Product Description
1.Semi trailer axles:
| Model | Capacity | Brake size | PCD | CBD | BEARING | Beam size | Track | Wheel size | Wheel fixing |
| UTT13 | 13T | 420X180 | 335 | 281 | 32216/32218 | 150 | 1850 | 7.5V-20 | ISO |
| UTT20 | 20t | 420X220 | 335 | 281 | 32220/32218 | 150 | 1850 | 7.5V-20 | ISO |
| Axle Type | Capacity | Brake | Bearing | Axle Beam | Track L1 | Distance of Spring L2 | Distance of Brake Chamber L3 | Wheel Fixing | Total Length L4 | Weight | Recommend Wheel | ||
| Stud | P.C.D | φA Pilot Hole Diameter | |||||||||||
| t | mm | mm | mm | mm | mm | mm | mm | kg | |||||
| UTS08U11T1 | 8 | S420×150 | 518445/10 | ○140 | 1939 | 671 | 1259 | 10-M22×1.5 ISO | 335 | 281 | ≈2237 | ≈385 | 7.50V-20, ET=165 |
| 33213 | |||||||||||||
| UTS10U11 | 10 | S420×150 | 518445/10 | ○140 | 2335 | 1695 | 511 | 10-M22×1.5 ISO | 335 | 281 | ≈2733 | ≈400 | 7.50V-20, ET=165 |
| 33213 | |||||||||||||
| UTD11Y10 | 11 | S311×190 | 518445/10 | ○127 | 1850 | 1000 | 450 | 10-M22×1.5 ISO | 225 | 176 | 2154 | 292 | 6.5-15, 17.5×6.75 |
| 33213 | |||||||||||||
| UTD11Y10T1 | 11 | S311×190 | 518445/10 | ○127 | 1950 | 1110 | 550 | 10-M22×1.5 ISO | 225 | 176 | 2254 | 296 | 6.5-15, 17.5×6.75 |
| 33213 | |||||||||||||
| UTD12F21TA | 12 | S410×180 | 683/672 | ○150 | 1840 | 940 | – | 10-M22×1.5 ISO | 335 | 281 | 7.50V-20 | ||
| 32217 | |||||||||||||
| UTD12F21AL | 12 | S410×180 | 683/672 | ○150 | 1840 | 940 | – | 10-M22×1.5 ISO | 335 | 281 | 7.50V-20 | ||
| 580/572 | |||||||||||||
| UTD08Y11 | 8 | S420×150 | 33215 | ○127 | 1850 | 1080 | 428 | 10-M22×1.5 ISO | 335 | 281 | ≈2145 | ≈323 | 7.50V-20 |
| 33213 | |||||||||||||
| UTD08Y11T1 | 8 | S420×150 | 33215 | ○127 | 2050 | 1280 | 628 | 10-M22×1.5 ISO | 335 | 281 | ≈2345 | ≈333 | 7.50V-20 |
| 33213 | |||||||||||||
| UTD12Y11 | 12 | S420×180 | 33215 | ○127 | 1820 | 950 | 365 | 10-M22×1.5 ISO | 335 | 281 | ≈2170 | ≈365 | 7.50V-20 |
| 33213 | |||||||||||||
| UTD12Y21 | 12 | S420×180 | 518445/10 | ○127 | 1820 | 950 | 365 | 10-M22×1.5 ISO | 335 | 176 | ≈2170 | ≈365 | 7.50V-20 |
| UTD12Y21T3 | 12 | S420×180 | 518445/10 | ○127 | 1850 | 1571 | 395 | 10-M22×1.5 ISO | 335 | 176 | ≈2200 | ≈382 | 7.50V-20 |
| UTD12Y21T4 | 12 | S420×180 | 518445/10 | ○127 | 2050 | 1210 | 595 | 10-M22×1.5 ISO | 335 | 281 | ≈2400 | ≈391 | 7.50V-20 |
| UTD12K11 | 12 | S420×180 | 518445/10 | ○127 | 1820 | 950 | 364 | 10-M22×1.5 ISO | 335 | 281 | ≈2170 | ≈365 | 7.50V-20 |
| UTD12K20 | 12 | S420×180 | 518445/10 | ○127 | 1820 | 950 | 374 | 10-M22×1.5 ISO | 285.75 | 221 | ≈2170 | ≈359 | 7.50V-20 |
| UTD13F11(A) | 13 | S420×180 | 518445/10 | ○150 | 1840 | 940 | 385 | 10-M22×1.5 ISO | 335 | 281 | ≈2170 | ≈382 | 7.50V-20 |
| UTD13F28(A) | 13 | S420×180 | 518445/10 | ○150 | 1840 | 940 | 385 | 8-M20×1.5 JIS | 285 | 221 | ≈2170 | ≈373 | 7.50V-20 |
| UTD13F21(A) | 13 | S420×180 | 518445/10 | ○150 | 1840 | 940 | 385 | 10-M22×1.5 ISO | 335 | 281 | ≈2170 | ≈390 | 7.50V-20 |
| UTD14F11T | 14 | S420×220 | 518445/10 | ○150 | 1840 | 940 | 348 | 10-M22×1.5 ISO | 335 | 281 | ≈2192 | ≈408 | 8.00V-20 |
| UTD15F11(A) | 15 | S420×180 | 220149/10 | ○150 | 1840 | 940 | 381 | 10-M22×1.5 ISO | 335 | 281 | ≈2200 | ≈411 | 8.00V-20 |
| 518445/10 | |||||||||||||
| UTD16F11(A) | 16 | S420×220 | 220149/10 | ○150 | 1850 | 940 | 353 | 10-M22×1.5 ISO | 335 | 281 | ≈2210 | ≈438 | 8.50V-20 |
| 518445/10 | |||||||||||||
| UTD20F13 | 20 | S420×220 | 32222 | ○150 | 1850 | 940 | 353 | 10-M24×1.5 ISO | 335 | 281 | ≈2256 | ≈466 | 8.50V-20 |
| 518445/10 | |||||||||||||
.Optional track length available.
