Product Description
What are the symptoms of a damaged half shaft/drive shaft/axle shaft?
The half shaft/drive shaft/axle shaft is the component that transmits power to the wheels. Without the half shaft, the power cannot be transmitted to the wheels. If the car’s half shaft is damaged, it will cause the car to vibrate abnormally when driving, and will also cause abnormal noises when the car is driving. If the drive shaft is damaged, it needs to be replaced immediately.
If there is a problem with the drive shaft when the vehicle is driving at high speed, it may cause the car tires to fall off or the wheel hub to become out of round. The wheel hub out of roundness will cause the car’s dynamic balance to become unbalanced, causing the car’s high-speed steering wheel to shake. In the vehicle’s transmission system, the half shaft plays an important role and is the shaft that connects the drive wheels and the differential. The inner tie rod ends are generally connected to each other through side gears and splines, and the outer tie rod ends are connected to the wheel hub and flange. The structure of the automobile drive wheel is determined by the structural form of the half shaft. According to the different stress conditions of the half shaft, it can be divided into semi-floating half shaft and fully floating half shaft. It can be seen that the automobile half shaft is the most important factor in the daily driving of the car. An important component, the safe driving of the car depends on the performance of the drive shaft. After long-term torsional fatigue and impact, automobile half shafts are prone to bending, breakage, twisting, skewing, and spline tooth wear. The fractures of automobile half shafts usually have the following morphological types: 1.The spiral of the half-shaft shaft is broken; 2. Mixed cracks and fractures appear in the half-shaft shaft; 3.The splines of the half-shaft are broken; 4.The half-shaft is blue Cracks appear on the disc, and may even fall off in severe cases; 5.Other morphological fractures and cracks in the half shaft.
Product description
Genuine Auto Parts 2 2 2 oem Cardan cv joint Half Shaft Russia Drive Shaft for Lada vaz Niva Uaz
Item Name | Auto or car CV JOINT,Universal Joint,CV JOINT INNER OUTER, DRIVE SHAFT, DRIVESHAFT,CV AXLE, JOINT SHAFT ASSEMBLY,CV AXLE JOINT SHAFT, HALF SHAFT, WHEEL BEARING HUB, WHEEL HUB BEARING, WHEEL BEARING | |||||
OEM/REF NO. | 2 2 2 2 2 2 2 -20 21213 -2203012-1 | |||||
Car Model | For cardan lada vaz UAZ 2206/3151/3303/3741/9 3741 236571 3160 3163 NIVA VAZ samara moskvich 2141 Tavria 1102 GRANTA LARGUS Vesta X-Ray Kalina PRIORA BA3 Granta Kalina Priora OKA VESTA Gazelle Gazelle Gazel Gazon Kamaz Patriot | |||||
POSITION | RH/LH/Right/ Left/ Front/Rear | |||||
MOQ | 1 1 | , 2- | 1 | |||
2 | EX-BK1102OT 215215710 051 | EX-BK1102IN2 215 | ||||
96243578 | EX-BK1102OT-3T 215215710 051 | 215914750 | 2 | |||
21591475 82-20-103 | 32-1116J-k | 82-20-103 | ||||
32-1116J-k 2 | 2 2 | SK96257804BK 35711 | 82-20-103 | |||
96391553 93743422 | CV35571 96220402 | EX-BK43578 SK96257804BK | 49541-24 | -01 | -01 | -01 |
