Product Description
Products: Free Forging and Open Die Forging factory.
Our factory:
A. More than 25 years of professional free forging and open-die forging manufacturing experience
B. The company covers an area of 71,000 square meters
C. The construction area of the production workshop is 12,000 square meters
D. Total number of employees: 158
E. 28 engineering and technical personnel
F. 59 skilled workers
G. Annual production capacity is 38,000 tons
H. Annual raw material steel throughput turnover reaches 56,000 tons
Our Forged Steel Products
Tiangong Forging supplies a variety of semi-finished forged steel products, with the main materials being nickel-molybdenum steel, alloy steel, die steel, stainless steel and carbon steel. In addition to general steel grades such as 35#, 45#, 42CrMo, 42CrMo4, 18CrNiMo7-6, 20CrNi2Mo, 30CrNiMo8 and etc., we can also prepare the required steel according to other national specifications or specified alloy compositions requested by customers.
The maximum production shaft forging length/weight is 12m/15T; the maximum gear and wheel forging diameter/weight is 1.9m/9T.
We are particularly specialized in the forging of special-shaped forging parts.
steel hot forging raw forging gear shaft
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Description |
Steel hot forging raw forging gear shaft |
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Type |
Free forging. |
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Application |
Wind power Transformisson system , machinery and other industry |
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Processing |
Forging+machining+heating Treatment |
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Material |
steel SAE 4340, 4140,C45,42CrMo4,20CrMnTi, |
| Weight Ranges |
0.1kg-50tons |
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Roughness |
Ra0.4 – 0.8 |
Our Certificates:
Our Lab equipment:
Our main Products:
A.Forged Gear Blank
B.Wheel and Pulley
C.Forged Shaft
D.Hollow Shaft
E.Crankshaft
F.Multi-stepped Shaft
G.Various forged blank and block
I. Special-shaped Forging Parts
Application:
Our main customers: ZPMC, NGC and ZheJiang Electric etc.
Our parts are widely used in Chemical Industry, Wind power generator, Large machinery parts Chemical industry,Agricultural machinery parts ship shaft fittings. Wind Power gearbox Transmission system.
HangZhou Port, HangZhou automatic Port, ZheJiang Yang shan Port, Italy Vado port. ZheJiang Tailway crane, Egypt hanging bridge, Sri Lanka railway crane, Thailand port bridge. South Korea railway crane, Hongkong island bridge, Singapore railway crane, Russia oil & mining machines and some miltary project. etc.
Customized solutions
Our modular process allows us to design solutions various industrial application requiring free-forged and open-die-forged parts. Our modularity means flexibility, wide choice, faster delivery and, above all, competitiveness.
All Tiangong Forging, products and production processes are designed to ensure exceptional, reliable and long-lasting unique mechanical properties, thereby reducing operating costs and extending service life.
With an extensive product range and extensive experience gained in most industrial applications, we can also provide engineering advice to our customers.
Welcome to visit our factory! Welcome to send inquiry to us.
Welcom Trading compamy to co-operate.
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| Processing Object: | Metal |
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| Molding Style: | Forging |
| Molding Technics: | Free Forging |
| Samples: |
US$ 1000/Ton
1 Ton(Min.Order) | Order Sample |
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| Customization: |
Available
| Customized Request |
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.shipping-cost-tm .tm-status-off{background: none;padding:0;color: #1470cc}
| Shipping Cost:
Estimated freight per unit. |
about shipping cost and estimated delivery time. |
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| Payment Method: |
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Initial Payment Full Payment |
| Currency: | US$ |
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| Return&refunds: | You can apply for a refund up to 30 days after receipt of the products. |
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What is the relationship between the axle spindle and the wheel bearing in a vehicle?