2.Semi trailer axle factory:
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| Type: | Axle |
|---|---|
| Certification: | ISO/TS16949, DOT, ISO |
| Loading Weight: | 13tons |
| ABS: | Without ABS |
| Tent Type: | Simple |
| Axle Number: | 3 |
| Customization: |
Available
| Customized Request |
|---|
Are there guidelines for choosing the right axle for towing heavy loads?
When it comes to towing heavy loads, selecting the appropriate axle is crucial for ensuring safe and efficient towing performance. While the specific guidelines may vary depending on the vehicle and towing requirements, there are general considerations to keep in mind when choosing the right axle. Here’s a detailed explanation of the guidelines for selecting the right axle for towing heavy loads:
Gross Axle Weight Rating (GAWR):
One of the primary factors to consider is the Gross Axle Weight Rating (GAWR) provided by the vehicle manufacturer. The GAWR specifies the maximum weight that an axle is designed to support safely. It is essential to ensure that the selected axle’s GAWR is sufficient to handle the anticipated weight of the loaded trailer and any additional cargo or passengers in the towing vehicle. Exceeding the GAWR can lead to axle failure, compromised handling, and safety risks.
Towing Capacity:
Check the towing capacity of your vehicle, which represents the maximum weight that the vehicle is rated to tow. The axle’s capacity should align with the towing capacity to ensure safe and efficient towing. Consider the type and size of the trailer you intend to tow, including its loaded weight, tongue weight, and any weight distribution considerations. The axle should be capable of handling the anticipated load without exceeding its capacity.
Matching Axle and Suspension:
The axle and suspension system work together to support the weight of the vehicle and the trailer being towed. It is important to ensure that the axle and suspension are properly matched to provide adequate support and stability. Consider the type of suspension (leaf springs, coil springs, air suspension) and the axle’s design (solid axle, independent suspension) to ensure compatibility and optimal towing performance.
Braking System:
When towing heavy loads, the braking system plays a critical role in maintaining control and safety. Ensure that the axle is equipped with appropriate brakes that can handle the increased load. Consider the type of brakes, such as electric brakes or hydraulic brakes, and their capacity to provide sufficient stopping power for the combined weight of the towing vehicle and trailer.
Weight Distribution:
Proper weight distribution is essential for safe towing. The axle should be selected based on the anticipated weight distribution between the towing vehicle and the trailer. Consider factors like tongue weight and the use of weight distribution hitches or sway control devices to ensure balanced weight distribution and optimal handling characteristics.
Consult Manufacturer Recommendations:
Always refer to the vehicle manufacturer’s recommendations, specifications, and guidelines when selecting an axle for towing heavy loads. The manufacturer’s guidelines will provide accurate and vehicle-specific information to help you make the right choice. Consult the owner’s manual or contact the manufacturer directly for any specific towing-related recommendations.
It’s important to note that towing requirements and axle specifications can vary depending on the vehicle make and model, as well as regional regulations. It is advisable to consult with automotive experts, such as mechanics or dealerships, who have expertise in towing and can provide specific recommendations based on your vehicle and towing needs.
Can you provide insights into the advancements in axle technology in recent years?
In recent years, there have been significant advancements in axle technology to enhance performance, efficiency, and safety in vehicles. Here are some insights into the key advancements:
- Lightweight Materials:
- Electronic Differential:
- Advanced Axle Bearings:
- Electric Axles:
- Active Suspension Integration:
- Improved Sealing and Lubrication:
- Autonomous Vehicle Integration:
One notable advancement is the use of lightweight materials in axle construction. Manufacturers have increasingly utilized materials such as aluminum alloys and high-strength steels to reduce the weight of axles without compromising strength and durability. Lighter axles contribute to improved fuel efficiency and overall vehicle performance.