2 2 | 3-01 | -01 |
Reference our cv joint/drive shaft/half shaft packing way,we have full experience to supply different brands all over the world:
Our HDAG CV JOINTS universal joint Drive shafts machining and production workshops:
Our HDAG CV JOINTS universal joint Drive shafts assemble line:
Our semi finished CV JOINT universal joint Drive shaft in stock before packing and shipment:
HDAG CV JOINTS universal joint Drive shafts pull push force and tensile testing, assemble Testing, full size tolerance testing:
I. We only do OEM, produce high precisional Auto CV JOINT,Universal Joint,Car CV JOINT INNER OUTER, DRIVE SHAFT, DRIVESHAFT,CV AXLE, JOINT SHAFT ASSEMBLY,CV AXLE JOINT SHAFT, HALF SHAFT, WHEEL BEARING HUB, WHEEL HUB BEARING, WHEEL BEARING, different with other factories
II.Quality guarantee: We promise to all of our old and new customers: ONE year guarantee or 50,E 1H0498099A/1H57111/357498099EX/357498099EV/357498099E/1J57111D
CHINAMFG :
CHINAMFG :
CHINAMFG :
CHINAMFG : 4342
CHINAMFG : 4342
CHINAMFG : 4342R20
CHINAMFG : 4346R30
CHINAMFG : 4346S50
CHINAMFG : 4346
CHINAMFG : 4347S60
CHINAMFG : 4347U90
CHINAMFG :
CHINAMFG :
CHINAMFG : 434708Z033
CHINAMFG : 434708Z037
CHINAMFG : 391571JJ10
CHINAMFG : 39157117JJ10
CHINAMFG : 3910110JJ10
CHINAMFG : 391Y10
CHINAMFG : 391M570
CHINAMFG : 391N215
CHINAMFG : 391571M311
CHINAMFG : 391571M915
CHINAMFG : 3910140Y10
CHINAMFG : 391014M570
CHINAMFG : 391014M575
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391012Y175
392112Y070
391J210
CHINAMFG : 391J171
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CHINAMFG : 391J071
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CHINAMFG : 391016J071
CHINAMFG : 391016J076
CHINAMFG : 391016J915
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CHINAMFG : 39101AW110
CHINAMFG : 39101CX116
CHINAMFG : 39101WF715
CHINAMFG : 39101WF716
3921185E
CHINAMFG : 4347Z035
CHINAMFG : 434708Z039
191498103A
191498103C
191498103CV
191498103CX
191498104C
321498103D
357498103
357498103A
357498103V
357498103X
357498350X
191498103
1K0498103
VAG :
,96396134,512395
CHINAMFG : 391V70A
CHINAMFG : 391013U505
CHINAMFG : 391014V01C
CHINAMFG : 391014V51A
CHINAMFG : 391014V70A
CHINAMFG : 392113U
96348790
CHINAMFG : 8111304
CHINAMFG : 86011
CHINAMFG : 9122833
CHINAMFG : 9163595
MAZDA : G571550X
MAZDA : G571560X
MAZDA : G565715
OPEL : 374
VAUXHALL : 571
391
MAZDA : MD1922510
MAZDA : MD1922510A
MAZDA : MD192550X
MAZDA : MD257160XB
33
A
OPEL : 374048
OPEL : 374067
OPEL : 37408
OPEL : 374118
OPEL : 374148
OPEL : 374195
OPEL : 90125876
OPEL : 90157212
OPEL : 95718734
OPEL : 9317340
OPEL : 93173430
SAAB : 4242319
A1683601872
CHINAMFG : 391KD0A
CHINAMFG : 391019Y015
CHINAMFG : 39101CNY015
CHINAMFG : 39211CN,7701349689,7701349839,7701349873
,7701351948,7701352571,7701352571
,7701498918,7701498919,7701498921
3910173N10
HONDA : 44305S04J60
HONDA : 44305S0A960
HONDA : 44305S0AN60
HONDA : 44305S2H571
HONDA : 44305S2H050
HONDA : 44305S2H950
HONDA : 44305S2H951
HONDA : 44305S2HN50
HONDA : 44305S5AJ50
HONDA : 44305S5AJ60
HONDA : 44305S5AJ61
HONDA : 44305S5AJ62
HONDA : 44305S5C950