In a vehicle, the axle spindle and the wheel bearing are two interconnected components that work together to allow the wheel to rotate smoothly and support the vehicle’s weight. Here’s a detailed explanation of their relationship:
The axle spindle is a key part of the vehicle’s suspension system, specifically in the axle assembly. It is a shaft-like component that protrudes from the axle housing and provides support for the wheel assembly. The spindle is typically located at the center of the wheel hub and serves as a mounting point for various components, including the wheel bearing.
The wheel bearing, on the other hand, is a set of precision-engineered bearings that are usually housed within a hub assembly. It is responsible for reducing friction and facilitating the smooth rotation of the wheel. The wheel bearing allows the wheel to spin freely while supporting the weight of the vehicle and enduring the forces generated during acceleration, braking, and cornering.
The relationship between the axle spindle and the wheel bearing is one of integration and mutual dependency. The axle spindle provides the structural support and attachment point for the wheel bearing assembly. The wheel bearing, in turn, enables the wheel to rotate with minimal friction and provides load-bearing capability.
When the vehicle is in motion, the axle spindle transfers the weight of the vehicle and the forces generated by the road surface to the wheel bearing. The wheel bearing, with its lubricated bearings and races, allows the wheel to rotate smoothly and evenly distribute the applied forces. This relationship ensures that the wheel assembly operates effectively, providing stability, control, and a comfortable ride.
Over time, the wheel bearing may experience wear and tear due to continuous use, exposure to contaminants, or lack of proper maintenance. When a wheel bearing becomes worn or damaged, it can lead to various symptoms such as excessive noise, vibration, uneven tire wear, or even wheel detachment. In such cases, it is necessary to replace the wheel bearing assembly, which often involves disassembling the axle spindle to access and replace the bearing.
It’s important to note that the specific design and configuration of the axle spindle and wheel bearing can vary between different vehicle models and manufacturers. Some vehicles may have integrated wheel bearing and hub assemblies, while others may have separate components that are assembled onto the spindle. It is recommended to consult the vehicle’s repair manual or seek professional assistance for specific instructions and procedures related to your vehicle.
In summary, the axle spindle and the wheel bearing have a close relationship in a vehicle’s suspension system. The axle spindle provides structural support and serves as the mounting point for the wheel bearing assembly. The wheel bearing, in turn, allows the wheel to rotate smoothly, supports the vehicle’s weight, and helps absorb the forces generated during driving. Understanding this relationship is important for proper maintenance, repair, and replacement of the wheel bearing assembly.
Can changes in the vehicle’s ride height impact the angles and performance of axle spindles?
Yes, changes in the vehicle’s ride height can indeed impact the angles and performance of axle spindles. Here is a detailed explanation:
The ride height of a vehicle refers to the distance between the ground and the chassis or body of the vehicle. It is determined by several factors, including the suspension system, springs, shocks, and overall design. Altering the ride height, either by raising or lowering the vehicle, can have various effects on the angles and performance of the axle spindles.
Here are some ways in which changes in ride height can impact the axle spindles:
- Steering Geometry: The angles and geometry of the steering system are closely linked to the ride height of the vehicle. When the ride height is modified, it can affect the steering angles, such as the caster, camber, and toe. These angles determine how the wheels interact with the road surface and influence the handling, stability, and tire wear. Any alteration to the steering geometry can indirectly impact the axle spindles and their performance.
- Axle Alignment: Changes in ride height can also affect the alignment of the axles. Raising or lowering the vehicle can lead to changes in the relative position and alignment of the front and rear axles. This can introduce changes in the suspension geometry, including the axle angles, which in turn can affect the load distribution, tire contact patch, and overall performance of the axle spindles.
- Components Interference: In some cases, significant changes in ride height can lead to interference issues between suspension components and other parts of the vehicle. For example, lowering the vehicle excessively can cause the axle spindles or other suspension elements to come into contact with the body, frame, or other nearby components. This can result in limited suspension travel, reduced performance, or potential damage to the axle spindles.
