China factory 37100-04342 for CHINAMFG Tacoma 07-14 Propshaft Tail Shaft Drive Shaft Manufacturer

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

 

OEM NO. 65-5012 37100-5712 936-724
Application for CZPT Tacoma 07-14
Material SS430/45# steel 
Balancing Standrad G16, 3200rpm
Warranty One Year

For some items, we have stock, small order (+3000USD) is welcome.

 

The following items are some of propeller shafts for Toyota, If you need more information, pls contact us for ASAP.
 

Propeller Shaft for TOYOTA

  OEM

     Application         

OEM

Application

37302-20040 for TOYOTA 37110-65710 for CZPT Land Cruiser 77-80
37120-0K030 for TOYOTA 37110-65710 for CZPT Land Cruiser 81-85 
37120-30420 for TOYOTA 37140-60170 for CZPT Land Cruiser 85-87
37140-6571 for TOYOTA 37140-65710 for CZPT Land Cruiser 88-90
37140-35050 for TOYOTA 37140-6 0571 for CZPT Land Cruiser 90-06
37140-60480 for CZPT 4Runner 03-09 37140-60540 for CZPT Land Cruiser 90-07
37110-6A440 for CZPT 4Runner 03-09 37110-60450 for CZPT Land Cruiser 90-92
37140-60380 for CZPT 4Runner 10-18 37110-6571 for CZPT Land Cruiser 90-99
37140-35060 for CZPT 4Runner 88-95 37140-65710 for CZPT Land Cruiser 90-99
65-9919 for CZPT 4Runner 89-95 37110-60460 for CZPT Land Cruiser 91-97
37140-35090 for CZPT 4Runner 89-95 37110-60520 for CZPT Land Cruiser 92-97
37140-35071 for CZPT 4Runner 90-92 37110-6A620 for CZPT Land Cruiser 98-07
37140-35130 for CZPT 4Runner 96-00 37110-6A250 for CZPT Land Cruiser 99-00
936-711 for CZPT 4Runner 96-02 37110-6A310 for CZPT Land Crusier
37110-6571 for CZPT 4Runner 96-20 37110-6A610 for CZPT Land Crusier 98-02
37110-3D300 for CZPT 4Runner 96-20 65-9375 for CZPT Pickup 79-83
37110-3D060 for CZPT 4Runner 97-02 37140-35013 for CZPT Pickup 80-83
37140-35190 for CZPT 4Runner 99-02 65-9376 for CZPT Pickup 84-87
37120-30390 for CZPT Crown 65-9842 for CZPT Previa 91-97
37100-48571 for CZPT Highlander 01-07 37100-42060 for CZPT RAV4 01-05
37100-48030 for CZPT Highlander 08-14 37100-42090 for CZPT RAV4 06-16
37110-60A20 for CZPT Hilux 37110-34120 for CZPT Sequoia 07
37140-0K571 for CZPT Hilux 37100-45571 for CZPT Sienna 04-10
37100-0K181 for CZPT Hilux 37100-45571 for CZPT SIENNA 2011-2018
37140-0K030 for CZPT Hilux 05-11 936-728 for CZPT Tacoma 05-15
37100-0K091 for CZPT Hilux 05-15 37100-5712 for CZPT Tacoma 07-14
37100-0K081 for CZPT Hilux 05-15 936-708 for CZPT Tacoma 2.7L 99-04
37100-0K480 for CZPT Hilux 2571 37100-35750 for CZPT Tacoma 2004
37140-35030 for CZPT Hilux 93-95 37100-5712 for CZPT Tacoma 2011-2015
37100-0K030 for CZPT Hilux 05- 936-738 for CZPT Tacoma 4.0L 05-15
37110-60330 for CZPT HJ60 82-84 37100-3D240 for CZPT Tacoma 95-04
371002A190 for CZPT JZX100 96-00 37140-35180 for CZPT Tacoma 95-04
37140-60121 for CZPT Land Cruiser 37100-35820 for CZPT Tacoma 95-99
37140-65710 for CZPT Land Cruiser 37100-3D250 for CZPT Tacoma 98-04
37140-65710 for CZPT Land Cruiser 37100-3D260 for CZPT Tacoma 99-04
37140-60320 for CZPT Land Cruiser 936-717 for CZPT Tundra 04
37140-60330 for CZPT Land Cruiser 37100-34130 for CZPT Tundra 05-06
37140-6571 for CZPT Land Cruiser 65-9257 for CZPT Tundra 2001-2004
37140-60430 for CZPT Land Cruiser 37100-34120 for CZPT Tundra 4.7L 05-06
37140-60450 for CZPT Land Cruiser 37110-6A430 for CZPT Land Cruiser 00-02
37140-6A610 for CZPT Land Cruiser 37140-6571 for CZPT Land Cruiser 02-09
37140-60080 for CZPT Land Cruiser 37110-60A50 for CZPT Land Cruiser 07
37110-60620 for CZPT Land Cruiser  37140-60590 for CZPT Land Cruiser 08-15
37110-6A260 for CZPT Land Cruiser  37140-60090 for CZPT Land Cruiser 74-80

