China Hot selling CZPT Plantery Gear Ratio (Final drive) Gft 110 T3 1435 for Tana Shark 5430 gear box

Product Description

Rexroth Plantery gear ratio ( Final drive) GFT 110 T3 1435 For Tana Shark 5430
Casagrande hydraulic piling rigs winch  GFT110, Final Drive GFT 110 W3 6371 
sany  rotary drilling  rig. main winch

1, good quality
2, low price, Original CHINAMFG motor reducer
3, deliver soon

Main performances Unit Parameters
Overall height(chassis/SANY chassis) mm 22,660/22,7/8822 0571
R988/8822 0571
R98857133 GFT60W3B86~/8822 0571
R GFT7T2B51-01
R98857156 GFT7T2B63-01
R9880 0571 9 GFT80T3-185-03
R9880 0571 6 GFT80T3B127-01 W/O MOTOR
R988056701 GFT80T3B127-09
R988064513 GFT80T3B127-09 W/O MOTOR
R988006366 GFT80T3B150-01
R988006367 GFT80T3B150-02
R988006370 GFT80T3B185-06
R98857127 GFT80T3B185-10
R988049613 GFT80T3B185-10 W/O MOTOR
R988062758 GFT80T3B185-11
R988006374 GFT80T3B204
R988006375 GFT80T3B77-01
R988006551 GFT80W3B127-07
R988006866 GFT80W3B127-14
R988018309 GFT80W3B127-17
R98857113 GFT80W3B127-19
R98857163 GFT60A3B65-03
R988006277 GFT60T3B106-03
R9880 0571 6 GFT60T3B106-05 W/O MOTOR
R988006284 GFT60T3B106-13
R988006286 GFT60T3B120-06
R GFT60T3B140-19
R988 0571 1 GFT60T3B140-20
R988006307 GFT60T3B170-06
R988006308 GFT60T3B170-08
R9880 0571 5 GFT60T3B170-12 W/O MOTOR
R GFT60T3B64-01
R9880 0571 4 GFT60T3B86-02
R9880 0571 2 GFT60W3B106-06
R9880 0571 3 GFT60W3B106-11
R988054345 GFT60W3B106-20
R988018532 GFT60W3B170-11
R988007035 GFT60W3B400 W/O MOTOR
R988006589 GFT60W3B64-01
R988006591 GFT60W3B64-02
R988006526 GFT60W3B64-03
R9885711 GFT60W3B64-09
R988054749 GFT60W3B64-10
R988064141 GFT60W3B64-12
R988006136 GFT24T2B19-01
R988006137 GFT24T2B19-03
R988006143 GFT24T3B103-07
R988049105 GFT26T2B43-08
R988006159 GFT26T2B51-02
R988006160 GFT26T2B62-06
R988006173 GFT26W2B62-06
R988006177 GFT26W2B62-10
R988006178 GFT26W2B62-15
R988018533 GFT26W2B62-20
R GFT34T2B43-01
R988006187 GFT36T2B28-02
R988006189 GFT36T3-131-04
R9885719 GFT36T3-131-04 W/O MOTOR
R988006199 GFT36T3B100-12
R988006216 GFT36T3B139-01
R9885712 GFT36T3B139-02 W/O MOTOR
R988046030 GFT36T3B139-07
R GFT36T3B67-15
R988006228 GFT36T3B79-09
R988006966 GFT36T3B79-09 W/O MOTOR
R988065729 GFT36W3B100-06
R988006244 GFT36W3B67-03
R988017691 GFT36W3B67-16
R988006255 GFT36W3B79-25
R988040808 GFT36W3B79-30
R98857110 GFT36W3B79-32
R9885718 GFT40T2B41-04
R98804 0571 GFT40T2B41-05
R988006266 GFT40W2B49-01
R988006267 GFT40W2B49-02
R988046595 GFT40W2B59-15
R98857123 GFT40W2B59-16
R GFT40W2B59-17
R GFT50T3B100-01
R98857162 GFT50T3B177-04
R988006274 GFT60A2B40-01
R98805711 GFT110W3B96-09
R988018531 GFT110W3B96-21
R988044467 GFT110W3B96-28
R GFT110W3B96-30
R GFT110W3B96-34
R98857173 GFT110W3B96-36
R98857175 GFT110W3B96-38
R988065817 GFT110W3B96-40
R988017539 GFT13T2B32-01
R988006082 GFT17T2B45-21
R988006086 GFT17T2B45-25
R988017334 GFT17T2B45-33
R988006089 GFT17T2B54-04
R988006090 GFT17T2B54-05
R988006093 GFT17T2B54-09
R988006886 GFT17T2B54-12 W/O MOTOR
R98857112 GFT17T2B54-22
R988006105 GFT17T3B78-07
R98857124 GFT17T3B88-05
R988006118 GFT17W2B45-15
R988006119 GFT17W2B45-16
R988058732 GFT17W3B78-06 W/O MOTOR
R91605715 GFT2160E/30-AAAA0045M1-HA1/0170AS0-0CJ
R916008231 GFT2160E/30-AAAA0045M1-HA1/0170AS0-0CJ
R988056777 GFB26T2B52-02
R988005877 GFB26T2B63-12
R988005879 GFB36T2B24-04
R988005881 GFB36T2B24-06
R988056999 GFB36T3B101-12
R988005909 GFB36T3B101-29
R9885710 GFB36T3B101-30
R9885711 GFB36T3B101-31
R9885713 GFB36T3B101-33
R9885717 GFB36T3B101-37
R988006816 GFB36T3B101-38
R98805712 GFB36T3B118-06
R98805714 GFB36T3B118-10
R98857185 GFB36T3B118-11
R988048093 GFB36T3B118-12
R98857195 GFB36T3B132-10
R988054750 GFB36T3B132-11
R9885711 GFB36T3B68-03
R9885713 GFB36T3B68-05
R988046591 GFB36T3B68-11
R98805713 GFB36T3B80-15
R98805715 GFB36T3B80-17
R9880571 GFB36T3B80-17 W/O MOTOR
R98805717 GFB40T2B49-01