- Suspension Travel and Dynamics: Altering the ride height can affect the suspension travel and dynamics of the vehicle. Lowering the ride height typically reduces the suspension’s range of motion, which can impact the ability of the axle spindles to absorb bumps, maintain tire contact with the road, and provide adequate suspension travel. Conversely, raising the ride height can increase the suspension travel but may also affect the vehicle’s center of gravity and stability.
- Ground Clearance: Changes in ride height can impact the vehicle’s ground clearance, which is the distance between the lowest point of the vehicle and the ground. Lowering the ride height reduces ground clearance, potentially increasing the risk of the axle spindles or other undercarriage components scraping or hitting obstacles on the road. This can lead to damage or premature wear of the axle spindles if they come into contact with road hazards.
It’s worth noting that modifying the ride height of a vehicle, particularly beyond the manufacturer’s specifications, can have implications on various aspects of vehicle performance, including the axle spindles. Therefore, it’s important to consider these factors and exercise caution when making ride height adjustments.
If you are considering changing the ride height of your vehicle, it is recommended to consult with knowledgeable professionals or experienced enthusiasts who are familiar with the specific vehicle model and its suspension system. They can provide guidance on appropriate modifications, potential impacts on the axle spindles, and the overall performance and safety of the vehicle.
In summary, changes in a vehicle’s ride height can impact the angles and performance of axle spindles. These changes can affect steering geometry, axle alignment, component interference, suspension travel and dynamics, as well as ground clearance. It’s important to consider these factors and seek expert advice when modifying the ride height to ensure optimal performance and safety of the axle spindles and the vehicle as a whole.
Are there differences between front and rear axle spindles in terms of design and function?
Yes, there are differences between front and rear axle spindles in terms of design and function. Here’s a detailed explanation:
The front and rear axle spindles serve similar purposes in a vehicle’s suspension system, but they have distinct characteristics and functions due to their positions and roles within the vehicle. Here are the key differences between front and rear axle spindles:
- Position: The front axle spindle is located at the front of the vehicle, usually connected to the steering system, while the rear axle spindle is positioned at the rear of the vehicle. The front spindle plays a crucial role in steering the vehicle, while the rear spindle primarily supports the rear wheel assembly.
- Steering Function: The front axle spindle is directly involved in the steering mechanism of the vehicle. It connects to the steering knuckle, which enables the front wheels to turn left or right, allowing the vehicle to change direction. The design of the front spindle incorporates features that facilitate steering, such as the attachment points for tie rods and steering components.
- Load Support: The rear axle spindle is primarily responsible for supporting the weight and load of the rear wheel assembly. It transfers the forces from the wheels to the suspension system and the vehicle chassis. The design of the rear spindle focuses on load-bearing capacity and durability to withstand the forces generated during acceleration, braking, and cornering.
- Drive Function: In vehicles with rear-wheel drive or four-wheel drive systems, the rear axle spindle may also have additional components for transmitting power from the drivetrain to the rear wheels. These components, such as axle shafts, differential gears, and drive flanges, are not typically found in front axle spindles.
- Braking System: Both front and rear axle spindles play a role in the vehicle’s braking system. However, the design and attachment points for brake components can vary between the front and rear spindles. The front spindle may incorporate mounting points for brake calipers and rotors, while the rear spindle may have provisions for brake drums or additional components for parking brake activation.
While there are differences in design and function between front and rear axle spindles, it’s important to note that these variations can also depend on the specific vehicle make, model, and suspension configuration. Different vehicles may have unique spindle designs and features tailored to their specific requirements.
Understanding the distinctions between front and rear axle spindles is important for proper maintenance, repair, and replacement. If you encounter issues with an axle spindle, it’s recommended to consult the vehicle’s manufacturer guidelines or seek assistance from a qualified mechanic or technician who can provide accurate diagnosis and appropriate solutions based on the specific axle spindle in question.
In summary, front and rear axle spindles differ in terms of position, steering function, load support, drive function (in certain cases), and braking system requirements. These differences arise from their respective roles in the vehicle’s suspension and drivetrain systems.
editor by CX 2024-04-24