China factory Aerospace-Approved Planetary Gearbox for Satellite Payload Deployment gearbox drive shaft

Product Description

 
 

Product Description

Product Parameters

Parameters Unit Level Reduction Ratio Flange Size Specification
060 090 115 142 180 220 280 330 400
Rated Output Torque T2n N.m 1 3 27.8 115 212 470 1226 1730 4230 8200 12500
4 46.32 142 268 582 1450 2270 5120 9800 16000
5 46.32 142 268 582 1450 2270 5120 8500 12200
7 38.9 110 212 468 1130 1610 3220 5000 7600
10 18.5 100 95 255 730 1050 1820 3500 5000
2 12 46.32 142 268 582 1450 2270 5120 9800 16000
15 46.32 142 268 582 1450 2270 5120 8500 12200
20 46.32 142 268 582 1450 2270 5120 9800 16000
25 46.32 142 268 582 1450 2270 5120 8500 12200
28 46.32 142 268 582 1450 2270 5120 9800 16000
30 27.8 115 212 470 1226 1730 4230 8200 12500
35 46.32 142 268 582 1450 2270 5120 8500 12200
40 46.32 142 268 582 1450 2270 5120 9800 16000
50 46.32 142 268 582 1450 2270 5120 8500 12200
70 38.9 110 212 468 1130 1610 3220 5000 7600
100 18.5 100 95 255 730 1050 1820 3500 5000
3 120 46.32 142 268 582 1450 2270 5120 9800 16000
150 46.32 142 268 582 1450 2270 5120 8500 12200
200 46.32 142 268 582 1450 2270 5120 9800 16000
250 46.32 142 268 582 1450 2270 5120 8500 12200
280 46.32 142 268 582 1450 2270 5120 9800 16000
350 46.32 142 268 582 1450 2270 5120 8500 12200
400 46.32 142 268 582 1450 2270 5120 9800 16000
500 46.32 142 268 582 1450 2270 5120 8500 12200
700 38.9 110 212 468 1130 1610 3220 5000 7600
1000 18.5 100 95 255 730 1050 1820 3500 5000
Maximum Output Torque T2b N.m 1,2,3 3~1000 2Times of Rated Output Torque
Rated Input Speed N1n rpm 1,2,3 3~1000 4000 3500 3500 3000 3000 2500 2000 1500 1500
Maximum Input Speed N1b rpm 1,2,3 3~1000 8000 7000 7000 5000 5000 4000 3000 2000 2000
Precision Backlash P1 arcmin 1 3~1000 ≤4 ≤4 ≤4 ≤4 ≤4 ≤4 ≤8 ≤8 ≤8
arcmin 2 3~1000 ≤6 ≤6 ≤6 ≤6 ≤6 ≤6 ≤12 ≤12 ≤12
arcmin 3 3~1000 ≤8 ≤8 ≤8 ≤8 ≤8 ≤8 ≤16 ≤16 ≤16
Standard Backlash P2 arcmin 1 3~1000 ≤8 ≤8 ≤8 ≤8 ≤8 ≤8 ≤12 ≤12 ≤12
arcmin 2 3~1000 ≤10 ≤10 ≤10 ≤10 ≤10 ≤10 ≤18 ≤18 ≤18
arcmin 3 3~1000 ≤12 ≤12 ≤12 ≤12 ≤12 ≤12 ≤24 ≤24 ≤24
Torsional Rigidity Nm/arcmin 1,2,3 3~1000 7 14 25 50 145 225 300 330 350
Allowable Radial Force F2rb2 N 1,2,3 3~1000 1550 3250 6700 9400 14500 50000 60000 70000 90000
Allowable Axial Force F2ab2 N 1,2,3 3~1000 775 1625 3350 4700 7250 25000 30000 95000 1250000
Moment of Inertia J1 kg.cm2 1 3~10 0.18 0.75 2.85 12.4 15.3 34.8 44.9 80 255
2 12~100 0.15 0.52 2.15 7.6 15.2 32.2 41.8 75 240
3 120~1000 0.07 0.36 2.05 6.3 14.2 18.3 28.1 68 220
Service Life hr 1,2,3 3~1000 20000
Efficiency η % 1 3~10 95%
2 12~100 92%
3 120~1000 85%
Noise Level dB 1,2,3 3~1000 ≤58 ≤62 ≤65 ≤70 ≤70 ≤75 ≤75 ≤75 ≤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 1.3 3.6 7.5 16 28 48 110 160 250
2 12~100 1.5 4.2 9.5 20 32 60 135 190 340
3 120~1000 1.8 4.8 11.5 24 36 72 150 225 420

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.

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Application: Motor, Electric Cars, Machinery, Agricultural Machinery, Gearbox
Hardness: Hardened Tooth Surface
Installation: Vertical Type
Layout: Coaxial
Gear Shape: Bevel Gear
Step: Three-Step
Customization:
Available

|

Customized Request

planetary gearbox

Contribution of Planetary Gearboxes to Conveyor Belt Efficiency in Mining Operations

Planetary gearboxes play a crucial role in enhancing the efficiency and performance of conveyor belts in mining operations:

  • High Torque Transmission: Planetary gearboxes are capable of transmitting high torque with minimal backlash. This feature ensures that the gearbox efficiently handles the substantial load requirements of conveyor belts used in mining, preventing slippage and ensuring reliable material transportation.
  • Compact Design: The compact size of planetary gearboxes allows them to be integrated seamlessly into conveyor systems, optimizing space utilization and allowing for efficient equipment layout in mining environments.
  • Variable Speed Control: Planetary gearboxes provide precise speed control and can accommodate various speed requirements of conveyor belts. This versatility allows operators to adjust the conveyor speed to match specific material handling needs.
  • High Efficiency: The inherent design of planetary gearboxes minimizes energy losses due to efficient power transmission. This efficiency translates into reduced energy consumption and operational costs over the lifetime of the conveyor system.
  • Reliability and Durability: Planetary gearboxes are engineered to withstand demanding conditions often encountered in mining environments, including shock loads, abrasive materials, and harsh weather. Their robust construction ensures reliable operation and minimal downtime.
  • Low Maintenance: The durability of planetary gearboxes leads to reduced maintenance requirements. This benefit is particularly valuable in mining operations where minimizing downtime is essential for maintaining high productivity levels.
  • Customizability: Planetary gearboxes can be tailored to suit specific conveyor system requirements, including gear ratios, torque ratings, and mounting options. This flexibility allows for optimized system design and performance.

By effectively transmitting power, providing accurate speed control, and offering a compact and robust design, planetary gearboxes significantly enhance the efficiency and reliability of conveyor belts in mining operations. Their ability to handle high loads, operate with low maintenance needs, and withstand harsh conditions contributes to improved productivity and reduced operational costs.

planetary gearbox

Impact of Temperature Variations and Environmental Conditions on Planetary Gearbox Performance

The performance of planetary gearboxes can be significantly influenced by temperature variations and environmental conditions. Here’s how these factors impact their operation:

Temperature Variations: Extreme temperature fluctuations can affect the lubrication properties of the gearbox. Cold temperatures can cause the lubricant to thicken, leading to increased friction and reduced efficiency. On the other hand, high temperatures can cause the lubricant to thin out, potentially leading to insufficient lubrication and accelerated wear.

Environmental Contaminants: Planetary gearboxes used in outdoor or industrial environments can be exposed to contaminants such as dust, dirt, moisture, and chemicals. These contaminants can infiltrate the gearbox and degrade the quality of the lubricant. Additionally, abrasive particles can cause wear on gear surfaces, leading to decreased performance and potential damage.

Corrosion: Exposure to moisture, especially in humid or corrosive environments, can lead to corrosion of gearbox components. Corrosion weakens the structural integrity of gears and other components, which can ultimately result in premature failure.

Thermal Expansion: Temperature changes can cause materials to expand and contract. In gearboxes, this can lead to misalignment of gears and improper meshing, causing noise, vibration, and reduced efficiency. Proper consideration of thermal expansion is crucial in gearbox design.

Sealing and Ventilation: To mitigate the impact of temperature and environmental factors, planetary gearboxes need effective sealing to prevent contaminants from entering and to retain the lubricant. Proper ventilation is also essential to prevent pressure build-up inside the gearbox due to temperature changes.

Cooling Systems: In applications where temperature control is critical, cooling systems such as fans or heat exchangers can be incorporated to maintain optimal operating temperatures. This helps prevent overheating and ensures consistent gearbox performance.

Overall, temperature variations and environmental conditions can have a profound impact on the performance and lifespan of planetary gearboxes. Manufacturers and operators need to consider these factors during design, installation, and maintenance to ensure reliable and efficient operation.

planetary gearbox

Challenges and Solutions for Managing Power Transmission Efficiency in Planetary Gearboxes

Managing power transmission efficiency in planetary gearboxes is crucial to ensure optimal performance and minimize energy losses. Several challenges and solutions are involved in maintaining high efficiency:

1. Gear Meshing Efficiency: The interaction between gears can lead to energy losses due to friction and meshing misalignment. To address this, manufacturers use precision manufacturing techniques to ensure accurate gear meshing and reduce friction. High-quality materials and surface treatments are also employed to minimize wear and friction.

2. Lubrication: Proper lubrication is essential to reduce friction and wear between gear surfaces. Using high-quality lubricants with the appropriate viscosity and additives can enhance power transmission efficiency. Regular maintenance and monitoring of lubrication levels are vital to prevent efficiency losses.

3. Bearing Efficiency: Bearings support the rotating elements of the gearbox and can contribute to energy losses if not properly designed or maintained. Choosing high-quality bearings and ensuring proper alignment and lubrication can mitigate efficiency losses in this area.

4. Bearing Preload: Incorrect bearing preload can lead to increased friction and efficiency losses. Precision assembly and proper adjustment of bearing preload are necessary to optimize power transmission efficiency.

5. Mechanical Losses: Various mechanical losses, such as windage and churning losses, can occur in planetary gearboxes. Designing gearboxes with streamlined shapes and efficient ventilation systems can reduce these losses and enhance overall efficiency.

6. Material Selection: Choosing appropriate materials with high strength and minimal wear characteristics is essential for reducing power losses due to material deformation and wear. Advanced materials and surface coatings can be employed to enhance efficiency.

7. Noise and Vibration: Excessive noise and vibration can indicate energy losses in the form of mechanical inefficiencies. Proper design and precise manufacturing techniques can help minimize noise and vibration, indicating better power transmission efficiency.

8. Efficiency Monitoring: Regular efficiency monitoring through testing and analysis allows engineers to identify potential issues and optimize gearbox performance. This proactive approach ensures that any efficiency losses are promptly addressed.

By addressing these challenges through careful design, material selection, manufacturing techniques, lubrication, and maintenance, engineers can manage power transmission efficiency in planetary gearboxes and achieve high-performance power transmission systems.

China factory Aerospace-Approved Planetary Gearbox for Satellite Payload Deployment   gearbox drive shaft	China factory Aerospace-Approved Planetary Gearbox for Satellite Payload Deployment   gearbox drive shaft
editor by CX 2024-04-03