Product Description
Stainless Steel Plastic Roller Chain Gear Platewheel Engineer Class Agricultural Pintle Cast Iron Weld On Hub Finished Bore Idler Bushing Taper Lock Qd Sprocket
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European standard sprockets |
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DIN stock bore sprockets & plateheels |
03B-1 04B-1 05B-1-2 06B-1-2-3 081B-1 083B-1/084B-1 085B-1 086B-1 08B-1-2-3 10B-1-2-3 12B-1-2-3 16B-1-2-3 20B-1-2-3 24B-1-2-3 |
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03A-1 04A-1 05A-1-2 06A-1-2-3 081A-1 083A-1/084A-1 085A-1 086A-1 08A-1-2-3 10A-1-2-3 12A-1-2-3 16A-1-2-3 20A-1-2-3 24A-1-2-3 |
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DIN finished bore sprockets |
06B-1 08B-1 10B-1 12B-1 16B-1 20B-1 |
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stainless steel sprockets |
06B-1 08B-1 10B-1 12B-1 16B-1 |
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taper bore sprockets |
3/8″×7/32″ 1/2″×5/16″ 5/8″×3/8″ 3/4″×7/16″ 1″×17.02mm 1 1/4″×3/4″ |
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cast iron sprockets |
06B-1-2-3 081B-1 083B-1/084B-1 085B-1 086B-1 08B-1-2-3 10B-1-2-3 12B-1-2-3 16B-1-2-3 20B-1-2-3 24B-1-2-3 |
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platewheels for conveyor chain |
20×16mm 30×17.02mm P50 P75 P100 |
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table top wheels |
P38.1 |
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idler sprockets with ball bearing |
8×1/8″ 3/8″×7/32″ 1/2″×1/8″ 1/2″×3/16″ 1/2″×5/16″ 5/8″×3/8″ 5/8″×3/8″ 5/8″×3/8″ 3/4″×7/16″ 3/4″×7/16″ 1″×17.02mm 1 1/4″×3/4″ |
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double simplex sprockets |
06B-1 08B-1 10B-1 12B-1 16B-1 |
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American standard sprockets |
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ASA stock bore sprockets |
-2 35-3 -2 40-3 50 50-2-50-3 60 60-2 60-3 80-80-2 80-3 100 100-2 100-3 120 120-2 120-3 140 140-2 160 160-2 180 200 |
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finished bore sprockets |
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stainless steel sprockets |
60 |
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double single sprockets&single type Csprockets |
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taper bore sprockets |
35 35-2 -2 50 50-2 60 60-2 80 80-2 |
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double pitch sprockets |
2040/2042 2050/2052 2060/2062 2080/2082 |
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sprockets with split taper bushings |
40-2 40-3 50 50-2 50-3 60 60-2 60-3 80 80-2 80-3 100 100-2 120 120-2 |
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sprockets with QD bushings |
35 35-1 35-2 -2 40-3 50 50-2 50-3 60 60-2 60-3 80 80-2 80-3 100 100-2 100-3 |
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Japan standard sprockets |
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JIS stock sprockets |
140 160 |
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finished bore sprockets |
FB25B FB35B FB40B FB50B FB60B FB80B FB100B FB120B |
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double single sprockets |
40SD 50SD 60SD 80SD 100SD |
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double pitch sprockets |
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speed-ratio sprockets |
C3B9N C3B10N C4B10N C4B11 C4B12 C5B10N C5B11 C5B12N C6B10N C6B11 C6B12 |
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idler sprockets |
35BB20H 40BB17H 40BB18H 50BB15H 50BB17H 60BB13H 60BB15H 80BB12H |
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table top sprockets |
P38.1 |
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Material available |
Low carbon steel, C45, 20CrMnTi, 42CrMo, 40Cr, stainless steel. Can be adapted regarding customer requirements. |
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Surface treatment |
Blacking, galvanization, chroming, electrophoresis, color painting, … |
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Heat treatment |
High frequency quenching heat treatment, hardened teeth, carbonizing, nitride, … |
Customization process
1.Provide documentation:CAD, DWG, DXF, PDF,3D model ,STEP, IGS, PRT
2.Quote:We will give you the best price within 24 hours
3.Place an order:Confirm the cooperation details and CZPT the contract, and provide the labeling service
4.Processing and customization:Short delivery time
Related products:
Factory:
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| Standard Or Nonstandard: | Standard |
|---|---|
| Application: | Motor, Motorcycle, Machinery, Agricultural Machinery, Car |
| Hardness: | Hardened Tooth Surface |
| Manufacturing Method: | Rolling Gear |
| Toothed Portion Shape: | Spur Gear |
| Material: | Stainless Steel |
Factors Affecting the Efficiency of a wheel sprocket Setup
Several factors can influence the efficiency of a wheel sprocket system in power transmission and motion control applications. These factors should be carefully considered and optimized to ensure the system’s overall effectiveness and performance:
- 1. Friction: Friction between the wheel, sprocket, and the chain or belt can lead to energy losses. Using high-quality materials and lubrication can help reduce friction and improve efficiency.
