Product Description
High Pressure Electric/Diesel Air Booster/Air Compressor
Introductions:
Our products have complete varieties and specifications. From the compressor type, it is divided into mobile type, fixed type, vehicle-mounted type, skid-mounted type and so on. Compressed media include air, natural gas, liquefied petroleum gas, hydrogen, recycled gas, nitrogen, ammonia, propylene, biogas, coalbed methane, carbon dioxide, etc. From the cylinder lubrication method, it is divided into oil lubrication and oil-free lubrication. From the compression type, it is divided into reciprocating piston type and screw type. Products are widely used in metallurgical machinery manufacturing, urban construction, steel, national defense, coal, mining, geology, natural gas, petroleum, petrochemical, chemical, electric power, textile, biology, medicine, glass and other industries.
Main features:
1. The compressor is manufactured by air-cooling and water-cooling technology, with high reliability and long service life.
2. The compressor unit has a high degree of automation. The unit operation is controlled by a programmable controller PLC and is equipped with multiple protections.
3. Automatic shutdown protection, unloading restart, automatic drainage, and alarm for insufficient oil.
| Flow rate | ≤50 Nm³/min |
| Pressure | ≤40 MPa |
| Medium | air, nitrogen, carbon dioxide, natural gas |
| Control | PLC automatic control |
| Drive mode | electric motor, diesel engine |
| Cooling method | air cooling, water cooling, mixed cooling |
| Installation method | mobile type, fixed type, vehicle-mounted type, skid-mounted type |
Main Technical Parameters:
| NO. | Model | Rotating Speed (r/min) |
Intake Pressure (Mpa) |
Exhaust Pressure (Mpa) |
Exhaust Volume (Nm³/min) |
Dimension (L*W*H)mm | Drive Power/Shaft Power(KW) | Weight (T) | Remark |
| 1 | SF-10/150 | 1330 | Atmospheric Pressure | 15 | 10 | 5500*2000*2300 | 227/139 | 6 | Stationary Diesel Engine |
| 2 | SF-10/150 | 1330 | 15 | 10 | 7500*2300*2300 | 227/139 | 8 | Container Skid Mounted Diesel Engine | |
| 3 | SF-10/250 | 1330 | 25 | 10 | 5500*2000*2300 | 227/173 | 6 | Stationary Diesel Engine | |
| 4 | SF-10/250 | 1330 | 25 | 10 | 7500*2300*2300 | 227/173 | 8 | Container Skid Mounted Diesel Engine | |
| 5 | SF-10/250 | 1330 | 25 | 10 | 15710*2496*3900 | 227/173 | 21.98 | Vehicular | |
| 6 | WF-10/60 | 1000 | 6 | 10 | 6000*2200*2200 | 135/110 | 6 | Container Skid Mounted Diesel Engine | |
| 7 | W-10/350 | 980 | 35 | 10 | 15710*2496*3900 | 303/187 | 21.98 | Vehicular | |
| 8 | WF-0.9/3-120 | 980 | 0.3 | 12 | 0.9 | 5100*2000*2350 | 75/50 | 5.4 | Container Skid Mounted Diesel Engine |
| 9 | SF-1.2/24-150 | 1200 | 2.4 | 15 | 1.2 | 7500*2300*2415 | 303/195 | 8.6 | Container Skid Mounted Diesel Engine |
| 10 | W-0.86/17-350 | 1000 | 1.7 | 35 | 0.86 | 8500*2500*2300 | 277/151 | 12 | Container Skid Mounted Diesel Engine |
| 11 | W-1.25/11-350 | 980 | 1.1 | 35 | 1.25 | 8000*2500*2500 | 185/145.35 | 15 | Container Skidding Motor |
| 12 | LG.V-25/150 | Screw 2279 Piston 800 | Atmospheric Pressure | 15 | 25 | 7000*2420*2300 | 355 | 16 | Container Skidding Motor |
| Model | Flow | Pressure | Stages | Cooling Type | Rotating Speed | Power |
| m³/min | Mpa | r/min | ||||
| SVF-15/100 | 15 | 10 | 1+2 | Air Cooling | 1150 | Diesel series |
| SVF-18/100 | 18 | 10 | 1+2 | 1150 | ||
| SVF-20/120 | 20 | 12 | 1+2 | 1150 | ||
| LGW-15/100 | 15 | 10 | 1+2 | 1150 | ||
| LGW-15/150 | 15 | 15 | 1+3 | 1150 | ||
| LGW-15/200 | 15 | 20 | 1+3 | 1150 | ||
