Product Description
| Model Name | LUY050-7 | LUY085-14 | LUY100-10 | LUY100-12 | LUY118-7 | LUY120-14 | LUY130-13 | LUY150-15 | LUY160-17 | LUY235-9 | LUY220-10 |
| Working pressure, bar(psi) | 7 (100) | 14 (205) | 10 (150) | 12 (175) | 7 (100) | 14 (205) | 13(190) | 15 (220) | 17 (250) | 8.6 (125) | 10 (150) |
| Flow, l/s|cfm|m3/min | 83|177|5 | 142|300|8.5 | 167|353|10 | 167|353|10 | 197|420|11.8 | 200|424|12 | 217|460|13 | 250|530|15 | 267|565|16 | 396|830|23.5 | 367|780|22 |
| Noise sound level (at 7m distance, dBA ) | 70±3 | 79±3 | 79±3 | 79±3 | 79±3 | 83±3 | 83±3 | 83±3 | 83±3 | 79±3 | 79±3 |
| Fuel tank capacity, l | 67 | 185 | 120 | 120 | 120 | 180 | 180 | 250 | 250 | 300 | 300 |
| Compressor oil capacity, l | 8 | 25 | 26 | 26 | 26 | 23 | 30 | 32 | 32 | 55 | 55 |
| Outlet valves, qty x size | 3xG3/4 | 3xG3/4 1xG1 1/2 | 3xG3/4 1xG1 1/3 | 3xG3/4 1xG1 1/4 | 3xG3/4 1xG1 1/5 | 1*G2 1*G3/4 | 1*G2 1*G3/4 | 1*G2 1*G3/4 | 1*G2 1*G3/4 | 1*G2 1*G3/4 | 1*G2 1*G3/4 |
| Engine exhuast emission | Tier 3 | Tier 3 | Tier 3 | Tier 3 | Tier 2 | Tier 2 | |||||
| Engine maker | Kubota | Cummins | Cummins | Cummins | Cummins | Yuchai | Cummins | Yuchai | Yuchai | Cummins | Cummins |
| Engine model | V1505T | 4BTAA3.9-C125 | YC4A130-H311 | YC4A130-H311 | YC4A130-H311 | YC6J175-H301 | QSB5.9-C180-31 | YC6A205-H300 | YC6A240-H301 | 6CTA8.3-C260 | 6CTA8.3-C260 |
| Engine power, Kw | 33 | 93 | 96 | 96 | 96 | 129 | 132 | 151 | 176 | 194 | 194 |
| Norminal engine speed, rpm | 2950 | 2300 | 2300 | 2300 | 2300 | 2300 | 2400 | 2050 | 1950 | 2000 | 2000 |
| Unloading engine speed, rpm | 1950 | 1500 | 1400 | 1400 | 1400 | 1400 | 1400 | 1200 | 1200 | 1500 | 1500 |
| Engine inspiration | torbue charger | torbue charger | torbue charger | torbue charger | torbue charger | torbue | torbue | torbue | torbue | torbue | torbue |
| Length, mm | 2960 | 3700 | 3700 | 3700 | 3700 | 4322 | 3000 | 4322 | 4322 | 3780 | 3780 |
| Width, mm | 1350 | 1790 | 1790 | 1790 | 1790 | 1950 | 2000 | 1950 | 1950 | 1950 | 1950 |
| Height, mm | 1420 | 1900 | 1900 | 1900 | 1900 | 1980 | 2190 | 1980 | 1980 | 2260 | 2260 |
| Weight, kg | 750 | 1650 | 1650 | 1650 | 1650 | 2250 | 1990 | 2550 | 2550 | 2990 | 2990 |
| Model Name | LUY200-10 | LUY170-17 | LUY180-19 | LUY180-20 | LUY210-17 | LUY230-14 | LUY250-12 | LUY270-10 | LUY290-9 | LUY215-21 | LUY290-23 |
| Working pressure, bar(psi) | 10(150) | 17(250) | 19 (275) | 20(290) | 17 (250) | 14 (205) | 12(175) | 10(150) | 8.6(125) | 21(305) | 23(335) |
| Flow, l/s|cfm|m3/min | 336|706|20 | 286|600|17 | 300|635|18 | 300|635|18 | 350|745|21 | 386|815|23 | 417|885|25 | 450|955|27 | 486|1571|29 | 357|760|21.5 | 486|1571|29 |
| Noise sound level (at 7m distance, dBA ) | 79±3 | 79±3 | 83±3 | 83±3 | 83±3 | 79±3 | 79±3 | 79±3 | 79±3 | 79±3 | 83±3 |
| Fuel tank capacity, l | 300 | 300 | 300 | 325 | 300 | 470 | 470 | 470 | 470 | 512 | 500 |
| Compressor oil capacity, l | 55 | 55 | 55 | 60 | 55 | 65 | 65 | 65 | 65 | 75 | 75 |
| Outlet valves, qty x size | 1*G2 1*G3/4 | 1*G2 1*G3/4 | 1*G2 1*G3/4 | 1*G2 1*G3/4 | 1*G2 1*G3/4 | 1*G2 1*G3/4 | 1*G2 1*G3/4 | 1*G2 1*G3/4 | 1*G2 1*G3/4 | 1*G2 1*G3/4 | 1*G2 1*G3/4 |
| Engine exhuast emission | Tier 2 | Tier 2 | Tier 3 | Tier 3 | Tier 3 | Tier 3 | Tier 3 | Tier 3 | Tier 3 | Tier 3 | Tier 3 |
| Engine maker | Cummins | Cummins | Yuchai | Cummins | Yuchai | Cummins | Cummins | Cummins | Cummins | Cummins | Yuchai |
| Engine model | 6CTA8.3-C260 | 6CTA8.3-C260 | YC6A260-H300 | QSB6.7-C260-32 | YC6A260-H300 | QSL8.9-C325-30 | QSL8.9-C325-30 | QSL8.9-C325-30 | QSL8.9-C325-30 | QSL8.9-C325-30 | YC6MK340-H300 |
| Engine power, Kw | 194 | 194 | 191 | 191 | 191 | 242 | 242 | 242 | 242 | 242 | 250 |
| Norminal engine speed, rpm | 2000 | 2000 | 1900 | 2000 | 1900 | 2000 | 2000 | 2000 | 2000 | 2000 | 1900 |
| Unloading engine speed, rpm | 1500 | 1500 | 1200 | 1300 | 1200 | 1300 | 1300 | 1300 | 1300 | 1300 | 1300 |
