Product Description
Company Profile
we have hydrogen production compressors, filling compressors, and hydrogen refueling station compressors to achieve full coverage of hydrogen energy compressors, one-stop supply and service. The displacement of a single hydrogen production compressor can reach 2000Nm3/min, the displacement of a single filling compressor can reach 2000Nm3/h, and the displacement of a single compressor at a hydrogen refueling station can reach 2000Nm3/h, fully covering compressors in the hydrogen energy industry need.
Product Description
Piston compressors are a type of positive displacement compressor that are commonly used in the chemical industry for a variety of applications. These compressors work by using a piston and cylinder to compress gas or air, which creates pressure and allows it to be transported through pipelines or used in other processes.
In the chemical industry, piston compressors are used for a variety of functions, including:
Gas compression – Piston compressors are used to compress natural gas, hydrogen, and other gases used in chemical processes.
Pneumatic conveying – Piston compressors are used to transport materials in a powdered or granular form through pipelines.
Refrigeration – Piston compressors are used in refrigeration systems to compress refrigerant gases, which are then used to cool industrial processes and equipment.
Process air compression – Piston compressors are used to compress air for use in chemical processes, such as in pneumatic equipment and air-powered tools.
Piston compressors are popular in the chemical industry because they are reliable, efficient, and can handle specific types of gases and air with ease. Additionally, they require minimal maintenance and can operate at high pressures, making them suitable for many applications
When choosing a piston compressor for use in the chemical industry, it is important to consider factors such as:
Type of gas or air being compressed – Different types of gases and air require different types of compression.
Required flow rate and pressure – The capacity and pressure capabilities of the compressor must meet the requirements of the application.
Environmental conditions – Factors such as temperature, humidity, and altitude can affect the performance of the compressor.
Maintenance requirements – The frequency and complexity of maintenance and servicing should be considered when selecting a compressor.
Overall, piston compressors are an important tool in the chemical industry, providing reliable and efficient compression for a variety of applications. Choosing the right compressor for the specific application is critical to ensuring optimal performance and efficiency.
Product Parameters
The machine is customized according to customer need, the specific price depends on the configuration requirements (gas composition, exhaust volume and pressure).quotation will be given according the specific parameters.
Hydrogen gas production compressor | |||||
parameter industry | hydrogen from natural gas | Hydrogen from coke oven gas | Chemical tail gas recovery | Fluorine alkali tail gas recovery | other |
Suction pressure MPa(G) | 0-0.5 | 0-0.2 | 0-1.0 | 0-0.1 | |
discharge pressureMPa(G) | 1.0-3.0 | 0.8-2.3 | 1.5-3.0 | 0.8-2.5 | |
capacity Nm3/min | 5-50 | 10-200 | 10-200 | 8-100 | |
Compression levels | 1-3 | 1-4 | 1-6 | 1-5 | 1-6 |
motor power(KW) | 30-2000 | ||||
skid mounted | skid mounted | ||||
Digital Analog Computing | yes | ||||
systolic algorithm | yes | ||||
Service Guarantee | Professional service team, 7X24 hours all day service |
Hydrogen filling compressor + hydrogen refueling station compressor | |||||
parameter industry | 45Mpahydrogen refueling station | 90Mpa hydrogen refueling station | Hydrogen tank truck | Hydrogen flushed into the bottle | High pressure hydrogen delivery |
Suction pressure MPa(G) | 3-20 | 10-30 | 0.8-3.0 | 0.1-30 | 0.8-3.0 |
discharge pressureMPa(G) | 45 | 90 | 20.0-22.20 | 15.0-20.0 | 5.2-20.0 |
capacity Nm3/min | 200-2000 | 100-1000 | 300-2000 | 10-800 | 100-1500 |
Compression levels | 1-2 | 1-2 | 1-3 | 1-2 | 1-2 |
motor power(KW) | 30-200 | 30-185 | 75-315 | 3-160 | 22-200 |
skid mounted | skid mounted | ||||
Digital Analog Computing | yes | ||||
Finite Element Analysis | yes | ||||
Service Guarantee | Professional service team, 7X24 hours all day service |
Detailed Photos
After-sales Service: | 12 Month |
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Warranty: | 12 Month |
Lubrication Style: | Oil-free |
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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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What Is the Noise Level of Gas Air Compressors?
