Product Description
R22 50HZ | SPEC. | |||||
Model | Power(HP) | Displacement(m³/h) | ARI | Weight(KG) | Height(MM) (Including shock-absorbing strap) | |
Capacity(W) | Input Power(W) | |||||
One-Phase(220V-240V) | ||||||
ZR28K3-PFJ | 2.33 | 6.83 | 6900 | 2520 | 26 | 383 |
ZR34K3-PFJ | 2.83 | 8.02 | 8200 | 2540 | 29 | 406 |
ZR34KH-PFJ | 2.83 | 8.02 | 8200 | 2540 | 29 | 406 |
ZR36K3-PFJ | 3 | 8.61 | 8900 | 2730 | 29 | 406 |
ZR36KH-PFJ | 3 | 8.61 | 8900 | 2730 | 29 | 406 |
ZR42K3-PFJ | 3.5 | 9.94 | 15710 | 3140 | 30 | 419 |
ZR47K3-PFJ | 3.92 | 11.02 | 11550 | 3460 | 32 | 436 |
Three-Phase(380V-420V) | ||||||
ZR28K3-TFD | 2.33 | 6.83 | 6900 | 2140 | 25 | 383 |
ZR34K3-TFD | 2.83 | 8.02 | 8200 | 2500 | 28 | 406 |
ZR34KH-TFD | 2.83 | 8.02 | 8200 | 2470 | 28 | 406 |
ZR36K3-TFD | 3 | 8.61 | 8790 | 2680 | 29 | 406 |
ZR36KH-TFD | 3 | 8.61 | 8300 | 2680 | 28 | 406 |
ZR42K3-TFD | 3.5 | 9.94 | 15710 | 3100 | 28 | 419 |
ZR47KC-TFD | 3.92 | 11.16 | 11550 | 2430 | 30 | 436 |
VR61KF-TFP-542 | 5.08 | 14.37 | 14900 | 4636 | 28.5 | 436 |
ZR61KC-TFD | 5.08 | 14.37 | 14600 | 4430 | 37 | 457 |
ZR61KH-TFD | 5.08 | 14.37 | 14972 | 4440 | 35.9 | 457 |
ZR68KC-TFD | 5.57 | 16.18 | 16900 | 4950 | 39 | 457 |
ZR72KC-TFD | 6 | 17.06 | 17700 | 5200 | 39 | 457 |
ZR81KC-TFD | 6.75 | 19.24 | 19900 | 5800 | 40 | 462 |
VR94KS-TFP | 8 | 22.14 | 23300 | 6750 | 57 | 497 |
VR108KS-TFP | 9 | 25.68 | 26400 | 7500 | 63 | 552 |
VR125KS-TFP | 10 | 28.81 | 31000 | 9000 | 63 | 552 |
VR144KS-TFP | 12 | 33.22 | 35000 | 15710 | 63 | 552 |
VR160KS-TFP | 13 | 36.37 | 38400 | 11400 | 65 | 572 |
VR190KS-TFP | 15 | 43.34 | 46300 | 13700 | 66 | 572 |
ZR250KC-TWD | 20 | 56.57 | 60000 | 17700 | 142 | 736 |
ZR310KC-TWD | 25 | 71.43 | 74000 | 22000 | 160 | 725 |
ZR380KC-TWD | 30 | 57.5 | 92000 | 26900 | 176 | 725 |
ZR81KC-TFD | 6.75 | 19.24 | 19900 | 5800 | 40 | 462 |
VR94KS-TFP | 8 | 22.14 | 23300 | 6750 | 57 | 497 |
VR108KS-TFP | 9 | 25.68 | 26400 | 7500 | 63 | 552 |
VR125KS-TFP | 10 | 28.81 | 31000 | 9000 | 63 | 552 |
VR144KS-TFP | 12 | 33.22 | 35000 | 15710 | 63 | 552 |
VR160KS-TFP | 13 | 36.37 | 38400 | 11400 | 65 | 572 |
VR190KS-TFP | 15 | 43.34 | 46300 | 13700 | 66 | 572 |
ZR250KC-TWD | 20 | 56.57 | 60000 | 17700 | 142 | 736 |
ZR310KC-TWD | 25 | 71.43 | 74000 | 22000 | 160 | 725 |
ZR380KC-TWD | 30 | 57.5 | 92000 | 26900 | 176 | 725 |
TECHNICAL DATA | |||||||
Model | ZB15KQ | ZB19KQ | ZB21KQ | ZB26KQ | ZB29KQ | ZB38KQ | ZB45KQ |
ZB15KQE | ZB19KQE | ZB21KQE | ZB26KQE | ZB29KQE | ZB38KQE | ZB45KQE | |
Motor Type | TFD | TFD | TFD | TFD | TFD | TFD | TFD |
PFJ | PFJ | PFJ | PFJ | PFJ | |||
Power(HP) | 2 | 2.5 | 3 | 3.5 | 4 | 5 | 6 |
Displacement(m³/h) | 5.92 | 6.8 | 8.6 | 9.9 | 11.4 | 14.5 | 17.2 |
Starting Current(LRA) | |||||||
TFD | 24.5-26 | 30-32 | 36-40 | 41-46 | 50 | 58.6-65.5 | 67-74 |
PFJ | 53-58 | 56-61 | 75-82 | 89-97 | 113 | ||
Rated Load Current(RLA) | |||||||
TFD | 4.3 | 4.3 | 5.7 | 7.1 | 7.9 | 8.9 | 11.5 |
PFJ | 11.4 | 12.9 | 16.4 | 18.9 | 19.3 | ||
Max. Operating Current(MCC) | |||||||
TFD | 6 | 6 | 8 | 10 | 11 | 12.5 | 16.1 |
PFJ | 16 | 18 | 23 | 24 | 27 | ||