HONDA : 44305S5CN50
HONDA : 44305S5CN51
HONDA : 44305S7B950
HONDA : 44305S7C950
HONDA : 44305SOA960
HONDA : 44305SOAN60
HONDA : 44306S0A960
HONDA : 44306S0AN60
HONDA : 44306S2H571
HONDA : 44306S2H950
HONDA : 44306S2H951
HONDA : 44306S5AJ51
HONDA : 44306S5AJ61
HONDA : 44306S5AJ62
HONDA : 44306S5C951
HONDA : 44306S5C952
HONDA : 44306S7B950
HONDA : 44306S7C950
HONDA : 44306SOA960
HONDA : 44306SOAN60
326582
FG02-25-500E
FG02-25-600D
FG02-25-600E
44305-SA2-960
39100ED00A
39101ED00A
39101ED005
44571-SH3-J01,44306-SB2-984
39211-CN000
CHINAMFG : 0K558-25-60X
3272.S5
39211-AY125
39101-AX005
39100-AX005
39101-AX000
MAZDA : M 0571 1510A
MAZDA : M 0571 1500C
MAZDA : M 0571 1500D
MAZDA : M 0571 1600A
MAZDA : M 0571 1600B
MAZDA : MD0925500A
MAZDA : MD0925600A
MAZDA : G064-25-600
MAZDA : G564-25-500A
MAZDA : G564-25-600A
MAZDA : G564-25-60X
MAZDA : GR01-25-500
MAZDA : GR01-25-50X
MAZDA : GR01-25-600
MAZDA : GR01-25-60X
MAZDA : GU01-25-500
MAZDA : GU01-25-50XA
MAZDA : GU01-25-50XC
MAZDA : GU01-25-600
MAZDA : GU01-25-60XA
MAZDA : GU01-25-60XD
HONDA : 44014-SNG-000
HONDA : 44305-SDC-A00
HONDA : 44305-SEA-000
HONDA : 44305-SNG-571
HONDA : 44306-SDC-A01
HONDA : 44306-SDE-T00
HONDA : 44306-SEA-000
HONDA : 44306-SNG-571
CHINAMFG : 39100JD24B
CHINAMFG : 39100JD52B
CHINAMFG : 39101JD24B
CHINAMFG : 39101JD52B
CHINAMFG : 39211JA00A
CHINAMFG : 39211JD22B
CHINAMFG : C9211JA00A
CHINAMFG : C9211JD22B
CHINAMFG : C92AAJA00A
CHINAMFG : C92AAJD22B
CHINAMFG : C9B11JA00A
CHINAMFG : C9BAAJA00A
MAZDA : FA8571500A
MAZDA : FA8571600B
MAZDA : FA8125600B
MAZDA : FA8225500A
MAZDA : FD8571500B
MAZDA : FD8571600A
MAZDA : FP0125500C
3272-HY
3272-KW
3273-HQ
3273-KJ
CHINAMFG : 39100-ED105
CHINAMFG : 39100-ED305
CHINAMFG : 39100-ED805
CHINAMFG : 39101-ED105
CHINAMFG : 39101-ED305
CHINAMFG : 39101-ED805
CHINAMFG : 39211-ED100
CHINAMFG : C9211-EL10A
CHINAMFG : KK38825600
CHINAMFG : 49500-25302
CHINAMFG : 49500-25310
CHINAMFG : 49500-25311
CHINAMFG : 49500-25312
CHINAMFG : 49500-25301
CHINAMFG : 49500-25302
CHINAMFG : 49500-25310
CHINAMFG : 49500-25311
CHINAMFG : 49500-25312
LAND ROVER : STC3046
40011-M5626
39100-M7270
39101-M7270
39113-M7275
39112-M7225
LAND ROVER : TDJ00571
CHINAMFG : 49500-25400
CHINAMFG : 49500-25200
CHINAMFG : 49500-25400
LAND ROVER : TDB500110
LAND ROVER : TDJ500030
39101-CA100
39211-CA100
39100-CA100
HONDA : 44305S74E01
HONDA : 44305S74E51
ROVER : GCV1123
ROVER : TFB000070
39211-AY125
39101-AX005
39100-AX005
39101-AX000
CITROEN : 3272TH
CITROEN : 3272WX
CITROEN : 3273QQ
CITROEN : 3273TT
CITROEN : 3273XR
DS : 3272QF
DS : 3272TH
DS : 3273QQ
DS : 3273TT
PEUGEOT : 3272QF
PEUGEOT : 3272TH
PEUGEOT : 3272WX
PEUGEOT : 3273QQ
PEUGEOT : 3273TT
PEUGEOT : 3273XR
39211-CG571
/* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
After-sales Service: | Three Years |
---|---|
Condition: | New |
Color: | OEM Standard |
Certification: | CE, ISO, ISO/Ts16949 |
Type: | C.V. Joint |
Application Brand: | Nissan, Iveco, Toyota, Ford, Lada Mitsubishi Isuzu Suzuki Subaru |
Customization: |
Available
| Customized Request |
---|
How Do Rear Drive Shafts Ensure Efficient Power Transfer While Maintaining Balance?
