Product Description
| Model No. | all | Material | Metal |
| Warranty | 3 months | Brand | RuiHangZhou |
| Type | parts | Stock | In Stock |
| MOQ | 1 piece | Part Name | engine parts |
| Part Number | all | Transport Package | neutral carton |
| Specification | xugong | Trademark | xugong |
| Origin | ZheJiang | HS Code | 845719990 |
1. We supply both original and CHINAMFG products for you
2. From the manufacturer to the customer directly, saving your cost
3. Stable stock for normal parts
4. In Time Delivery Time, with competitive shipping cost
5. Professional and on time after service
ZheJiang RuiHangZhou Machinery Equipment Co., Ltd. is mainly engaged in engineering machinery and equipment spare parts, oil products, filter elements, and related equipment maintenance services. Currently, we are full-time agents of Cummins, Xihu (West Lake) Dis.feng Motors, and authorized service providers of HangZhou Cummins. Now we are providing spare parts and maintenance services for large domestic mines such as ZheJiang Xihu (West Lake) Dis. Mining, CHINAMFG Copper, and Longmang Mining.Now we have long-term cooperation with China Railway 19th Bureau in China.
We are specialized in the sale of CHINAMFG and CHINAMFG engine parts,Donaldson and Fleetguard filter, and excavator parts: VOLVO,Komatsu,Shantui,XCMG,Liugong,
If you are interested in any of our products, please contact us immediately.
We promise: high quality + reasonable price + fastdelivery!
Due to too many types of spare parts, we cannot display them all on the website. Please feel free to contact us for specific information.
ZC0 0571 13 Y 865716689 803
ZC0 0571 12 Y 865716688 803
ZC0 0571 11 Y 865716687 803
ZC0 0571 10 Y 865716686 803
ZC 86571 3 2521571
ZC 86571 2 25210571
ZC 865716683 803
ZC 86571 9 2521 86571 8 2521 86571 7 2521 86571 6 25210571
ZC 865716678 857111 25210571
ZC 865716677 857110 2521 865716676 80305719 25210571
ZC 86571 8 25210571
ZC 86571 7 2521 86571 3 2521 86571 1 2521 86571 0 2521 86571 8 2521 86571 7 2521 86571 0 2521 865716667 80305719 2521 865716666 80305717 25210571
ZC 865716665 80305716 2521 865716664 80305715 25210571
ZC 865716663 80305713 25210 0571
ZC 865716662 80305712 2521 865716661 80305711 2521 865716660 80305710 25210 0571
——————————————–
Quality guarantee
1)3 months
2)Quality Certification: ISO9002/TS16949
3)100% tested for the accuracy and quality prior to shipment
Features
1)Fast delivery and good after sales service
2)Long Service life
3)High-speed production
4)Flexile and convenient logistic service
5)OEM orders are welcome
If you can’t find what you are looking for, pls contact us and place a customized order. We can produce according to your sample or drawings /* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
| Certification: | ISO9001, TS16949 |
|---|---|
| Standard Component: | Standard Component |
| Technics: | Forging |
| Material: | Iron |
| Type: | Gear |
| Weight: | Standard |
| Customization: |
Available
| Customized Request |
|---|
Can you explain the impact of gear shaft misalignment on gear performance?
Gear shaft misalignment can have a significant impact on the performance of gears within a system. When gear shafts are not properly aligned, several issues can arise, affecting the overall functionality and reliability of the gears. Let’s explore the impact of gear shaft misalignment in detail:
- Reduced Efficiency:
Misalignment causes a loss of efficiency in gear systems. When gear shafts are misaligned, the teeth of the gears do not mesh correctly, leading to increased friction and energy losses. This results in reduced power transmission efficiency, as a portion of the input power is dissipated as heat instead of being effectively transferred through the gears.
