Product Description
Product Description
The filter system is newly designed for the bipolar compression system, and the reasonable system design is equipped with the top 3 filters to ensure long-term stable operation of the equipment.
Air filter: front cyclone separation plus bipolar air filter with top filter material.
Oil separation core: large filter area plus high-strength metal mesh cover.
Oil Filter: the most extensive filter medium, with low system pressure drop and strong, anti-corrosion shell.
Main Engine Feature
Main Engine
The main engine adopts the design concept of large rotor and low speed, and the spindle speed is 1480. Low noise and vibration.
Two-stage main engine are more energy efficient than single-stage main engine. Under the same working conditions of exhaust volume and exhaust pressure, the energy consumption of the two-stage main engine is reduced by about 15% compared with that of the single-stage main engine. Under the same power consumption and exhaust pressure, the air volume of the two-stage main engine is about 15% larger than that of the single-stage main engine.
Power system:
High-efficiency fully enclosed air-cooled three-phase asynchronous motor, protection grade IP55, insulation grade F, in line with European EFF2 standard. Large starting torque, low noise, more reasonable structure, high efficiency (97%), energy saving, low vibration, reliable performance. Easy installation and maintenance. The front and rear bearings of the motor are the imported SKF bearings, and both are equipped with grease filling ports.
Cooling system:
The design of the super-large cooler makes the heat exchange efficiency higher, the resistance loss is smaller, and the temperature controls and cools fan’s start and stop, which achieves the operation of the constant temperature, so as to achieve the effect of stable operation and energy saving, and make the whole machine especially suitable for areas with large temperature difference and various different Ambient temperature.
Two super-large cooling fans independently control the start and stop of each fan according to the exhaust temperature of the system, which perfectly fits the operation of the air compressor and saves electricity.
Filtration system:
A new filter system is designed for two-stage compression system. The reasonable system design is equipped with the top 3 filter system to ensure the long-term stable operation of the equipment.
Pipeline connection:
Metal hoses are used in oil roads and gas lines. Beautiful and reliable.
Electrical system:
Select the world’s top Schneider Electric components. Reliable work, high protection level, and strong thermal stability.
Specification
| Mode | R90‖-20/8 | R110‖-24/8 | R132‖-28/8 | |
|
Machine Set |
Exhaust volume (m3/min) | 20 | 24 | 28 |
| Exhaust pressure (MPa) | 0.8 | 0.8 | 0.8 | |
| Compression level | two-stage compression | two-stage compression | two-stage compression | |
| Motor power(kw) | 90 | 110 | 132 | |
| Motor speed(rpm) | 1485 | 1485 | 1485 | |
| Energy efficiency rating | Grade I | Grade I | Grade I | |
| Power supply(V/P/Hz) | 380/3/50 | 380/3/50 | 380/3/50 | |
| Start method | Y-△ | Y-△ | Y-△ | |
| Transmission mode | direct connection | direct connection | direct connection | |
| Connection size | DN80 | DN80 | DN80 | |
| Cooling method | air cooling | air cooling | air cooling | |
| Length(mm) | 2682 | 2682 | 3165 | |
| Width(mm) | 1680 | 1680 | 1680 | |
| Height(mm) | 1925 | 1925 | 1945 | |
| Machine weight(kg) | 3350 | 3750 | 3900 | |
| Mode | R160‖-34/8 | R185‖-40/8 | R200‖-43/8 | |
|
Machine Set |
Exhaust volume (m3/min) | 34 | 40 | 43 |
| Exhaust pressure (MPa) | 0.8 | 0.8 | 0.8 | |
| Compression level | two-stage compression | two-stage compression | two-stage compression | |
| Motor power(kw) | 160 | 185 | 200 | |
| Motor speed(rpm) | 1485 | 1485 | 1485 | |
| Energy efficiency rating | Grade I | Grade I | Grade I | |
| Power supply(V/P/Hz) | 380/3/50 | 380/3/50 | 380/3/50 | |
| Start method | Y-△ | Y-△ | Y-△ | |
| Transmission mode | direct connection | direct connection | direct connection | |
| Connection size | DN80 | DN100 | DN100 | |
| Cooling method | air cooling | air cooling | air cooling | |
| Length(mm) | 3165 | 3500 | 3500 | |
| Width(mm) | 1680 | 1860 | 1860 | |
| Height(mm) | 1945 | 2100 | 2100 | |
| Machine weight(kg) | 4200 | 4500 | 4500 | |
| Mode | R220‖-47/8 | R250‖-54/8 | R280‖-60/8 | |
|
Machine Set |
Exhaust volume (m3/min) | 47 | 54 | 60 |
| Exhaust pressure (MPa) | 0.8 | 0.8 | 0.8 | |
| Compression level | two-stage compression | two-stage compression | two-stage compression | |
| Motor power(kw) | 220 | 250 | 280 | |
| Motor power(rpm) | 1485 | 1485 | 1485 | |
| Energy efficiency rating | Grade I | Grade I | Grade I | |
| Power supply (V/P/Hz) | 380/3/50 | 380/3/50 | 380/3/50 | |
| Start method | Y-△ | Y-△ | Y-△ | |
| Transmission mode | direct connection | direct connection | direct connection | |
| Connection size | DN100 | DN125 | DN125 | |
| Cooling method | air cooling | Water cooling | Water cooling | |
| Length(mm) | 3500 | 4240 | 4240 | |
| Width(mm) | 1860 | 2000 | 2000 | |
| Height(mm) | 2100 | 2100 | 2100 | |
| Machine weight(kg) | 4600 | 6500 | 6700 | |
| Mode | R315‖-67.5/8 | |
|
Machine Set |
Exhaust volume (m3/min) | 67.5 |
| Exhaust pressure (MPa) | 0.8 | |