Electronic differentials, also known as eDiffs, have gained popularity in recent years. They utilize sensors, actuators, and control algorithms to monitor and distribute torque between the wheels more efficiently. Electronic differentials enhance traction, stability, and handling by actively managing torque distribution, especially in vehicles equipped with advanced stability control systems.
Axle bearings have seen advancements in design and materials to reduce friction, improve efficiency, and enhance durability. For example, the use of roller bearings or tapered roller bearings has become more prevalent, offering reduced frictional losses and improved load-carrying capacity. Some manufacturers have also introduced sealed or maintenance-free bearings to minimize maintenance requirements.
With the rise of electric vehicles (EVs) and hybrid vehicles, electric axles have emerged as a significant technological advancement. Electric axles integrate electric motors, power electronics, and gear systems into the axle assembly. They eliminate the need for traditional drivetrain components, simplify vehicle packaging, and offer benefits such as instant torque, regenerative braking, and improved energy efficiency.
Advancements in axle technology have facilitated the integration of active suspension systems into axle designs. Active suspension systems use sensors, actuators, and control algorithms to adjust the suspension characteristics in real-time, providing improved ride comfort, handling, and stability. Axles with integrated active suspension components offer more precise control over vehicle dynamics.
Axles have seen advancements in sealing and lubrication technologies to enhance durability and minimize maintenance requirements. Improved sealing systems help prevent contamination and retain lubricants, reducing the risk of premature wear or damage. Enhanced lubrication systems with better heat dissipation and reduced frictional losses contribute to improved efficiency and longevity.
The development of autonomous vehicles has spurred advancements in axle technology. Axles are being designed to accommodate the integration of sensors, actuators, and communication systems necessary for autonomous driving. These advancements enable seamless integration with advanced driver-assistance systems (ADAS) and autonomous driving features, ensuring optimal performance and safety.
It’s important to note that the specific advancements in axle technology can vary across different vehicle manufacturers and models. Furthermore, ongoing research and development efforts continue to drive further innovations in axle design, materials, and functionalities.
For the most up-to-date and detailed information on axle technology advancements, it is advisable to consult automotive manufacturers, industry publications, and reputable sources specializing in automotive technology.
Can you explain the importance of axle alignment for vehicle stability and handling?
Axle alignment plays a crucial role in ensuring vehicle stability and handling characteristics. Proper alignment of the axles is essential for maintaining optimal tire contact with the road surface, minimizing tire wear, maximizing traction, and promoting safe and predictable handling. Here are the key reasons why axle alignment is important:
- Tire Wear and Longevity:
- Optimal Traction:
- Steering Response and Stability:
- Reduced Rolling Resistance:
- Vehicle Safety:
Correct axle alignment helps distribute the vehicle’s weight evenly across all four tires. When the axles are properly aligned, the tires wear evenly, reducing the risk of premature tire wear and extending their lifespan. Misaligned axles can cause uneven tire wear patterns, such as excessive wear on the inner or outer edges of the tires, leading to the need for premature tire replacement.
Proper axle alignment ensures that the tires maintain optimal contact with the road surface. When the axles are aligned correctly, the tires can evenly distribute the driving forces, maximizing traction and grip. This is particularly important during acceleration, braking, and cornering, as proper alignment helps prevent tire slippage and improves overall vehicle stability.
Axle alignment directly affects steering response and stability. When the axles are properly aligned, the vehicle responds predictably to driver inputs, providing precise and accurate steering control. Misaligned axles can lead to steering inconsistencies, such as pulling to one side or requiring constant correction, compromising vehicle stability and handling.
Proper axle alignment helps reduce rolling resistance, which is the force required to move the vehicle forward. When the axles are aligned correctly, the tires roll smoothly and effortlessly, minimizing energy loss due to friction. This can contribute to improved fuel efficiency and reduced operating costs.
Correct axle alignment is crucial for ensuring vehicle safety. Misaligned axles can affect the vehicle’s stability, especially during emergency maneuvers or sudden lane changes. Proper alignment helps maintain the intended handling characteristics of the vehicle, reducing the risk of loss of control and improving overall safety.
To achieve proper axle alignment, several key parameters are considered, including camber, toe, and caster angles. Camber refers to the vertical tilt of the wheel when viewed from the front, toe refers to the angle of the wheels in relation to each other when viewed from above, and caster refers to the angle of the steering axis in relation to vertical when viewed from the side. These alignment angles are adjusted to meet the vehicle manufacturer’s specifications and ensure optimal performance.
It’s important to note that factors such as road conditions, driving habits, and vehicle modifications can affect axle alignment over time. Regular maintenance and periodic alignment checks are recommended to ensure that the axles remain properly aligned, promoting vehicle stability, handling, and safety.
editor by CX 2024-02-22