- Increased Wear and Fatigue:
Misalignment can lead to uneven contact and loading between gear teeth. This uneven distribution of forces causes localized high-stress areas on the gear teeth, leading to accelerated wear and fatigue. The concentrated stress on specific areas of the teeth can result in pitting, wear, and even tooth breakage over time. Increased wear and fatigue significantly reduce the lifespan of gears and can lead to unexpected failures.
- Noise and Vibration:
Gear shaft misalignment often results in increased noise and vibration levels within the gear system. As the misaligned teeth engage, they generate excessive noise due to impact and increased friction. The vibrations caused by the misalignment can propagate through the gear assembly and the surrounding components, causing additional noise and potentially affecting the performance and lifespan of the entire system.
- Loss of Tooth Contact:
Misalignment can cause a loss of proper tooth contact between the gears. Insufficient tooth contact reduces the load-carrying capacity of the gears and compromises the transmission of torque. The reduced contact area also increases the likelihood of localized stress concentrations, leading to premature wear and failure.
- Overloading and Unbalanced Loads:
Gear shaft misalignment can result in overloading and unbalanced loads on the gears. Misalignment can cause uneven distribution of forces, with some teeth bearing a higher load than others. This can lead to excessive stress on specific gear teeth, potentially exceeding their load-carrying capacity. Over time, the overloading of certain teeth can result in accelerated wear, tooth breakage, and even catastrophic gear failure.
- Seal and Bearing Issues:
Misalignment can also affect the performance of seals and bearings within the gear system. Misaligned gear shafts can create additional radial or axial loads on the bearings, reducing their lifespan and causing premature failure. Seal integrity can also be compromised, leading to leaks and contamination of the gear system, further exacerbating the issues associated with misalignment.
In summary, gear shaft misalignment has a detrimental impact on gear performance. It reduces efficiency, increases wear and fatigue, generates noise and vibration, causes loss of tooth contact, leads to overloading and unbalanced loads, and affects the performance of seals and bearings. Proper alignment of gear shafts is crucial to ensure optimal gear performance, longevity, and reliable power transmission within the gear system.
What is the significance of gear shaft alignment in mechanical systems?
Gear shaft alignment holds great significance in mechanical systems where gears are employed. Proper alignment of gear shafts is crucial for ensuring optimal performance and longevity of the system. Let’s explore the significance of gear shaft alignment:
- Efficient Power Transmission:
Accurate alignment of gear shafts facilitates efficient power transmission within the mechanical system. When gear shafts are properly aligned, the gear teeth mesh smoothly and engage without unnecessary friction or resistance. This minimizes power losses due to misalignment, reducing energy wastage and maximizing power transfer efficiency. Efficient power transmission ensures that the mechanical system operates at its intended performance level.
- Reduced Wear and Damage:
Proper gear shaft alignment helps in reducing wear and damage to the gears and other components within the mechanical system. Misalignment can cause excessive stress on the gear teeth, resulting in accelerated wear and premature failure. By aligning the gear shafts correctly, the load is evenly distributed, preventing concentrated stress points. This leads to reduced wear, improved gear life, and decreased chances of unexpected breakdowns or malfunctions.
- Noise and Vibration Reduction:
Misalignment of gear shafts can lead to increased noise and vibration levels within the mechanical system. When gears are not properly aligned, they may generate excessive vibration and noise during operation. This can be detrimental to the overall performance and user experience. Proper gear shaft alignment ensures that the gears mesh accurately, reducing vibration and noise. It contributes to a quieter and smoother operation of the mechanical system.
- Optimal Load Distribution:
Alignment of gear shafts enables optimal load distribution among the gears. When gear shafts are aligned correctly, the load is evenly shared across the gear teeth and their supporting components. This prevents overloading of specific gears, minimizing the risk of premature wear or failure. Proper load distribution enhances the overall reliability and efficiency of the mechanical system, as each gear operates within its intended design parameters.