| Compression level | two-stage compression | |
| Motor power(kw) | 315 | |
| Motor speed(rpm) | 1485 | |
| Energy efficiency rating | Grade I | |
| Power supply (V/P/Hz) | 380/3/50 | |
| Start method | Y-△ | |
| Transmission mode | direct connection | |
| Connection size | DN125 | |
| Cooling method | water cooling | |
| Length(mm) | 4240 | |
| Width(mm) | 2000 | |
| Height(mm) | 2100 | |
| Machine weight(kg) | 7200 | |
Specification
| Mode | G7EZ | GV7M | GV15M | GV22M | GV37M | |
|
Machine Set |
Exhaust volume(m³/min) | 1 | 1 | 2.0 | 3.4 | 6.1 |
| Exhaust pressure (MPa) | 0.8 | 0.8 | 0.8 | 0.8 | 0.8 | |
| Compression level | single stage | single stage | single stage | single stage | single stage | |
| Motor power(kW) | 7.5 | 7.5 | 15 | 22 | 37 | |
| Motor speed rmp) | 2900 | 3600 | 3000 | 3000 | 3000 | |
| Energy efficiency rating | Grade III | Grade III | Grade III | Grade III | Grade III | |
| Power supply (V/P/Hz) | 380/3/50 | 380/3/50 | 380/3/50 | 380/3/50 | 380/3/50 | |
| Start method | △ | frequency conversion | frequency conversion | frequency conversion | frequency conversion | |
| Transmission mode | direct connection | direct connection | direct connection | direct connection | direct connection | |
| Outlet size | G3/4″ | G1/2″ | G1″ | G1″ | G1 1/2″ | |
| Cooling method | air cooling | air cooling | air cooling | air cooling | air cooling | |
| Length ×Width x Height (mm) | 710×580× 810 |
710×580× 810 |
1170×690× 940 |
1050×880×1260 | 1200×1000×1430 | |
| Machine weight (kg) | 220 | 220 | 350 | 450 | 550 | |
| After-sales Service: | Online |
|---|---|
| Lubrication Style: | Lubricated |
| Cooling System: | Air Cooling |
| Customization: |
Available
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Shipping Cost:
Estimated freight per unit. |
about shipping cost and estimated delivery time. |
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| Payment Method: |
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Initial Payment Full Payment |
| Currency: | US$ |
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| Return&refunds: | You can apply for a refund up to 30 days after receipt of the products. |
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How are air compressors utilized in the aerospace industry?
Air compressors play a crucial role in various applications within the aerospace industry. They are utilized for a wide range of tasks that require compressed air or gas. Here are some key uses of air compressors in the aerospace industry:
1. Aircraft Systems:
Air compressors are used in aircraft systems to provide compressed air for various functions. They supply compressed air for pneumatic systems, such as landing gear operation, braking systems, wing flap control, and flight control surfaces. Compressed air is also utilized for starting aircraft engines and for cabin pressurization and air conditioning systems.
2. Ground Support Equipment:
Air compressors are employed in ground support equipment used in the aerospace industry. They provide compressed air for tasks such as inflating aircraft tires, operating pneumatic tools for maintenance and repair, and powering air-driven systems for fueling, lubrication, and hydraulic operations.
3. Component Testing:
Air compressors are utilized in component testing within the aerospace industry. They supply compressed air for testing and calibrating various aircraft components, such as valves, actuators, pressure sensors, pneumatic switches, and control systems. Compressed air is used to simulate operating conditions and evaluate the performance and reliability of these components.
4. Airborne Systems:
In certain aircraft, air compressors are employed for specific airborne systems. For example, in military aircraft, air compressors are used for air-to-air refueling systems, where compressed air is utilized to transfer fuel between aircraft in mid-air. Compressed air is also employed in aircraft de-icing systems, where it is used to inflate inflatable de-icing boots on the wing surfaces to remove ice accumulation during flight.
5. Environmental Control Systems:
Air compressors play a critical role in the environmental control systems of aircraft. They supply compressed air for air conditioning, ventilation, and pressurization systems, ensuring a comfortable and controlled environment inside the aircraft cabin. Compressed air is used to cool and circulate air, maintain desired cabin pressure, and control humidity levels.
6. Engine Testing:
In the aerospace industry, air compressors are utilized for engine testing purposes. They provide compressed air for engine test cells, where aircraft engines are tested for performance, efficiency, and durability. Compressed air is used to simulate different operating conditions and loads on the engine, allowing engineers to assess its performance and make necessary adjustments or improvements.
7. Oxygen Systems:
In aircraft, air compressors are involved in the production of medical-grade oxygen for onboard oxygen systems. Compressed air is passed through molecular sieve beds or other oxygen concentrator systems to separate oxygen from other components of air. The generated oxygen is then supplied to the onboard oxygen systems, ensuring a sufficient and continuous supply of breathable oxygen for passengers and crew at high altitudes.