| Engine inspiration | torbue | torbue | torbue | torbue | torbue | torbue | torbue | torbue | charger | torbue charger torbue charger | torbue |
| Length, mm | 3780 | 3780 | 4404 | 4550 | 4404 | 5260 | 5260 | 5260 | 5260 | 5260 | 3850 |
| Width, mm | 1950 | 1950 | 1950 | 1770 | 1950 | 1800 | 1800 | 1800 | 1800 | 2040 | 2100 |
| Height, mm | 2260 | 2260 | 2296 | 2230 | 2270 | 2630 | 2630 | 2630 | 2630 | 2630 | 2690 |
| Weight, kg | 2990 | 2990 | 3330 | 3920 | 3330 | 4835 | 4835 | 4835 | 4835 | 4850 | 4100 |
/* 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: | Video Technical Support, Online Support, Spare PAR |
|---|---|
| Warranty: | 1 Year |
| Lubrication Style: | Lubricated |
| Cooling System: | Air Cooling |
| Power Source: | Diesel Engine |
| Cylinder Position: | / |
| Customization: |
Available
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Can air compressors be used for shipbuilding and maritime applications?
Air compressors are widely used in shipbuilding and maritime applications for a variety of tasks and operations. The maritime industry relies on compressed air for numerous essential functions. Here’s an overview of how air compressors are employed in shipbuilding and maritime applications:
1. Pneumatic Tools and Equipment:
Air compressors are extensively used to power pneumatic tools and equipment in shipbuilding and maritime operations. Pneumatic tools such as impact wrenches, drills, grinders, sanders, and chipping hammers require compressed air to function. The versatility and power provided by compressed air make it an ideal energy source for heavy-duty tasks, maintenance, and construction activities in shipyards and onboard vessels.
2. Painting and Surface Preparation:
Air compressors play a crucial role in painting and surface preparation during shipbuilding and maintenance. Compressed air is used to power air spray guns, sandblasting equipment, and other surface preparation tools. Compressed air provides the force necessary for efficient and uniform application of paints, coatings, and protective finishes, ensuring the durability and aesthetics of ship surfaces.
3. Pneumatic Actuation and Controls:
Air compressors are employed in pneumatic actuation and control systems onboard ships. Compressed air is used to operate pneumatic valves, actuators, and control devices that regulate the flow of fluids, control propulsion systems, and manage various shipboard processes. Pneumatic control systems offer reliability and safety advantages in maritime applications.
4. Air Start Systems:
In large marine engines, air compressors are used in air start systems. Compressed air is utilized to initiate the combustion process in the engine cylinders. The compressed air is injected into the cylinders to turn the engine’s crankshaft, enabling the ignition of fuel and starting the engine. Air start systems are commonly found in ship propulsion systems and power generation plants onboard vessels.
5. Pneumatic Conveying and Material Handling:
In shipbuilding and maritime operations, compressed air is used for pneumatic conveying and material handling. Compressed air is utilized to transport bulk materials, such as cement, sand, and grain, through pipelines or hoses. Pneumatic conveying systems enable efficient and controlled transfer of materials, facilitating construction, cargo loading, and unloading processes.
6. Air Conditioning and Ventilation:
Air compressors are involved in air conditioning and ventilation systems onboard ships. Compressed air powers air conditioning units, ventilation fans, and blowers, ensuring proper air circulation, cooling, and temperature control in various ship compartments, cabins, and machinery spaces. Compressed air-driven systems contribute to the comfort, safety, and operational efficiency of maritime environments.