- Improved Efficiency:
Gear shaft alignment directly impacts the overall efficiency of the mechanical system. Proper alignment reduces energy losses due to friction, misalignment, or inefficient gear engagement. It allows for smooth and efficient power transmission throughout the system, optimizing the utilization of available energy. Improved efficiency translates into reduced operating costs, increased productivity, and enhanced performance of the mechanical system.
- Longer Service Life:
Correct gear shaft alignment contributes to a longer service life for the mechanical system. By minimizing wear, reducing stress concentrations, and preventing excessive vibration, proper alignment helps to preserve the integrity of the gears and other related components. This leads to extended service intervals, reduced maintenance requirements, and increased reliability. A mechanical system with aligned gear shafts is more likely to operate smoothly and consistently over an extended period.
In summary, gear shaft alignment is of significant importance in mechanical systems. It ensures efficient power transmission, reduces wear and damage, minimizes noise and vibration, enables optimal load distribution, improves overall efficiency, and extends the service life of the system. Proper alignment of gear shafts is essential for achieving reliable and high-performance operation in gear-based mechanical systems.
Can you describe the design and construction of a gear shaft?
The design and construction of a gear shaft are crucial factors in ensuring its functionality and durability within a mechanical system. A gear shaft is typically designed and constructed with specific considerations to meet the requirements of the application. Here’s a detailed description of the design and construction aspects of a gear shaft:
- Material Selection:
The choice of material for a gear shaft depends on various factors such as the application, operating conditions, and required strength. Common materials used for gear shafts include steel alloys, such as carbon steel, alloy steel, or stainless steel. These materials offer excellent strength, durability, and resistance to wear and fatigue. In some cases, gear shafts may also be made from other materials like brass or bronze for specific applications.
- Shape and Dimensions:
The shape and dimensions of a gear shaft are determined based on the specific requirements of the gear system and the mechanical system as a whole. Gear shafts are typically cylindrical in shape, with accurate dimensions and tolerances to ensure proper fit and alignment with the gears. The length and diameter of the gear shaft are determined based on factors such as the torque to be transmitted, the space available, and the required stiffness.
- Teeth and Splines:
In gear systems, gear shafts may have teeth or splines to provide a positive engagement with the gears. The teeth or splines are machined onto the gear shaft to ensure accurate meshing and transfer of rotational motion and torque. The shape, size, and profile of the teeth or splines depend on the specific gear system requirements, such as the module or pitch of the gears and the desired gear ratio.
- Bearing Surfaces:
Gear shafts often incorporate bearing surfaces to support and guide the rotation of the shaft within the mechanical system. These bearing surfaces can be in the form of journals or bushings, which reduce friction and wear. The design and construction of these bearing surfaces are critical to minimizing rotational resistance, ensuring smooth operation, and extending the lifespan of the gear shaft.
- Heat Treatment and Surface Finish:
To enhance the strength and durability of a gear shaft, heat treatment processes like quenching and tempering may be applied to improve the material’s properties. These processes can increase the hardness, toughness, and resistance to wear of the gear shaft. Additionally, the surface of the gear shaft may undergo finishing processes such as grinding, polishing, or coating to reduce surface roughness, enhance corrosion resistance, and improve overall performance.
- Accurate Machining and Tolerances:
The manufacturing of a gear shaft involves precise machining processes to achieve accurate dimensions and tolerances. CNC machining or other specialized machining techniques are employed to ensure the gear shaft’s proper fit and alignment with the gears and other components in the mechanical system. Tight tolerances are essential to achieve smooth and efficient operation, minimize backlash, and maintain the desired gear meshing characteristics.
In summary, the design and construction of a gear shaft involve material selection, consideration of shape and dimensions, implementation of teeth or splines, incorporation of bearing surfaces, application of heat treatment and surface finish, and accurate machining with tight tolerances. These design and construction aspects are crucial in creating a gear shaft that can efficiently transmit motion and power, withstand the operating conditions, and provide reliable performance within mechanical systems.
editor by CX 2024-04-09