Product Description
ABS Ring Included : No
Axle Nut Locking Type: Self Lock
Axle Nut Supplied: Yes
Compressed Length: 21 1/4″
CV Axles Inboard Spline Count: 26
Emission Code : 1
Inboard Joint Type: Female
Input Shaft Connection Style: Spline
Input Shaft Spline Count: 26
Interchange Part Number: , GM-8047, 179047, GM-6120, GM6120, 9456N
Label Description – 80: New Constant Velocity Drive Axle
Length Measurement Method: Compressed
Life Cycle Status Code: 2
Life Cycle Status Description: Available to Order
Maximum Cases per Pallet Layer: 10
MSDS Required Flag: N
National Popularity Code : B
National Popularity Description: Next 20% of Product Group Sales Value
New or Remanufactured: New
Nut Head Size: 36mm Hex Head
Nut Length: OAH 20.8mm
Nut Locking Type: Self Lock
Nut Thread Size: M24 x 2.0
Other Part Number: 815-5270, GM-8232, 80-1507, , 80571
Outboard Joint Type: Male
Outboard Spline Count: 27
Output Shaft Connection Style: Spline
Output Shaft Spline Count: 27
Overall Length: 21 1/4″
Pallet Layer Maximum: 6
Product Condition: New
Product Description – Invoice – 40: CV Drive Axle New
Product Description – Long – 80: CV Drive Axle – Domestic New
Product Description – Short – 20: CV Drive Axle
Remanufactured Part: N
Spindle Nut Hex Head Size: 36mm
Spindle Nut Included: Yes
Spindle Nut Thread Size: M24 x 2.0
Drive Shaft | PATRON : PDS1507
- Fitting Position: Front Axle Right
REF NO.
FactoryNumber
GSP208050
OE Number
MakeNumber
GMC93720063
MakeNumber
GMC
MakeNumber
CHINAMFG
/* 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(/(.*?):(.*)$/))&&1
| After-sales Service: | Available |
|---|---|
| Condition: | New |
| Certification: | DIN, ISO, ISO, DIN |
| Type: | C.V. Joint |
| Application Brand: | GM |
| Material: | Steel |
| Samples: |
US$ 30/Piece
1 Piece(Min.Order) | |
|---|
| Customization: |
Available
| Customized Request |
|---|
What is the role of needle bearings in a cardan joint?
Needle bearings play a crucial role in the smooth operation and performance of a cardan joint. They are commonly used as a type of rolling element bearing within the joint’s design. The primary role of needle bearings in a cardan joint is to provide support, reduce friction, and facilitate the transmission of torque between the joint’s components. Here’s a detailed explanation of the role of needle bearings in a cardan joint:
- Load Distribution: Needle bearings are designed to distribute loads evenly across their cylindrical rolling elements. In a cardan joint, they help distribute the axial and radial loads between the input and output shafts, yokes, and cross members. This load distribution capability helps minimize stress concentrations and ensures efficient torque transmission.
- Reduced Friction: The rolling motion of the needle bearings reduces the friction between the joint’s components. By reducing friction, needle bearings help minimize power losses and energy consumption within the cardan joint. This is particularly important in applications where efficiency and power transmission are critical.
- Misalignment Compensation: Cardan joints are designed to accommodate misalignments between the input and output shafts. Needle bearings allow a certain degree of misalignment while maintaining smooth rotation and torque transmission. Their design and arrangement provide flexibility and allow for angular, parallel, and axial misalignment compensation.
- High Load Capacity: Needle bearings are specially designed to handle high radial and axial loads. In a cardan joint, they are subjected to varying loads and torque forces. The robust construction of needle bearings enables them to withstand these loads while maintaining their structural integrity and performance.
- Compact Design: Needle bearings offer a high load capacity relative to their size, allowing for a more compact cardan joint design. Their small size and high load-carrying capability make them well-suited for applications with limited space or weight constraints.