Rear drive shafts play a crucial role in ensuring efficient power transfer from the engine or transmission to the rear wheels of a vehicle. At the same time, they must maintain balance to prevent vibrations, reduce stress on drivetrain components, and enhance overall performance. Here’s a detailed explanation of how rear drive shafts achieve efficient power transfer while maintaining balance:
1. Balanced Design:
Rear drive shafts are carefully designed and manufactured to achieve balance. Balance refers to the distribution of mass along the length of the drive shaft. Imbalances can lead to vibrations and unwanted forces that affect the smooth operation of the drivetrain. To achieve balance, drive shafts are dynamically balanced during the manufacturing process. This involves adding weights or removing material at specific locations to counteract any uneven distribution of mass. By achieving balance, the drive shaft can rotate smoothly at high speeds, minimizing vibrations and ensuring efficient power transfer.
2. Proper Length and Diameter:
The length and diameter of the rear drive shaft are important considerations for maintaining balance. A drive shaft that is too long or too short can result in excessive deflection or bending, leading to vibrations and potential failure. Similarly, an incorrect diameter can affect the stiffness and torsional strength of the drive shaft, resulting in imbalances. Manufacturers carefully calculate the optimal length and diameter of the drive shaft based on the vehicle’s specifications and requirements to ensure proper balance and power transfer.
3. High-Quality Materials:
The selection of high-quality materials is crucial for maintaining balance in rear drive shafts. Drive shafts are typically made from materials such as steel or aluminum. These materials offer the necessary strength and rigidity while being lightweight. The use of high-quality materials ensures that the drive shaft can withstand the torque and rotational forces without excessive flexing or bending, which can lead to imbalances. Additionally, the materials are chosen for their ability to resist fatigue and vibration, further contributing to balanced operation.
4. Precision Manufacturing:
Rear drive shafts are manufactured with precision to maintain balance. Advanced manufacturing techniques, such as computer-aided design (CAD) and computer numerical control (CNC) machining, are employed to ensure the drive shaft’s dimensional accuracy and balance. The manufacturing process involves precise machining of the shaft, including the yokes, flanges, and other components, to achieve tight tolerances and minimize any deviations that could affect balance. Strict quality control measures are implemented to verify the balance of each drive shaft before it is installed in a vehicle.
5. Vibration Dampening Techniques:
Rear drive shafts often incorporate vibration dampening techniques to further enhance balance and reduce unwanted vibrations. These techniques may include the use of balancing weights, dampers, or vibration-absorbing materials. Balancing weights can be strategically placed along the drive shaft to counteract any remaining imbalances. Dampers, such as rubber or elastomer components, are employed to absorb and dissipate vibrations, preventing them from propagating throughout the drivetrain. By minimizing vibrations, these techniques help maintain overall balance and contribute to efficient power transfer.
6. Universal Joints or Constant Velocity Joints:
Rear drive shafts incorporate flexible joints, such as universal joints (u-joints) or constant velocity (CV) joints, to accommodate changes in angles and maintain balance. These joints allow for angular movement and compensate for variations in the alignment between the transmission or transfer case and the rear differential. By allowing the drive shaft to flex and articulate, these joints help prevent binding, minimize stress on the drivetrain components, and maintain balance throughout the range of motion.
7. Regular Maintenance and Inspection:
Maintaining balance in rear drive shafts requires regular maintenance and inspection. Over time, components may wear or become damaged, leading to imbalances. It is important to periodically inspect the drive shaft for signs of wear, such as worn u-joints or damaged CV joints. Additionally, proper lubrication of the joints and ensuring the drive shaft is properly installed and aligned are essential for maintaining balance. Routine maintenance and inspections help detect and address any issues that could affect the drive shaft’s balance and overall performance.