It is important to note that air compressors used in the aerospace industry must meet stringent quality and safety standards. They need to be reliable, efficient, and capable of operating under demanding conditions to ensure the safety and performance of aircraft systems.
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How does the horsepower of an air compressor affect its capabilities?
The horsepower of an air compressor is a crucial factor that directly impacts its capabilities and performance. Here’s a closer look at how the horsepower rating affects an air compressor:
Power Output:
The horsepower rating of an air compressor indicates its power output or the rate at which it can perform work. Generally, a higher horsepower rating translates to a greater power output, allowing the air compressor to deliver more compressed air per unit of time. This increased power output enables the compressor to operate pneumatic tools and equipment that require higher air pressure or greater airflow.
Air Pressure:
The horsepower of an air compressor is directly related to the air pressure it can generate. Air compressors with higher horsepower ratings have the capacity to produce higher air pressures. This is particularly important when operating tools or machinery that require specific air pressure levels to function optimally. For example, heavy-duty pneumatic tools like jackhammers or impact wrenches may require higher air pressure to deliver the necessary force.
Air Volume:
In addition to air pressure, the horsepower of an air compressor also affects the air volume or airflow it can provide. Higher horsepower compressors can deliver greater volumes of compressed air, measured in cubic feet per minute (CFM). This increased airflow is beneficial when using pneumatic tools that require a continuous supply of compressed air, such as paint sprayers or sandblasters.
Duty Cycle:
The horsepower rating of an air compressor can also influence its duty cycle. The duty cycle refers to the amount of time an air compressor can operate continuously before it needs to rest and cool down. Higher horsepower compressors often have larger and more robust components, allowing them to handle heavier workloads and operate for longer periods without overheating. This is particularly important in demanding applications where continuous and uninterrupted operation is required.
Size and Portability:
It’s worth noting that the horsepower rating can also affect the physical size and portability of an air compressor. Higher horsepower compressors tend to be larger and heavier due to the need for more substantial motors and components to generate the increased power output. This can impact the ease of transportation and maneuverability, especially in portable or mobile applications.
When selecting an air compressor, it is essential to consider the specific requirements of your intended applications. Factors such as desired air pressure, airflow, duty cycle, and portability should be taken into account. It’s important to choose an air compressor with a horsepower rating that aligns with the demands of the tools and equipment you plan to operate, ensuring optimal performance and efficiency.
Consulting the manufacturer’s specifications and guidelines can provide valuable information on how the horsepower rating of an air compressor corresponds to its capabilities and suitability for different tasks.
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What are the safety considerations when operating an air compressor?
Operating an air compressor requires careful attention to safety to prevent accidents, injuries, and equipment damage. Here are some important safety considerations to keep in mind:
1. Read the Manual: Before operating an air compressor, thoroughly read and understand the manufacturer’s instruction manual. Familiarize yourself with the specific safety guidelines, recommended operating procedures, and any specific precautions or warnings provided by the manufacturer.
2. Proper Ventilation: Ensure that the area where the air compressor is operated has adequate ventilation. Compressed air can produce high levels of heat and exhaust gases. Good ventilation helps dissipate heat, prevent the buildup of fumes, and maintain a safe working environment.
3. Personal Protective Equipment (PPE): Always wear appropriate personal protective equipment, including safety glasses or goggles, hearing protection, and non-slip footwear. Depending on the task, additional PPE such as gloves, a dust mask, or a face shield may be necessary to protect against specific hazards.
4. Pressure Relief: Air compressors should be equipped with pressure relief valves or devices to prevent overpressurization. Ensure that these safety features are in place and functioning correctly. Regularly inspect and test the pressure relief mechanism to ensure its effectiveness.
5. Secure Connections: Use proper fittings, hoses, and couplings to ensure secure connections between the air compressor, air tools, and accessories. Inspect all connections before operation to avoid leaks or sudden hose disconnections, which can cause injuries or damage.
6. Inspect and Maintain: Regularly inspect the air compressor for any signs of damage, wear, or leaks. Ensure that all components, including hoses, fittings, and safety devices, are in good working condition. Follow the manufacturer’s recommended maintenance schedule to keep the compressor in optimal shape.
7. Electrical Safety: If the air compressor is electric-powered, take appropriate electrical safety precautions. Use grounded outlets and avoid using extension cords unless approved for the compressor’s power requirements. Protect electrical connections from moisture and avoid operating the compressor in wet or damp environments.
8. Safe Start-Up and Shut-Down: Properly start and shut down the air compressor following the manufacturer’s instructions. Ensure that all air valves are closed before starting the compressor and release all pressure before performing maintenance or repairs.
9. Training and Competence: Ensure that operators are adequately trained and competent in using the air compressor and associated tools. Provide training on safe operating procedures, hazard identification, and emergency response protocols.
10. Emergency Preparedness: Have a clear understanding of emergency procedures and how to respond to potential accidents or malfunctions. Know the location of emergency shut-off valves, fire extinguishers, and first aid kits.
