Product Description
Product Description
Product Parameters
Parameters | Unit | Level | Reduction Ratio | Flange Size Specification | ||||||||
042 | 060 | 090 | 115 | 142 | 180 | 220 | 280 | 330 | ||||
Rated Output Torque T2n | N.m | 1 | 3 | 20 | 55 | 130 | 208 | 342 | 750 | 1140 | 1500 | 3000 |
4 | 19 | 50 | 140 | 290 | 542 | 1050 | 1700 | 5800 | 10190 | |||
5 | 22 | 60 | 160 | 330 | 650 | 1200 | 2000 | 4400 | 7180 | |||
6 | 20 | 55 | 140 | 300 | 550 | 1100 | 1800 | 3500 | 6500 | |||
7 | 19 | 50 | 140 | 300 | 550 | 1100 | 1800 | 3220 | 5000 | |||
8 | 17 | 45 | 120 | 260 | 500 | 1000 | 1600 | 2595 | 4080 | |||
10 | 14 | 40 | 100 | 230 | 450 | 900 | 1500 | 1820 | 3500 | |||
2 | 12 | 20 | 55 | 130 | 208 | 342 | 1050 | 1700 | 5800 | 10190 | ||
15 | 22 | 60 | 160 | 330 | 650 | 1200 | 2000 | 4400 | 7180 | |||
20 | 22 | 60 | 160 | 330 | 650 | 1200 | 2000 | 5800 | 10190 | |||
25 | 22 | 60 | 160 | 330 | 650 | 1200 | 2000 | 4400 | 7180 | |||
28 | 19 | 50 | 140 | 300 | 550 | 1100 | 1800 | 5800 | 10190 | |||
30 | 20 | 55 | 130 | 230 | 450 | 900 | 1500 | 1500 | 3500 | |||
35 | 22 | 60 | 160 | 330 | 650 | 1200 | 2000 | 4400 | 7180 | |||
40 | 22 | 60 | 160 | 330 | 650 | 1200 | 2000 | 5800 | 10190 | |||
50 | 22 | 60 | 160 | 330 | 650 | 1200 | 2000 | 4400 | 7180 | |||
70 | 19 | 50 | 140 | 300 | 550 | 1100 | 1800 | 3220 | 5000 | |||
100 | 14 | 40 | 100 | 230 | 450 | 900 | 1500 | 1820 | 3500 | |||
3 | 120 | 20 | 55 | 140 | 290 | 542 | 1050 | 1700 | 5800 | 10190 | ||
150 | 22 | 60 | 160 | 330 | 650 | 1200 | 2000 | 4400 | 7180 | |||
200 | 22 | 60 | 160 | 330 | 650 | 1200 | 2000 | 5800 | 10190 | |||
250 | 22 | 60 | 160 | 330 | 650 | 1200 | 2000 | 4400 | 7180 | |||
280 | 19 | 50 | 140 | 300 | 550 | 1100 | 1800 | 5800 | 10190 | |||
350 | 22 | 60 | 160 | 330 | 650 | 1200 | 2000 | 4400 | 7180 | |||
400 | 22 | 60 | 160 | 330 | 650 | 1200 | 2000 | 5800 | 10190 | |||
500 | 22 | 60 | 160 | 330 | 650 | 1200 | 2000 | 4400 | 7180 | |||
700 | 19 | 50 | 140 | 300 | 550 | 1100 | 1800 | 3220 | 5000 | |||
1000 | 14 | 40 | 100 | 230 | 450 | 900 | 1500 | 1820 | 3500 | |||
Maximum Output Torque T2b | N.m | 1,2,3 | 3~1000 | 3Times of Rated Output Torque | 2Times of Rated Output Torque | |||||||
Rated Input Speed N1n | rpm | 1,2,3 | 3~1000 | 5000 | 5000 | 3000 | 3000 | 3000 | 3000 | 2000 | 1500 | 1500 |