Motor Run | 40μF/370V | 40μF/370V | 55μF/370V | 60μF/370V | 60μF/370V | ||
Crankcase Heater Power(W) | 70 | 70 | 70 | 70 | 70 | 70 | 70 |
Size of Connecting Pipe(INCH) | |||||||
Outer Diameter of Wxhaust Pipe | 1/2 | 1/2 | 1/2 | 1/2 | 1/2 | 1/2 | 1/2 |
Outer Diameter of Suction Pipe | 3/4 | 3/4 | 3/4 | 3/4 | 7/8 | 7/8 | 7/8 |
Dimensions(MM) | |||||||
Length | 242 | 242 | 243 | 243 | 242 | 242 | 242 |
Width | 242 | 242 | 244 | 244 | 242 | 242 | 242 |
Height | 383 | 383 | 412 | 425 | 430 | 457 | 457 |
Foot Bottom Installation Dimensions(Aperture) | 190X190(8.5) | 190X190(8.5) | 190X190(8.5) | 190X190(8.5) | 190X190(8.5) | 190X190(8.5) | 190X190(8.5) |
Fuel Injection(L) | 1.18 | 1.45 | 1.45 | 1.45 | 1.89 | 1.89 | 1.89 |
Weight(KG) | |||||||
Net.W | 23 | 25 | 27 | 28 | 37 | 38 | 40 |
Gross.W | 26 | 29 | 30 | 31 | 40 | 41 | 44 |
TECHNICAL DATA | |||||||
Model | ZB48KQ | ZB58KQ | ZB66KQ | ZB76KQ | ZB88KQ | ZB95KQ | ZB114KQ |
ZB48KQE | ZB58KQE | ZB66KQE | ZB76KQE | ||||
Motor Type | TFD | TFD | TFD | TFD | TFD | TFD | TFD |
Power(HP) | 7 | 8 | 9 | 10 | 12 | 13 | 15 |
Displacement(m³/h) | 18.8 | 22.1 | 25.7 | 28.8 | 38.2 | 36.4 | 43.4 |
Starting Current(LRA) | 101 | 86-95 | 100-111 | 110-118 | 110-118 | 140 | 174 |
Rated Load Current(RLA) | 12.1 | 16.4 | 17.3 | 19.2 | 22.1 | 22.1 | 27.1 |
Max. Operating Current(MCC) | 17 | 23 | 24.2 | 26.9 | 31 | 31 | 39 |
Crankcase Heater Power(W) | 70 | 90 | 90 | 90 | 90 | ||
Size of Connecting Pipe(INCH) | |||||||
Outer Diameter of Wxhaust Pipe | 3/4 | 7/8 | 7/8 | 7/8 | 7/8 | 7/8 | 7/8 |
Outer Diameter of Suction Pipe | 7/8 | 11/8 | 13/8 | 13/8 | 13/8 | 13/8 | 13/8 |
Dimensions(MM) | |||||||
Length | 242 | 263.6 | 263.6 | 263.6 | 263.6 | 242 | 264 |
Width | 242 | 284.2 | 284.2 | 284.2 | 284.2 | 285 | 285 |
Height | 457 | 477 | 546.1 | 546.1 | 546.1 | 522 | 553 |
Foot Bottom Installation Dimensions(Aperture) | 190X190(8.5) | 190X190(8.5) | 190X190(8.5) | 190X190(8.5) | 190X190(8.5) | 190X190(8.5) | 190X190(8.5) |
Fuel Injection(L) | 1.8 | 2.51 | 2.25 | 3.25 | 3.25 | 3.3 | 3.3 |
Weight(KG) | |||||||
Net.W | 40 | 59.87 | 60.33 | 65.32 | 65.32 | 65 | 65 |
Gross.W | 44 |
Archean refrigeration has been focusing on the refrigeration industry for more than 10 years. The compressors are sold all over the world and have been well received. The company has accumulated strong experience in the compressor market, rich technical support, and a satisfactory one-stop procurement solution. You can rest assured You don’t need to worry about this series, from placing an order to receiving the goods. We provide a complete solution to serve customers well, which is our purpose of hospitality.
Installation Type: | Movable Type |
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Lubrication Style: | Lubricated |
Cylinder Position: | Vertical |
Model: | Zp182kce-Tfd-425 |
Transport Package: | Wooden/Cartoon Box |
Specification: | 26*26*58CM |
Samples: |
US$ 100/Piece
1 Piece(Min.Order) | |
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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.
