Tag Archives: drive shaft joint replacement

China Best Sales 39101-1HS0b T98741 Wholesale CV Joint Axle Assy Left Front Drive Shaft for CZPT Micra K13 Mt Japanese Car cv axle replacement cost

Product Description

As a professional manufacturer for propeller shaft, we have +800 items for all kinds of car, main suitable
for AMERICA & EUROPE market.

 

Our advantage:

 

1. Full range of products

2. MOQ qty: 5pcs/items

3. Delivery on time

4: Warranty: 1 YEAR

5. Develope new items: FREE

 

Brand Name

KOWA DRIVE SHAFT

Item name

 39101-1HS0B

Car maker

For  NISSAN MICRA

Moq

5pcs

Guarantee

12 months

sample

Available if have stock

Price

Send inquiry to get lastest price

BOX/QTY

1PCS/Bag 4PCS /CTNS

We have more drive shafts of models that have not been uploaded in time, such as: For Hyundai Mazda CZPT CZPT CZPT Honda Nissan… Please send an inquiry and we will solve your needs, click Contact Supplier, thank you.

For Japanese Car
for TOYOTA for TOYOTA
43420-57170 43420-57180 43410-0W081 43420-0W080
43410-57120 43420-57190 43410-0W091 43420-0W090
43410-57130 43420-57120 43410-0W100 43420-0W110
43410-57150 43420-02B10 43410-0W110 43420-0W160
43410-06221 43420-02B11 43410-0W140 43420-32161
43410-06231 43420-02B60 43410-0W150 43420-33250
43410-06460 43420-02B61 43410-0W180 43420-33280
43410-06570 43420-02B62 43410-12410 43420-48090
43410-06580 43420-06221 43410-33280 43420-48091
43410-066-90 43420-06231 43410-33290 43430OK571
43410-06750 43420-06460 43410-33330 66-5245
43410-06780 43420-06490 43410-48070 66-5247
43410-06A40 43420-06500 43410-48071 43420-57150
43410-06A50 43420- 0571 0 43410-0W061 43420-0W061
43410-07070 43420-06610 43410-0W071 43420-0W071
for Acura for LEXUS
44305STKA00 66-4198 43410-06200 43410-06480
44305STKA01 66-4261 43410-06450 43410-06560
44305SZPA00 66-4262 66-5265  
44306STKA00 66-4270 for MITSUBISHI
44306STKA01 66-4271 3815A309 3815A310
44306SZPA00      
for Honda for MAZDA
44571S1571 44306S3VA61 5L8Z3A428AB GG052550XD
44011S1571 44306S3VA62 5L8Z3A428DA GG052560XE
44305S2HN50 44306S9VA51 66-2090 GG362550XA
44305SCVA50 44306S9VA71 6L8Z3A428A YL8Z3A427AA
44305SCVA51 44306SCVA50 9L8Z3A427B YL8Z3A427BA
44305SCVA90 44306SCVA51 GG032550XD YL8Z3A428AA
44305SCVA91 44306SCVA90 GG042550XD YL8Z3A428BA
44305STXA02 44306SCVA91 GG042560XG ZC32550XA
44305SZAA01 44306STXA02    
44306S2H951 44306SZAA01    
44306SZAA11 44306SZAA01RM    
44306SZAA12 66-4213    
66-4214      
for Europe Car
for VOLKSWAGEN for VOLKSWAGEN
4885712AD 7B0407271B 7E0407271G 7LA407272C
4885713AF 7B0407272 7E0407271P 7LA4 0571 2CX
4881214AE 7B0407272E 7LA407271E  
7B0407271A      
for America Car
for CHRYSLER for MERCURY
4593447AA 557180AD 4F1Z3B437AA GG322560X
4641855AA 52114390AB 5L8Z3A428DB GG362560XA
4641855AC 5273546AC 66-2249 YL8Z3A427CA
4641856AA 66-3108 9L8Z3A427C YL8Z3A427DA
4641856AC 66-3109 9L8Z3A427D YL8Z3A427EA
4882517 66-3130 GG062550XD YL8Z3A427FA
4882518 66-3131 GG062560XE YL8Z3A428CA
4882519 66-3234 GG312560X ZZDA2560X
4882520 66-3518 ZZDA2560XC ZZDA2560XA
557130AB 66-3520 for RAM
66-3552 66-3522 4885713AD 55719AB
66-3553 66-3551 4881214AD 66-3404
66-3554 66-3639 55719AA 66-3740
68193908AB 66-3641 68571398AA  
for FORD for DODGE
1F0571400 E6DZ3V428AARM 4593449AA 7B0407272A
1F0571410 E8DZ3V427AARM 4641855AE 7B0407272B
1F2Z3B436AA E8DZ3V428AARM 4641855EE 7B0407272C
2F1Z3A428CA E90Y3V427AARM 4641856AD R4881214AE
2M5Z3B437CA E90Y3V428AARM 4641856AF RL189279AA
4F1Z3B437BA F0DZ3V427AARM 4885710AC 557180AG
5M6Z3A428AA F0DZ3V428AARM 4885710AE 5170822AA
5S4Z3B437AA F21Z3B437A 4885710AF 52114390AA
66-2005 F21Z3B437B 4885710AG 5273546AD
66-2008 F2DZ3B436A 4885711AC 5273546AE
66-2571 F2DZ3B436B 4885711AD 5273546AF
66-2084 F2DZ3B437A 4885712AC 5273558AB
66-2086 F2DZ3B437B 4885712AE 5273558AD
66-2095 F4DZ3B437A 4885712AG 5273558AE
66-2101 F57Z3B436BA 4885712AH 5273558AF
66-2143 F57Z3B437BA 4885713AC 4881214AC
6S4Z3B437BA F5DZ3A427BA 4885713AG 4881214AF
8S4Z3B437A F5DZ3A428AS 4885713AI 4881214AG
9L8Z3A427A F5DZ3B426D 4885713AJ 557130AA
E6DZ3V427AARM F5DZ3B436D 5273558AG 557180AE
YF1Z3A428RS F5DZ3B437B 66-3382 557180AF
YL8Z3A428DA F5TZ3B436A 66-3511 66-3514
YS4Z3B437BB GG032560XG 66-3759 66-3564
YS4Z3B437CB GG362550X    
YF1Z3A427L      
for CHEVROLET for JEEP
257191 26062613 4578885AA 5215710AA
22791460 4578885AB 5215711AB
26011961 4578885AC 5215711AB
26571730 2657189 4720380 5273438AC
2657165 66-1401 4720381 5273438AD
26058932 66-1438 5012456AB 5273438AE
26065719 88982496 5012457AB 5273438AG
for HUMMER 5066571AA 66-3220
1571204 595716 557120AB 66-3221
15886012 66-1417 557120AC 66-3298
for CADILLAC 557120AD 66-3352
88957151 66-1416 557120AE 66-3417
66-1009 66-1430 5189278AA 66-3418
66-1415 88957150 5189279AA 66-3419

