Product Description
Compressor for Oxygen Concentrator Oxygen Gas Tank Filling
Product Introduction
This Compressor for Oxygen Concentrator high pressure is suitable for inlet pressure 3-4bar and discharge pressure 150-200bar.
The Compressor for Oxygen Concentrator flow rate of 15nm3-60nm3/hour of PSA air separation oxygen system provides clean oxygen filling service in clinic and hospitals. It can run continuously for 24 hours, and can reach more than 60 bottles per time. This is the feature of medical oil free high pressure Compressor for Oxygen Concentrator.
Structural Advantage
Compressor for Oxygen Concentrator adopts 4 stage compression, water/air cooling method and stainless steel water/air cooler to ensure the good cooling effect of the compressor, which can effectively extend the service life of key wearing parts. The inlet is equipped with low intake pressure and the exhaust end is equipped with exhaust. High pressure protection, high exhausts temperature protection, safety valve and temperature display for each stage. If over temperature and overpressure, the system will alarm and stop, ensuring safe operation. There is a forklift at the bottom of the compressor, which can be easily transferred.
All standard oil free high pressure Compressor for Oxygen Concentrator are CE marked to meet the requirements of the CHINAMFG market. We can also provide customized Compressor for Oxygen Concentrator according to customer conditions.
Technical Specification
| Model |
Capacity/ Flow Rate |
Inlet Pressure | Discharge Pressure | Power | Weight | Weight |
| GOW-3/4-150 | 3m³/h | 3-4bar | 150bar | 3KW | 140kg | 850*640*680mm |
| GOW-5/4-150 | 5m³/h | 3-4bar | 150bar | 3.5KW | 320kg | 1000*800*1100mm |
| GOW-10/4-150 | 10m³/h | 3-4bar | 150bar | 5KW | 320kg | 1000*800*1100mm |
| GOW-15/4-150 | 15m³/h | 3-4bar | 150bar | 11.5KW | 960kg | 1650*950*1470mm |
| GOW-20/4-150 | 20m³/h | 3-4bar | 150bar | 12KW | 960kg | 1650*950*1470mm |
| GOW-30/4-150 | 30m³/h | 3-4bar | 150bar | 13.5KW | 960kg | 1650*950*1470mm |
| GOW-40/4-150 | 40m³/h | 3-4bar | 150bar | 15KW | 960kg | 1650*950*1470mm |
| GOW-50/4-150 | 50m³/h | 3-4bar | 150bar | 17KW | 960kg | 1650*950*1470mm |
Technical Characteristics
| 1 | Completely 100% oil free, no oil required (depending on the specific model) |
| 2 | Cylinder is stainless steel |
| 3 | Oxygen for VPSA PSA and LOX gas source |
| 4 | Not any pollution, keep the same purity into the gas |
| 5 | High reliability and high quality |
| 6 | Low maintenance cost and simple operation |
| 7 | 4000 hours piston ring working life under low pressure conditions, 1500-2000 hours working life under high pressure conditions |
| 8 | TOP brand motor, can be specially pointed out, just like the SIMENSE brand |
| 9 | CE approved to meet the requirements of the EU market |
| 10 | According to the customer’s specific working conditions, the compressor is designed for 1 machine compression, 2 stage compression, 3 stage compression and 4 stage compression |
| 11 | Low speed, long life, average speed 260-350RPM |
| 12 | Low noise, average noise below 75dB, can work quietly in the medical field |
| 13 | Continuous heavy-duty operation can run stably for 24 hours without stopping |
| 14 | Each stage has an interstate safety valve. If the stage is over pressured, the safety valve will take off and release the overpressure gas to ensure the stable operation of the compressor |
| 15 | Each level has a temperature controller. If the temperature between the stages exceeds the standard, the temperature display will sound and light alarm |
Product Show
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| Usage: | Hydrogen, Nitrogen, Oxygen, Ozone |
|---|---|
| Purpose: | Gas Filling |
| Parts: | Valve |
| Application Fields: | Medical |
| Noise Level: | Low |
| Machine Size: | Medium |
| Samples: |
US$ 11550/Set
1 Set(Min.Order) | |
|---|
| Customization: |
Available
|
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|---|
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Can Gas Air Compressors Be Used in Cold Weather Conditions?
