Product Description
Spicer | P (mm) | R (mm) | Caterpillar | Precision | Rockwell | GKN | Alloy | Neapcon | Serie | Bearing type |
5-2002X | 33.34 | 79 | 644683 | 951 | CP2002 | HS520 | 1-2171 | 2C | 4LWT | |
5-2117X | 33.34 | 79 | 316117 | 994 | HS521 | 1-2186 | 2C | 4LWD | ||
5-2116X | 33.34 | 79 | 6S6902 | 952 | CP2116 | 1063 | 2C | 2LWT,2LWD | ||
5-3000X | 36.5 | 90.4 | 5D9153 | 536 | HS530 | 1711 | 3-3152 | 3C | 4LWT | |
5-3014X | 36.5 | 90.4 | 9K1976 | 535 | HS532 | 3C | 2LWT,2LWD | |||
5-4143X | 36.5 | 108 | 6K 0571 | 969 | HS545 | 1689 | 3-4143 | 4C | 4HWD | |
5-4002X | 36.5 | 108 | 6F7160 | 540 | CP4002 | HS540 | 1703 | 3-4138 | 4C | 4LWT |
5-4123X | 36.5 | 108 | 9K3969 | 541 | CP4101 | HS542 | 1704 | 3-4123 | 4C | 2LWT,2LWD |
5-4140X | 36.5 | 108 | 5M800 | 929 | CP4130 | HS543 | 3-4140 | 4C | 2LWT,2HWD | |
5-1405X | 36.5 | 108 | 549 | 1708 | 4C | 4LWD | ||||
5-4141X | 36.5 | 108 | 7M2695 | 996 | 4C | 2LWD,2HWD | ||||
5-5177X | 42.88 | 115.06 | 2K3631 | 968 | CP5177 | HS555 | 1728 | 4-5177 | 5C | 4HWD |
5-5000X | 42.88 | 115.06 | 7J5251 | 550 | CP5122 | HS550 | 1720 | 4-5122 | 5C | 4LWT |
5-5121X | 42.88 | 115.06 | 7J5245 | 552 | CP5101 | HS552 | 1721 | 4-5127 | 5C | 2LWT,2LWD |
5-5173X | 42.88 | 115.06 | 933 | HS553 | 1722 | 4-5173 | 5C | 2LWT,2HWD | ||
5-5000X | 42.88 | 115.06 | 999 | 5C | 4HWD | |||||
5-5139X | 42.88 | 115.06 | 5C | 2LWD,2HWD | ||||||
5-6102X | 42.88 | 140.46 | 643633 | 563 | CP62N-13 | HS563 | 1822 | 4-6114 | 6C | 2LWT,2HWD |
5-6000X | 42.88 | 140.46 | 641152 | 560 | CP62N-47 | HS560 | 1820 | 4-6143 | 6C | 4LWT |
5-6106X | 42.88 | 140.46 | 1S9670 | 905 | CP62N-49 | HS565 | 1826 | 4-6128 | 6C | 4HWD |
G5-6103X | 42.88 | 140.46 | 564 | 1823 | 4-6103 | 6C | 2LWT,2LWD | |||
G5-6104X | 42.88 | 140.46 | 566 | 1824 | 4-6104 | 6C | 4LWD | |||
G5-6149X | 42.88 | 140.46 | 6C | 2LWD,2HWD | ||||||
5-7105X | 49.2 | 148.38 | 6H2577 | 927 | CP72N-31 | HS575 | 1840 | 5-7126 | 7C | 4HWD |
5-7000X | 49.2 | 148.32 | 8F7719 | 570 | CP72N-32 | HS570 | 1841 | 5-7205 | 7C | 4LWT |
5-7202X | 49.2 | 148.38 | 7J5242 | 574 | CP72N-33 | HS573 | 1843 | 5-7207 | 7C | 2LWT,2HWD |
5-7203X | 49.2 | 148.38 | 575 | CP72N-55 | 5-7208 | 7C | 4LWD | |||
5-7206X | 49.2 | 148.38 | 572 | CP72N-34 | 1842 | 5-7206 | 7C | 2LWT,2LWD | ||
5-7204X | 49.2 | 148.38 | 576 | CP72N-57 | 5-7209 | 7C | 2LWD,2HWD | |||
5-8105X | 49.2 | 206.32 | 6H2579 | 928 | CP78WB-2 | HS585 | 1850 | 6-8113 | 8C | 4HWD |
5-8200X | 49.2 | 206.32 | 581 | CP82N-28 | 1851 | 6-8205 | 8C | 4LWT |
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Condition: | New |
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Certification: | ISO, Ts16949 |
Structure: | Single |
Material: | 20cr |
Type: | Universal Joint |
Transport Package: | Box + Plywood Case |
Samples: |
US$ 10/Piece
1 Piece(Min.Order) | |
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Customization: |
Available
| Customized Request |
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How do you ensure proper alignment when connecting a universal joint?
