beverage, pharmaceutical, textile, and electronics industries
Reducing energy costs: Combining variable speed operation with Nirvana HPM Motors, as well as advanced system controllers, provide ultra efficient performance
Stronger reliability: stainless steel components, double row sealing, and precision machined rotors with UltraCoat protection ensure smooth operation
Reduce lubricant replacement: The industry-leading Ultra Coolant provides up to 8000 hours of lubricant usage time, which is 8 times the lifespan of conventional lubricants
High temperature working environment: Long life components are designed to withstand the highest ambient temperature of 46 º C
| Water Cooling | |||||||||||
| Model | Hz | FAD | Dimension | Weight | |||||||
| m³/min | Width (mm) | Length (mm) | Height (mm) | kg | |||||||
| SL-37 | 50 | 6 | 1372 | 2248 | 1914 | 2387/2410 | |||||
| SM-37 | 50 | 5.1 | 1372 | 2248 | 1914 | 2387/2410 | |||||
| SH-37 | 50 | / | 1372 | 2248 | 1914 | 2387/2410 | |||||
| SL-45 | 50 | 7.6 | 1372 | 2248 | 1914 | 2497/2520 | |||||
| SM-45 | 50 | 6.5 | 1372 | 2248 | 1914 | 2497/2520 | |||||
| SH-45 | 50 | / | 1372 | 2248 | 1914 | 2497/2520 | |||||
| SL-55 | 50 | 9.6 | 1372 | 2248 | 1914 | 2577/2600 | |||||
| SM-55 | 50 | 8.6 | 1372 | 2248 | 1914 | 2577/2600 | |||||
| SH-55 | 50 | 7.7* | 1372 | 2248 | 1914 | 2577/2600 | |||||
| SL-75 | 50 | 12.5 | 1372 | 2248 | 1914 | 2682/2705 | |||||
| SM-75 | 50 | 11.6 | 1372 | 2248 | 1914 | 2682/2705 | |||||
| SH-75 | 50 | 10.7* | 1372 | 2248 | 1914 | 2682/2705 | |||||
| SL-90 | 50 | 15.9 | 1588 | 2692 | 2362/1841 | 3040/3195 | |||||
| SM-90 | 50 | 13.6 | 1588 | 2692 | 2362/1842 | 3040/3195 | |||||
| SH-90 | 50 | 13 | 1588 | 2692 | 2362/1843 | 3040/3195 | |||||
| SL-110 | 50 | 19.4 | 1588 | 2692 | 2362/1844 | 3095/3250 | |||||
| SM-110 | 50 | 18 | 1588 | 2692 | 2362/1845 | 3095/3250 | |||||
| SH-110 | 50 | 15.3 | 1588 | 2692 | 2362/1846 | 3095/3250 | |||||
| SL-132 | 50 | 22.8 | 1588 | 2692 | 2362/1847 | 3274/3429 | |||||
| SM-132 | 50 | 21.4 | 1588 | 2692 | 2362/1848 | 3274/3429 | |||||
| SH-132 | 50 | 18.8 | 1588 | 2692 | 2362/1849 | 3274/3429 | |||||
| SL-150 | 50 | 25.9 | 1588 | 2692 | 2362/1850 | 3275/3430 | |||||
| SM-150 | 50 | 24.6 | 1588 | 2692 | 2362/1851 | 3275/3430 | |||||
| SH-150 | 50 | 22.1 | 1588 | 2692 | 2362/1852 | 3275/3430 | |||||
| SL-200 | 50 | 35 | 1930 | 3048 | 2438/2571 | 4186 | |||||
| SM-200 | 50 | 32.6 | 1930 | 3048 | 2438/2571 | 4186 | |||||
| SH-200 | 50 | 27.4 | 1930 | 3048 | 2438/2571 | 4186 | |||||
| SL-250 | 50 | 45.2 | 1930 | 3048 | 2438/2026 | 4306 | |||||
| SM-250 | 50 | 41.2 | 1930 | 3048 | 2438/2571 | 4306 | |||||
| SH-250 | 50 | 35.5 | 1930 | 3048 | 2438/2571 | 4306 | |||||
| SL-300 | 50 | 43.6 | 1930 | 3048 | 2438/2571 | 4366 | |||||
| SM-300 | 50 | 43.5 | 1930 | 3048 | 2438/2030 | 4366 | |||||
| SH-300 | 50 | 43.3 | 1930 | 3048 | 2438/2031 | 4366 | |||||
| Air Cooling | |||||||||||
| Model | HZ | FAD | Dimension | Weight | |||||||
| cfm | Width (mm) | Length (mm) | Height (mm) | Ib | |||||||
| L-50 | 60 | 214 | 54 | 88.5 | 75.4 | 5111 | |||||
| H-50 | 60 | 179 | 54 | 88.5 | 75.4 | 5111 | |||||
| HH-50 | 60 | / | 54 | 88.5 | 75.4 | 5111 | |||||
| L-60 | 60 | 266 | 54 | 88.5 | 75.4 | 5364 | |||||
| H-60 | 60 | 229 | 54 | 88.5 | 75.4 | 5364 | |||||
| HH-60 | 60 | / | 54 | 88.5 | 75.4 | 5364 | |||||
| L-75 | 60 | 333 | 54 | 88.5 | 75.4 | 5364 | |||||
| H-75 | 60 | 288 | 54 | 88.5 | 75.4 | 5364 | |||||
| HH-75 | 60 | 268* | 54 | 88.5 | 75.4 | 5500 | |||||