In summary, rear drive shafts ensure efficient power transfer while maintaining balance through a combination of balanced design, proper length and diameter, high-quality materials, precision manufacturing, vibration dampening techniques, flexible joints, and regular maintenance. By achieving and maintaining balance, rear drive shafts contribute to smooth operation, minimize vibrations, and enhance the overall performance and longevity of the drivetrain system.
Can Rear Drive Shafts Be Customized for Specific Vehicle Configurations or Upgrades?
Rear drive shafts can indeed be customized to accommodate specific vehicle configurations or upgrades. Customization allows for optimal fitment, performance, and compatibility with modified drivetrain systems or unique vehicle configurations. Here’s a detailed explanation of how rear drive shafts can be customized for specific vehicle configurations or upgrades:
1. Length and Diameter:
Custom rear drive shafts can be manufactured with specific lengths and diameters to suit different vehicle configurations. When modifying a vehicle’s drivetrain, such as installing a lift kit, altering suspension components, or changing the transmission or differential, the drive shaft’s length and diameter may need to be adjusted accordingly. Modifying these dimensions ensures proper alignment and engagement with the transmission output shaft and differential input flange, allowing for smooth and efficient power transfer.
2. Material Selection:
Custom rear drive shafts can be crafted from different materials depending on the specific vehicle requirements or upgrades. While steel is commonly used for its strength and durability, alternative materials like aluminum or carbon fiber can be chosen to reduce weight and improve overall vehicle performance. The choice of material will depend on factors such as the vehicle’s weight, power output, intended use, and budget considerations.
3. U-Joints and CV Joints:
U-joints and CV joints are critical components of rear drive shafts, allowing for flex and rotational movement while transmitting torque. When customizing a rear drive shaft, the type and size of U-joints or CV joints can be selected based on the specific vehicle configuration or upgrade. Heavy-duty or high-performance U-joints or CV joints may be chosen to handle increased power, torque, or off-road demands. Upgraded joints can provide improved strength, reliability, and articulation angles, ensuring optimal performance in modified drivetrain setups.
4. Balancing and Harmonics:
Custom rear drive shafts can be carefully balanced to minimize vibrations and harmonics. Balancing is crucial to ensure smooth operation and prevent excessive wear on drivetrain components. When modifying or upgrading the vehicle’s drivetrain, changes in weight distribution, rotational speeds, or component stiffness can affect the dynamic balance of the drive shaft. Custom balancing techniques, such as precision weights or dynamic balancing machines, can be employed to achieve optimal balance and reduce vibrations, ensuring a comfortable and reliable driving experience.
5. Performance Enhancements:
Custom rear drive shafts can be tailored to enhance performance in specific vehicle configurations or upgrades. For example, in high-performance applications or off-road vehicles, reinforced drive shafts with thicker walls or additional gussets can be fabricated to handle increased power and torque loads. Upgraded materials, such as heat-treated alloys, can be utilized to improve strength and durability. By customizing the rear drive shaft, vehicle owners can ensure that the drivetrain system can effectively handle the demands of their specific applications.
6. Compatibility with Differential Ratios:
When changing the differential gear ratios in a vehicle, the rear drive shaft’s rotational speed and torque requirements may be affected. Custom rear drive shafts can be designed to accommodate these changes in gear ratios, ensuring proper torque transmission and maintaining compatibility between the transmission, transfer case (if applicable), and the differential. This customization helps maintain optimal drivetrain performance and prevents potential driveline vibrations or failures that may arise from mismatched gear ratios.
7. Professional Consultation and Expertise:
Customizing rear drive shafts for specific vehicle configurations or upgrades often requires professional consultation and expertise. Working with experienced drivetrain specialists, automotive engineers, or aftermarket manufacturers can help ensure that the customization aligns with the vehicle’s requirements and performance goals. These experts can provide valuable insights and recommendations, taking into account factors such as vehicle weight, powertrain modifications, intended use, and budget constraints.