Ensuring proper alignment when connecting a universal joint is essential for its optimal performance and longevity. Here’s a detailed explanation:
Proper alignment of a universal joint involves aligning the input and output shafts to minimize angular misalignment and maintain a smooth and efficient power transfer. Here are the steps to ensure proper alignment:
- Measure shaft angles: Begin by measuring the angles of the input and output shafts that the universal joint will connect. This can be done using a protractor or an angle measuring tool. The angles should be measured in relation to a common reference plane, such as the horizontal or vertical.
- Calculate the operating angle: The operating angle of the universal joint is the difference between the angles of the input and output shafts. This angle determines the amount of angular misalignment that the universal joint needs to accommodate. It is crucial to calculate the operating angle accurately to ensure the proper selection of a universal joint suitable for the application.
- Select the appropriate universal joint: Based on the calculated operating angle, choose a universal joint that is designed to handle the specific misalignment requirements. Universal joints come in various sizes and designs to accommodate different operating angles and torque loads. Refer to the manufacturer’s specifications and guidelines to select the appropriate universal joint for the application.
- Achieve parallel alignment: To ensure proper alignment, it is important to align the input and output shafts so that they are parallel to each other when viewed from the common reference plane. This can be achieved by adjusting the mounting positions of the shafts or using alignment tools such as straightedges or laser alignment systems. The goal is to minimize any offset or skew between the shafts.
- Check centerline alignment: Once the shafts are parallel, it is necessary to check the centerline alignment. This involves verifying that the centerline of the input shaft and the centerline of the output shaft are in line with each other. Misalignment in the centerline can result in additional stress on the universal joint and lead to premature wear or failure. Use measurement tools or visual inspection to ensure the centerline alignment is maintained.
- Securely fasten the universal joint: After achieving proper alignment, securely fasten the universal joint to the input and output shafts according to the manufacturer’s recommendations. Follow the specified torque values for the fasteners to ensure proper clamping force without over-tightening. This will help maintain the alignment during operation.
- Perform regular maintenance: To ensure continued proper alignment, it is important to perform regular maintenance, including periodic inspections and lubrication of the universal joint. Regular maintenance can help detect any misalignment or wear issues early on and prevent further damage or failure.
By following these steps and paying attention to proper alignment, the universal joint can operate smoothly and effectively, minimizing stress, wear, and the risk of premature failure.
In summary, ensuring proper alignment when connecting a universal joint involves measuring shaft angles, calculating the operating angle, selecting the appropriate universal joint, achieving parallel alignment, checking centerline alignment, securely fastening the joint, and performing regular maintenance.
Can universal joints be used in heavy-duty machinery and equipment?
Yes, universal joints can be used in heavy-duty machinery and equipment. Here’s a detailed explanation:
Universal joints are widely employed in various industrial applications, including heavy-duty machinery and equipment. They offer several advantages that make them suitable for such applications:
- Flexibility: Universal joints are designed to transmit torque and accommodate angular misalignment between shafts. This flexibility allows for the transmission of power even when the shafts are not perfectly aligned, which is often the case in heavy-duty machinery where misalignment can occur due to structural deflection, thermal expansion, or other factors.