The noise level of gas air compressors can vary depending on several factors, including the compressor’s design, engine type, operating conditions, and the presence of noise-reducing features. Here’s a detailed explanation:
1. Compressor Design:
The design of the gas air compressor can influence its noise level. Some compressors are engineered with noise reduction in mind, utilizing features such as sound insulation, vibration dampening materials, and mufflers to minimize noise generation. Compressors with enclosed cabinets or acoustic enclosures tend to have lower noise levels compared to open-frame compressors.
2. Engine Type:
The type of engine used in the gas air compressor can impact the noise level. Gas air compressors typically use internal combustion engines powered by gasoline or propane. Gasoline engines tend to produce higher noise levels compared to diesel engines or electric motors. However, advancements in engine technology have led to quieter gasoline engines with improved noise control.
3. Operating Conditions:
The operating conditions of the gas air compressor can affect the noise level. Factors such as the load capacity, speed of operation, and ambient temperature can influence the amount of noise generated. Compressors operating at higher loads or speeds may produce more noise compared to those running at lower levels.
4. Noise-Reducing Features:
Some gas air compressors are equipped with noise-reducing features to minimize sound emissions. These may include built-in silencers, acoustic enclosures, or noise-absorbing materials. Such features help dampen the noise produced by the compressor and reduce its overall noise level.
5. Manufacturer Specifications:
Manufacturers often provide noise level specifications for their gas air compressors. These specifications typically indicate the sound pressure level (SPL) in decibels (dB) at a specific distance from the compressor. It is important to refer to these specifications to get an idea of the expected noise level of a particular compressor model.
6. Distance and Location:
The distance between the gas air compressor and the listener can impact the perceived noise level. As sound waves disperse, the noise level decreases with distance. Locating the compressor in an area that is isolated or distant from occupied spaces can help minimize the impact of noise on the surrounding environment.
It is important to note that gas air compressors, especially those used in industrial or heavy-duty applications, can generate substantial noise levels. Occupational health and safety regulations may require the use of hearing protection for individuals working in close proximity to loud compressors.
Overall, the noise level of gas air compressors can vary, and it is advisable to consult the manufacturer’s specifications and consider noise-reducing features when selecting a compressor. Proper maintenance, such as regular lubrication and inspection of components, can also help minimize noise levels and ensure optimal performance.
What Are the Key Components of a Gas Air Compressor Control Panel?
A gas air compressor control panel typically consists of several key components. Here’s a detailed explanation:
1. Power Switch:
The power switch allows the operator to turn the compressor on or off. It is usually a toggle switch or a push-button switch located on the control panel.
2. Pressure Gauges:
Pressure gauges display the compressed air pressure at different stages of the compression process. Commonly, there are two pressure gauges: one to measure the incoming air pressure (suction pressure) and another to measure the outgoing compressed air pressure (discharge pressure).
3. Control Knobs or Buttons:
Control knobs or buttons are used to adjust and set various parameters of the compressor operation. These controls may include pressure settings, on/off timers, automatic start/stop functions, and other operational parameters specific to the compressor model.
4. Emergency Stop Button:
An emergency stop button is a critical safety feature that immediately shuts down the compressor in case of an emergency. Pressing the emergency stop button cuts off power to the compressor and stops its operation.
5. Motor Start/Stop Buttons:
Motor start and stop buttons allow the operator to manually start or stop the compressor motor. These buttons are used when manual control of the motor is required, such as during maintenance or troubleshooting.
6. Control Indicators:
Control indicators include various lights or LEDs that provide visual feedback about the compressor’s status and operation. These indicators may include power indicators, motor running indicators, pressure indicators, and fault indicators to signal any malfunctions or abnormal conditions.