| L-100 | 60 | 419 | 54 | 88.5 | 75.4 | 5500 | |||||
| H-100 | 60 | 407 | 54 | 88.5 | 75.4 | 5500 | |||||
| HH-100 | 60 | 378* | 54 | 88.5 | 75.4 | 5500 | |||||
| L-125 | 60 | 585 | 62.5 | 106 | 93.3/72.5 | 6437/6709** | |||||
| H-125 | 60 | 523 | 62.5 | 106 | 93.3/72.5 | 6437/6709** | |||||
| HH-125 | 60 | 477 | 62.5 | 106 | 93.3/72.5 | 6437/6709** | |||||
| L-150 | 60 | 690 | 62.5 | 106 | 93.3/72.5 | 6452/6724** | |||||
| H-150 | 60 | 690 | 62.5 | 106 | 93.3/72.5 | 6452/6724** | |||||
| HH-150 | 60 | 565 | 62.5 | 106 | 93.3/72.5 | 6452/6724** | |||||
| L-200 | 60 | 911 | 62.5 | 106 | 93.3/72.5 | 7099/7385** | |||||
| H-200 | 60 | 854 | 62.5 | 106 | 93.3/72.5 | 7099/7385** | |||||
| HH-200 | 60 | 759 | 62.5 | 106 | 93.3/72.5 | 7099/7385** | |||||
| L-250 | 60 | 1182 | 76 | 120 | 96/80** | 8820 | |||||
| H-250 | 60 | 1070 | 76 | 120 | 96/80** | 8820 | |||||
| HH-250 | 60 | 905 | 76 | 120 | 96/80** | 8820 | |||||
| L-300 | 60 | 1398 | 76 | 120 | 96/80** | 9090 | |||||
| H-300 | 60 | 1264 | 76 | 120 | 96/80** | 9090 | |||||
| HH-300 | 60 | 1112 | 76 | 120 | 96/80** | 9090 | |||||
| L-350 | 60 | 1600 | 76 | 120 | 96/80** | 9610 | |||||
| H-350 | 60 | 1501 | 76 | 120 | 96/80** | 9610 | |||||
| HH-350 | 60 | 1330 | 76 | 120 | 96/80** | 9610 | |||||
| L-400 | 60 | 1539 | 76 | 120 | 96/80** | 9610 | |||||
| H-400 | 60 | 1535 | 76 | 120 | 96/80** | 9610 | |||||
| HH-400 | 60 | 1527 | 76 | 120 | 96/80** | 9610 | |||||
| After-sales Service: | Online Service |
|---|---|
| Warranty: | One Year |
| Lubrication Style: | Oil-free |
| Cooling System: | Air Cooling |
| Power Source: | AC Power |
| Cylinder Position: | Horizontal |
| Customization: |
Available
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What are the advantages of using rotary vane compressors?
Rotary vane compressors offer several advantages that make them a popular choice for various applications. These compressors are widely used in industries where a reliable and efficient source of compressed air is required. Here are the advantages of using rotary vane compressors:
1. Compact and Lightweight:
Rotary vane compressors are typically compact and lightweight compared to other types of compressors. Their compact design makes them suitable for installations where space is limited, such as in small workshops or mobile applications. The lightweight nature of these compressors allows for easy transportation and maneuverability.
2. High Efficiency:
Rotary vane compressors are known for their high efficiency. The design of the vanes and the compression chamber allows for smooth and continuous compression, resulting in minimal energy losses. This efficiency translates into lower energy consumption and reduced operating costs over time.
3. Quiet Operation:
Rotary vane compressors operate with relatively low noise levels. The design of the compressor, including the use of vibration damping materials and sound insulation, helps to minimize noise and vibrations during operation. This makes rotary vane compressors suitable for applications where noise reduction is important, such as in indoor environments or noise-sensitive areas.
4. Oil Lubrication:
Many rotary vane compressors utilize oil lubrication, which provides several benefits. The oil lubrication helps to reduce wear and friction between the moving parts, resulting in extended compressor life and improved reliability. It also contributes to better sealing and improved efficiency by minimizing internal leakage.