- Reduced Wear and Longevity: Needle bearings are designed to have high wear resistance and durability. Their rolling motion reduces the sliding contact between the joint’s components, minimizing wear and extending the joint’s service life. This is particularly important in high-speed or high-load applications where wear can lead to premature failure.
- Operating Conditions: Needle bearings are designed to operate in a variety of conditions, including high-speed and high-temperature environments. They are often manufactured with high-quality materials and heat treatments to enhance their performance and reliability, making them suitable for demanding operating conditions commonly encountered in cardan joint applications.
Overall, needle bearings play a critical role in the functionality, efficiency, and longevity of a cardan joint. By providing load distribution, reduced friction, misalignment compensation, and high load capacity, they contribute to the smooth operation and reliable torque transmission of the joint. Proper selection, lubrication, and maintenance of needle bearings are essential to ensure optimal performance and maximize the lifespan of the cardan joint.
Can cardan joints be used in conveyor systems?
Yes, cardan joints can be used in conveyor systems, and they offer several advantages in certain applications. Cardan joints, also known as universal joints, are versatile mechanical couplings that provide flexibility in transmitting torque and accommodating misalignments between rotating shafts. Here’s a detailed explanation of the use of cardan joints in conveyor systems:
Conveyor systems are widely used in various industries for the efficient movement of bulk materials, goods, or components. These systems consist of multiple components, including conveyor belts, pulleys, rollers, and drive systems, that work together to transport materials from one location to another.
Cardan joints can be integrated into conveyor systems to enable torque transmission and accommodate misalignments in certain parts of the system. Here are some key considerations and advantages of using cardan joints in conveyor systems:
- Misalignment Compensation: Conveyor systems often require flexibility to accommodate misalignments between different components, such as pulleys and drive shafts. Cardan joints provide a flexible coupling solution that can handle angular, parallel, and axial misalignments, allowing smooth operation and minimizing stress on the system.
- Torque Transmission: Cardan joints are designed to transmit torque between shafts that are not aligned. In conveyor systems, they can be used to connect the drive shaft to the pulleys or rollers, allowing torque to be efficiently transferred throughout the system. This enables the movement of the conveyor belt and facilitates the transportation of materials along the desired path.
- Compact Design: Cardan joints offer a compact and space-saving design, making them suitable for conveyor systems with limited space constraints. Their small size allows for efficient integration into the system without compromising its overall footprint.
- High Load Capacity: Conveyor systems often handle significant loads, and the components must be capable of withstanding these loads. Cardan joints are designed to handle high torque and can transmit substantial loads, making them suitable for conveyor systems that require robust and reliable torque transmission.
- Variable Speed and Direction: Cardan joints provide the ability to transmit torque at various angles, allowing conveyor systems to operate at different speeds and change direction if needed. This flexibility allows for versatility in conveyor system design and adaptability to different material handling requirements.
- Reduced Vibrations and Noise: Cardan joints can help dampen vibrations and reduce noise levels in conveyor systems. The flexible coupling nature of the joint absorbs and dampens vibrations caused by the operation of the system, resulting in smoother and quieter performance.
- Application-Specific Considerations: The use of cardan joints in conveyor systems requires careful consideration of specific application requirements, such as the type of material being transported, system layout, operating conditions, and load characteristics. Proper selection of the cardan joint size, materials, lubrication, and maintenance practices is essential to ensure optimal performance and reliability.
It is worth noting that while cardan joints can offer advantages in certain conveyor system applications, other types of couplings or drive systems may be more suitable depending on the specific requirements and constraints of the system. Consulting with engineers and industry experts can help determine the most appropriate coupling solution for a given conveyor system.
How does a cardan joint accommodate misalignment between shafts?
A cardan joint, also known as a universal joint or U-joint, is designed to accommodate misalignment between shafts. Its unique structure and mechanism allow for flexibility and compensation when there are angular or axial deviations between the input and output shafts. Here’s a detailed explanation of how a cardan joint accommodates misalignment:
The cardan joint consists of two yokes, typically fork-shaped, and a cross-shaped member called the cross or spider. The yokes are attached to the input and output shafts, while the cross sits in the center, connecting the yokes. The cross has four arms, and each arm has a bearing cap that holds a bearing. The bearings allow the cross to rotate within the yokes.