 

 

 

 

 

 

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After-sales Service: 1 Year
Condition: New
Color: Black
Certification: ISO
Type: Drive Shaft
Application Brand: Nissan
Samples:
US$ 300/Piece
1 Piece(Min.Order)

|
Request Sample

Customization:
Available

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Customized Request

cv axle

How do I determine the correct CV axle length for my modified or customized vehicle?

When it comes to modified or customized vehicles, determining the correct CV axle length is essential to ensure proper fitment, functionality, and optimal performance. Here’s an explanation of how you can determine the correct CV axle length for your modified or customized vehicle:

1. Consult with a Suspension Specialist or Mechanic:

It is highly recommended to consult with a suspension specialist or a qualified mechanic who has experience with modified or customized vehicles. They have the expertise and knowledge to assess your specific vehicle modifications and provide guidance on the correct CV axle length required. They can take into account factors such as suspension lift, wheel travel, geometry changes, and other modifications to determine the appropriate axle length.

2. Measure Existing Axle Length:

If you are replacing an existing CV axle and want to ensure that the new axle has the correct length, you can measure the existing axle to use as a reference. Follow these steps:

  1. Jack up the vehicle and secure it on jack stands.
  2. Remove the wheel and brake assembly to access the CV axle.
  3. Measure the length of the CV axle from the center of the inner CV joint to the center of the outer CV joint.
  4. Take note of the measurement for reference when selecting the new CV axle.

