Product Description
We can produce 13ton and 16ton English axle, and we can produce according to your requirement.
1. Capacity: 13ton
2. Brake size: 420*180
3. 8 hole or 10 hole
4. Bearing: 33213 218248
5. Bean size: Squre 150
6. Weight: 350 KGS
| SPECIFICATION FOR AXLE | ||||||||||||
| AXLETYPE | BRAKE SIZE | WHEEL FIXING | DIM D | bearing | MIN WHEEL SIZE | BEAM SIZE | AXLE CAPACITY | SPIRNG SEAT INSTALLATIONE | weight | |||
| NO. × SIZE OF WHEEL STUD× PCD(DIMA) | WHEEL REG. DIA. (DIM B) | |||||||||||
| 218248 | ||||||||||||
| RNY1218J | 420× 180 | JAP | 8× M20× 285 | 281 | 700 | 33213 | 20″ | square150 | 13t | ≤ 450 | 350kg | |
| 218248 | ||||||||||||
| RNY1218B | 420× 180 | BSF | 10× 7/8″ × 335 | 221 | 700 | 33213 | 20″ | square150 | 13t | ≤ 450 | 350kg | |
| 218248 | ||||||||||||
| RNY1222I | 420× 220 | ISO | 10× M22× 335 | 281 | 700 | 33213 | 20″ | square150 | 13t | ≤ 450 | 370kg | |
| 218248 | ||||||||||||
| RNY1622I | 420× 220 | ISO | 10× M22× 335 | 281 | 700 | 218248 | 20″ | square150 | 16t | ≤ 450 | 430kg | |
| 220149 | ||||||||||||
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| After-sales Service: | 1 Year |
|---|---|
| Condition: | New |
| Axle Number: | 1 |
| Application: | Trailer |
| Certification: | CE, ISO |
| Material: | Steel |
| Samples: |
US$ 1000/Piece
1 Piece(Min.Order) | |
|---|
| Customization: |
Available
| Customized Request |
|---|
How does the weight distribution affect the performance of beam axles?
The weight distribution significantly impacts the performance of vehicles equipped with beam axles, and it plays a crucial role in determining their stability and handling characteristics. Here’s how weight distribution affects the performance of beam axles:
1. Balance and Stability:
The even distribution of weight among the vehicle’s axles is essential for maintaining balance and stability. When the weight is evenly distributed, the vehicle is less likely to experience weight shifts that can lead to instability or loss of control, especially during cornering and sudden maneuvers.
2. Oversteer and Understeer:
Weight distribution affects a vehicle’s tendency to oversteer or understeer. Oversteer occurs when the rear of the vehicle loses traction and swings outward during a turn, potentially leading to a loss of control. Understeer happens when the front tires lose traction, causing the vehicle to plow straight ahead rather than following the intended path. Proper weight distribution minimizes the risk of oversteer or understeer, contributing to predictable and safe handling.
3. Traction and Grip:
Weight distribution influences the amount of weight pressing down on each tire. Adequate weight on each tire enhances traction and grip, especially when driving on slippery or uneven surfaces. When too much weight is concentrated on a single axle, it can lead to wheel spin and reduced traction, affecting the vehicle’s performance off-road or in adverse weather conditions.
4. Load-Carrying Capacity:
For vehicles designed to carry heavy loads or passengers, proper weight distribution is critical to ensure that the suspension and beam axles can support the weight without strain. An imbalanced load can lead to premature wear and tear on suspension components, reducing the vehicle’s load-carrying capacity and potentially compromising safety.
5. Maneuverability:
Well-balanced weight distribution improves a vehicle’s maneuverability. It makes the vehicle more responsive to steering inputs, facilitating smoother and more controlled handling. This is particularly important for commercial and utility vehicles that need to navigate through tight spaces or make precise movements.
6. Tire Wear:
Uneven weight distribution can result in uneven tire wear. When one set of tires carries a significantly higher load than the others, those tires may wear out faster, leading to the need for premature replacement. Proper weight distribution helps ensure even tire wear and extends the lifespan of the tires.
Summary:
Weight distribution is a critical factor in optimizing the performance of vehicles equipped with beam axles. Properly balanced weight contributes to stability, predictable handling, enhanced traction, and increased load-carrying capacity. It ensures that the beam axles and suspension components operate efficiently, promoting the vehicle’s safety and overall performance.
What is the history of beam axles in automotive engineering?