When the input and output shafts are perfectly aligned, the cardan joint operates in a straight configuration, and the cross remains in a centered position. However, when misalignment occurs, such as angular misalignment or axial misalignment, the cardan joint can flex and adjust to accommodate the deviation.
Angular Misalignment: When the input and output shafts are at an angle to each other, the cardan joint can accommodate the angular misalignment. As the input shaft rotates, it causes the yoke attached to it to rotate. This rotation is transmitted to the cross through the bearing cap and bearing. As the cross rotates, it causes the other yoke attached to the output shaft to rotate. The angular misalignment is compensated by the ability of the cross to tilt and follow the changing angles of the shafts. The bearings and bearing caps allow the cross to pivot and adjust its position, ensuring that the rotational motion is smoothly transmitted despite the misalignment.
Axial Misalignment: In cases of axial misalignment, where there is a difference in the axial position of the input and output shafts, the cardan joint can also accommodate the misalignment. The axial misalignment can cause the yokes to be slightly offset along the axis. However, the flexibility of the cardan joint allows the cross to adjust its position and maintain the connection between the yokes. The bearings and bearing caps within the cross allow it to move slightly along the axis, compensating for the axial misalignment and ensuring that the rotational motion can still be transmitted.
By allowing the cross to tilt and adjust its position, the cardan joint effectively accommodates misalignment between shafts. It provides the flexibility needed to transmit rotational motion and torque even when the input and output shafts are not perfectly aligned. The ability of the cardan joint to compensate for misalignment makes it a versatile component in various applications where flexibility and misalignment tolerance are required.
editor by CX 2024-01-22
China wholesaler New Ccr or Private Label Cardan Shaft Outer CV Joint, with DIN
Product Description
ABS Ring Included: No
Axle Nut Locking Type: Self Lock
Axle Nut Supplied: Yes
Compressed Length: 21 1/4″
CV Axles Inboard Spline Count: 26
Emission Code : 1
Inboard Joint Type: Female
Input Shaft Connection Style: Spline
Input Shaft Spline Count: 26
Interchange Part Number: , GM-8047, 179047, GM-6120, GM6120, 9456N
Label Description – 80: New Constant Velocity Drive Axle
Length Measurement Method: Compressed
Life Cycle Status Code: 2
Life Cycle Status Description: Available to Order
Maximum Cases per Pallet Layer: 10
MSDS Required Flag: N
National Popularity Code : B
National Popularity Description: Next 20% of Product Group Sales Value
New or Remanufactured: New
Nut Head Size: 36mm Hex Head
Nut Length: OAH 20.8mm
Nut Locking Type: Self Lock
Nut Thread Size: M24 x 2.0
Other Part Number: 815-5270, GM-8232, 80-1507, , 80571
Outboard Joint Type: Male
Outboard Spline Count: 27
Output Shaft Connection Style: Spline
Output Shaft Spline Count: 27
Overall Length: 21 1/4″
Pallet Layer Maximum: 6
Product Condition: New
Product Description – Invoice – 40: CV Drive Axle New
Product Description – Long – 80: CV Drive Axle – Domestic New
Product Description – Short – 20: CV Drive Axle
Remanufactured Part: N
Spindle Nut Hex Head Size: 36mm
Spindle Nut Included: Yes
Spindle Nut Thread Size: M24 x 2.0
Drive Shaft | PATRON : PDS1507
- Fitting Position: Front Axle Right
REF NO.
