China factory High Power Transmission Differential Gear for Gear Box helical bevel gear

Product Description

High Power Transmission Differential Gear for Gear Box

1. Description

No. Item Description
1 Name Straight Gear
2 Size Products can be customized.
3 Manufacture Standard 5-8 Grade ISO1328-1997.
4 Material 45#Steel,20CrMnTi,40Cr,20CrNiMo,20MnCr5,GCR15SiMn,42CrMo,2Cr13stainless steel,Nylon,Bakelite,Copper,Aluminium.etc
5 Production Process The main process is Gear Hobbing, Gear Shaping and Gear Grinding, Selecting production process according to the different products.
6 Heat Treatment Carburizing and quenching ,High-frequency quenching,Nitriding, Hardening and tempering, Selecting heat treatment according to the different materials.
7 Testing Equipment Rockwell hardness tester 500RA, Double mesh instrument HD-200B & 3102,Gear measurement center instrument CNC3906T and other High precision detection equipments
8 Certification GB/T19001-2016/ISO9001:2015
9 Usage Used in printing machine, cleaning machine, medical equipment, garden machine, construction machine, electric car, valve, forklift, transportation equipment and various gear reducers.etc
10 Package According to customer’s request

 

No. Item Description
1 Name Differential Gear
2 Size Products can be customized.
3 Testing Equipment Rockwell hardness tester 500RA, Double mesh instrument HD-200B & 3102,Gear measurement center instrument CNC3906T and other High precision detection equipments
4 Certification GB/T19001-2016/ISO9001:2015
5 Usage Used in printing machine, cleaning machine, medical equipment, garden machine, construction machine, electric car, valve, forklift, transportation equipment and various gear reducers.etc
6 Package According to customer’s request

 

2. Photos

 

 

3. Order process
a. Customer sends us the drawing or sample, If only sample, our company supply the CAD drawing.
b. Our company supplies the processing technique and quotation.
c. Our company supplies the sample after customer confirmed processing technique and quotation.
d. Customer places the order after confirm the sample.
e. Customer pay 50% deposit
f. Quantity production.
g. Pay the balance after the acceptance and confirmation.
h. Delivery.

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Application: Electric Cars, Machinery, Agricultural Machinery, Industry
Hardness: Hardened
Gear Position: External Gear
Manufacturing Method: Assembling
Toothed Portion Shape: Involute
Material: Carbon Steel, Stainless Steel, Plasitc, POM, Alumi
Samples:
US$ 20/Piece
1 Piece(Min.Order)

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Request Sample

Customization:
Available

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Customized Request

differential gear

How does a differential gear distribute power between the wheels?

A differential gear is responsible for distributing power between the wheels of a vehicle, allowing them to rotate at different speeds while maintaining torque transfer. Here’s a detailed explanation of how a differential gear accomplishes this:

1. Power Input:

The differential gear receives power from the transmission or driveshaft connected to the engine. This power is transmitted to the differential assembly, which is typically located in the axle housing.

2. Ring and Pinion Gears:

Within the differential assembly, the power from the driveshaft is transferred to the ring and pinion gears. The ring gear is a large gear that surrounds the differential assembly, while the pinion gear is a smaller gear connected to the driveshaft. The interaction between these gears allows the power to be redirected.

3. Side Gears and Spider Gears:

The ring gear is connected to side gears, also known as bevel gears, through a set of small gears called spider gears. The side gears are attached to the axle shafts, which are responsible for transmitting power to the wheels. The spider gears allow the side gears to rotate independently of each other while maintaining torque transfer.

4. Differential Action:

As the vehicle moves, the differential gears enable the wheels to rotate at different speeds during turns. When the vehicle is moving in a straight line, the spider gears rotate smoothly, allowing equal power distribution to both wheels. However, during a turn, the inside wheel travels a shorter distance than the outside wheel, causing them to rotate at different speeds.

5. Speed and Torque Distribution:

The differential gear adjusts the speed and torque distribution between the wheels based on their rotational differences. When the vehicle is turning, the spider gears allow one wheel to rotate faster than the other, ensuring that torque is transferred to the wheel with better traction. This allows the wheels to rotate at different speeds, preventing tire scrubbing and providing smooth cornering.

6. Limited-Slip and Locking Differentials:

In certain differential systems, such as limited-slip differentials or locking differentials, additional mechanisms are incorporated to enhance traction and power distribution. Limited-slip differentials use clutch packs or friction plates to provide a predetermined amount of resistance, allowing some speed differentiation between the wheels while still transferring power. Locking differentials, on the other hand, lock the side gears together, ensuring equal torque distribution to both wheels, regardless of traction conditions.

7. Differential Types:

There are various types of differentials, including open differentials, limited-slip differentials, electronic differentials, torque vectoring differentials, and more. Each type has its own mechanisms and technologies to distribute power between the wheels effectively, depending on the vehicle’s requirements and driving conditions.

In summary, a differential gear distributes power between the wheels by utilizing a system of gears, including ring and pinion gears, side gears, and spider gears. The differential action allows the wheels to rotate at different speeds during turns, ensuring smooth cornering and preventing tire scrubbing. Additional mechanisms, such as limited-slip or locking differentials, can further enhance traction and power distribution in various driving conditions.

differential gear

How do differential gears affect fuel efficiency in vehicles?