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

|
Request Sample

Customization:
Available

|

Customized Request

pto shaft

Are there any limitations or disadvantages associated with drive shafts?

While drive shafts are widely used and offer several advantages, they also have certain limitations and disadvantages that should be considered. Here’s a detailed explanation of the limitations and disadvantages associated with drive shafts:

1. Length and Misalignment Constraints:

Drive shafts have a maximum practical length due to factors such as material strength, weight considerations, and the need to maintain rigidity and minimize vibrations. Longer drive shafts can be prone to increased bending and torsional deflection, leading to reduced efficiency and potential driveline vibrations. Additionally, drive shafts require proper alignment between the driving and driven components. Misalignment can cause increased wear, vibrations, and premature failure of the drive shaft or its associated components.

2. Limited Operating Angles:

Drive shafts, especially those using U-joints, have limitations on operating angles. U-joints are typically designed to operate within specific angular ranges, and operating beyond these limits can result in reduced efficiency, increased vibrations, and accelerated wear. In applications requiring large operating angles, constant velocity (CV) joints are often used to maintain a constant speed and accommodate greater angles. However, CV joints may introduce higher complexity and cost compared to U-joints.

3. Maintenance Requirements:

Drive shafts require regular maintenance to ensure optimal performance and reliability. This includes periodic inspection, lubrication of joints, and balancing if necessary. Failure to perform routine maintenance can lead to increased wear, vibrations, and potential driveline issues. Maintenance requirements should be considered in terms of time and resources when using drive shafts in various applications.

4. Noise and Vibration:

Drive shafts can generate noise and vibrations, especially at high speeds or when operating at certain resonant frequencies. Imbalances, misalignment, worn joints, or other factors can contribute to increased noise and vibrations. These vibrations may affect the comfort of vehicle occupants, contribute to component fatigue, and require additional measures such as dampers or vibration isolation systems to mitigate their effects.

5. Weight and Space Constraints:

Drive shafts add weight to the overall system, which can be a consideration in weight-sensitive applications, such as automotive or aerospace industries. Additionally, drive shafts require physical space for installation. In compact or tightly packaged equipment or vehicles, accommodating the necessary drive shaft length and clearances can be challenging, requiring careful design and integration considerations.

6. Cost Considerations:

Drive shafts, depending on their design, materials, and manufacturing processes, can involve significant costs. Customized or specialized drive shafts tailored to specific equipment requirements may incur higher expenses. Additionally, incorporating advanced joint configurations, such as CV joints, can add complexity and cost to the drive shaft system.

7. Inherent Power Loss:

Drive shafts transmit power from the driving source to the driven components, but they also introduce some inherent power loss due to friction, bending, and other factors. This power loss can reduce overall system efficiency, particularly in long drive shafts or applications with high torque requirements. It is important to consider power loss when determining the appropriate drive shaft design and specifications.

