Product Description
TROGY-220A 160KW 220HP 0.7Mpa-0.8Mpa portable air compressor bare
Product Description
Product Parameters
| Model | TROGY-220A | ||
| Power(KW) | 160 | ||
| Horse Power(HP) | 220 | ||
| Capacity & Pressure(m3/min)(Mpa) | 21.0/0.7 | ||
| 20.0/0.8 | |||
| / | |||
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| Rotary Speed(rpm) | 2200 | ||
| Logon Mode | Diesel Engine,Direct Starting | ||
| Voltage(v) | 24V | ||
| Supply Air Temperature | ≤80ºC | ||
| Cooling Type | Air cooling compressor,water cooling diesel | ||
| Diesel Engine |
CUMMINS 6CTA8.3-C215 |
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Dimension (mm) with wheels |
Length | With tow-bar | 5100 |
| Without two-bar | 3800 | ||
| Width | 1800 | ||
| Height | 2250 | ||
| Air Outlet Dia. | 3-3/4″,1-2″ | ||
| Weight(kg) | 3700 | ||
| Model | Capacity & Pressure (m3/min)(Mpa) | Power (KW) | Horse Power (HP) | Diesel Engine |
| TROGY-50A | 3.3/0.7,3.15/0.8,3.0/0.85,2.85/1.0 | 40KW | 50HP | ISUZU4JB1 |
| TROGY-50AH | 4.6/0.7,4.5/0.8,4.4/0.85,4.2/1.0 | 40KW | 50HP | ISUZU4JB1 |
| TROGY-67A | 3.5/0.7,3.15/0.8,3.0/0.85,2.85/1.0 | 50KW | 67HP | DEUTZ F4L912G140 |
| TROGY-67AH | 5.1/0.7,5/0.8,4.6/0.85,4.2/1.0 | 50KW | 67HP | DEUTZ F4L912G140A |
| TROGY-85A | 6.6/0.7,6.2/0.8,5.8/0.85,5.3/1.0 | 62KW | 85HP | ISUZU4JB1T |
| TROGY-102A | 7.0/0.7,6.6/0.8,6.3/0.85,6.0/1.0 | 75KW | 102HP | CUMMINS 4BT3.9-C100 |
| TROGY-105A | 9.0/0.7,8.5/0.8,8.4/0.85,8.0/1.0 | 77KW | 105HP | CUMMINS 4BT3.9-C105 |
| TROGY-145A | 12.0/0.7,11.2/0.8 | 110KW | 145HP | CUMMINS 6BT5.9-C150 |
| TROGY-145AH | 11.0/0.85,10.5/1.0 | 110KW | 145HP | CUMMINS 6BT5.9-C170 |
| TROGY-220A | 21.0/0.7,20.0/0.8 | 160KW | 220HP | CUMMINS 6CTA8.3-C215 |
| TROGY-220AH | 19.0/0.85,18.0/1.0 | 160KW | 220HP | CUMMINS 6CTA8.3-C215 |
| TROGY-325A | 33.8/0.7,32.0/0.8,30.0/0.85,28.8/1.0 | 240KW | 325HP | CUMMINS 6CTA8.9-C325 |
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| Lubrication Style: | Lubricated |
|---|---|
| Cooling System: | Water Cooling |
| Power Source: | Diesel Engine |
| Structure Type: | Closed Type |
| Installation Type: | Movable Type |
| Type: | Single Screw Compressor |
| Samples: |
US$ 38000/Piece
1 Piece(Min.Order) | |
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| Customization: |
Available
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What are the energy-saving technologies available for air compressors?
There are several energy-saving technologies available for air compressors that help improve their efficiency and reduce energy consumption. These technologies aim to optimize the operation of air compressors and minimize energy losses. Here are some common energy-saving technologies used:
1. Variable Speed Drive (VSD) Compressors:
VSD compressors are designed to adjust the motor speed according to the compressed air demand. By varying the motor speed, these compressors can match the output to the actual air requirement, resulting in energy savings. VSD compressors are particularly effective in applications with varying air demands, as they can operate at lower speeds during periods of lower demand, reducing energy consumption.
2. Energy-Efficient Motors:
The use of energy-efficient motors in air compressors can contribute to energy savings. High-efficiency motors, such as those with premium efficiency ratings, are designed to minimize energy losses and operate more efficiently than standard motors. By using energy-efficient motors, air compressors can reduce energy consumption and achieve higher overall system efficiency.
3. Heat Recovery Systems:
Air compressors generate a significant amount of heat during operation. Heat recovery systems capture and utilize this wasted heat for other purposes, such as space heating, water heating, or preheating process air or water. By recovering and utilizing the heat, air compressors can provide additional energy savings and improve overall system efficiency.
4. Air Receiver Tanks:
Air receiver tanks are used to store compressed air and provide a buffer during periods of fluctuating demand. By using appropriately sized air receiver tanks, the compressed air system can operate more efficiently. The tanks help reduce the number of starts and stops of the air compressor, allowing it to run at full load for longer periods, which is more energy-efficient than frequent cycling.