In vehicles, differential gears can have an impact on fuel efficiency. Here’s a detailed explanation of how differential gears affect fuel efficiency:

  • Gear Ratio: The gear ratio of the differential can affect fuel efficiency. A higher gear ratio (numerically lower) allows the engine to run at lower RPMs for a given speed, which can result in improved fuel efficiency. This is because the engine operates more efficiently in its lower RPM range, consuming less fuel. On the other hand, a lower gear ratio (numerically higher) can provide better acceleration and performance but may result in higher fuel consumption.
  • Friction and Efficiency Losses: Differential gears introduce friction and mechanical losses in the drivetrain. As power is transmitted from the engine to the wheels through the differential, some energy is lost due to friction in the gears, bearings, and other components. These frictional losses reduce overall efficiency and can have a slight impact on fuel consumption. However, modern differentials are designed with efficiency in mind, and advancements in lubrication, materials, and manufacturing techniques help minimize these losses.
  • Limited-Slip Differentials (LSD): Limited-slip differentials (LSDs) can have a minor effect on fuel efficiency compared to open differentials. LSDs use additional mechanisms to distribute torque between wheels, resulting in a slight increase in mechanical losses and energy consumption. However, the impact on fuel efficiency is generally minimal and may not be noticeable in everyday driving situations.
  • Driving Style and Traction: The traction characteristics of differential gears can indirectly influence fuel efficiency. In slippery conditions or situations where wheelspin occurs, open differentials may allow excessive power to be lost in wheel slip, resulting in reduced traction and poorer fuel efficiency. Limited-slip differentials or advanced traction control systems can minimize wheel slip and improve overall traction, leading to better fuel efficiency by reducing power wastage.
  • Vehicle Type and Design: The impact of differential gears on fuel efficiency can vary depending on the vehicle type and design. Factors such as weight, aerodynamics, tire type, transmission, and overall drivetrain configuration play a significant role in determining fuel efficiency. While differential gears are a part of the drivetrain, their influence on fuel efficiency needs to be considered in conjunction with other vehicle characteristics.

In summary, differential gears can affect fuel efficiency in vehicles primarily through their gear ratio, friction and efficiency losses, and traction characteristics. While the impact on fuel efficiency is generally modest, optimizing the gear ratio and minimizing frictional losses can contribute to improved fuel economy. Additionally, the traction benefits provided by limited-slip differentials or advanced traction control systems can indirectly enhance fuel efficiency by reducing power wastage in wheel slip situations.

differential gear

What is a locking differential, and when is it used?

A locking differential is a specialized type of differential gear that provides maximum traction in challenging driving conditions. Here’s a detailed explanation:

Definition:

A locking differential, also known as a locker, is a mechanism that locks the rotation of the two wheels on an axle together, ensuring they both receive equal torque simultaneously. Unlike open differentials or limited-slip differentials, which allow the wheels to rotate at different speeds, a locking differential forces both wheels to turn together, regardless of traction conditions.

Function:

The primary function of a locking differential is to maximize traction. By mechanically linking the two wheels on an axle, a locking differential ensures that both wheels receive an equal amount of torque, regardless of the traction available to each wheel. This feature is particularly useful in off-road or extreme driving conditions where maintaining traction on all wheels is crucial.

Usage:

A locking differential is typically used in situations where improved traction is essential. Here are some scenarios where a locking differential is commonly employed:

1. Off-Road Driving:

Off-road enthusiasts often encounter challenging terrains with uneven surfaces, deep mud, rocks, or slippery conditions. In these situations, a locking differential can provide maximum traction by ensuring that both wheels on an axle rotate together. This helps prevent wheel spin and increases the likelihood of successfully navigating through difficult obstacles.

2. Rock Crawling:

Rock crawling involves traversing over large rocks and boulders, where maintaining traction is crucial. A locking differential allows both wheels to maintain contact with the ground simultaneously, providing better grip and stability. This enables the vehicle to crawl over rocks with minimal wheel spin and improved control.

3. Towing and Hauling:

When towing or hauling heavy loads, a locking differential can enhance traction and stability. The additional torque applied to both wheels helps prevent wheel slip and provides better power transfer to the ground. This is particularly useful in situations where the load may affect weight distribution and traction on the drive wheels.

4. Extreme Weather Conditions:

In certain weather conditions such as deep snow, ice, or mud, a locking differential can offer improved traction. By ensuring that both wheels on an axle rotate together, a locking differential helps mitigate wheel slip and enhances the vehicle’s ability to maintain forward momentum even in low-traction environments.

5. Off-Road Racing:

In off-road racing, where high-performance vehicles face demanding terrains and aggressive maneuvers, locking differentials are often utilized. The maximum traction provided by a locking differential allows for better acceleration, cornering, and overall performance in challenging racing conditions.

It’s important to note that while a locking differential offers superior traction, it can also negatively impact handling and maneuverability on paved surfaces. Due to the locked wheel rotation, turning becomes more difficult, and tire scrubbing may occur. Therefore, locking differentials are predominantly used in specialized applications or off-road vehicles designed for demanding environments.

In summary, a locking differential is a mechanism that locks the rotation of both wheels on an axle together, maximizing traction in challenging driving conditions. It is commonly used in off-road driving, rock crawling, towing and hauling, extreme weather conditions, and off-road racing, where maintaining traction is crucial for performance and stability.

China factory High Power Transmission Differential Gear for Gear Box helical bevel gearChina factory High Power Transmission Differential Gear for Gear Box helical bevel gear
editor by CX 2024-03-27