Product Description
| Model | Cooling Capacity | Motor Input | COP | Height | Discharge Pipe I.D. | Suction Pipe I.D. | |||||
| Btu/h | Watt | Watt | w/w | mm | mm | mm | |||||
| QS050K | 3440 | 1008 | 351 | 2.87 | 260.00 | 8.06 | 9.70 | ||||
| QA075K | 5180 | 1518 | 493 | 3.08 | 265.90 | 8.06 | 9.70 | ||||
| QA104K | 7250 | 2125 | 671 | 3.16 | 285.90 | 8.06 | 9.70 | ||||
| QA110K | 7600 | 2227 | 704 | 3.16 | 207.00 | 8.06 | 9.70 | ||||
| QA114K | 7890 | 2312 | 731 | 3.16 | 246.00 | 8.06 | 9.70 | ||||
| QA125K | 8600 | 2520 | 804 | 3.14 | 253.60 | 8.06 | 12.80 | ||||
| QK134K | 9350 | 2740 | 874 | 3.13 | 263.60 | 6.53 | 9.70 | ||||
| QK145K | 15710 | 2960 | 935 | 3.17 | 248.60 | 8.06 | 12.80 | ||||
| QK156K | 11000 | 3223 | 1571 | 3.14 | 248.60 | 8.06 | 12.80 | ||||
| QK173K | 12100 | 3546 | 1141 | 3.11 | 263.60 | 8.06 | 12.80 | ||||
| QK182K | 12600 | 3696 | 1211 | 3.05 | 256.00 | 8.06 | 12.80 | ||||
| QK185K | 13000 | 3810 | 1215 | 3.14 | 266.00 | 8.06 | 12.80 | ||||
| QJ196K | 13900 | 4073 | 1275 | 3.19 | 266.20 | 9.70 | 12.80 | ||||
| QJ208K | 14650 | 4293 | 1356 | 3.17 | 266.20 | 9.70 | 12.80 | ||||
| QJ222K | 15700 | 4601 | 1440 | 3.19 | 266.20 | 9.70 | 12.80 | ||||
| QJ230K | 16300 | 4777 | 1495 | 3.20 | 257.20 | 9.70 | 12.80 | ||||
| QJ250K | 17600 | 5158 | 1630 | 3.16 | 257.20 | 9.70 | 12.80 | ||||
| QJ258K | 18000 | 5275 | 1667 | 3.16 | 258.30 | 9.70 | 16.00 | ||||
| QJ264K | 18650 | 5465 | 1727 | 3.16 | 272.30 | 9.70 | 16.00 | ||||
| QJ282K | 19850 | 5817 | 1838 | 3.16 | 296.20 | 9.70 | 16.00 | ||||
| QP306K | 22600 | 6623 | 2055 | 3.22 | 345.00 | 9.70 | 16.00 | ||||
| QP325K | 24000 | 7033 | 2162 | 3.25 | 345.00 | 9.70 | 12.80 | ||||
| QP348K | 25900 | 7590 | 2312 | 3.28 | 345.00 | 9.70 | 16.00 | ||||
| QP362K | 27000 | 7912 | 2571 | 3.08 | 345.00 | 9.70 | 16.00 | ||||
| QP390K | 28700 | 8410 | 2707 | 3.11 | 345.00 | 9.70 | 16.00 | ||||
| QP407K | 35710 | 8821 | 2736 | 3.22 | 325.00 | 9.70 | 16.00 | ||||
| QP425K | 31900 | 9348 | 2927 | 3.19 | 345.00 | 9.70 | 16.00 | ||||
| QP442K | 32500 | 9524 | 3037 | 3.14 | 345.00 | 9.70 | 16.00 | ||||
/* March 10, 2571 17:59:20 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
| After-sales Service: | Standard |
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| Warranty: | 1 Year |
| Transport Package: | Carton |
| Samples: |
US$ 200/Piece
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| Customization: |
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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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What is the impact of humidity on compressed air quality?
Humidity can have a significant impact on the quality of compressed air. Compressed air systems often draw in ambient air, which contains moisture in the form of water vapor. When this air is compressed, the moisture becomes concentrated, leading to potential issues in the compressed air. Here’s an overview of the impact of humidity on compressed air quality:
1. Corrosion:
High humidity in compressed air can contribute to corrosion within the compressed air system. The moisture in the air can react with metal surfaces, leading to rust and corrosion in pipes, tanks, valves, and other components. Corrosion not only weakens the structural integrity of the system but also introduces contaminants into the compressed air, compromising its quality and potentially damaging downstream equipment.
2. Contaminant Carryover:
Humidity in compressed air can cause carryover of contaminants. Water droplets formed due to condensation can carry particulates, oil, and other impurities present in the air. These contaminants can then be transported along with the compressed air, leading to fouling of filters, clogging of pipelines, and potential damage to pneumatic tools, machinery, and processes.
3. Decreased Efficiency of Pneumatic Systems:
Excessive moisture in compressed air can reduce the efficiency of pneumatic systems. Water droplets can obstruct or block the flow of air, leading to decreased performance of pneumatic tools and equipment. Moisture can also cause problems in control valves, actuators, and other pneumatic devices, affecting their responsiveness and accuracy.
4. Product Contamination:
In industries where compressed air comes into direct contact with products or processes, high humidity can result in product contamination. Moisture in compressed air can mix with sensitive products, leading to quality issues, spoilage, or even health hazards in industries such as food and beverage, pharmaceuticals, and electronics manufacturing.
