Product Description
Portable Diesel Motor Screw Air Compressor
KaiShan Brand (reliable quality)
Cummins Diesel Motor (easy maintainence on spare parts)
0.8~2.3 Mpa (suitable for most working conditions)
10~30 m³/min (large working capacity)
2/4 rubber tire (portable)
Two-Stage High Air Pressure Models (LGCY series)
| Model | Air Pressure | Air Delivery | Diesel Motor Power | Output Ball Valve | Weight | Overall Size |
| Mpa | m³/min | HP | kg | MM | ||
| LGCY-15/16TK | 1.6 | 15 | CUMMINS 180HP | G1 1/2x1, G3/4x1 | 2400 | 3100x1520x2200 |
| LGCY-15/18-17/14TKL (two wheels) | 1.8-1.4 | 15-17 | CUMMINS 210HP | G2x1, G3/4x1 | 2200 | 3520x1980x2250 |
| LGCY-17/17TK | 1.7 | 17 | CUMMINS 210HP | G2x1, G3/4x1 | 3200 | 3000x1520x2200 |
| LGCY-17/18-18/15TK | 1.8-1.5 | 17-18 | CUMMINS 210HP | G2x1, G3/4x1 | 2200 | 3000x1520x2300 |
| LGCY-19/20-20/17KL (two wheels) | 2.0-1.7 | 19-20 | CUMMINS 260HP | G2x1, G3/4x1 | 3400 | 3700x2100x2395 |
| LGCY-25/8TK | 0.8 | 25 | CUMMINS 260HP | G2x1, G3/4x1 | 3000 | 3600x1600x2500 |
| LGCY-19/21-21/18K | 2.1-1.8 | 19-21 | CUMMINS 260HP | G2x1, G3/4x1 | 3600 | 3300x1700x2420 |
| LGCY-23/23-25/18K | 2.3-1.8 | 23-25 | CUMMINS 360HP | G2x1, G3/4x1 | 4850 | 4150x1950x2850 |
| LGCY-25/23-27/18K | 2.3-1.8 | 25-27 | CUMMINS 360HP | G2x1, G3/4x1 | 4850 | 4150x1950x2850 |
| LGCY-31/25K | 2.5 | 31 | CUMMINS 550HP | G2x1, G3/4x1 | 5100 | 3750x1950x2870 |
| LGCY-33/25K | 2.5 | 33 | CUMMINS 550HP | G2x1, G3/4x1 | 6800 | 4700x2160x2650 |
Single-Stage Low Air Pressure Models (LGCY series)
| Model | Air Pressure | Air Delivery | Diesel Motor Power | Output Ball Valve | Weight | Overall Size |
| Mpa | m³/min | HP | kg | MM | ||
| LGCY-12.5/14L (two wheels) | 1.4 | 12.5 | CUMMINS 180HP | G2x1, G3/4x1 | 2100 | 3520x1980x2256 |
| LGCY-14/14L (two wheels) | 1.4 | 14 | CUMMINS 210HP | G2x1, G3/4x1 | 2400 | 3520x1980x2356 |
| LGCY-18/17K | 1.7 | 18 | CUMMINS 260HP | G2x1, G3/4x1 | 3400 | 3980x1800x2450 |
| LGCY-22/8K | 0.8 | 22 | CUMMINS 260HP | G2x1, G3/4x1 | 4000 | 3764x1800x2213 |
| LGCY-27/10K | 1 | 27 | CUMMINS 360HP | G2x1, G3/4x1 | 5000 | 4600x1950x2850 |
| LGCY-32/10K | 1 | 32 | CUMMINS 360HP | G2x1, G3/4x1 | 5000 | 4600x1950x2850 |
High Air Pressure Models (KSCY series)
| Model | Air Pressure | Air Delivery | Diesel Motor Power | Output Ball Valve | Weight | Overall Size |
| Mpa | m³/min | HP | kg | MM | ||
| KSCY-570/12-550/15K | 1.2-1.5 | 16-15 | CUMMINS 180HP | G1 1/2x1, G3/4x1 | 2000 | 3500x1880x2100 |
| KSCY-550/14.5K | 1.45 | 15 | CUMMINS 180HP | G1 1/2x1, G3/4x1 | 2400 | 3000x1520x2200 |
| KSCY-560/15K | 1.5 | 16 | CUMMINS 210HP | G2x1, G3/4x1 | 2400 | 3000x1520x2200 |
| KSCY-650/20-700/17TK | 2.0-1.7 | 18-19 | CUMMINS 260HP | G2x1, G3/4x1 | 2700 | 3000x1520x2390 |
| Lubrication Style: | Lubricated |
|---|---|
| Cooling System: | Air Cooling |
| Power Source: | Diesel Engine |
| Cylinder Position: | Vertical |
| Structure Type: | Closed Type |
| Installation Type: | Movable Type |
| Customization: |
Available
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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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How do you maintain proper air quality in compressed air systems?