How does the horsepower of an air compressor affect its capabilities?
The horsepower of an air compressor is a crucial factor that directly impacts its capabilities and performance. Here’s a closer look at how the horsepower rating affects an air compressor:
Power Output:
The horsepower rating of an air compressor indicates its power output or the rate at which it can perform work. Generally, a higher horsepower rating translates to a greater power output, allowing the air compressor to deliver more compressed air per unit of time. This increased power output enables the compressor to operate pneumatic tools and equipment that require higher air pressure or greater airflow.
Air Pressure:
The horsepower of an air compressor is directly related to the air pressure it can generate. Air compressors with higher horsepower ratings have the capacity to produce higher air pressures. This is particularly important when operating tools or machinery that require specific air pressure levels to function optimally. For example, heavy-duty pneumatic tools like jackhammers or impact wrenches may require higher air pressure to deliver the necessary force.
Air Volume:
In addition to air pressure, the horsepower of an air compressor also affects the air volume or airflow it can provide. Higher horsepower compressors can deliver greater volumes of compressed air, measured in cubic feet per minute (CFM). This increased airflow is beneficial when using pneumatic tools that require a continuous supply of compressed air, such as paint sprayers or sandblasters.
Duty Cycle:
The horsepower rating of an air compressor can also influence its duty cycle. The duty cycle refers to the amount of time an air compressor can operate continuously before it needs to rest and cool down. Higher horsepower compressors often have larger and more robust components, allowing them to handle heavier workloads and operate for longer periods without overheating. This is particularly important in demanding applications where continuous and uninterrupted operation is required.
Size and Portability:
It’s worth noting that the horsepower rating can also affect the physical size and portability of an air compressor. Higher horsepower compressors tend to be larger and heavier due to the need for more substantial motors and components to generate the increased power output. This can impact the ease of transportation and maneuverability, especially in portable or mobile applications.
When selecting an air compressor, it is essential to consider the specific requirements of your intended applications. Factors such as desired air pressure, airflow, duty cycle, and portability should be taken into account. It’s important to choose an air compressor with a horsepower rating that aligns with the demands of the tools and equipment you plan to operate, ensuring optimal performance and efficiency.
Consulting the manufacturer’s specifications and guidelines can provide valuable information on how the horsepower rating of an air compressor corresponds to its capabilities and suitability for different tasks.
What is the difference between a piston and rotary screw compressor?
Piston compressors and rotary screw compressors are two common types of air compressors with distinct differences in their design and operation. Here’s a detailed explanation of the differences between these two compressor types:
1. Operating Principle:
- Piston Compressors: Piston compressors, also known as reciprocating compressors, use one or more pistons driven by a crankshaft to compress air. The piston moves up and down within a cylinder, creating a vacuum during the intake stroke and compressing the air during the compression stroke.
- Rotary Screw Compressors: Rotary screw compressors utilize two intermeshing screws (rotors) to compress air. As the male and female screws rotate, the air is trapped between them and gradually compressed as it moves along the screw threads.
2. Compression Method:
- Piston Compressors: Piston compressors achieve compression through a positive displacement process. The air is drawn into the cylinder and compressed as the piston moves back and forth. The compression is intermittent, occurring in discrete cycles.
- Rotary Screw Compressors: Rotary screw compressors also employ a positive displacement method. The compression is continuous as the rotating screws create a continuous flow of air and compress it gradually as it moves along the screw threads.
3. Efficiency:
- Piston Compressors: Piston compressors are known for their high efficiency at lower flow rates and higher pressures. They are well-suited for applications that require intermittent or variable air demand.
- Rotary Screw Compressors: Rotary screw compressors are highly efficient for continuous operation and are designed to handle higher flow rates. They are often used in applications with a constant or steady air demand.
4. Noise Level:
- Piston Compressors: Piston compressors tend to generate more noise during operation due to the reciprocating motion of the pistons and valves.
- Rotary Screw Compressors: Rotary screw compressors are generally quieter in operation compared to piston compressors. The smooth rotation of the screws contributes to reduced noise levels.
5. Maintenance:
- Piston Compressors: Piston compressors typically require more frequent maintenance due to the higher number of moving parts, such as pistons, valves, and rings.
- Rotary Screw Compressors: Rotary screw compressors have fewer moving parts, resulting in lower maintenance requirements. They often have longer service intervals and can operate continuously for extended periods without significant maintenance.
6. Size and Portability:
- Piston Compressors: Piston compressors are available in both smaller portable models and larger stationary units. Portable piston compressors are commonly used in construction, automotive, and DIY applications.
- Rotary Screw Compressors: Rotary screw compressors are typically larger and more suitable for stationary installations in industrial and commercial settings. They are less commonly used in portable applications.
These are some of the key differences between piston compressors and rotary screw compressors. The choice between the two depends on factors such as required flow rate, pressure, duty cycle, efficiency, noise level, maintenance needs, and specific application requirements.
editor by CX 2023-10-07