By adhering to these safety considerations and implementing proper safety practices, the risk of accidents and injuries associated with operating an air compressor can be significantly reduced. Prioritizing safety promotes a secure and productive working environment.
editor by CX 2023-11-08
China Hot selling Air Compressor Filter System Reliable Air Compressors with Best Sales
Product Description
Refrigerated Compressed Air Dryer (Built-In Pre-Cooler)
Detailed Photos
Principle of working :
The amount of water vapor in the air compression by compressed air temperature determined: in case of compressed air pressure is basically the same, reduce the temperature of the air compressed compression to reduce the amount of water vapor in the air, and the excess water vapor will condense into liquid.
Freezing dryer is according to the corresponding relationship between the saturation water vapor pressure and temperature, use refrigeration device makes the compressed air is cooled to a certain dew point temperature, precipitation containing water, through the steam water separator and electric drainage device will discharge water, so that the compressed air can be dry.
Product Parameters
| Model |
Air Capacity (Nm3/min) |
Voltage (V) |
Fan Power (W) |
Air connector dia | Net weight (Kg) |
Lenghth (mm) |
Wideth (mm) |
Height (mm) |
Air flow (Nm3/n) |
| SDLF-0.5HT | 0.65 | 220 | 80 | G1″ | 54 | 400 | 560 | 730 | 820 |
| SDLF-1HT | 1.2 | 220 | 80 | G1″ | 57 | 400 | 560 | 730 | 820 |
| SDLF-2HT | 2.5 | 220 | 100 | G1″ | 66 | 520 | 640 | 890 | 1640 |
| SDLF-3HT | 3.6 | 220 | 135 | G1″ | 79 | 520 | 640 | 890 | 2670 |
| SDLF-4.5HT | 5.0 | 220 | 250 | G1-1/2″ | 86 | 540 | 700 | 1000 | 4650 |
| SDLF-6HT | 6.8 | 220 | 250 | G1-1/2″ | 90 | 540 | 700 | 1000 | 4650 |
| SDLF-8HT | 8.5 | 220 | 270 | G2″ | 99 | 610 | 900 | 1070 | 5700 |
| SDLF-10HT | 10.9 | 380/220 | 260 | G2″ | 113 | 610 | 900 | 1070 | 5700 |
| SDLF-12HT | 12.8 | 380/200 | 260 | G2″ | 113 | 610 | 900 | 1070 | 5700 |
Note: The above models use plate/plate-fin heat exchangers.
Company Profile
Certifications
Packaging & Shipping
FAQ
| After-sales Service: | Ok |
|---|---|
| Warranty: | 1 Year |
| Flow: | Cross Flow |
| Material Status: | Bulk |
| Drying Medium: | Air |
| Structure: | All Kinds |
| Samples: |
US$ 400/Piece
1 Piece(Min.Order) | |
|---|
| Customization: |
Available
|
|
|---|
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How does variable speed drive technology improve air compressor efficiency?
Variable Speed Drive (VSD) technology improves air compressor efficiency by allowing the compressor to adjust its motor speed to match the compressed air demand. This technology offers several benefits that contribute to energy savings and enhanced overall system efficiency. Here’s how VSD technology improves air compressor efficiency:
1. Matching Air Demand:
Air compressors equipped with VSD technology can vary the motor speed to precisely match the required compressed air output. Traditional fixed-speed compressors operate at a constant speed regardless of the actual demand, leading to energy wastage during periods of lower air demand. VSD compressors, on the other hand, ramp up or down the motor speed to deliver the necessary amount of compressed air, ensuring optimal energy utilization.
2. Reduced Unloaded Running Time:
Fixed-speed compressors often run unloaded during periods of low demand, where they continue to consume energy without producing compressed air. VSD technology eliminates or significantly reduces this unloaded running time by adjusting the motor speed to closely follow the air demand. As a result, VSD compressors minimize energy wastage during idle periods, leading to improved efficiency.
3. Soft Starting:
Traditional fixed-speed compressors experience high inrush currents during startup, which can strain the electrical system and cause voltage dips. VSD compressors utilize soft starting capabilities, gradually ramping up the motor speed instead of instantly reaching full speed. This soft starting feature reduces mechanical and electrical stress, ensuring a smooth and controlled startup, and minimizing energy spikes.
4. Energy Savings at Partial Load:
In many applications, compressed air demand varies throughout the day or during different production cycles. VSD compressors excel in such scenarios by operating at lower speeds during periods of lower demand. Since power consumption is proportional to motor speed, running the compressor at reduced speeds significantly reduces energy consumption compared to fixed-speed compressors that operate at a constant speed regardless of the demand.
5. Elimination of On/Off Cycling:
Fixed-speed compressors often use on/off cycling to adjust the compressed air output. This cycling can result in frequent starts and stops, which consume more energy and cause mechanical wear. VSD compressors eliminate the need for on/off cycling by continuously adjusting the motor speed to meet the demand. By operating at a consistent speed within the required range, VSD compressors minimize energy losses associated with frequent cycling.
6. Enhanced System Control:
VSD compressors offer advanced control capabilities, allowing for precise monitoring and adjustment of the compressed air system. These systems can integrate with sensors and control algorithms to maintain optimal system pressure, minimize pressure fluctuations, and prevent excessive energy consumption. The ability to fine-tune the compressor’s output based on real-time demand contributes to improved overall system efficiency.
By utilizing variable speed drive technology, air compressors can achieve significant energy savings, reduce operational costs, and enhance their environmental sustainability by minimizing energy wastage and optimizing efficiency.
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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.
