Product Description

 

GB 8 Fonts Encoder-specific Series coupling Special aluminium alloy coupling for encoder


Description of
 GB 8 Fonts Encoder-specific Series coupling Special aluminium alloy coupling
>Designed for encoder
>Good flexibility, not easy to break
>The elastomer is made of polyurethane, resistant to oil and oxidation

Dimensions of GB 8 Fonts Encoder-specific Series coupling Special aluminium alloy coupling

  

model parameter common bore diameter d1,d2 ΦD L LP S F M tightening screw torque
(N.M)
GB-15X24 3,4,5,6,6.35,7,8 15 24 20 1.8 2.5 M3 0.7
GB-15×32 3,4,5,6,6.35,7,8 15 32 20 1.8 2.5 M3 0.7
GB-18×28 4,5,6,6.35,7,8,9,10 18 28 25 1.8 3.1 M4 1.7
GB-18×38 4,5,6,6.35,7,8,9,10 18 38 25 1.8 3.1 M4 1.7

model parameter Rated torque
(N.M)*
allowable eccentricity
(mm)*
allowable deflection angle
(°)*
allowable axial deviation
(mm)*
maximum speed
rpm
static torsional stiffness
(N.M/rad)
moment of inertia
(Kg.M2)
Material of shaft sleeve Material of shrapnel surface treatment weight
(g)
GB-15X24 0.5 1 2 + 2-5 8000 15 4.5×10-4 High strength aluminum alloy PU

 

Anodizing treatment

8
GB-15X32 0.5 1 2 + 2-5 8000 15 4.5×10-4 8
GB-18X28 0.8 1 3 + 2-5 6000 20 5.6×10-4 13
GB-18X38 0.8 1 3 + 2-5 6000 20 5.6×10-4 13

 

shaft coupling

High-Speed Rotations and Signal Accuracy in Encoder Couplings

Encoder couplings are designed to handle high-speed rotations while maintaining accurate signal transmission between the encoder and the driven shaft. Several factors contribute to their ability to achieve this:

1. Precision Manufacturing: Encoder couplings are manufactured with high precision to ensure minimal runout and concentricity errors. This precision minimizes vibrations and ensures accurate signal transmission at high speeds.

2. Low Backlash: Many encoder couplings are designed to have minimal or zero backlash. Backlash refers to the play or movement between the coupling’s mating components. Low backlash reduces signal inaccuracies caused by sudden changes in direction or speed.

3. Balanced Design: Balanced design helps distribute forces and torques evenly across the coupling, reducing the likelihood of vibration-induced signal distortions during high-speed rotations.

4. Material Selection: The choice of materials with suitable mechanical properties plays a role in achieving high-speed performance. Materials with low density and high strength help minimize the coupling’s mass while maintaining structural integrity.

5. Vibration Damping: Some encoder couplings incorporate vibration-damping features, such as elastomeric inserts, to mitigate vibrations and oscillations generated during high-speed rotations.

6. Dynamic Balance: Encoder couplings may undergo dynamic balancing to ensure that any uneven mass distribution is corrected, further reducing vibrations at high speeds.

7. Bearing Support: Proper bearing support on both sides of the encoder coupling helps maintain alignment and reduces stress on the coupling and encoder shaft, enhancing signal accuracy.

Encoder couplings are engineered to offer high-speed capabilities while preserving signal accuracy, making them suitable for applications where precision motion control and signal integrity are critical.

shaft coupling

Impact of Encoder Resolution on Choice of Coupling

The encoder resolution plays a crucial role in selecting an appropriate coupling for your system. Encoder resolution refers to the number of distinct positions a rotary encoder can detect in one full rotation. Here’s how encoder resolution impacts the choice of coupling:

1. Precision Requirements:

Higher encoder resolutions provide finer position accuracy. If your application demands high precision and accuracy, such as in robotics or CNC machines, a coupling that minimizes backlash and offers precise torque transmission is essential.

2. Backlash Sensitivity:

As encoder resolution increases, the system becomes more sensitive to backlash (play between coupling components). To mitigate this, a coupling with minimal backlash, such as a zero-backlash or low-backlash coupling, is recommended to ensure accurate position feedback.

3. Dynamic Response:

Higher encoder resolutions allow systems to detect even small movements, improving dynamic response. For applications requiring rapid and accurate positioning changes, a coupling that provides high torsional stiffness and low wind-up is beneficial.

4. Mechanical Compliance:

Low-resolution encoders may tolerate some misalignment due to their coarser feedback intervals. However, high-resolution encoders are more sensitive to misalignment, making it important to choose a coupling that accommodates misalignment while maintaining signal accuracy.

5. Coupling Selection:

For high-resolution encoders, consider couplings that provide precision, low backlash, and accurate torque transmission, such as beam couplings, bellows couplings, or Oldham couplings. These couplings help maintain the integrity of position feedback and optimize system performance.

6. Environmental Factors:

The operating environment can affect the choice of coupling. For applications with extreme conditions, such as temperature fluctuations or aggressive chemicals, select a coupling material that can withstand these conditions without compromising the encoder’s accuracy.

Ultimately, the encoder resolution influences the coupling choice by demanding a coupling that complements the precision, accuracy, and dynamic performance required by the application.

shaft coupling

Facilitating Precise Signal Transmission with Encoder Couplings

An encoder coupling plays a crucial role in facilitating precise signal transmission between the encoder and the shaft in motion control and automation systems. Here’s how it works:

1. Minimizing Misalignment: Encoder couplings are designed to accommodate various types of misalignment, including angular, axial, and radial misalignment. By allowing controlled flexibility, the coupling minimizes the stress on both the encoder and the shaft, ensuring accurate signal transmission.

2. Reducing Backlash: Backlash is the amount of movement a system can experience before the motion is effectively transferred. High-quality encoder couplings have minimal backlash, ensuring that the encoder’s output accurately corresponds to the shaft’s movement.

3. Increasing Torque Transmission: Encoder couplings provide efficient torque transmission between the encoder and the shaft, allowing the encoder to accurately detect changes in position or speed.

4. Enhancing Response Time: The mechanical properties of the encoder coupling ensure that any changes in the shaft’s position or movement are promptly transmitted to the encoder. This results in a faster response time and more accurate signal feedback.

5. Reducing Signal Disturbances: Vibrations, shocks, and other disturbances in machinery can negatively impact signal accuracy. A well-designed encoder coupling dampens vibrations and disturbances, ensuring that the encoder receives a clean and accurate signal.

6. Compensating for Thermal Expansion: In some applications, temperature changes can cause the shaft and encoder to expand or contract at different rates. Encoder couplings accommodate these thermal variations, preventing signal discrepancies caused by thermal expansion.

Overall, the encoder coupling acts as a reliable intermediary between the encoder and the shaft, ensuring that the signal accurately reflects the shaft’s position, speed, and movement. This precise signal transmission is essential for the accurate control and performance of motion control and automation systems.

China factory GB-15X24 Fonts Encoder-Specific Series Coupling Special Aluminium Alloy Coupling for Encoder  China factory GB-15X24 Fonts Encoder-Specific Series Coupling Special Aluminium Alloy Coupling for Encoder
editor by CX 2023-11-16