Maximum Input Speed N1b | rpm | 1,2,3 | 3~1000 | 10000 | 10000 | 6000 | 6000 | 6000 | 6000 | 4000 | 3000 | 3000 |
Ultra Precision Backlash PS | arcmin | 1 | 3~10 | ≤1 | ≤1 | ≤1 | ≤1 | ≤1 | ≤1 | ≤1 | ||
arcmin | 2 | 12~100 | ≤2 | ≤2 | ≤2 | ≤2 | ≤2 | ≤2 | ≤2 | |||
arcmin | 3 | 120~1000 | ≤5 | ≤5 | ≤5 | ≤5 | ≤5 | ≤5 | ≤5 | |||
High Precision Backlash P0 | arcmin | 1 | 3~10 | ≤2 | ≤2 | ≤2 | ≤2 | ≤2 | ≤2 | ≤2 | ||
arcmin | 2 | 12~100 | ≤3 | ≤3 | ≤3 | ≤3 | ≤3 | ≤3 | ≤3 | |||
arcmin | 3 | 120~1000 | ≤7 | ≤7 | ≤7 | ≤7 | ≤7 | ≤7 | ≤7 | |||
Precision Backlash P1 | arcmin | 1 | 3~10 | ≤3 | ≤3 | ≤3 | ≤3 | ≤3 | ≤3 | ≤3 | ≤15 | ≤15 |
arcmin | 2 | 12~100 | ≤5 | ≤5 | ≤5 | ≤5 | ≤5 | ≤5 | ≤5 | ≤18 | ≤18 | |
arcmin | 3 | 12~1000 | ≤9 | ≤9 | ≤9 | ≤9 | ≤9 | ≤9 | ≤9 | ≤22 | ≤22 | |
Standard Backlash P2 | arcmin | 1 | 3~10 | ≤5 | ≤5 | ≤5 | ≤5 | ≤5 | ≤5 | ≤5 | ||
arcmin | 2 | 12~100 | ≤7 | ≤7 | ≤7 | ≤7 | ≤7 | ≤7 | ≤7 | |||
arcmin | 3 | 120~1000 | ≤11 | ≤11 | ≤11 | ≤11 | ≤11 | ≤11 | ≤11 | |||
Torsional Rigidity | Nm/arcmin | 1,2,3 | 3~1000 | 3 | 4.5 | 14 | 25 | 50 | 145 | 225 | 213.3 | 339 |
Allowable Radial Force F2rb2 | N | 1,2,3 | 3~1000 | 780 | 1550 | 3250 | 6700 | 9400 | 14500 | 30000 | 15000 | 17000 |
Allowable Axial Force F2ab2 | N | 1,2,3 | 3~1000 | 390 | 770 | 1630 | 3350 | 4700 | 7250 | 14000 | 12000 | 15000 |
Moment of Inertia J1 | kg.cm2 | 1 | 3~10 | 0.05 | 0.2 | 1.2 | 2 | 7.2 | 25 | 65 | 39.9 | 73.4 |
kg.cm2 | 2 | 12~100 | 0.03 | 0.08 | 0.18 | 0.7 | 1.7 | 7.9 | 14 | 18.8 | 23.8 | |
kg.cm2 | 3 | 120~1000 | 0.03 | 0.03 | 0.01 | 0.04 | 0.09 | 0.21 | 0.82 | 13.54 | 18.8 | |
Service Life | hr | 1,2,3 | 3~1000 | 20000 | ||||||||
Efficiency η | % | 1 | 3~10 | 97% | ||||||||
2 | 12~100 | 94% | ||||||||||
3 | 120~1000 | 91% | ||||||||||
Noise Level | dB | 1,2,3 | 3~1000 | ≤56 | ≤58 | ≤60 | ≤63 | ≤65 | ≤67 | ≤70 | ≤73 | ≤75 |
Operating Temperature | ºC | 1,2,3 | 3~1000 | -10~+90 | ||||||||
Protection Class | IP | 1,2,3 | 3~1000 | IP65 | ||||||||
Weights | kg | 1 | 3~10 | 0.6 | 1.3 | 3.9 | 8.7 | 16 | 31 | 48 | 110 | 160 |
2 | 12~100 | 0.8 | 1.8 | 4.6 | 10 | 20 | 39 | 62 | 135 | 180 | ||
3 | 120~1000 | 1.2 | 2.3 | 5.3 | 11 | 22 | 44 | 68 | 145 | 192 |
FAQ
Q: How to select a gearbox?