These are just a few examples of how air compressors are utilized in shipbuilding and maritime applications. Compressed air’s versatility, reliability, and convenience make it an indispensable energy source for various tasks and systems in the maritime industry.
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Can air compressors be integrated into automated systems?
Yes, air compressors can be integrated into automated systems, providing a reliable and versatile source of compressed air for various applications. Here’s a detailed explanation of how air compressors can be integrated into automated systems:
Pneumatic Automation:
Air compressors are commonly used in pneumatic automation systems, where compressed air is utilized to power and control automated machinery and equipment. Pneumatic systems rely on the controlled release of compressed air to generate linear or rotational motion, actuating valves, cylinders, and other pneumatic components. By integrating an air compressor into the system, a continuous supply of compressed air is available to power the automation process.
Control and Regulation:
In automated systems, air compressors are often connected to a control and regulation system to manage the compressed air supply. This system includes components such as pressure regulators, valves, and sensors to monitor and adjust the air pressure, flow, and distribution. The control system ensures that the air compressor operates within the desired parameters and provides the appropriate amount of compressed air to different parts of the automated system as needed.
Sequential Operations:
Integration of air compressors into automated systems enables sequential operations to be carried out efficiently. Compressed air can be used to control the timing and sequencing of different pneumatic components, ensuring that the automated system performs tasks in the desired order and with precise timing. This is particularly useful in manufacturing and assembly processes where precise coordination of pneumatic actuators is required.
Energy Efficiency:
Air compressors can contribute to energy-efficient automation systems. By incorporating energy-saving features such as Variable Speed Drive (VSD) technology, air compressors can adjust their power output according to the demand, reducing energy consumption during periods of low activity. Additionally, efficient control and regulation systems help optimize the use of compressed air, minimizing waste and improving overall energy efficiency.
Monitoring and Diagnostics:
Integration of air compressors into automated systems often includes monitoring and diagnostic capabilities. Sensors and monitoring devices can be installed to collect data on parameters such as air pressure, temperature, and system performance. This information can be used for real-time monitoring, preventive maintenance, and troubleshooting, ensuring the reliable operation of the automated system.
When integrating air compressors into automated systems, it is crucial to consider factors such as the specific requirements of the automation process, the desired air pressure and volume, and the compatibility of the compressor with the control and regulation system. Consulting with experts in automation and compressed air systems can help in designing an efficient and reliable integration.
In summary, air compressors can be seamlessly integrated into automated systems, providing the necessary compressed air to power and control pneumatic components, enabling sequential operations, and contributing to energy-efficient automation processes.
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What is the role of air compressor tanks?
Air compressor tanks, also known as receiver tanks or air receivers, play a crucial role in the operation of air compressor systems. They serve several important functions:
1. Storage and Pressure Regulation: The primary role of an air compressor tank is to store compressed air. As the compressor pumps air into the tank, it accumulates and pressurizes the air. The tank acts as a reservoir, allowing the compressor to operate intermittently while providing a steady supply of compressed air during periods of high demand. It helps regulate and stabilize the pressure in the system, reducing pressure fluctuations and ensuring a consistent supply of air.
2. Condensation and Moisture Separation: Compressed air contains moisture, which can condense as the air cools down inside the tank. Air compressor tanks are equipped with moisture separators or drain valves to collect and remove this condensed moisture. The tank provides a space for the moisture to settle, allowing it to be drained out periodically. This helps prevent moisture-related issues such as corrosion, contamination, and damage to downstream equipment.
3. Heat Dissipation: During compression, air temperature increases. The air compressor tank provides a larger surface area for the compressed air to cool down and dissipate heat. This helps prevent overheating of the compressor and ensures efficient operation.
4. Pressure Surge Mitigation: Air compressor tanks act as buffers to absorb pressure surges or pulsations that may occur during compressor operation. These surges can be caused by variations in demand, sudden changes in airflow, or the cyclic nature of reciprocating compressors. The tank absorbs these pressure fluctuations, reducing stress on the compressor and other components, and providing a more stable and consistent supply of compressed air.
5. Energy Efficiency: Air compressor tanks contribute to energy efficiency by reducing the need for the compressor to run continuously. The compressor can fill the tank during periods of low demand and then shut off when the desired pressure is reached. This allows the compressor to operate in shorter cycles, reducing energy consumption and minimizing wear and tear on the compressor motor.
6. Emergency Air Supply: In the event of a power outage or compressor failure, the stored compressed air in the tank can serve as an emergency air supply. This can provide temporary air for critical operations, allowing time for maintenance or repairs to be carried out without disrupting the overall workflow.
Overall, air compressor tanks provide storage, pressure regulation, moisture separation, heat dissipation, pressure surge mitigation, energy efficiency, and emergency backup capabilities. They are vital components that enhance the performance, reliability, and longevity of air compressor systems in various industrial, commercial, and personal applications.
editor by CX 2024-01-15