3. Consider Suspension Geometry:

When modifying or customizing a vehicle’s suspension, changes in suspension geometry can affect the required CV axle length. Factors such as suspension lift, altered suspension components, and changes in ride height need to be taken into account. Modifying the suspension can result in changes to the angle and position of the CV axles, which may require longer or shorter axles to maintain proper alignment and operation.

4. Seek Guidance from Aftermarket Manufacturers:

Aftermarket manufacturers and suppliers specializing in modified or customized vehicles may offer specific CV axles designed for certain modifications. They can provide guidance on the correct axle length based on your vehicle’s specific modifications. Research reputable aftermarket brands and reach out to their customer support or consult their product catalogs to find CV axles suitable for your modified or customized vehicle.

5. Test Fitment and Professional Installation:

Once you have determined the appropriate CV axle length based on the above considerations, it is recommended to test fit the axle before final installation. This involves temporarily fitting the axle to ensure proper alignment, engagement with the CV joints, and adequate suspension travel. If necessary, make any adjustments or seek professional assistance to ensure the correct fitment and functionality of the CV axle.

In summary, determining the correct CV axle length for a modified or customized vehicle requires consulting with suspension specialists or mechanics, measuring existing axle length as a reference, considering suspension geometry changes, seeking guidance from aftermarket manufacturers, and conducting test fitment. Proper selection and installation of the CV axle are crucial to ensure optimal performance and reliability in your modified or customized vehicle.

cv axle

What is the impact of lifted or lowered suspension on CV axle angles and longevity?

Lifting or lowering a vehicle’s suspension can have a significant impact on the angles and longevity of CV axles. Here’s an explanation of how lifted or lowered suspension affects CV axle angles and longevity:

1. Lifted Suspension:

When a vehicle’s suspension is lifted, either through the use of taller springs, spacers, or suspension modifications, it can result in increased CV axle angles. The higher ride height alters the geometry of the suspension system, causing the CV axles to operate at more severe angles. This increased angle can lead to several effects:

a. Increased Wear and Stress: The higher CV axle angles in a lifted suspension setup can increase wear and stress on the CV joints and boots. The joints are forced to operate at more extreme angles, which can accelerate wear and potentially lead to premature failure. The constant articulation and operating angles can cause the CV boots to wear out faster, increasing the risk of contamination and damage to the CV joints.

b. Binding and Limited Articulation: In extreme cases, excessive lift can cause the CV axles to bind or reach their maximum operating angles, limiting the suspension’s articulation. This can result in reduced wheel travel, compromised off-road performance, and potential damage to the CV axles if the binding is severe.

c. Axle Shaft Length: In some lifted suspension setups, longer axle shafts may be required to accommodate the increased ride height. Longer axle shafts can help maintain proper CV axle angles and prevent excessive stress on the joints. It’s important to ensure that the correct length axle shafts are installed to maintain optimal CV axle operation.

2. Lowered Suspension:

Lowering a vehicle’s suspension, typically achieved through shorter springs, modified suspension components, or aftermarket kits, also affects CV axle angles and longevity. Here are some considerations:

a. Decreased CV Axle Angles: Lowering the suspension reduces the ride height of the vehicle, which can result in decreased CV axle angles. The reduced angles may alleviate some stress on the CV joints and boots, potentially leading to improved longevity.

b. Ground Clearance Concerns: Lowering a vehicle’s suspension may decrease ground clearance, making the CV axles more susceptible to potential impacts from road debris, speed bumps, or uneven surfaces. It’s important to consider the potential risks of reduced ground clearance and take appropriate measures to protect the CV axles, such as installing skid plates or ensuring proper alignment.

c. Suspension Geometry Adjustments: Lowering the suspension often requires adjustments to suspension geometry to maintain proper alignment. Incorrect suspension geometry can lead to increased CV axle angles, premature wear, and potential damage. It’s crucial to consult with a professional mechanic or suspension specialist to ensure proper suspension geometry adjustments are made when lowering the vehicle.