8. Limited Torque Capacity:

While drive shafts can handle a wide range of torque loads, there are limits to their torque capacity. Exceeding the maximum torque capacity of a drive shaft can lead to premature failure, resulting in downtime and potential damage to other driveline components. It is crucial to select a drive shaft with sufficient torque capacity for the intended application.

Despite these limitations and disadvantages, drive shafts remain a widely used and effective means of power transmission in various industries. Manufacturers continuously work to address these limitations through advancements in materials, design techniques, joint configurations, and balancing processes. By carefully considering the specific application requirements and potential drawbacks, engineers and designers can mitigate the limitations and maximize the benefits of drive shafts in their respective systems.

pto shaft

How do drive shafts handle variations in load and vibration during operation?

Drive shafts are designed to handle variations in load and vibration during operation by employing various mechanisms and features. These mechanisms help ensure smooth power transmission, minimize vibrations, and maintain the structural integrity of the drive shaft. Here’s a detailed explanation of how drive shafts handle load and vibration variations:

1. Material Selection and Design:

Drive shafts are typically made from materials with high strength and stiffness, such as steel alloys or composite materials. The material selection and design take into account the anticipated loads and operating conditions of the application. By using appropriate materials and optimizing the design, drive shafts can withstand the expected variations in load without experiencing excessive deflection or deformation.

2. Torque Capacity:

Drive shafts are designed with a specific torque capacity that corresponds to the expected loads. The torque capacity takes into account factors such as the power output of the driving source and the torque requirements of the driven components. By selecting a drive shaft with sufficient torque capacity, variations in load can be accommodated without exceeding the drive shaft’s limits and risking failure or damage.

3. Dynamic Balancing:

During the manufacturing process, drive shafts can undergo dynamic balancing. Imbalances in the drive shaft can result in vibrations during operation. Through the balancing process, weights are strategically added or removed to ensure that the drive shaft spins evenly and minimizes vibrations. Dynamic balancing helps to mitigate the effects of load variations and reduces the potential for excessive vibrations in the drive shaft.

4. Dampers and Vibration Control:

Drive shafts can incorporate dampers or vibration control mechanisms to further minimize vibrations. These devices are typically designed to absorb or dissipate vibrations that may arise from load variations or other factors. Dampers can be in the form of torsional dampers, rubber isolators, or other vibration-absorbing elements strategically placed along the drive shaft. By managing and attenuating vibrations, drive shafts ensure smooth operation and enhance overall system performance.

5. CV Joints:

Constant Velocity (CV) joints are often used in drive shafts to accommodate variations in operating angles and to maintain a constant speed. CV joints allow the drive shaft to transmit power even when the driving and driven components are at different angles. By accommodating variations in operating angles, CV joints help minimize the impact of load variations and reduce potential vibrations that may arise from changes in the driveline geometry.

6. Lubrication and Maintenance:

Proper lubrication and regular maintenance are essential for drive shafts to handle load and vibration variations effectively. Lubrication helps reduce friction between moving parts, minimizing wear and heat generation. Regular maintenance, including inspection and lubrication of joints, ensures that the drive shaft remains in optimal condition, reducing the risk of failure or performance degradation due to load variations.

7. Structural Rigidity:

Drive shafts are designed to have sufficient structural rigidity to resist bending and torsional forces. This rigidity helps maintain the integrity of the drive shaft when subjected to load variations. By minimizing deflection and maintaining structural integrity, the drive shaft can effectively transmit power and handle variations in load without compromising performance or introducing excessive vibrations.

8. Control Systems and Feedback:

In some applications, drive shafts may be equipped with control systems that actively monitor and adjust parameters such as torque, speed, and vibration. These control systems use sensors and feedback mechanisms to detect variations in load or vibrations and make real-time adjustments to optimize performance. By actively managing load variations and vibrations, drive shafts can adapt to changing operating conditions and maintain smooth operation.