- Torque Transmission: Universal joints are capable of transmitting significant amounts of torque. The torque capacity of a universal joint depends on factors such as its size, design, and the materials used. In heavy-duty machinery, where high torque levels are common, appropriately sized and robust universal joints can effectively handle the required torque transmission.
- Compactness: Universal joints are compact in design, allowing them to be integrated into tight spaces within machinery and equipment. Their compactness enables efficient power transmission in applications where space constraints are a concern.
- Durability: Universal joints can be manufactured from materials that provide high strength and durability, such as alloy steels or stainless steels. This durability allows them to withstand heavy loads, harsh operating conditions, and repetitive motion, making them suitable for heavy-duty machinery and equipment.
- Cost-Effectiveness: Universal joints are often a cost-effective solution for torque transmission in heavy-duty machinery. Compared to alternative power transmission methods, such as gearboxes or direct drives, universal joints can offer a more economical option while still providing adequate performance and reliability.
However, it’s important to consider the specific requirements and operating conditions of the heavy-duty machinery when selecting and implementing universal joints. Factors such as the torque levels, rotational speed, angular misalignment, operating temperature, and maintenance practices should be carefully evaluated to ensure that the chosen universal joints are appropriately sized, rated, and maintained for reliable and safe operation.
In summary, universal joints can indeed be used in heavy-duty machinery and equipment. Their flexibility, torque transmission capabilities, compactness, durability, and cost-effectiveness make them a viable choice for power transmission in a wide range of heavy-duty applications.
Can you provide examples of vehicles that use universal joints?
Universal joints are commonly used in various types of vehicles for transmitting torque between shafts that are not in a straight line or are at an angle to each other. Here are some examples of vehicles that use universal joints:
- Automobiles: Universal joints are widely used in automobiles for transmitting torque from the engine to the rear wheels in rear-wheel drive vehicles. They are commonly found in the driveline, connecting the transmission or gearbox to the driveshaft, and in the driveshaft itself. Universal joints are also used in front-wheel drive vehicles for transmitting torque from the transaxle to the front wheels.
- Trucks and commercial vehicles: Universal joints are utilized in trucks and commercial vehicles for transmitting torque between various components of the drivetrain. They can be found in the driveshaft, connecting the transmission or gearbox to the rear differential or axle assembly.
- Off-road vehicles and SUVs: Universal joints are extensively used in off-road vehicles and SUVs that have four-wheel drive or all-wheel drive systems. They are employed in the driveline to transmit torque from the transmission or transfer case to the front and rear differentials or axle assemblies.
- Military vehicles: Universal joints are utilized in military vehicles for transmitting torque between different components of the drivetrain, similar to their use in trucks and off-road vehicles. They provide reliable torque transfer in demanding off-road and rugged environments.
- Agricultural and construction machinery: Universal joints are commonly found in agricultural and construction machinery, such as tractors, combines, excavators, loaders, and other heavy equipment. They are used in the drivelines and power take-off (PTO) shafts to transmit torque from the engine or motor to various components, attachments, or implements.
- Marine vessels: Universal joints are employed in marine vessels for transmitting torque between the engine and the propeller shaft. They are used in various types of watercraft, including boats, yachts, ships, and other marine vessels.
- Aircraft: Universal joints are utilized in certain aircraft applications, such as helicopters, to transmit torque between the engine and the rotor assembly. They allow for angular displacement and smooth transmission of power in the complex rotor systems of helicopters.
- Industrial machinery: Universal joints find applications in various types of industrial machinery, including manufacturing equipment, conveyors, pumps, and other power transmission systems. They enable torque transmission between non-aligned or angularly displaced shafts in industrial settings.
Please note that the specific usage of universal joints may vary depending on the vehicle design, drivetrain configuration, and application requirements. Different types of universal joints, such as single joint, double joint, constant velocity (CV) joint, or Cardan joint, may be employed based on the specific needs of the vehicle or machinery.
editor by CX 2024-03-29