How do you choose the right size of air compressor for your needs?
Choosing the right size of air compressor is essential to ensure optimal performance and efficiency for your specific needs. Here are some factors to consider when selecting the appropriate size:
1. Air Demand: Determine the air demand requirements of your applications. Calculate the total CFM (Cubic Feet per Minute) needed by considering the air consumption of all the pneumatic tools and equipment that will be operated simultaneously. Choose an air compressor with a CFM rating that meets or exceeds this total demand.
2. Pressure Requirements: Consider the required operating pressure for your applications. Check the PSI (Pounds per Square Inch) rating of the tools and equipment you will be using. Ensure that the air compressor you choose can deliver the necessary pressure consistently.
3. Duty Cycle: Evaluate the duty cycle of the air compressor. The duty cycle represents the percentage of time the compressor can operate within a given time period without overheating or experiencing performance issues. If you require continuous or heavy-duty operation, choose a compressor with a higher duty cycle.
4. Power Source: Determine the available power source at your location. Air compressors can be powered by electricity or gasoline engines. Ensure that the chosen compressor matches the available power supply and consider factors such as voltage, phase, and fuel requirements.
5. Portability: Assess the portability requirements of your applications. If you need to move the air compressor frequently or use it in different locations, consider a portable or wheeled compressor that is easy to transport.
6. Space and Noise Constraints: Consider the available space for installation and the noise restrictions in your working environment. Choose an air compressor that fits within the allocated space and meets any noise regulations or requirements.
7. Future Expansion: Anticipate any potential future expansions or increases in air demand. If you expect your air demand to grow over time, it may be wise to choose a slightly larger compressor to accommodate future needs and avoid the need for premature replacement.
8. Budget: Consider your budgetary constraints. Compare the prices of different air compressor models while ensuring that the chosen compressor meets your specific requirements. Keep in mind that investing in a higher-quality compressor may result in better performance, durability, and long-term cost savings.
By considering these factors and evaluating your specific needs, you can choose the right size of air compressor that will meet your air demand, pressure requirements, and operational preferences, ultimately ensuring efficient and reliable performance.
editor by CX 2023-11-06
China factory Zat-200 160kw Portable Two-Stage Compression Air Compressors air compressor CHINAMFG freight
Product Description
ZAT-200 160kw Two-stage compression air compressors portable manufacturer
ZAKF air compressor belongs to the general equipment category, and is widely used in steel, electric power, metallurgy, shipbuilding, electronics, textile, mining, chemical, petroleum, light industry, paper printing, machinery manufacturing, food and medicine, transportation facilities, casting spraying, and shipping terminals , Automotive industry, military technology, aerospace, infrastructure and other fields.
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Product Brand
ZAKF import advanced technology from Europe, through constant practice and improvement, design a new generation of “ZAKF” air compressor.
Improved quality assurance manual, advanced production process, control management program files comprehensive, standardized, ensuring high quality brand name products “ZAKF”, stable and durable. High quality, intimate service get the praise from users all over the world.
Why use CHINAMFG screw air compressor?
1. we are air compressor factory, quality and deliver time is under control, compessor colour, logo, voltage, pressure , motor can customized.
2. Monthly output capacity is 1500set machine, Quality has been recognized by the market
3. All English Compressor data and manual .
4. 24hours After-sale service.
5. our own factory, visit factory on anytime you want.
6. Top quality spare parts
A. Air filter: air filter, Dust removal effect 99.99%, work good under bad enviroment
B. Oil filter: Oil filter with glass fiber filter material with spin on type, the filtration effect is 20% higher than the conventional filter element
C. Air / oil separator: Large-capacity design, high-quality air and oil separation, three time oil and gas separation, oil content below 2ppm
D. Thermostat valve: Prevent the temperature of the lubricant from being too high make oil emulsification or too low make oil carbon deposit
, Guaranteed long-term use of lubricating oil and good sealing performance
7. energy saving and environmental protection , especially the Inverter machine / Two stage machine, 50HP for example:
When the air demand becomes small, the air compressor frequency is automatically reduced, the power sequentially reduced 50HP to 40HP to 30HP,20hp….
When the air gas demand becomes larger, the frequency of the air compressor automatically increases, the power is sequentially increased 30HP to 40HP to 50HP…
8. Inverter machine is good at Power saving, and Saving electricity bills, 37kw /50HP for example (energy saving 20% -25% )
37kw * 20% * 22hours one day * 312 days one year * us$ 0.15 kw/h (electricity cost) = us$ 7619.00 / year
our inverter compressor machine can save us$ 7619.00 each year for you of the electricity cost
Where you use?