The history of beam axles in automotive engineering is rich and spans several decades. Beam axles, also known as solid axles or live axles, have played a crucial role in the development of vehicles. Here’s a brief overview of their history:
Early Automobiles:
When automobiles were first introduced in the late 19th and early 20th centuries, they primarily used beam axles due to their simplicity and reliability. These axles provided a solid platform for mounting the wheels and supporting the vehicle’s weight. Early cars often featured front and rear beam axles connected by leaf springs for a smoother ride.
1920s and 1930s:
During the 1920s and 1930s, beam axles were prevalent in the automotive industry. They were commonly found in both passenger cars and commercial vehicles. The Ford Model T, for example, used beam axles and was one of the most iconic vehicles of that era.
Evolution and Diversification:
As automotive engineering progressed, there was a diversification of suspension systems. While beam axles remained a staple in many vehicles, independent suspension systems began to gain popularity for their improved ride comfort and handling characteristics. Independent front suspension systems, which allowed each wheel to move independently, became a common feature in passenger cars, while beam axles remained popular in trucks and heavy-duty applications due to their load-bearing capacity.
Post-World War II Era:
After World War II, there was a shift toward more advanced suspension systems. Passenger cars increasingly adopted independent suspension, offering a smoother and more comfortable ride. However, beam axles continued to be used in the rear of many vehicles, especially trucks and SUVs, where load-bearing capability and durability were key considerations.
Specialized Applications:
Beam axles found new life in off-road vehicles and heavy-duty trucks, where their durability and ability to handle rough terrain made them ideal choices. In the world of off-roading and 4×4 vehicles, solid axles (a type of beam axle) were preferred for their ruggedness and articulation capabilities.
Modern Use:
Today, beam axles are still used in specific vehicle applications, primarily in the rear suspension of trucks and heavy-duty commercial vehicles. Their load-bearing capacity and durability make them well-suited for these demanding roles. Additionally, some retro-style and classic vehicles may incorporate beam axles to capture the aesthetics and character of older vehicle designs.
In summary, the history of beam axles in automotive engineering is marked by their enduring presence in various vehicle types. While independent suspension systems have gained ground in passenger cars, beam axles continue to thrive in specialized applications, ensuring their relevance in modern automotive design.
What are the advantages and disadvantages of using a beam axle?
A beam axle, also known as a solid axle or live axle, has its own set of advantages and disadvantages, which can make it suitable or less suitable for various vehicle applications:
Advantages of Using a Beam Axle:
- 1. Durability: Beam axles are known for their robust construction and ability to withstand heavy loads and rough terrain. They are commonly used in applications where durability and strength are paramount, such as in heavy-duty trucks and off-road vehicles.
- 2. Cost-Effective: Beam axles are generally simpler and more cost-effective to manufacture and maintain compared to independent suspension systems. This makes them an economical choice for certain vehicle types.
- 3. Load-Carrying Capacity: Vehicles with beam axles have excellent load-carrying capacity, making them suitable for applications that involve transporting heavy goods or towing trailers.
- 4. Articulation (Off-Road): In off-road and 4×4 vehicles, front and rear beam axles provide exceptional articulation, allowing the wheels to maintain contact with uneven terrain, enhancing off-road performance.
- 5. Simplicity: The design of a beam axle is straightforward and lacks complex components, making it easier to maintain and repair.
Disadvantages of Using a Beam Axle:
- 1. Ride Comfort: Vehicles with beam axles often provide a less comfortable ride, especially on uneven road surfaces, as both wheels on the same axle move together in response to bumps and imperfections.
- 2. Reduced Traction: In off-road or slippery conditions, the lack of independent wheel movement can reduce traction, as one wheel’s loss of grip affects the other on the same axle.
- 3. Handling and Stability: Beam axles may result in less precise handling and stability, particularly in high-speed or cornering situations, compared to vehicles with independent suspension.
- 4. Weight: The solid construction of a beam axle can add weight to the vehicle, which can impact fuel efficiency and overall performance.
- 5. Limited Applications: Beam axles are less versatile and are typically used in specific applications, such as rear axles in trucks, off-road vehicles, and some industrial vehicles. They are less common in modern passenger cars due to their limitations in ride comfort and handling.
The choice of whether to use a beam axle or independent suspension depends on the intended use of the vehicle and the trade-offs between durability, load-carrying capacity, ride comfort, and handling characteristics.
editor by CX 2024-05-07