Application: Motor, Machinery, Marine, Agricultural Machinery
Function: Distribution Power, Speed Changing, Speed Increase
Layout: Planetary
Hardness: Hardened Tooth Surface
Installation: Torque Arm Type
Step: Three-Step


Customized Request

spur gear

What are the potential challenges in designing and manufacturing spur gears?

Designing and manufacturing spur gears involve several challenges that need to be addressed to ensure optimal performance and reliability. Here’s a detailed explanation of the potential challenges in designing and manufacturing spur gears:

  • Gear Tooth Design: Designing the gear tooth profile is a critical aspect of gear design. Achieving the desired tooth shape, pressure angle, and tooth thickness distribution while considering factors such as load capacity, durability, and noise generation can be challenging. Iterative design processes, computer-aided design (CAD) software, and gear design expertise are often employed to overcome these challenges.
  • Material Selection: Choosing the appropriate material for gear manufacturing is crucial. Gears need to withstand high loads, transmit power efficiently, and exhibit excellent wear resistance. Selecting materials with suitable hardness, strength, and fatigue resistance can be challenging, especially when considering factors such as cost, availability, and compatibility with other components in the gear system.
  • Manufacturing Processes: The manufacturing processes for producing spur gears, such as hobbing, shaping, or broaching, can present challenges. Achieving precise gear tooth profiles, accurate dimensions, and proper surface finish requires advanced machining techniques, specialized equipment, and skilled operators. Maintaining tight tolerances and ensuring consistent quality during mass production can also be demanding.
  • Tooth Surface Finish: The surface finish of gear teeth plays a crucial role in gear performance. Achieving a smooth and precise tooth surface finish is challenging due to factors such as tool wear, heat generation during manufacturing, and the complexity of the gear tooth profile. Surface finishing processes, such as grinding or honing, may be required to achieve the desired surface quality.
  • Noise and Vibration: Gears can generate noise and vibration during operation, which can affect the overall performance and user experience. Designing gears to minimize noise and vibration requires careful consideration of factors such as tooth profile optimization, load distribution, gear meshing characteristics, and proper lubrication. Conducting noise and vibration analysis and implementing appropriate design modifications may be necessary to address these challenges.
  • Backlash Control: Controlling backlash, the slight gap between mating gear teeth, can be challenging. Backlash affects gear accuracy, smoothness of operation, and the ability to transmit torque efficiently. Balancing the need for adequate backlash to accommodate thermal expansion and minimize gear engagement issues while ensuring precise control of backlash can be a complex task in gear design and manufacturing.
  • Heat Treatment: Heat treatment processes, such as carburizing or quenching, are often employed to enhance the hardness and strength of gear teeth. Proper heat treatment is crucial to achieve the desired material properties and gear performance. However, challenges such as distortion, residual stresses, and material property variations can arise during heat treatment, requiring careful process control, post-heat treatment machining, or additional treatments to mitigate these challenges.
  • Quality Control: Ensuring consistent quality and reliability of spur gears is a challenge in manufacturing. Implementing effective quality control measures, such as dimensional inspections, hardness testing, and gear tooth profile analysis, is essential. Statistical process control (SPC) techniques and quality assurance systems help monitor manufacturing processes, identify potential issues, and maintain consistent gear quality.
  • Cost and Time Constraints: Designing and manufacturing spur gears that meet performance requirements within cost and time constraints can be challenging. Balancing factors such as material costs, tooling expenses, production lead times, and market competitiveness requires careful consideration and optimization. Efficient production planning, cost analysis, and value engineering techniques are often employed to address these challenges.