A: Firstly, determine the torque and speed requirements for your application. Consider the load characteristics, operating environment, and duty cycle. Then, choose the appropriate gearbox type, such as planetary, worm, or helical, based on the specific needs of your system. Ensure compatibility with the motor and other mechanical components in your setup. Lastly, consider factors like efficiency, backlash, and size to make an informed selection.
Q: What type of motor can be paired with a gearbox?
A: Gearboxes can be paired with various types of motors, including servo motors, stepper motors, and brushed or brushless DC motors. The choice depends on the specific application requirements, such as speed, torque, and precision. Ensure compatibility between the gearbox and motor specifications for seamless integration.
Q: Does a gearbox require maintenance, and how is it maintained?
A: Gearboxes typically require minimal maintenance. Regularly check for signs of wear, lubricate as per the manufacturer’s recommendations, and replace lubricants at specified intervals. Performing routine inspections can help identify issues early and extend the lifespan of the gearbox.
Q: What is the lifespan of a gearbox?
A: The lifespan of a gearbox depends on factors such as load conditions, operating environment, and maintenance practices. A well-maintained gearbox can last for several years. Regularly monitor its condition and address any issues promptly to ensure a longer operational life.
Q: What is the slowest speed a gearbox can achieve?
A: Gearboxes are capable of achieving very slow speeds, depending on their design and gear ratio. Some gearboxes are specifically designed for low-speed applications, and the choice should align with the specific speed requirements of your system.
Q: What is the maximum reduction ratio of a gearbox?
A: The maximum reduction ratio of a gearbox depends on its design and configuration. Gearboxes can achieve various reduction ratios, and it’s important to choose 1 that meets the torque and speed requirements of your application. Consult the gearbox specifications or contact the manufacturer for detailed information on available reduction ratios.
/* 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(/(.*?):(.*)$/))&&1
Application: | Motor, Electric Cars, Machinery, Agricultural Machinery, Gearbox |
---|---|
Hardness: | Hardened Tooth Surface |
Installation: | Vertical Type |
Customization: |
Available
| Customized Request |
---|
.shipping-cost-tm .tm-status-off{background: none;padding:0;color: #1470cc}
Shipping Cost:
Estimated freight per unit. |
about shipping cost and estimated delivery time. |
---|
Payment Method: |
|
---|---|
Initial Payment Full Payment |
Currency: | US$ |
---|
Return&refunds: | You can apply for a refund up to 30 days after receipt of the products. |
---|
Contribution of Planetary Gearboxes to Conveyor Belt Efficiency in Mining Operations
Planetary gearboxes play a significant role in enhancing the efficiency of conveyor belts used in mining operations:
- High Torque Capability: Planetary gearboxes are capable of providing high torque output, which is essential for handling heavy loads of mined materials on conveyor belts.
- Compact Design: The compact nature of planetary gearboxes allows them to be integrated into tight spaces, making them suitable for conveyor systems where space is limited.
- Multi-Stage Design: Planetary gearboxes can achieve high gear ratios through multiple stages of gear reduction. This allows for efficient power transmission from the motor to the conveyor, reducing the load on the motor and increasing overall efficiency.
- Load Distribution: Planetary gearboxes distribute the load across multiple planet gears, which helps in minimizing wear and ensuring longer lifespan of the gearbox.
- Variable Speed Control: By using planetary gearboxes with variable speed capabilities, conveyor belts can be operated at different speeds to match the processing requirements, optimizing material handling and energy consumption.
- Overload Protection: Some planetary gearboxes feature built-in overload protection mechanisms, safeguarding the gearbox and conveyor system from damage due to sudden increases in load.
Overall, planetary gearboxes enhance the efficiency, reliability, and performance of conveyor belts in mining operations by providing the necessary torque, compact design, and precise control needed to transport mined materials effectively.