Regular Maintenance and Inspection:

Regardless of whether the suspension is lifted or lowered, it’s essential to regularly inspect and maintain the CV axles. This includes checking the CV boots for tears or damage, ensuring proper lubrication, and monitoring for any abnormal noises or vibrations during operation. Regular maintenance can help identify potential issues early and prevent further damage to the CV axles.

In summary, lifting or lowering a vehicle’s suspension can affect the angles and longevity of CV axles. Lifted suspensions can increase CV axle angles, leading to increased wear and stress, while lowered suspensions can potentially decrease angles but may present ground clearance concerns. Proper installation, alignment, and regular maintenance are crucial to mitigate the impact of suspension modifications on CV axle angles and longevity.

cv axle

Can you explain the symptoms of a failing CV axle and how to diagnose the issue?

When a CV axle starts to fail, it can exhibit several symptoms that indicate potential issues. Recognizing these symptoms and properly diagnosing the problem is essential for timely repairs. Here’s an explanation of the symptoms of a failing CV axle and how to diagnose the issue:

Symptoms of a Failing CV Axle:

1. Clicking or popping sounds: One of the most common symptoms of a failing CV axle is a clicking or popping sound, especially when making turns. This sound may indicate that the CV joint is worn or damaged, causing it to bind or catch during rotation.

2. Vibration or shuddering: A failing CV axle can cause vibrations or shuddering felt in the vehicle’s steering wheel or floorboard. These vibrations are often most noticeable during acceleration, particularly when turning or maneuvering at low speeds.

3. Grease leakage: Inspect the CV axle boots for any signs of grease leakage. Damaged or torn CV boots can allow grease to escape, exposing the CV joints to dirt, debris, and moisture. This can lead to accelerated wear and eventual failure of the CV axle.

4. Excessive vibration during acceleration: If you experience strong vibrations during acceleration, it may indicate an issue with the CV axle. Damaged CV joints can cause the axle to become imbalanced, resulting in vibrations that intensify as the vehicle accelerates.

5. Difficulty in turning: A failing CV axle can make it difficult to turn the vehicle, especially at lower speeds. You may notice increased resistance or a jerking sensation when trying to steer.

6. Visible damage or excessive wear: Inspect the CV axle visually for any visible damage, such as cracks, tears, or excessive wear on the CV boots or joints. Physical damage or wear can impair the functionality of the CV axle and lead to failure.

Diagnosing a Failing CV Axle:

To diagnose a failing CV axle, you can perform the following steps:

1. Visual inspection: Inspect the CV axle visually for any signs of damage, leakage, or excessive wear. Look for cracks, tears, or loose components. Pay close attention to the CV boots and joints, as they are common areas of failure.

2. Listening for noises: While driving, listen for clicking, popping, or grinding sounds, especially during turns. These noises can indicate worn or damaged CV joints.

3. Test drive: Take the vehicle for a test drive and pay attention to any vibrations, shuddering, or difficulty in turning. Note when these symptoms occur, such as during acceleration, deceleration, or turns, as it can provide valuable information for diagnosis.

4. Inspection of CV boots: If you suspect a failing CV axle, inspect the CV boots for damage or leaks. Grease leakage or torn boots can be indicative of a failing CV joint.

5. Professional inspection: If you are uncertain about the diagnosis or lack the necessary tools and experience, it is recommended to have a qualified mechanic or technician inspect the CV axle. They can perform more in-depth diagnostics, such as checking for excessive play or movement in the CV joints, using specialized tools.

Remember, early detection and repair of a failing CV axle are crucial to prevent further damage to the drivetrain and ensure safe operation of the vehicle. If you suspect a failing CV axle based on the symptoms described, it is recommended to seek professional assistance for an accurate diagnosis and appropriate repairs.

China Best Sales 39101-1HS0b T98741 Wholesale CV Joint Axle Assy Left Front Drive Shaft for CZPT Micra K13 Mt Japanese Car   cv axle replacement costChina Best Sales 39101-1HS0b T98741 Wholesale CV Joint Axle Assy Left Front Drive Shaft for CZPT Micra K13 Mt Japanese Car   cv axle replacement cost
editor by CX 2024-01-15