7. Control Panel Display:
Some gas air compressors feature a control panel display that provides real-time information and feedback on the compressor’s performance. The display may show parameters such as operating pressure, temperature, maintenance alerts, fault codes, and other relevant information.
8. Start/Stop Control Circuit:
The start/stop control circuit is responsible for initiating and controlling the motor start and stop sequences. It typically includes relays, contactors, and other electrical components that enable the control panel to safely start and stop the compressor motor.
9. Safety and Protection Devices:
Gas air compressor control panels may incorporate safety and protection devices to safeguard the compressor and prevent potential damage or hazardous situations. These devices can include overload relays, thermal protection, pressure relief valves, and other safety features.
10. Control Panel Enclosure:
The control panel enclosure houses and protects the electrical components and wiring of the control panel. It provides insulation, protection from dust and moisture, and ensures the safety of the operator.
In summary, a gas air compressor control panel typically includes a power switch, pressure gauges, control knobs or buttons, emergency stop button, motor start/stop buttons, control indicators, control panel display (if applicable), start/stop control circuit, safety and protection devices, and a control panel enclosure. These components work together to monitor and control the compressor’s operation, ensure safety, and provide essential information to the operator.
How Does a Gas Air Compressor Work?
A gas air compressor works by utilizing a gas engine to power a compressor pump, which draws in air and compresses it to a higher pressure. The compressed air can then be used for various applications. Here’s a detailed explanation of how a gas air compressor operates:
1. Gas Engine:
A gas air compressor is equipped with a gas engine as its power source. The gas engine is typically fueled by gasoline, diesel, natural gas, or propane. When the engine is started, the fuel is combusted within the engine’s cylinders, generating mechanical energy in the form of rotational motion.
2. Compressor Pump:
The gas engine drives the compressor pump through a mechanical linkage, such as a belt or direct coupling. The compressor pump is responsible for drawing in atmospheric air and compressing it to a higher pressure. There are different types of compressor pumps used in gas air compressors, including reciprocating, rotary screw, or centrifugal, each with its own operating principles.
3. Intake Stroke:
In a reciprocating compressor pump, the intake stroke begins when the piston moves downward within the cylinder. This creates a vacuum, causing the inlet valve to open and atmospheric air to be drawn into the cylinder. In rotary screw or centrifugal compressors, air is continuously drawn in through the intake port as the compressor operates.
4. Compression Stroke:
During the compression stroke in a reciprocating compressor, the piston moves upward, reducing the volume within the cylinder. This compression action causes the air to be compressed and its pressure to increase. In rotary screw compressors, two interlocking screws rotate, trapping and compressing the air between them. In centrifugal compressors, air is accelerated and compressed by high-speed rotating impellers.
5. Discharge Stroke:
Once the air is compressed, the discharge stroke begins in reciprocating compressors. The piston moves upward, further reducing the volume and forcing the compressed air out of the cylinder through the discharge valve. In rotary screw compressors, the compressed air is discharged through an outlet port as the interlocking screws continue to rotate. In centrifugal compressors, the high-pressure air is discharged from the impeller into the surrounding volute casing.
6. Pressure Regulation:
Gas air compressors often include pressure regulation mechanisms to control the output pressure of the compressed air. This can be achieved through pressure switches, regulators, or control systems that adjust the compressor’s operation based on the desired pressure setting. These mechanisms help maintain a consistent and controlled supply of compressed air for the specific application requirements.
7. Storage and Application:
The compressed air produced by the gas air compressor is typically stored in a receiver tank or used directly for applications. The receiver tank helps stabilize the pressure and provides a reservoir of compressed air for immediate use. From the receiver tank, the compressed air can be distributed through pipelines to pneumatic tools, machinery, or other devices that require the compressed air for operation.
Overall, a gas air compressor operates by using a gas engine to power a compressor pump, which draws in air and compresses it to a higher pressure. The compressed air is then regulated and used for various applications, providing a reliable source of power for pneumatic tools, machinery, and other equipment.
editor by CX 2023-11-21