Considerations for Selecting Size and Gear Materials in Planetary Gearboxes
Choosing the appropriate size and gear materials for a planetary gearbox is crucial for optimal performance and reliability. Here are the key considerations:
1. Load and Torque Requirements: Evaluate the anticipated load and torque that the gearbox will experience in the application. Select a gearbox size that can handle the maximum load without exceeding its capacity, ensuring reliable and durable operation.
2. Gear Ratio: Determine the required gear ratio to achieve the desired output speed and torque. Different gear ratios are achieved by varying the number of teeth on the gears. Select a gearbox with a suitable gear ratio for your application’s requirements.
3. Efficiency: Consider the efficiency of the gearbox, which is influenced by factors such as gear meshing, bearing losses, and lubrication. A higher efficiency gearbox minimizes energy losses and improves overall system performance.
4. Space Constraints: Evaluate the available space for installing the gearbox. Planetary gearboxes offer compact designs, but it’s essential to ensure that the selected size fits within the available area, especially in applications with limited space.
5. Material Selection: Choose suitable gear materials based on factors like load, speed, and operating conditions. High-quality materials, such as hardened steel or specialized alloys, enhance gear strength, durability, and resistance to wear and fatigue.
6. Lubrication: Proper lubrication is critical for reducing friction and wear in the gearbox. Consider the lubrication requirements of the selected gear materials and ensure the gearbox is designed for efficient lubricant distribution and maintenance.
7. Environmental Conditions: Assess the environmental conditions in which the gearbox will operate. Factors such as temperature, humidity, and exposure to contaminants can impact gear material performance. Choose materials that can withstand the operating environment.
8. Noise and Vibration: Gear material selection can influence noise and vibration levels. Some materials are more adept at dampening vibrations and reducing noise, which is essential for applications where quiet operation is crucial.
9. Cost: Consider the budget for the gearbox and balance the cost of materials, manufacturing, and performance requirements. While high-quality materials may increase initial costs, they can lead to longer gearbox lifespan and reduced maintenance expenses.
10. Manufacturer’s Recommendations: Consult with gearbox manufacturers or experts for guidance on selecting the appropriate size and gear materials. They can provide insights based on their experience and knowledge of various applications.
Ultimately, the proper selection of size and gear materials is vital for achieving reliable, efficient, and long-lasting performance in planetary gearboxes. Taking into account load, gear ratio, materials, lubrication, and other factors ensures the gearbox meets the specific needs of the application.
Examples of High Torque and Compact Design Applications for Planetary Gearboxes
Planetary gearboxes excel in applications where high torque output and a compact design are essential. Here are some scenarios where these characteristics are crucial:
- Automotive Transmissions: In modern vehicles, planetary gearboxes are used in automatic transmissions to efficiently transmit engine power to the wheels. The compact size of planetary gearboxes allows for integration within the limited space of a vehicle’s transmission housing.
- Robotics: Planetary gearboxes are utilized in robotic arms and joints, where compactness is essential to maintain the robot’s overall size while providing the necessary torque for precise and controlled movement.
- Conveyor Systems: Conveyor belts in industries like material handling and manufacturing often require high torque to move heavy loads. The compact design of planetary gearboxes allows them to be integrated into the conveyor system’s framework.
- Wind Turbines: Wind turbine applications demand high torque to convert low wind speeds into sufficient rotational force for power generation. The compact design of planetary gearboxes helps optimize space within the turbine’s nacelle.
- Construction Machinery: Heavy equipment used in construction, such as excavators and loaders, rely on planetary gearboxes to provide the necessary torque for digging and lifting operations without adding excessive weight to the machinery.
- Marine Propulsion: Planetary gearboxes play a crucial role in marine propulsion systems by efficiently transmitting high torque from the engine to the propeller shaft. The compact design is particularly important in the limited space of a ship’s engine room.
These examples highlight the significance of planetary gearboxes in applications where both high torque output and a compact footprint are vital considerations. Their ability to deliver efficient torque conversion within a small space makes them well-suited for a wide range of industries and machinery.
editor by CX 2024-03-26