| LGW-20/100 | 20 | 10 | 1+2 | 1150 | ||
| LGW-20/150 | 20 | 15 | 1+2 | 1150 | ||
| LGS-24/150 | 24 | 15 | 1+2 | 1150 | ||
| LGS-30/150 | 30 | 15 | 1+2 | 1150 | ||
| LGW-25/150 | 25 | 15 | 1+2 | Water cooling | 980 | Electric tandem |
| LGV-25/250 | 25 | 25 | 1+3 | 740 | Diesel series | |
| LGW-12/275 | 12 | 27.5 | 1+3 | 980 | Electric tandem | |
| LGV-15/85 | 15 | 8.5 | 1+2 | 980 | ||
| LGV-15/250 | 15 | 25 | 1+3 | Air Cooling | 740 | |
| LGV-15/350 | 15 | 35 | 1+4 | Water cooling | 740 | |
| LGV-15/400 | 15 | 40 | 1+4 | 740 | ||
| LGV-12.5/400 | 12.5 | 40 | 1+4 | 740 | ||
| LGV-15/100 | 15 | 10 | 1+2 | 740 |
Application Industry:
1. Suitable for oilfield pressure test, line sweeping, gas lift, well drilling and other projects.
2. Used in air tightness testing, air tightness inspection, pressure test, strength inspection, air tightness verification and other fields of various high-pressure vessels or pressure vessels such as gas cylinders, steel cylinders, valves, pipelines, pressure meters, high-pressure boilers, etc. .
3. On-board pressure testing, pressurization, pipeline pressure testing, line sweeping, gas lift and other projects in oil exploration.
4. Sand blasting and rust removal, parts dust removal, high pressure phosphorus removal, anti-corrosion engineering, well drilling operations, mountain quarrying.
5. For hydropower station turbine control and high-voltage power grid air short-circuit device for arc extinguishing.
6. Provide air source for large and medium-sized bottle blowing machines.
How to Choose the Right Air Compressor
An air compressor uses pressurized air to power a variety of tools. They are most commonly used to power nailers and impact wrenches. Other popular uses for air compressors include paint sprayers and impact wrenches. While all air compressors have the same basic construction, their specialty differs. Ultimately, their differences come down to the amount of air they can push. Read on for information on each type of air compressor. These tools are great for many different purposes, and choosing the right air compressor depends on your specific needs.
Electric motor
While purchasing an electric motor for air compressor, compatibility is a key factor. Not all motors work with the same type of air compressor, so it’s important to check the manufacturer’s instructions before purchasing. By doing this, you can avoid wasting money on an incompatible motor. Another important consideration is speed. A motor’s speed is its rate of rotation, measured in revolutions per minute. It is critical that you purchase a motor with sufficient speed to meet the needs of your air compressor.
Typically, an electric motor for air compressor is 1.5 hp. It is ideal for use with medical equipment and metal-cutting machines. It also performs well under continuous operation and offers a high efficiency and energy-saving performance. Moreover, it features an attractive price, making it a good choice for a wide range of applications. If you are looking for a motor for an air compressor, look no further than a ZYS series.
A motor’s protection class indicates how the motor will operate. Protection classes are specified by the IEC 60034-5. These are stated with 2 digits and represent the protection against solid objects and water. For example, an IP23 rating means that the motor will be protected from solid objects, while IP54 means that it will protect from dust and water sprayed from all directions. It is vital to choose a motor with the correct protection class for your air compressor.