By recognizing these challenges and employing appropriate design methodologies, manufacturing techniques, and quality control measures, it is possible to overcome the potential challenges associated with designing and manufacturing spur gears.

It’s important to note that the specific challenges may vary depending on the gear application, size, complexity, and operating conditions. Collaboration with gear design experts, manufacturing engineers, and industry specialists can provide valuable insights and guidance in addressing the challenges specific to your spur gear design and manufacturing processes.

spur gear

What is the purpose of using spur gears in machinery?

In machinery, spur gears serve several important purposes due to their unique characteristics and capabilities. Here’s a detailed explanation of the purpose of using spur gears in machinery:

  1. Power Transmission: Spur gears are primarily used for power transmission in machinery. They transfer rotational motion and torque from one shaft to another, allowing machinery to perform various tasks. By meshing the teeth of two or more spur gears together, power can be transmitted efficiently and reliably throughout the machinery.
  2. Speed Reduction or Increase: Spur gears enable speed reduction or increase in machinery. By combining gears with different numbers of teeth, the rotational speed can be adjusted to match the desired output speed. For example, using a larger gear driving a smaller gear can increase the speed output while reducing the torque, while the opposite arrangement can decrease the speed while increasing the torque.
  3. Torque Amplification: Spur gears can amplify torque in machinery. By using gears with different numbers of teeth, the torque can be adjusted to match the required output. For example, using a smaller gear driving a larger gear can increase the torque output while reducing the speed, while the opposite arrangement can decrease the torque while increasing the speed.
  4. Directional Control: Spur gears provide directional control in machinery. By meshing gears with opposite orientations, the rotational direction of the driven shaft can be reversed or changed. This directional control is crucial for machinery that requires bi-directional motion or needs to change the direction of operation.
  5. Mechanical Advantage: Spur gears offer a mechanical advantage in machinery. By utilizing gear ratios, spur gears can multiply or divide the force exerted on the input shaft. This mechanical advantage allows machinery to generate higher forces or achieve precise movements with reduced effort.
  6. Precision Positioning: Spur gears facilitate precise positioning in machinery. The accurate tooth engagement of spur gears ensures precise control over rotational motion, making them suitable for applications that require precise positioning or synchronization of components. Machinery such as CNC machines, robotics, and automation systems often rely on spur gears for accurate movement and positioning.
  7. Compact Design: Spur gears have a compact design, making them suitable for machinery with space constraints. They can be arranged in-line, parallel, or at right angles, allowing for efficient power transmission in tight spaces. Their compactness enables machinery to be designed with smaller footprints and optimized layouts.
  8. Reliability and Durability: Spur gears are known for their reliability and durability in machinery. The direct tooth engagement and uniform load distribution result in efficient power transmission with reduced wear and stress concentration. When properly lubricated and maintained, spur gears can withstand heavy loads and operate reliably over extended periods.
  9. Cost-Effectiveness: Spur gears are often cost-effective in machinery applications. Their simple design and ease of manufacturing contribute to lower production costs. Additionally, their high efficiency helps reduce energy consumption, resulting in potential long-term cost savings. The availability of spur gears in various sizes and materials further enhances their cost-effectiveness.