5. Versatile Applications:
Rotary vane compressors are versatile and can be used in a wide range of applications. They are suitable for both industrial and commercial applications, including automotive workshops, small manufacturing facilities, dental offices, laboratories, and more. They can handle various compressed air requirements, from light-duty tasks to more demanding applications.
6. Easy Maintenance:
Maintenance of rotary vane compressors is relatively straightforward. Routine maintenance tasks typically include oil changes, filter replacements, and periodic inspection of vanes and seals. The simplicity of the design and the availability of replacement parts make maintenance and repairs easier and more cost-effective.
These advantages make rotary vane compressors an attractive choice for many applications, providing reliable and efficient compressed air solutions.
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Can air compressors be integrated into automated systems?
Yes, air compressors can be integrated into automated systems, providing a reliable and versatile source of compressed air for various applications. Here’s a detailed explanation of how air compressors can be integrated into automated systems:
Pneumatic Automation:
Air compressors are commonly used in pneumatic automation systems, where compressed air is utilized to power and control automated machinery and equipment. Pneumatic systems rely on the controlled release of compressed air to generate linear or rotational motion, actuating valves, cylinders, and other pneumatic components. By integrating an air compressor into the system, a continuous supply of compressed air is available to power the automation process.
Control and Regulation:
In automated systems, air compressors are often connected to a control and regulation system to manage the compressed air supply. This system includes components such as pressure regulators, valves, and sensors to monitor and adjust the air pressure, flow, and distribution. The control system ensures that the air compressor operates within the desired parameters and provides the appropriate amount of compressed air to different parts of the automated system as needed.
Sequential Operations:
Integration of air compressors into automated systems enables sequential operations to be carried out efficiently. Compressed air can be used to control the timing and sequencing of different pneumatic components, ensuring that the automated system performs tasks in the desired order and with precise timing. This is particularly useful in manufacturing and assembly processes where precise coordination of pneumatic actuators is required.
Energy Efficiency:
Air compressors can contribute to energy-efficient automation systems. By incorporating energy-saving features such as Variable Speed Drive (VSD) technology, air compressors can adjust their power output according to the demand, reducing energy consumption during periods of low activity. Additionally, efficient control and regulation systems help optimize the use of compressed air, minimizing waste and improving overall energy efficiency.
Monitoring and Diagnostics:
Integration of air compressors into automated systems often includes monitoring and diagnostic capabilities. Sensors and monitoring devices can be installed to collect data on parameters such as air pressure, temperature, and system performance. This information can be used for real-time monitoring, preventive maintenance, and troubleshooting, ensuring the reliable operation of the automated system.
When integrating air compressors into automated systems, it is crucial to consider factors such as the specific requirements of the automation process, the desired air pressure and volume, and the compatibility of the compressor with the control and regulation system. Consulting with experts in automation and compressed air systems can help in designing an efficient and reliable integration.
In summary, air compressors can be seamlessly integrated into automated systems, providing the necessary compressed air to power and control pneumatic components, enabling sequential operations, and contributing to energy-efficient automation processes.
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How is air pressure measured in air compressors?
Air pressure in air compressors is typically measured using one of two common units: pounds per square inch (PSI) or bar. Here’s a brief explanation of how air pressure is measured in air compressors:
1. Pounds per Square Inch (PSI): PSI is the most widely used unit of pressure measurement in air compressors, especially in North America. It represents the force exerted by one pound of force over an area of one square inch. Air pressure gauges on air compressors often display pressure readings in PSI, allowing users to monitor and adjust the pressure accordingly.
2. Bar: Bar is another unit of pressure commonly used in air compressors, particularly in Europe and many other parts of the world. It is a metric unit of pressure equal to 100,000 pascals (Pa). Air compressors may have pressure gauges that display readings in bar, providing an alternative measurement option for users in those regions.
To measure air pressure in an air compressor, a pressure gauge is typically installed on the compressor’s outlet or receiver tank. The gauge is designed to measure the force exerted by the compressed air and display the reading in the specified unit, such as PSI or bar.
It’s important to note that the air pressure indicated on the gauge represents the pressure at a specific point in the air compressor system, typically at the outlet or tank. The actual pressure experienced at the point of use may vary due to factors such as pressure drop in the air lines or restrictions caused by fittings and tools.
When using an air compressor, it is essential to set the pressure to the appropriate level required for the specific application. Different tools and equipment have different pressure requirements, and exceeding the recommended pressure can lead to damage or unsafe operation. Most air compressors allow users to adjust the pressure output using a pressure regulator or similar control mechanism.
Regular monitoring of the air pressure in an air compressor is crucial to ensure optimal performance, efficiency, and safe operation. By understanding the units of measurement and using pressure gauges appropriately, users can maintain the desired air pressure levels in their air compressor systems.
editor by CX 2023-10-16