Product parameters
| Model | ZAT-20 | ZAT-25 | ZAT-30 | ZAT-40 | ZAT-50 | ZAT-60 | ZAT-75 | ZAT-100 | ZAT-120 | ZAT-150 | ZAT-175 | ZAT-200 | ZAT-250 | ZAT-300 | ZAT-350 | ZAT-375 | ZAT-420 | |||||||||||||||||||||||||||||
| Power | KW | 15 | 18.5 | 22 | 30 | 37 | 45 | 55 | 75 | 90 | 110 | 132 | 160 | 185 | 200 | 250 | 280 | 315 | ||||||||||||||||||||||||||||
| Capacity | m³/Min/MPa | 2.9/0.7 | 3.6/0.7 | 4.2/0.7 | 6.4/0.7 | 7.1/0.7 | 9.8/0.7 | 12.2/0.7 | 16.8/0.7 | 19.8/0.7 | 23.6/0.7 | 30.7/0.7 | 34.5/0.7 | 41.0/0.7 | 44.6/0.7 | 50.0/0.7 | 60.0/0.7 | 67.5/0.7 | ||||||||||||||||||||||||||||
| 2.8/0.8 | 3.5/0.8 | 4.1/0.8 | 6.3/0.8 | 7.0/0.8 | 9.7/0.8 | 12.0/0.8 | 16.5/0.8 | 19.2/0.8 | 23.1/0.8 | 28.0/0.8 | 33.6/0.8 | 38.4/0.8 | 43.0/0.8 | 54.0/0.8 | 51.0/0.8 | 65.0/0.8 | ||||||||||||||||||||||||||||||
| 2.4/1.0 | 2.9/1.0 | 3.5/1.0 | 4.9/1.0 | 5.8/1.0 | 7.8/1.0 | 9.6/1.0 | 12.5/1.0 | 16.9/1.0 | 19.7/1.0 | 23.5/1.0 | 30.0/1.0 | 32.5/1.0 | 38.5/1.0 | 46.0/1.0 | 50.0/0.7 | 61.0/1.0 | ||||||||||||||||||||||||||||||
| 2.2/1.3 | 2.5/1.3 | 3.2/1.3 | 4.2/1.3 | 5.4/1.3 | 6.5/1.3 | 8.6/1.3 | 11.2/1.3 | 14.3/1.3 | 17.6/1.3 | 19.8/1.3 | 23.8/1.3 | 24.8/1.3 | 32.8/1.3 | 40.0/1.3 | 45.0/1.3 | 51.0/1.3 | ||||||||||||||||||||||||||||||
| Compress Stage | Double stage compression / double stage frequency conversion compression / permanent magnet double frequency conversion | |||||||||||||||||||||||||||||||||||||||||||||
| Ambient Temperature(ºC) | -5ºC ± 45ºC | |||||||||||||||||||||||||||||||||||||||||||||
| Cooling Method | Air Cooling/Water Cooling/Oil Cooling | |||||||||||||||||||||||||||||||||||||||||||||
| Exhaust Temperature(ºC) | ≤Ambient temperature
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How does variable speed drive technology improve air compressor efficiency?Variable Speed Drive (VSD) technology improves air compressor efficiency by allowing the compressor to adjust its motor speed to match the compressed air demand. This technology offers several benefits that contribute to energy savings and enhanced overall system efficiency. Here’s how VSD technology improves air compressor efficiency: 1. Matching Air Demand: Air compressors equipped with VSD technology can vary the motor speed to precisely match the required compressed air output. Traditional fixed-speed compressors operate at a constant speed regardless of the actual demand, leading to energy wastage during periods of lower air demand. VSD compressors, on the other hand, ramp up or down the motor speed to deliver the necessary amount of compressed air, ensuring optimal energy utilization. 2. Reduced Unloaded Running Time: Fixed-speed compressors often run unloaded during periods of low demand, where they continue to consume energy without producing compressed air. VSD technology eliminates or significantly reduces this unloaded running time by adjusting the motor speed to closely follow the air demand. As a result, VSD compressors minimize energy wastage during idle periods, leading to improved efficiency. 3. Soft Starting: Traditional fixed-speed compressors experience high inrush currents during startup, which can strain the electrical system and cause voltage dips. VSD compressors utilize soft starting capabilities, gradually ramping up the motor speed instead of instantly reaching full speed. This soft starting feature reduces mechanical and electrical stress, ensuring a smooth and controlled startup, and minimizing energy spikes. 4. Energy Savings at Partial Load: In many applications, compressed air demand varies throughout the day or during different production cycles. VSD compressors excel in such scenarios by operating at lower speeds during periods of lower demand. Since power consumption is proportional to motor speed, running the compressor at reduced speeds significantly reduces energy consumption compared to fixed-speed compressors that operate at a constant speed regardless of the demand. 5. Elimination of On/Off Cycling: Fixed-speed compressors often use on/off cycling to adjust the compressed air output. This cycling can result in frequent starts and stops, which consume more energy and cause mechanical wear. VSD compressors eliminate the need for on/off cycling by continuously adjusting the motor speed to meet the demand. By operating at a consistent speed within the required range, VSD compressors minimize energy losses associated with frequent cycling. 6. Enhanced System Control: VSD compressors offer advanced control capabilities, allowing for precise monitoring and adjustment of the compressed air system. These systems can integrate with sensors and control algorithms to maintain optimal system pressure, minimize pressure fluctuations, and prevent excessive energy consumption. The ability to fine-tune the compressor’s output based on real-time demand contributes to improved overall system efficiency. By utilizing variable speed drive technology, air compressors can achieve significant energy savings, reduce operational costs, and enhance their environmental sustainability by minimizing energy wastage and optimizing efficiency.