Gas air compressors are generally designed to operate in a wide range of environmental conditions, including cold weather. However, there are certain considerations and precautions to keep in mind when using gas air compressors in cold weather conditions. Here’s a detailed explanation:
1. Cold Start-Up:
In cold weather, starting a gas air compressor can be more challenging due to the low temperatures affecting the engine’s performance. It is important to follow the manufacturer’s recommendations for cold start procedures, which may include preheating the engine, using a cold weather starting aid, or ensuring the proper fuel mixture. These measures help facilitate smooth start-up and prevent potential damage to the engine.
2. Fuel Type:
Consider the type of fuel used in the gas air compressor. Some fuels, such as gasoline, can be more susceptible to cold weather issues like vapor lock or fuel line freezing. In extremely cold conditions, it may be necessary to use a fuel additive or switch to a fuel type that is better suited for cold weather operation, such as winter-grade gasoline or propane.
3. Lubrication:
Cold temperatures can affect the viscosity of the oil used in the compressor’s engine. It is important to use the recommended oil grade suitable for cold weather conditions. Thicker oil can become sluggish and impede proper lubrication, while oil that is too thin may not provide adequate protection. Consult the manufacturer’s guidelines for the appropriate oil viscosity range for cold weather operation.
4. Moisture Management:
In cold weather, moisture can condense more readily in the compressed air system. It is crucial to properly drain the moisture from the compressor tank and ensure the air lines are free from any accumulated moisture. Failure to manage moisture can lead to corrosion, freezing of air lines, and decreased performance.
5. Protection from Freezing:
In extremely cold conditions, it is important to protect the gas air compressor from freezing. This may involve using insulated covers or enclosures, providing heat sources in the compressor area, or storing the compressor in a temperature-controlled environment when not in use. Taking measures to prevent freezing helps maintain proper operation and prevents potential damage to the compressor components.
6. Monitoring Performance:
Regularly monitor the performance of the gas air compressor in cold weather conditions. Pay attention to any changes in operation, such as reduced air pressure, increased noise, or difficulties in starting. Promptly address any issues and consult the manufacturer or a qualified technician if necessary.
By considering these factors and taking appropriate precautions, gas air compressors can be effectively used in cold weather conditions. However, it is important to consult the specific guidelines provided by the manufacturer for your compressor model, as they may have additional recommendations or specifications for cold weather operation.
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What Is the Role of Air Receivers in Gas Air Compressor Systems?
Air receivers play a crucial role in gas air compressor systems by serving as storage tanks for compressed air. Here’s a detailed explanation:
1. Storage and Stabilization:
The primary function of an air receiver is to store compressed air generated by the gas air compressor. As the compressor produces compressed air, the air receiver collects and stores it. This storage capacity helps meet fluctuating demand in compressed air usage, providing a buffer between the compressor and the system’s air consumption.
By storing compressed air, the air receiver helps stabilize the supply to the system, reducing pressure fluctuations and ensuring a consistent and reliable flow of compressed air. This is particularly important in applications where the demand for compressed air may vary or experience peaks and valleys.
2. Pressure Regulation:
Another role of the air receiver is to assist in pressure regulation within the gas air compressor system. As compressed air enters the receiver, the pressure inside increases. When the pressure reaches a predetermined upper limit, typically set by a pressure switch or regulator, the compressor stops supplying air, and the excess air is stored in the receiver.
Conversely, when the pressure in the system drops below a certain lower limit, the pressure switch or regulator signals the compressor to start, replenishing the compressed air in the receiver and maintaining the desired pressure level. This cycling of the compressor based on pressure levels helps regulate and control the overall system pressure.