In summary, rear drive shafts can be customized to suit specific vehicle configurations or upgrades. Customization options include adjusting the length and diameter, selecting appropriate materials, choosing the right type and size of U-joints or CV joints, balancing the drive shaft, incorporating performance enhancements, ensuring compatibility with differential ratios, and seeking professional consultation and expertise. By customizing rear drive shafts, vehicle owners can optimize drivetrain performance, ensure compatibility with modified configurations, and meet the unique demands of their specific applications or upgrades.
How Do Rear Drive Shafts Impact the Performance and Drivability of Vehicles?
Rear drive shafts have a significant impact on the performance and drivability of vehicles. As a crucial component of the drivetrain system, the rear drive shaft affects various aspects of a vehicle’s operation, including power delivery, handling, stability, and overall driving experience. Here’s a detailed explanation of how rear drive shafts impact the performance and drivability of vehicles:
1. Power Transmission:
Rear drive shafts play a vital role in transmitting power from the engine or transmission to the wheels. As the engine generates torque, the rear drive shaft transfers this rotational force to the rear wheels, enabling propulsion and vehicle movement. The efficiency and effectiveness of power transmission through the rear drive shaft directly impact a vehicle’s acceleration, towing capacity, and overall performance.
2. Traction and Stability:
The distribution of power between the rear wheels, controlled by the rear drive shaft and the rear differential, significantly affects a vehicle’s traction and stability. By transmitting torque to the rear differential, the rear drive shaft allows the differential to distribute power to each rear wheel based on traction conditions.
Proper power distribution between the rear wheels ensures balanced traction, reducing the likelihood of wheel slippage or loss of control. This enhances the vehicle’s stability, especially during acceleration, cornering, or driving on uneven or slippery surfaces.
3. Handling and Cornering:
Rear drive shafts influence a vehicle’s handling and cornering capabilities. In rear-wheel drive (RWD) vehicles, the rear drive shaft connects the transmission or transfer case to the rear differential, resulting in a weight distribution biased towards the rear of the vehicle.
This weight distribution, combined with the rear drive shaft’s torque transmission to the rear wheels, contributes to better traction and stability during cornering. RWD vehicles typically exhibit a more balanced and predictable handling characteristic, allowing drivers to maintain better control and confidence while navigating turns.
4. Suspension Compatibility:
Rear drive shafts also need to be compatible with a vehicle’s suspension system. The suspension system allows the wheels to move independently, absorbing bumps, road irregularities, and other disturbances for a smoother ride.
The rear drive shaft must accommodate the vertical movement of the suspension without affecting power transmission. It achieves this by incorporating flexible joints or splines that allow the drive shaft to expand or contract in length as the suspension moves. This compatibility ensures that the rear drive shaft does not hinder the suspension’s ability to absorb shocks and maintain tire contact with the road surface.
5. Drivetrain Efficiency:
The efficiency of a vehicle’s drivetrain system is influenced by the performance of the rear drive shaft. A well-designed and properly maintained rear drive shaft minimizes power losses and mechanical friction, allowing more power to reach the wheels and optimizing overall drivetrain efficiency.
Efficient power transmission through the rear drive shaft contributes to improved fuel efficiency, reduced energy waste, and enhanced performance. Regular maintenance, such as lubrication and alignment, ensures that the rear drive shaft operates smoothly and maximizes its contribution to drivetrain efficiency.
6. Four-Wheel Drive Capability:
In vehicles equipped with four-wheel drive (4WD) or all-wheel drive (AWD) systems, rear drive shafts play a crucial role in enabling four-wheel drive capability. The rear drive shaft transfers torque to the transfer case, which distributes power to both the front and rear differentials.
By facilitating power distribution to all four wheels, rear drive shafts enhance the vehicle’s off-road performance, traction, and stability. Four-wheel drive capability allows the vehicle to tackle challenging terrain, slippery conditions, or uneven surfaces with improved control and maneuverability.
In summary, rear drive shafts have a significant impact on the performance and drivability of vehicles. They affect power transmission, traction, stability, handling, suspension compatibility, drivetrain efficiency, and enable four-wheel drive capability. By understanding and optimizing the design, maintenance, and performance of rear drive shafts, manufacturers and drivers can enhance a vehicle’s overall performance, efficiency, and driving experience.
editor by CX 2024-04-22