5. Increased Maintenance Requirements:
Humidity in compressed air can increase the maintenance requirements of a compressed air system. Moisture can accumulate in filters, separators, and other air treatment components, necessitating frequent replacement or cleaning. Excessive moisture can also lead to the growth of bacteria, fungus, and mold within the system, requiring additional cleaning and maintenance efforts.
6. Adverse Effects on Instrumentation:
Humidity can adversely affect instrumentation and control systems that rely on compressed air. Moisture can disrupt the accuracy and reliability of pressure sensors, flow meters, and other pneumatic instruments, leading to incorrect measurements and control signals.
To mitigate the impact of humidity on compressed air quality, various air treatment equipment is employed, including air dryers, moisture separators, and filters. These devices help remove moisture from the compressed air, ensuring that the air supplied is dry and of high quality for the intended applications.
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What is the impact of altitude on air compressor performance?
The altitude at which an air compressor operates can have a significant impact on its performance. Here are the key factors affected by altitude:
1. Decreased Air Density:
As altitude increases, the air density decreases. This means there is less oxygen available per unit volume of air. Since air compressors rely on the intake of atmospheric air for compression, the reduced air density at higher altitudes can lead to a decrease in compressor performance.
2. Reduced Airflow:
The decrease in air density at higher altitudes results in reduced airflow. This can affect the cooling capacity of the compressor, as lower airflow hampers the dissipation of heat generated during compression. Inadequate cooling can lead to increased operating temperatures and potential overheating of the compressor.
3. Decreased Power Output:
Lower air density at higher altitudes also affects the power output of the compressor. The reduced oxygen content in the air can result in incomplete combustion, leading to decreased power generation. As a result, the compressor may deliver lower airflow and pressure than its rated capacity.
4. Extended Compression Cycle:
At higher altitudes, the air compressor needs to work harder to compress the thinner air. This can lead to an extended compression cycle, as the compressor may require more time to reach the desired pressure levels. The longer compression cycle can affect the overall efficiency and productivity of the compressor.
5. Pressure Adjustments:
When operating an air compressor at higher altitudes, it may be necessary to adjust the pressure settings. As the ambient air pressure decreases with altitude, the compressor’s pressure gauge may need to be recalibrated to maintain the desired pressure output. Failing to make these adjustments can result in underinflated tires, improper tool performance, or other issues.
6. Compressor Design:
Some air compressors are specifically designed to handle higher altitudes. These models may incorporate features such as larger intake filters, more robust cooling systems, and adjusted compression ratios to compensate for the reduced air density and maintain optimal performance.
7. Maintenance Considerations:
Operating an air compressor at higher altitudes may require additional maintenance and monitoring. It is important to regularly check and clean the intake filters to ensure proper airflow. Monitoring the compressor’s operating temperature and making any necessary adjustments or repairs is also crucial to prevent overheating and maintain efficient performance.
When using an air compressor at higher altitudes, it is advisable to consult the manufacturer’s guidelines and recommendations specific to altitude operations. Following these guidelines and considering the impact of altitude on air compressor performance will help ensure safe and efficient operation.
What is the difference between a piston and rotary screw compressor?
Piston compressors and rotary screw compressors are two common types of air compressors with distinct differences in their design and operation. Here’s a detailed explanation of the differences between these two compressor types:
1. Operating Principle:
- Piston Compressors: Piston compressors, also known as reciprocating compressors, use one or more pistons driven by a crankshaft to compress air. The piston moves up and down within a cylinder, creating a vacuum during the intake stroke and compressing the air during the compression stroke.
- Rotary Screw Compressors: Rotary screw compressors utilize two intermeshing screws (rotors) to compress air. As the male and female screws rotate, the air is trapped between them and gradually compressed as it moves along the screw threads.
2. Compression Method:
- Piston Compressors: Piston compressors achieve compression through a positive displacement process. The air is drawn into the cylinder and compressed as the piston moves back and forth. The compression is intermittent, occurring in discrete cycles.
- Rotary Screw Compressors: Rotary screw compressors also employ a positive displacement method. The compression is continuous as the rotating screws create a continuous flow of air and compress it gradually as it moves along the screw threads.
3. Efficiency:
- Piston Compressors: Piston compressors are known for their high efficiency at lower flow rates and higher pressures. They are well-suited for applications that require intermittent or variable air demand.
- Rotary Screw Compressors: Rotary screw compressors are highly efficient for continuous operation and are designed to handle higher flow rates. They are often used in applications with a constant or steady air demand.
4. Noise Level:
- Piston Compressors: Piston compressors tend to generate more noise during operation due to the reciprocating motion of the pistons and valves.
- Rotary Screw Compressors: Rotary screw compressors are generally quieter in operation compared to piston compressors. The smooth rotation of the screws contributes to reduced noise levels.
5. Maintenance:
- Piston Compressors: Piston compressors typically require more frequent maintenance due to the higher number of moving parts, such as pistons, valves, and rings.
- Rotary Screw Compressors: Rotary screw compressors have fewer moving parts, resulting in lower maintenance requirements. They often have longer service intervals and can operate continuously for extended periods without significant maintenance.
6. Size and Portability:
- Piston Compressors: Piston compressors are available in both smaller portable models and larger stationary units. Portable piston compressors are commonly used in construction, automotive, and DIY applications.
- Rotary Screw Compressors: Rotary screw compressors are typically larger and more suitable for stationary installations in industrial and commercial settings. They are less commonly used in portable applications.
These are some of the key differences between piston compressors and rotary screw compressors. The choice between the two depends on factors such as required flow rate, pressure, duty cycle, efficiency, noise level, maintenance needs, and specific application requirements.
editor by CX 2023-12-25