How do you troubleshoot common air compressor problems?Troubleshooting common air compressor problems can help identify and resolve issues that may affect the performance and functionality of the compressor. Here are some steps to troubleshoot common air compressor problems: 1. No Power:
2. Low Air Pressure:
3. Excessive Noise or Vibration:
4. Air Leaks:
5. Excessive Moisture in Compressed Air:
6. Motor Overheating:
If troubleshooting these common problems does not resolve the issue, it may be necessary to consult the manufacturer’s manual or seek assistance from a qualified technician. Regular maintenance, such as cleaning, lubrication, and inspection, can also help prevent common problems and ensure the optimal performance of the air compressor.
Can you explain the basics of air compressor terminology?Understanding the basic terminology related to air compressors can help in better comprehension of their operation and discussions related to them. Here are some essential terms related to air compressors: 1. CFM (Cubic Feet per Minute): CFM is a unit of measurement that denotes the volumetric flow rate of compressed air. It indicates the amount of air a compressor can deliver within a minute and is a crucial factor in determining the compressor’s capacity. 2. PSI (Pounds per Square Inch): PSI is a unit of measurement used to quantify pressure. It represents the force exerted by the compressed air on a specific area. PSI is a vital specification for understanding the pressure capabilities of an air compressor and determining its suitability for various applications. 3. Duty Cycle: Duty cycle refers to the percentage of time an air compressor can operate in a given time period. It indicates the compressor’s ability to handle continuous operation without overheating or experiencing performance issues. For instance, a compressor with a 50% duty cycle can run for half the time in a given hour or cycle. 4. Horsepower (HP): Horsepower is a unit used to measure the power output of a compressor motor. It indicates the motor’s capacity to drive the compressor pump and is often used as a reference for comparing different compressor models. 5. Receiver Tank: The receiver tank, also known as an air tank, is a storage vessel that holds the compressed air delivered by the compressor. It helps in stabilizing pressure fluctuations, allowing for a more consistent supply of compressed air during peak demand periods. 6. Single-Stage vs. Two-Stage: These terms refer to the number of compression stages in a reciprocating air compressor. In a single-stage compressor, air is compressed in a single stroke of the piston, while in a two-stage compressor, it undergoes initial compression in one stage and further compression in a second stage, resulting in higher pressures. 7. Oil-Free vs. Oil-Lubricated: These terms describe the lubrication method used in air compressors. Oil-free compressors have internal components that do not require oil lubrication, making them suitable for applications where oil contamination is a concern. Oil-lubricated compressors use oil for lubrication, enhancing durability and performance but requiring regular oil changes and maintenance. 8. Pressure Switch: A pressure switch is an electrical component that automatically starts and stops the compressor motor based on the pre-set pressure levels. It helps maintain the desired pressure range in the receiver tank and protects the compressor from over-pressurization. 9. Regulator: A regulator is a device used to control and adjust the output pressure of the compressed air. It allows users to set the desired pressure level for specific applications and ensures a consistent and safe supply of compressed air. These are some of the fundamental terms associated with air compressors. Familiarizing yourself with these terms will aid in understanding and effectively communicating about air compressors and their functionality.
China Custom Chinese Air Compressors Electricity Specification Air Compressor lowes air compressorProduct Description
Smart Choice for Air Solution Our products help customers to achieve sustainable productivity in a wide range of markets, With a CHINAMFG heart of the rotary screw air compressor, we make sure our products are running at maximum efficiency and minimum downtime at our customers’ sites. We developed our own special rotors, which provide energy savings of up to 15% compared to other conventional rotor designs. Our roller bearings guarantee that our airends live much longer than ever before. The capacity of rotary screw compressors are perfectly regulated by our inlet valves.
How are air compressors utilized in pharmaceutical manufacturing?Air compressors play a crucial role in pharmaceutical manufacturing, where they are utilized for various critical applications. The pharmaceutical industry requires a reliable source of clean and compressed air to ensure the safety, efficiency, and quality of its processes. Here’s an overview of how air compressors are utilized in pharmaceutical manufacturing: 1. Manufacturing Processes: Air compressors are used in numerous manufacturing processes within the pharmaceutical industry. Compressed air is employed for tasks such as mixing and blending of ingredients, granulation, tablet compression, coating, and encapsulation of pharmaceutical products. The controlled delivery of compressed air facilitates precise and consistent manufacturing processes, ensuring the production of high-quality pharmaceuticals. 2. Instrumentation and Control Systems: Pharmaceutical manufacturing facilities rely on compressed air for powering instrumentation and control systems. Compressed air is used to operate pneumatic valves, actuators, and control devices that regulate the flow of fluids, control temperature and pressure, and automate various processes. The clean and dry nature of compressed air makes it ideal for maintaining the integrity and accuracy of these critical control mechanisms. 3. Packaging and Filling: Air compressors are employed in pharmaceutical packaging and filling processes. Compressed air is used to power machinery and equipment for bottle cleaning, labeling, capping, and sealing of pharmaceutical products. Compressed air provides the necessary force and precision for efficient and reliable packaging, ensuring product safety and compliance. 4. Cleanroom Environments: Pharmaceutical manufacturing often takes place in controlled cleanroom environments to prevent contamination and maintain product quality. Air compressors are used to supply clean and filtered compressed air to these cleanrooms, ensuring a controlled and sterile environment for the production of pharmaceuticals. Compressed air is also utilized in cleanroom air showers and air curtains for personnel and material decontamination. 5. Laboratory Applications: In pharmaceutical laboratories, air compressors are utilized for various applications. Compressed air is used in laboratory instruments, such as gas chromatographs, mass spectrometers, and other analytical equipment. It is also employed in clean air cabinets, fume hoods, and laminar flow benches, providing a controlled and clean environment for testing, analysis, and research. 6. HVAC Systems: Air compressors are involved in heating, ventilation, and air conditioning (HVAC) systems in pharmaceutical manufacturing facilities. Compressed air powers the operation of HVAC controls, dampers, actuators, and air handling units, ensuring proper air circulation, temperature control, and environmental conditions in various manufacturing areas. By utilizing air compressors in pharmaceutical manufacturing, the industry can maintain strict quality standards, enhance operational efficiency, and ensure the safety and efficacy of pharmaceutical products.