3. Condensate Separation:
During the compression process, moisture or condensate can form in the compressed air due to the cooling effect. The air receiver acts as a reservoir that allows the condensate to settle at the bottom, away from the outlet. The receiver often includes a drain valve at the bottom to facilitate the removal of accumulated condensate, preventing it from reaching downstream equipment and causing potential damage or performance issues.
4. Energy Efficiency:
Air receivers contribute to energy efficiency in gas air compressor systems. They help optimize the operation of the compressor by reducing the occurrence of short-cycling, which refers to frequent on-off cycling of the compressor due to rapid pressure changes. Short-cycling can cause excessive wear on the compressor and reduce its overall efficiency.
The presence of an air receiver allows the compressor to operate in longer and more efficient cycles. The compressor runs until the receiver reaches the upper pressure limit, ensuring a more stable and energy-efficient operation.
5. Air Quality Improvement:
Depending on the design, air receivers can also aid in improving air quality in the compressed air system. They provide a space for the compressed air to cool down, allowing moisture and some contaminants to condense and separate from the air. This can be further enhanced with the use of additional filtration and drying equipment installed downstream of the receiver.
In summary, air receivers play a vital role in gas air compressor systems by providing storage capacity, stabilizing compressed air supply, regulating system pressure, separating condensate, improving energy efficiency, and contributing to air quality control. They are an integral component in ensuring the reliable and efficient operation of compressed air systems across various industries and applications.
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How Do You Choose the Right Size Gas Air Compressor for Your Needs?
Choosing the right size gas air compressor is crucial to ensure optimal performance and efficiency for your specific needs. Selecting a compressor that is too small may result in insufficient airflow or pressure, while choosing one that is too large can lead to unnecessary energy consumption and higher costs. Here’s a detailed explanation of the factors to consider when choosing the right size gas air compressor:
1. Required Airflow:
Determine the airflow requirements of your applications. Consider the tools, equipment, or processes that will be powered by the compressor and their respective airflow demands. The required airflow is typically measured in cubic feet per minute (CFM). Determine the total CFM required, taking into account any simultaneous or intermittent tool usage.
2. Operating Pressure:
Identify the operating pressure required for your applications. Different tools and systems have specific pressure requirements, measured in pounds per square inch (PSI). Ensure that the compressor you choose can deliver the required pressure consistently.
3. Duty Cycle:
Consider the duty cycle, which refers to the amount of time the compressor will be in operation within a given period. Some applications may require continuous operation, while others involve intermittent or occasional use. Take into account the duty cycle to ensure that the compressor can handle the expected workload without overheating or experiencing excessive wear.
4. Tank Size:
The tank size of a gas air compressor determines its ability to store compressed air and provide a steady supply. A larger tank can help accommodate fluctuations in demand and reduce the frequency of the compressor cycling on and off. Consider the required storage capacity based on the specific applications and the desired balance between continuous operation and storage capacity.
5. Power Source:
Gas air compressors can be powered by different fuels, such as gasoline, diesel, natural gas, or propane. Consider the availability and cost of the fuel options in your location, as well as the specific requirements of your applications. Choose a compressor that is compatible with a power source that suits your needs.
6. Portability:
Determine if portability is a requirement for your applications. If you need to move the compressor to different job sites or locations, consider a portable model with features like wheels, handles, or a compact design that facilitates easy transportation.
7. Noise Level:
If noise is a concern in your working environment, consider the noise level of the compressor. Gas air compressors can vary in their noise output, and certain models may have noise-reducing features or insulation to minimize sound emissions.
8. Manufacturer Recommendations:
Consult the manufacturer’s recommendations and guidelines for selecting the appropriate compressor size for your specific needs. Manufacturers often provide guidelines based on the anticipated applications, airflow requirements, and other factors to help you make an informed decision.
By considering these factors and carefully assessing your specific requirements, you can choose the right size gas air compressor that meets your airflow, pressure, duty cycle, and other operational needs. It’s advisable to consult with industry professionals or compressor experts for guidance, especially for complex or specialized applications.
editor by CX 2024-05-14