Maintaining proper air quality in compressed air systems is essential to ensure the reliability and performance of pneumatic equipment and the safety of downstream processes. Here are some key steps to maintain air quality:
1. Air Filtration:
Install appropriate air filters in the compressed air system to remove contaminants such as dust, dirt, oil, and water. Filters are typically placed at various points in the system, including the compressor intake, aftercoolers, and before point-of-use applications. Regularly inspect and replace filters to ensure their effectiveness.
2. Moisture Control:
Excessive moisture in compressed air can cause corrosion, equipment malfunction, and compromised product quality. Use moisture separators or dryers to remove moisture from the compressed air. Refrigerated dryers, desiccant dryers, or membrane dryers are commonly employed to achieve the desired level of dryness.
3. Oil Removal:
If the compressed air system utilizes oil-lubricated compressors, it is essential to incorporate proper oil removal mechanisms. This can include coalescing filters or adsorption filters to remove oil aerosols and vapors from the air. Oil-free compressors eliminate the need for oil removal.
4. Regular Maintenance:
Perform routine maintenance on the compressed air system, including inspections, cleaning, and servicing of equipment. This helps identify and address any potential issues that may affect air quality, such as leaks, clogged filters, or malfunctioning dryers.
5. Air Receiver Tank Maintenance:
Regularly drain and clean the air receiver tank to remove accumulated contaminants, including water and debris. Proper maintenance of the tank helps prevent contamination from being introduced into the compressed air system.
6. Air Quality Testing:
Periodically test the quality of the compressed air using appropriate instruments and methods. This can include measuring particle concentration, oil content, dew point, and microbial contamination. Air quality testing provides valuable information about the effectiveness of the filtration and drying processes and helps ensure compliance with industry standards.
7. Education and Training:
Educate personnel working with compressed air systems about the importance of air quality and the proper procedures for maintaining it. Provide training on the use and maintenance of filtration and drying equipment, as well as awareness of potential contaminants and their impact on downstream processes.
8. Documentation and Record-Keeping:
Maintain accurate records of maintenance activities, including filter replacements, drying system performance, and air quality test results. Documentation helps track the system’s performance over time and provides a reference for troubleshooting or compliance purposes.
By implementing these practices, compressed air systems can maintain proper air quality, minimize equipment damage, and ensure the integrity of processes that rely on compressed air.
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Can you explain the basics of air compressor terminology?
Understanding the basic terminology related to air compressors can help in better comprehension of their operation and discussions related to them. Here are some essential terms related to air compressors:
1. CFM (Cubic Feet per Minute): CFM is a unit of measurement that denotes the volumetric flow rate of compressed air. It indicates the amount of air a compressor can deliver within a minute and is a crucial factor in determining the compressor’s capacity.
2. PSI (Pounds per Square Inch): PSI is a unit of measurement used to quantify pressure. It represents the force exerted by the compressed air on a specific area. PSI is a vital specification for understanding the pressure capabilities of an air compressor and determining its suitability for various applications.
3. Duty Cycle: Duty cycle refers to the percentage of time an air compressor can operate in a given time period. It indicates the compressor’s ability to handle continuous operation without overheating or experiencing performance issues. For instance, a compressor with a 50% duty cycle can run for half the time in a given hour or cycle.
4. Horsepower (HP): Horsepower is a unit used to measure the power output of a compressor motor. It indicates the motor’s capacity to drive the compressor pump and is often used as a reference for comparing different compressor models.
5. Receiver Tank: The receiver tank, also known as an air tank, is a storage vessel that holds the compressed air delivered by the compressor. It helps in stabilizing pressure fluctuations, allowing for a more consistent supply of compressed air during peak demand periods.
6. Single-Stage vs. Two-Stage: These terms refer to the number of compression stages in a reciprocating air compressor. In a single-stage compressor, air is compressed in a single stroke of the piston, while in a two-stage compressor, it undergoes initial compression in one stage and further compression in a second stage, resulting in higher pressures.
7. Oil-Free vs. Oil-Lubricated: These terms describe the lubrication method used in air compressors. Oil-free compressors have internal components that do not require oil lubrication, making them suitable for applications where oil contamination is a concern. Oil-lubricated compressors use oil for lubrication, enhancing durability and performance but requiring regular oil changes and maintenance.
8. Pressure Switch: A pressure switch is an electrical component that automatically starts and stops the compressor motor based on the pre-set pressure levels. It helps maintain the desired pressure range in the receiver tank and protects the compressor from over-pressurization.
9. Regulator: A regulator is a device used to control and adjust the output pressure of the compressed air. It allows users to set the desired pressure level for specific applications and ensures a consistent and safe supply of compressed air.
These are some of the fundamental terms associated with air compressors. Familiarizing yourself with these terms will aid in understanding and effectively communicating about air compressors and their functionality.
editor by CX 2023-11-20