5. System Control and Automation:
Implementing advanced control and automation systems can optimize the operation of air compressors. These systems monitor and adjust the compressed air system based on demand, ensuring that only the required amount of air is produced. By maintaining optimal system pressure, minimizing leaks, and reducing unnecessary air production, control and automation systems help achieve energy savings.
6. Leak Detection and Repair:
Air leaks in compressed air systems can lead to significant energy losses. Regular leak detection and repair programs help identify and fix air leaks promptly. By minimizing air leakage, the demand on the air compressor is reduced, resulting in energy savings. Utilizing ultrasonic leak detection devices can help locate and repair leaks more efficiently.
7. System Optimization and Maintenance:
Proper system optimization and routine maintenance are essential for energy savings in air compressors. This includes regular cleaning and replacement of air filters, optimizing air pressure settings, ensuring proper lubrication, and conducting preventive maintenance to keep the system running at peak efficiency.
By implementing these energy-saving technologies and practices, air compressor systems can achieve significant energy efficiency improvements, reduce operational costs, and minimize environmental impact.
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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:
- Check the power source and ensure the compressor is properly plugged in.
- Inspect the circuit breaker or fuse box to ensure it hasn’t tripped or blown.
- Verify that the compressor’s power switch or control panel is turned on.
2. Low Air Pressure:
- Check the air pressure gauge on the compressor. If the pressure is below the desired level, the compressor might not be building up enough pressure.
- Inspect for air leaks in the system. Leaks can cause a drop in pressure. Listen for hissing sounds or use a soapy water solution to identify the location of leaks.
- Ensure the compressor’s intake filter is clean and not clogged, as this can restrict airflow and reduce pressure.
3. Excessive Noise or Vibration:
- Inspect the compressor’s mounting and foundation to ensure it is secure and stable. Loose mounts can cause excessive noise and vibration.
- Check for loose or damaged components, such as belts, pulleys, or motor mounts. Tighten or replace as necessary.
- Verify that the compressor’s cooling system, such as the fan or fins, is clean and free from obstructions. Overheating can lead to increased noise and vibration.
4. Air Leaks:
- Inspect all connections, valves, fittings, and hoses for leaks. Tighten or replace any loose or damaged components.
- Apply a soapy water solution to suspected areas and look for bubbles. Bubbles indicate air leaks.
- Consider using thread sealant or Teflon tape on threaded connections to ensure a proper seal.
5. Excessive Moisture in Compressed Air:
- Check the compressor’s drain valve and ensure it is functioning properly. Open the valve to release any accumulated moisture.
- Inspect and clean the compressor’s moisture separator or air dryer, if equipped.
- Consider installing additional filtration or drying equipment to remove moisture from the compressed air system.
6. Motor Overheating:
- Ensure the compressor’s cooling system is clean and unobstructed.
- Check the motor’s air intake vents and clean any dust or debris that may be blocking airflow.
- Verify that the compressor is not being operated in an excessively hot environment.
- Check the motor’s lubrication levels and ensure they are within the manufacturer’s recommended range.
- Consider using a thermal overload protector to prevent the motor from 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.
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What is the impact of tank size on air compressor performance?
The tank size of an air compressor plays a significant role in its performance and functionality. Here are the key impacts of tank size:
1. Air Storage Capacity: The primary function of the air compressor tank is to store compressed air. A larger tank size allows for greater air storage capacity. This means the compressor can build up a reserve of compressed air, which can be useful for applications that require intermittent or fluctuating air demand. Having a larger tank ensures a steady supply of compressed air during peak usage periods.
2. Run Time: The tank size affects the run time of the air compressor. A larger tank can provide longer continuous operation before the compressor motor needs to restart. This is because the compressed air in the tank can be used to meet the demand without the need for the compressor to run continuously. It reduces the frequency of motor cycling, which can improve energy efficiency and prolong the motor’s lifespan.
3. Pressure Stability: A larger tank helps maintain stable pressure during usage. When the compressor is running, it fills the tank until it reaches a specified pressure level, known as the cut-out pressure. As the air is consumed from the tank, the pressure drops to a certain level, known as the cut-in pressure, at which point the compressor restarts to refill the tank. A larger tank size results in a slower pressure drop during usage, ensuring more consistent and stable pressure for the connected tools or equipment.
4. Duty Cycle: The duty cycle refers to the amount of time an air compressor can operate within a given time period. A larger tank size can increase the duty cycle of the compressor. The compressor can run for longer periods before reaching its duty cycle limit, reducing the risk of overheating and improving overall performance.
5. Tool Compatibility: The tank size can also impact the compatibility with certain tools or equipment. Some tools, such as high-demand pneumatic tools or spray guns, require a continuous and adequate supply of compressed air. A larger tank size ensures that the compressor can meet the air demands of such tools without causing pressure drops or affecting performance.
It is important to note that while a larger tank size offers advantages in terms of air storage and performance, it also results in a larger and heavier compressor unit. Consider the intended application, available space, and portability requirements when selecting an air compressor with the appropriate tank size.
Ultimately, the optimal tank size for an air compressor depends on the specific needs of the user and the intended application. Assess the air requirements, duty cycle, and desired performance to determine the most suitable tank size for your air compressor.
editor by CX 2024-03-11