FactoryNumber
GSP208050
OE Number
MakeNumber
GMC93720063
MakeNumber
GMC
MakeNumber
ISUZU
| After-sales Service: | Available |
|---|---|
| Condition: | New |
| Certification: | DIN, ISO, ISO, DIN |
| Type: | C.V. Joint |
| Application Brand: | GM |
| Material: | Steel |
| Samples: |
US$ 30/Piece
1 Piece(Min.Order) | |
|---|
| Customization: |
Available
| Customized Request |
|---|
Can cardan joints be used in both horizontal and vertical orientations?
Yes, cardan joints can be used in both horizontal and vertical orientations. Cardan joints, also known as universal joints, are flexible mechanical couplings that transmit torque between misaligned shafts. Their design allows for angular movement and compensation of misalignments in various orientations. Here’s a detailed explanation of how cardan joints can be used in both horizontal and vertical orientations:
Horizontal Orientation: In a horizontal orientation, the input and output shafts of the cardan joint are aligned horizontally, typically parallel to the ground. The joint is capable of transmitting torque smoothly and efficiently between the misaligned shafts while accommodating angular, parallel, and axial misalignments. This makes it suitable for a wide range of horizontal applications, including automotive drivetrains, industrial machinery, and agricultural equipment.
Vertical Orientation: In a vertical orientation, the input and output shafts of the cardan joint are aligned vertically, with one shaft positioned above the other. The joint is still capable of transmitting torque and compensating for misalignments in this configuration. However, it is important to consider the effects of gravity and the additional load imposed on the joint due to the weight of the shafts and any connected components. Adequate support and proper bearing selection should be considered to ensure reliable operation in vertical applications.
Whether in horizontal or vertical orientations, cardan joints offer several advantages that make them versatile for various applications:
- Misalignment Compensation: Cardan joints excel at compensating for angular, parallel, and axial misalignments between shafts. This flexibility allows for smooth torque transmission and reduces stress on the connected components.
- Torque Transmission: Cardan joints are capable of transmitting high levels of torque between misaligned shafts. This makes them suitable for applications that require the transfer of substantial power.
- Durability: Cardan joints are typically constructed from durable materials, such as alloy steels, which provide excellent strength and resistance to fatigue and wear. This durability enables them to withstand the demands of various orientations and operating conditions.
- Compact Design: Cardan joints have a compact design, allowing for efficient installation and integration within the system, regardless of the orientation. This is particularly advantageous in applications with space constraints.
- Versatility: Cardan joints are available in various sizes and configurations to accommodate different orientations and applications. They can be customized to meet specific torque and speed requirements.
It is important to note that specific considerations may apply depending on the application and the magnitude of misalignments. Factors such as load capacity, lubrication, bearing arrangement, and maintenance should be taken into account to ensure optimal performance and longevity of the cardan joint.
In summary, cardan joints can be used in both horizontal and vertical orientations due to their ability to compensate for misalignments and transmit torque between shafts. Their versatility, durability, and compact design make them suitable for a wide range of applications in various orientations.
Can cardan joints be used in robotics and automation?
Yes, cardan joints can be used in robotics and automation applications, depending on the specific requirements and constraints of the system. Cardan joints offer certain advantages and considerations that make them suitable for certain robotic and automation tasks. Here’s a detailed explanation:
1. Flexibility and Misalignment Compensation: Cardan joints are designed to accommodate misalignment between rotating shafts. In robotics and automation, where multiple axes of movement are often involved, cardan joints can provide the necessary flexibility to handle misalignments and angular variations. They can compensate for misalignments resulting from assembly tolerances, thermal expansion, or mechanical deflections, allowing smooth and continuous motion.
2. Torque Transmission: Cardan joints are capable of transmitting torque between shafts at various angles. In robotics and automation, where power needs to be transferred between different components or joints, cardan joints can efficiently transmit torque, even when the shafts are not perfectly aligned. This enables the robot or automated system to perform complex tasks involving multi-axis motion and power transmission.
3. Rotational Freedom: Cardan joints provide rotational freedom and allow for angular movement. This is advantageous in robotics and automation applications where the system requires articulation and maneuverability. The universal joint design of cardan joints allows for smooth rotation and enables the robot or automated system to reach different orientations and perform tasks in various configurations.