By utilizing spur gears in machinery, engineers and designers can achieve efficient power transmission, speed and torque control, directional versatility, mechanical advantage, precise positioning, compact design, reliability, durability, and cost-effectiveness. These advantages make spur gears a popular choice in a wide range of machinery applications across industries.

spur gear

How do you choose the right size spur gear for your application?

Choosing the right size spur gear for your application requires careful consideration of various factors. Here’s a detailed explanation of the steps involved in selecting the appropriate size spur gear:

  1. Determine the Required Torque: Start by determining the torque requirements of your application. Calculate or estimate the maximum torque that the gear will need to transmit. Consider factors such as the power input, speed, and load conditions to determine the required torque.
  2. Identify the Speed Requirements: Determine the desired rotational speed or RPM (revolutions per minute) for your application. This will help in selecting a gear with the appropriate pitch diameter and tooth configuration to achieve the desired speed.
  3. Consider the Load Conditions: Evaluate the expected load conditions, including the magnitude and direction of the load. Determine if the load is constant or variable, and if it involves shock loads or cyclic loading. This will impact the gear’s durability and load-carrying capacity.
  4. Calculate the Pitch Diameter: Based on the torque and speed requirements, calculate the pitch diameter of the spur gear. The pitch diameter is determined by the formula: Pitch Diameter = (2 x Torque) / (Pressure Angle x Allowable Tooth Shear Stress).
  5. Select the Module Size: Choose an appropriate module size based on the gear size and application requirements. The module size determines the tooth size and spacing. Smaller module sizes are used for fine tooth profiles and higher precision, while larger module sizes are suitable for heavier loads and higher torque applications.
  6. Determine the Number of Teeth: Based on the pitch diameter and module size, calculate the number of teeth required for the gear. Ensure that the gear has an adequate number of teeth for smooth operation, load distribution, and sufficient contact ratio.
  7. Consider Space Constraints: Evaluate the available space and mounting requirements in your application. Ensure that the selected gear size can fit within the available space and can be properly mounted on the shaft or gearbox.
  8. Choose the Material: Consider the operating conditions, such as temperature, humidity, and presence of corrosive substances, to select the appropriate material for the spur gear. Common materials include steel, cast iron, brass, and plastic. Choose a material that offers the necessary strength, wear resistance, and durability for your specific application.
  9. Consider Additional Design Features: Depending on your application requirements, you may need to consider additional design features such as profile shift, hub configuration, and surface treatments. Profile shift can optimize gear performance, while specific hub configurations and surface treatments may be necessary for proper mounting and enhanced durability.

It’s important to note that gear selection is a complex process, and it may require consultation with gear manufacturers or experts in the field. They can provide guidance based on their expertise and assist in selecting the most suitable spur gear for your specific application.

By thoroughly considering factors such as torque requirements, speed, load conditions, pitch diameter, module size, number of teeth, space constraints, material selection, and additional design features, you can choose the right size spur gear that meets the demands of your application in terms of performance, durability, and efficiency.

China Hot selling CZPT Plantery Gear Ratio (Final drive) Gft 110 T3 1435 for Tana Shark 5430 gear boxChina Hot selling CZPT Plantery Gear Ratio (Final drive) Gft 110 T3 1435 for Tana Shark 5430 gear box
editor by CX 2023-10-19