- 2. Alignment: Proper alignment between the wheel and the sprocket is critical. Misalignment can cause increased wear, noise, and reduced efficiency. Regular maintenance and alignment checks are essential.
- 3. Tension: The correct tension in the chain or belt is crucial for efficient power transmission. Too loose or too tight tension can lead to performance issues and premature wear.
- 4. Material and Design: The choice of materials for the wheel sprocket, as well as their design, can impact efficiency. High-quality materials and well-engineered components reduce wear and improve overall system performance.
- 5. Load Distribution: Uneven load distribution across the wheel sprocket can lead to localized wear and decreased efficiency. Ensuring proper load distribution helps maintain uniform wear and power transmission.
- 6. Environmental Factors: Harsh environmental conditions, such as dust, moisture, and extreme temperatures, can affect the efficiency of the system. Choosing suitable materials and implementing protective measures can mitigate these effects.
- 7. Maintenance: Regular maintenance, including lubrication, inspection, and timely replacement of worn components, is vital for the long-term efficiency of the system.
- 8. Speed and Torque: The operating speed and torque requirements of the application should be considered when selecting the appropriate wheel sprocket size and specifications.
- 9. Chain or Belt Type: Different types of chains or belts, such as roller chains, silent chains, or toothed belts, have varying efficiencies. Choosing the right type for the specific application is crucial.
- 10. System Integration: The wheel sprocket system should be integrated correctly with other components in the machinery to ensure smooth operation and minimal energy losses.
By carefully considering and optimizing these factors, it is possible to improve the efficiency of the wheel sprocket system, leading to reduced energy consumption, less wear and tear, and overall better performance.
Vertical Power Transmission with wheel sprocket System
Yes, a wheel sprocket system can be used for vertical power transmission. In such cases, the system is designed to transmit power and motion between vertically aligned shafts. Vertical power transmission using a wheel sprocket assembly follows similar principles to horizontal transmission, but there are some factors to consider:
- Load and Torque: When transmitting power vertically, the weight of the load can significantly impact the torque requirements. The torque must be sufficient to lift the load against gravity while accounting for friction and other resistive forces.
- Sprocket Selection: Choosing the right sprocket is critical for vertical transmission. The sprocket teeth must be designed to engage the chain or belt effectively and prevent slipping, especially when lifting heavy loads.
- Lubrication: Proper lubrication is essential to reduce friction and wear in the system. Vertical applications may require specific lubricants to ensure smooth operation and prevent premature failure.
- Tensioning: Maintaining the correct tension in the chain or belt is crucial for vertical power transmission. Proper tension helps prevent sagging and ensures proper engagement between the wheel sprocket.
- Overhung Load: In vertical setups, the weight of the sprocket and shaft assembly can impose an overhung load on the bearings. Adequate support and bearing selection are necessary to handle this load.
Vertical power transmission with a wheel sprocket system is commonly used in various applications, including conveyor systems, elevators, and some industrial machinery. Proper design, installation, and maintenance are essential to ensure safe and efficient operation in vertical configurations.
Working Principle of a wheel sprocket System
In a wheel sprocket system, the sprocket is a toothed wheel that meshes with a chain or a belt to transmit rotational motion and power from one component to another. The working principle can be explained in the following steps:
1. Power Input:
The system begins with a power input source, such as an electric motor or an engine, that generates rotational motion or torque.
2. Sprocket and Chain/Belt:
The power is transferred to the sprocket, which is mounted on a shaft. The sprocket has teeth that fit into the gaps of the chain or engage with the teeth of the belt.
3. Chain/Belt Movement:
As the sprocket rotates, it pulls the chain or belt along with it due to the engagement between the teeth. This movement is transmitted to the connected component, which could be another sprocket, a wheel, or any other part of the machinery.
4. Power Output:
The rotational motion or power is then delivered to the connected component, which performs a specific function depending on the application. For example, the power could be used to drive a conveyor belt, rotate the wheels of a vehicle, or operate various industrial machines.
5. Speed and Torque:
The size of the sprocket and the number of teeth, along with the size of the chain or belt, determine the speed and torque ratio between the input and output components. Changing the size of the sprocket or using different-sized sprockets in the system can alter the speed and torque characteristics of the machinery.
6. Efficiency and Maintenance:
Efficient power transmission relies on proper alignment and tension of the chain or belt with the sprocket. Regular maintenance, such as lubrication and inspection, is essential to ensure smooth operation and prevent premature wear or damage to the system.
The wheel sprocket system is widely used in various applications, including bicycles, motorcycles, industrial machinery, agricultural equipment, and more, where efficient power transmission and motion control are required.
editor by CX 2024-01-22