Can air compressors be used for inflating tires and sporting equipment?Yes, air compressors can be used for inflating tires and sporting equipment, providing a convenient and efficient method for achieving the desired air pressure. Here’s how air compressors are used for these purposes: 1. Tire Inflation: Air compressors are commonly used for inflating vehicle tires, including car tires, motorcycle tires, bicycle tires, and even larger truck or trailer tires. Air compressors provide a continuous source of pressurized air, allowing for quick and accurate inflation. They are often used in automotive repair shops, gas stations, and by individuals who regularly need to inflate tires. 2. Sporting Equipment Inflation: Air compressors are also useful for inflating various types of sporting equipment. This includes inflatable balls such as soccer balls, basketballs, footballs, and volleyballs. Additionally, air compressors can be used to inflate inflatable water toys, air mattresses, inflatable kayaks, and other recreational items that require air for proper inflation. 3. Air Tools for Inflation: Air compressors can power air tools specifically designed for inflation purposes. These tools, known as inflators or air blow guns, provide controlled airflow for inflating tires and sporting equipment. They often have built-in pressure gauges and nozzles designed to fit different types of valves, making them versatile and suitable for various inflation tasks. 4. Adjustable Pressure: One advantage of using air compressors for inflation is the ability to adjust the pressure. Most air compressors allow users to set the desired pressure level using a pressure regulator or control knob. This feature ensures that tires and sporting equipment are inflated to the recommended pressure, promoting optimal performance and safety. 5. Efficiency and Speed: Air compressors provide a faster and more efficient inflation method compared to manual pumps. The continuous supply of compressed air allows for quick inflation, reducing the time and effort required to inflate tires and sporting equipment manually. 6. Portable Air Compressors: For inflating tires and sporting equipment on the go, portable air compressors are available. These compact and lightweight compressors can be easily carried in vehicles or taken to sports events and outdoor activities, ensuring convenient access to a reliable air supply. It is important to note that when using air compressors for inflating tires, it is recommended to follow manufacturer guidelines and proper inflation techniques to ensure safety and avoid overinflation.
What maintenance is required for air compressors?Maintaining air compressors is essential to ensure their optimal performance, longevity, and safe operation. Regular maintenance helps prevent breakdowns, improves efficiency, and reduces the risk of accidents. Here are some key maintenance tasks for air compressors: 1. Regular Inspection: Perform visual inspections of the air compressor to identify any signs of wear, damage, or leaks. Inspect the compressor, hoses, fittings, and connections for any abnormalities. Pay attention to oil leaks, loose bolts, and worn-out components. 2. Oil Changes: If your air compressor has an oil lubrication system, regular oil changes are crucial. Follow the manufacturer’s recommendations for the frequency of oil changes and use the recommended oil type. Dirty or degraded oil can impact compressor performance and lead to premature wear. 3. Air Filter Cleaning or Replacement: Clean or replace the air filter regularly to ensure proper air intake and prevent contaminants from entering the compressor. Clogged or dirty filters can restrict airflow and reduce efficiency. 4. Drain Moisture: Air compressors produce moisture as a byproduct of the compression process. Accumulated moisture in the tank can lead to rust and corrosion. Drain the moisture regularly from the tank to prevent damage. Some compressors have automatic drains, while others require manual draining. 5. Belt Inspection and Adjustment: If your compressor has a belt-driven system, inspect the belts for signs of wear, cracks, or tension issues. Adjust or replace the belts as necessary to maintain proper tension and power transmission. 6. Tank Inspection: Inspect the compressor tank for any signs of corrosion, dents, or structural issues. A damaged tank can be hazardous and should be repaired or replaced promptly. 7. Valve Maintenance: Check the safety valves, pressure relief valves, and other valves regularly to ensure they are functioning correctly. Test the valves periodically to verify their proper operation. 8. Motor and Electrical Components: Inspect the motor and electrical components for any signs of damage or overheating. Check electrical connections for tightness and ensure proper grounding. 9. Keep the Area Clean: Maintain a clean and debris-free area around the compressor. Remove any dirt, dust, or obstructions that can hinder the compressor’s performance or cause overheating. 10. Follow Manufacturer’s Guidelines: Always refer to the manufacturer’s manual for specific maintenance instructions and recommended service intervals for your air compressor model. They provide valuable information on maintenance tasks, lubrication requirements, and safety precautions. Regular maintenance is vital to keep your air compressor in optimal condition and extend its lifespan. It’s also important to note that maintenance requirements may vary depending on the type, size, and usage of the compressor. By following a comprehensive maintenance routine, you can ensure the reliable operation of your air compressor and maximize its efficiency and longevity.
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