When choosing an electric motor, you should consider whether it’s compatible with the brand of air compressor. Some may be compatible, while others may require advanced electronics skills to repair. However, most air compressors are covered by warranty, so it’s important to check with the manufacturer if the warranty is still in effect before you spend a dime on a replacement. The motor should be replaced if it has failed to perform as designed.
Oil bath
Air compressors require proper lubrication to function efficiently. The piston must draw air with minimal friction. Depending on their design, air compressors can either be oil-lubricated or oil-free. The former uses oil to reduce piston friction, while the latter splashes it on the cylinder bearings and walls. Such air compressors are commonly known as oil-flooded air compressors. In order to keep their oil baths clean, they are recommended for use in locations with high dust levels.
Start/stop control
An air compressor can be controlled by a start/stop control. This type of control sends a signal to the main motor that activates the compressor when the demand for air falls below a preset limit. This control strategy is effective for smaller air compressors and can be useful for reducing energy costs. Start/stop control is most effective in applications where air pressure does not change frequently and where the compressor is not required to run continuously.
To troubleshoot this problem, you need to check the power supply of your compressor. To check the supply side, use a voltage monitor to determine if power is flowing to the compressor. Ensure that the power supply to the compressor is steady and stable at all times. If it fluctuates, the compressor may not start or stop as expected. If you cannot find the problem with the air compressor power supply, it may be time to replace it.
In addition to the start/stop control, you may want to purchase additional air receivers for your air compressor. These can increase the capacity of air stored and reduce the number of times it starts and stops. Another way to decrease the number of starts per hour is to add more air receivers. Then, you can adjust the control to match your requirements. You can also install a pressure gauge that monitors the compressor’s performance.
Start/stop control for air compressors can be complex, but the basic components are relatively easy to understand. One way to test them is to turn the compressor on or off. It is usually located on the exterior of the motor. If you’re unsure of the location of these components, check the capacitors and make sure that the air compressor is not running while you’re not using it. If it does, try to remove the capacitor.
Variable displacement control is another way to adjust the amount of air flowing into the compressor. By controlling the amount of air, the control can delay the use of additional compressors until more required air is available. In addition to this, the device can also monitor the energy used in the compressor. This control method can result in substantial energy savings. You can even save on the amount of electricity by using variable displacement control. It is essential for efficient compressed air systems.
Variable speed drive
A VFD, or variable frequency drive, is a type of electric motor that adjusts its speed to match the demand for air. It is an efficient way to reduce energy costs and improve system reliability. In fact, studies have shown that a 20% reduction in motor speed can save up to 50% of energy. In addition, a VFD can monitor additional variables such as compressor oil pressure and motor temperature. By eliminating manual checks, a VFD will improve the performance of the application and reduce operating costs.
In addition to reducing energy costs, variable-speed drives also increase productivity. A variable-speed air compressor reduces the risk of system leaks by 30 percent. It also reduces the risk of system leaks by reducing pressure in the system. Because of these advantages, many governments are promoting this technology in their industries. Many even offer incentives to help companies upgrade to variable-speed drives. Therefore, the variable-speed drive can benefit many air compressor installations.
One major benefit of a variable-speed drive is its ability to optimize energy use. Variable frequency drives are able to ramp up and down to match the demand for air. The goal is to optimize the pressure and flow in the system so that the best “dead band” occurs between 40 percent and 80 percent of full load. A variable-speed compressor will also increase energy efficiency because of its programmability.
A variable-speed air compressor can also be used to control the amount of air that is compressed by the system. This feature adjusts the frequency of power supplied to the motor based on the demand. If the demand for air is low, the frequency of the motor will reduce to save energy. On the other hand, if there is an excess demand for air, the variable-speed compressor will increase its speed. In addition, this type of air compressor is more efficient than its fixed-speed counterpart.
A VFD has many benefits for compressed air systems. First, it helps stabilize the pressure in the pipe network, thereby reducing the power losses due to upstream pressure. It also helps reduce the power consumption caused by fluctuations in upward pressure. Its benefits are also far-reaching. And as long as the air pressure and air supply is properly sized, a VFD will help optimize the efficiency of compressed air systems.