4. Compact Design: Cardan joints have a relatively compact design, which can be beneficial in space-constrained robotics and automation setups. The compact size allows for efficient integration into robotic arms, end-effectors, or other automated mechanisms, minimizing the overall footprint and maximizing the utilization of available space.
5. Considerations for Precision and Backlash: When considering the use of cardan joints in robotics and automation, it’s important to account for precision requirements. Cardan joints have inherent clearances or play, which can introduce backlash and affect the system’s accuracy. In applications where high precision is crucial, additional measures such as backlash compensation mechanisms or precision-aligned cardan joints may be necessary.
It’s important to note that the suitability of cardan joints in robotics and automation depends on the specific application requirements, load conditions, precision needs, and other factors. Careful evaluation, system design, and integration are necessary to ensure that the cardan joints function optimally and meet the desired performance criteria.
When considering the use of cardan joints in robotics and automation, it is advisable to consult with engineers or experts specializing in robotics, automation, and power transmission systems. They can provide valuable insights and guidance on the selection, integration, and maintenance of cardan joints for specific robotic and automation applications.
What are the applications of a cardan joint?
A cardan joint, also known as a universal joint or U-joint, has a wide range of applications across various industries. Its ability to transmit rotational motion and accommodate misalignment between shafts makes it suitable for different systems and machines. Here’s a detailed explanation of the applications of a cardan joint:
- Automotive Drivetrains: One of the primary applications of cardan joints is in automotive drivetrains. They are used in vehicles with rear-wheel drive, all-wheel drive, and four-wheel drive systems. Cardan joints help transmit power from the engine to the driveshaft, allowing the rotational motion to be transferred to the rear axle or all four wheels. They provide flexibility and compensation for misalignment between the engine, transmission, and rear differential.
- Industrial Machinery: Cardan joints find extensive use in various industrial machinery applications. They are commonly employed in power transmission systems, especially when there is a need to transmit rotational motion between non-collinear shafts. Cardan joints are used in conveyor systems, printing presses, machine tools, pumps, mixers, and many other industrial machines that require efficient transmission of rotational power.
- Aerospace and Aviation: Cardan joints have applications in the aerospace and aviation industries. They are used in aircraft control systems, such as the control linkages between the control surfaces (elevator, rudder, ailerons) and the cockpit controls. Cardan joints allow for the transmission of pilot input to the control surfaces while accommodating any misalignment or changes in angles during flight.
- Marine Propulsion: In marine applications, cardan joints are utilized in propulsion systems. They are commonly used in boat drivetrains to transfer rotational motion from the engine to the propeller shaft. Cardan joints enable the engine to be mounted at an angle or in a different position from the propeller shaft, compensating for the misalignment that can arise due to the boat’s hull shape and design.
- Railway Systems: Cardan joints play a role in railway systems, particularly in drivetrains and couplings. They are used in locomotives and train cars to transfer rotational motion between different components, such as the engine, gearbox, and wheel axle. Cardan joints provide flexibility and accommodate misalignment that may occur due to the movement and articulation of train cars on curved tracks.
- Mining and Construction Equipment: Cardan joints are employed in heavy-duty mining and construction equipment. They are used in applications such as excavators, loaders, bulldozers, and off-highway trucks. Cardan joints help transmit power and motion between different components of these machines, allowing them to operate efficiently and withstand the demanding conditions of mining and construction environments.
- Industrial Robotics: Cardan joints find applications in industrial robotics and automation. They are used in robotic arms and manipulators to transmit rotational motion between different segments or joints of the robotic system. Cardan joints enable precise and flexible movement, allowing robots to perform complex tasks in manufacturing, assembly, and other industrial processes.
These are just a few examples of the diverse applications of cardan joints. Their ability to handle misalignment, transmit rotational motion at varying angles, and provide flexibility make them a fundamental component in numerous systems and machines across industries.
editor by CX 2023-12-04