In summary, drive shafts handle variations in load and vibration during operation through careful material selection and design, torque capacity considerations, dynamic balancing, integration of dampers and vibration control mechanisms, utilization of CV joints, proper lubrication and maintenance, structural rigidity, and, in some cases, control systems and feedback mechanisms. By incorporating these features and mechanisms, drive shafts ensure reliable and efficient power transmission while minimizing the impact of load variations and vibrations on overall system performance.

pto shaft

Are there variations in drive shaft designs for different types of machinery?

Yes, there are variations in drive shaft designs to cater to the specific requirements of different types of machinery. The design of a drive shaft is influenced by factors such as the application, power transmission needs, space limitations, operating conditions, and the type of driven components. Here’s an explanation of how drive shaft designs can vary for different types of machinery:

1. Automotive Applications:

In the automotive industry, drive shaft designs can vary depending on the vehicle’s configuration. Rear-wheel-drive vehicles typically use a single-piece or two-piece drive shaft, which connects the transmission or transfer case to the rear differential. Front-wheel-drive vehicles often use a different design, employing a drive shaft that combines with the constant velocity (CV) joints to transmit power to the front wheels. All-wheel-drive vehicles may have multiple drive shafts to distribute power to all wheels. The length, diameter, material, and joint types can differ based on the vehicle’s layout and torque requirements.

2. Industrial Machinery:

Drive shaft designs for industrial machinery depend on the specific application and power transmission requirements. In manufacturing machinery, such as conveyors, presses, and rotating equipment, drive shafts are designed to transfer power efficiently within the machine. They may incorporate flexible joints or use a splined or keyed connection to accommodate misalignment or allow for easy disassembly. The dimensions, materials, and reinforcement of the drive shaft are selected based on the torque, speed, and operating conditions of the machinery.

3. Agriculture and Farming:

Agricultural machinery, such as tractors, combines, and harvesters, often requires drive shafts that can handle high torque loads and varying operating angles. These drive shafts are designed to transmit power from the engine to attachments and implements, such as mowers, balers, tillers, and harvesters. They may incorporate telescopic sections to accommodate adjustable lengths, flexible joints to compensate for misalignment during operation, and protective shielding to prevent entanglement with crops or debris.

4. Construction and Heavy Equipment:

Construction and heavy equipment, including excavators, loaders, bulldozers, and cranes, require robust drive shaft designs capable of transmitting power in demanding conditions. These drive shafts often have larger diameters and thicker walls to handle high torque loads. They may incorporate universal joints or CV joints to accommodate operating angles and absorb shocks and vibrations. Drive shafts in this category may also have additional reinforcements to withstand the harsh environments and heavy-duty applications associated with construction and excavation.

5. Marine and Maritime Applications:

Drive shaft designs for marine applications are specifically engineered to withstand the corrosive effects of seawater and the high torque loads encountered in marine propulsion systems. Marine drive shafts are typically made from stainless steel or other corrosion-resistant materials. They may incorporate flexible couplings or dampening devices to reduce vibration and mitigate the effects of misalignment. The design of marine drive shafts also considers factors such as shaft length, diameter, and support bearings to ensure reliable power transmission in marine vessels.

6. Mining and Extraction Equipment:

In the mining industry, drive shafts are used in heavy machinery and equipment such as mining trucks, excavators, and drilling rigs. These drive shafts need to withstand extremely high torque loads and harsh operating conditions. Drive shaft designs for mining applications often feature larger diameters, thicker walls, and specialized materials such as alloy steel or composite materials. They may incorporate universal joints or CV joints to handle operating angles, and they are designed to be resistant to abrasion and wear.

These examples highlight the variations in drive shaft designs for different types of machinery. The design considerations take into account factors such as power requirements, operating conditions, space constraints, alignment needs, and the specific demands of the machinery or industry. By tailoring the drive shaft design to the unique requirements of each application, optimal power transmission efficiency and reliability can be achieved.

China factory 37100-04342 for CHINAMFG Tacoma 07-14 Propshaft Tail Shaft Drive Shaft Manufacturer  China factory 37100-04342 for CHINAMFG Tacoma 07-14 Propshaft Tail Shaft Drive Shaft Manufacturer
editor by CX 2024-05-16