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 |
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After-sales Service: | Video Technical Support, Online Support, Spare PAR |
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Warranty: | 1 Year |
Lubrication Style: | Lubricated |
Cooling System: | Air Cooling |
Power Source: | Diesel Engine |
Cylinder Position: | / |
Customization: |
Available
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Are there special considerations for air compressor installations in remote areas?
Yes, there are several special considerations to take into account when installing air compressors in remote areas. These areas often lack access to infrastructure and services readily available in urban or well-developed regions. Here are some key considerations:
1. Power Source:
Remote areas may have limited or unreliable access to electricity. It is crucial to assess the availability and reliability of the power source for operating the air compressor. In some cases, alternative power sources such as diesel generators or solar panels may need to be considered to ensure a consistent and uninterrupted power supply.
2. Environmental Conditions:
Remote areas can present harsh environmental conditions that can impact the performance and durability of air compressors. Extreme temperatures, high humidity, dust, and corrosive environments may require the selection of air compressors specifically designed to withstand these conditions. Adequate protection, insulation, and ventilation must be considered to prevent damage and ensure optimal operation.
3. Accessibility and Transport:
Transporting air compressors to remote areas may pose logistical challenges. The size, weight, and portability of the equipment should be evaluated to ensure it can be transported efficiently to the installation site. Additionally, the availability of suitable transportation infrastructure, such as roads or air transportation, needs to be considered to facilitate the delivery and installation process.
4. Maintenance and Service:
In remote areas, access to maintenance and service providers may be limited. It is important to consider the availability of trained technicians and spare parts for the specific air compressor model. Adequate planning for routine maintenance, repairs, and troubleshooting should be in place to minimize downtime and ensure the longevity of the equipment.
5. Fuel and Lubricants:
For air compressors that require fuel or lubricants, ensuring a consistent and reliable supply can be challenging in remote areas. It is necessary to assess the availability and accessibility of fuel or lubricant sources and plan for their storage and replenishment. In some cases, alternative or renewable fuel options may need to be considered.
6. Noise and Environmental Impact:
Remote areas are often characterized by their natural beauty and tranquility. Minimizing noise levels and environmental impact should be a consideration when installing air compressors. Selecting models with low noise emissions and implementing appropriate noise reduction measures can help mitigate disturbances to the surrounding environment and wildlife.
7. Communication and Remote Monitoring:
Given the remote location, establishing reliable communication channels and remote monitoring capabilities can be essential for effective operation and maintenance. Remote monitoring systems can provide real-time data on the performance and status of the air compressor, enabling proactive maintenance and troubleshooting.
By addressing these special considerations, air compressor installations in remote areas can be optimized for reliable operation, efficiency, and longevity.
What is the energy efficiency of modern air compressors?
The energy efficiency of modern air compressors has significantly improved due to advancements in technology and design. Here’s an in-depth look at the energy efficiency features and factors that contribute to the efficiency of modern air compressors:
Variable Speed Drive (VSD) Technology:
Many modern air compressors utilize Variable Speed Drive (VSD) technology, also known as Variable Frequency Drive (VFD). This technology allows the compressor motor to adjust its speed according to the compressed air demand. By matching the motor speed to the required airflow, VSD compressors can avoid excessive energy consumption during periods of low demand, resulting in significant energy savings compared to fixed-speed compressors.
Air Leakage Reduction:
Air leakage is a common issue in compressed air systems and can lead to substantial energy waste. Modern air compressors often feature improved sealing and advanced control systems to minimize air leaks. By reducing air leakage, the compressor can maintain optimal pressure levels more efficiently, resulting in energy savings.
Efficient Motor Design:
The motor of an air compressor plays a crucial role in its energy efficiency. Modern compressors incorporate high-efficiency electric motors that meet or exceed established energy efficiency standards. These motors are designed to minimize energy losses and operate more efficiently, reducing overall power consumption.
Optimized Control Systems:
Advanced control systems are integrated into modern air compressors to optimize their performance and energy consumption. These control systems monitor various parameters, such as air pressure, temperature, and airflow, and adjust compressor operation accordingly. By precisely controlling the compressor’s output to match the demand, these systems ensure efficient and energy-saving operation.
Air Storage and Distribution:
Efficient air storage and distribution systems are essential for minimizing energy losses in compressed air systems. Modern air compressors often include properly sized and insulated air storage tanks and well-designed piping systems that reduce pressure drops and minimize heat transfer. These measures help to maintain a consistent and efficient supply of compressed air throughout the system, reducing energy waste.
Energy Management and Monitoring:
Some modern air compressors feature energy management and monitoring systems that provide real-time data on energy consumption and performance. These systems allow operators to identify energy inefficiencies, optimize compressor settings, and implement energy-saving practices.
It’s important to note that the energy efficiency of an air compressor also depends on factors such as the specific model, size, and application. Manufacturers often provide energy efficiency ratings or specifications for their compressors, which can help in comparing different models and selecting the most efficient option for a particular application.
Overall, modern air compressors incorporate various energy-saving technologies and design elements to enhance their efficiency. Investing in an energy-efficient air compressor not only reduces operational costs but also contributes to sustainability efforts by minimizing energy consumption and reducing carbon emissions.
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 2024-02-03