China manufacturer Gd Encoder Shaft Coupling Spring Coupling Gd-16 X35

Product Description

GD Encoder Shaft Coupling Spring Coupling GD-16 x35

 

Description of GD Encoder Shaft Coupling Spring Coupling GD-16 x35
>The main body is made of zinc alloy
>The middle elastomer is made of spring steel
>It has the advantages of simple structure, good flexibility, low inertia and less allowable angular deviation
>Easy installation, spring steel more effective compensation radial, shaft deviation
>Suitable for micro motor and encoder
>Fastening method of set screw

 

Catalogue of GD Encoder Shaft Coupling Spring Coupling GD-16 x35

 

 

model parameter

common bore diameter d1,d2

ΦD

L

LF

F

M

tightening screw torque
(N.M)

GD-16 x27

5,6,6.35,7,8,9,10

16

27

8.5

3

M3

0.7

GD-16 x35

5,6,6.35,7,8,9,10

16

35

12.5

3.5

M4

1.7

GD-26 x50

6,6.35,7,8,9,10,11,12,12.7,14

26

50

17

4.5

M5

4

model parameter

Rated torque(N.m)

Maximum torque(N.M)

maximum speed

(rpm)

moment of inertia(Kg.M2)

allowable eccentricity(mm)

allowable deflection angle(°)

weight

(g)

GD-16 x27

0.5

1

3000

1.02×10-6

1

8

30

GD-16 x35

0.5

1

3000

1.02×10-6

1

8

70

GD-26 x50

1.5

3

3000

1.15×10-5

1.2

8

130

 

 

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shaft coupling

Crucial Industries and Applications for Encoder Couplings

Encoder couplings play a vital role in various industries and applications that require precise motion control and accurate signal transmission. Some examples include:

1. CNC Machining: In computer numerical control (CNC) machining, encoder couplings ensure accurate positioning of machine axes, resulting in precise and intricate machining of complex parts.

2. Robotics: Robotic systems rely on encoder couplings to enable precise movement control of robotic arms, ensuring accurate positioning and manipulation of objects in industries such as manufacturing and healthcare.

3. Semiconductor Manufacturing: In the semiconductor industry, encoder couplings are crucial for aligning and controlling the movement of wafer handling systems, which are essential for producing microchips and electronic components.

4. Printing and Packaging: In printing and packaging machinery, encoder couplings ensure precise control of printing heads, paper feeding, and packaging processes, resulting in high-quality and consistent output.

5. Medical Equipment: Encoder couplings are used in medical equipment such as imaging devices, robotic surgery systems, and diagnostic equipment to enable accurate and controlled movement for medical procedures.

6. Aerospace and Defense: In aerospace applications, encoder couplings are employed in aircraft control systems, radar systems, and satellite positioning systems, ensuring precise navigation and communication.

7. Automated Assembly Lines: Industries using automated assembly lines, such as automotive manufacturing, rely on encoder couplings to synchronize the movement of conveyor belts, robotic arms, and other components.

8. Laboratory Automation: In laboratory settings, encoder couplings contribute to the precise movement of instruments and devices for sample handling, analysis, and testing.

These examples illustrate the wide range of industries and applications where encoder couplings are crucial for achieving accurate motion control and maintaining signal integrity.

shaft coupling

Design Influence on Encoder Coupling’s Handling of Angular Misalignment

The design of an encoder coupling plays a crucial role in its ability to handle angular misalignment between shafts. Here’s how the design factors influence this capability:

  • Flexibility: Encoder couplings are designed with a certain level of flexibility to accommodate misalignment. Flexible elements, such as elastomeric inserts or helical cuts, allow the coupling to bend and compensate for angular errors without transmitting excessive stress to connected components.
  • Angular Offset Range: The design specifies the maximum angular misalignment that an encoder coupling can effectively handle. This range is determined by the coupling’s flexibility, material properties, and geometry.
  • Multi-Beam Design: Some encoder couplings feature a multi-beam design with multiple flexible beams arranged around the circumference. This design increases the coupling’s ability to absorb angular misalignment while maintaining consistent torque transmission.
  • Torsional Stiffness: While flexibility is essential, an overly flexible coupling might not be suitable for applications requiring precise motion control. The design must strike a balance between flexibility and torsional stiffness to ensure accurate signal transmission.
  • Backlash: The design should minimize or control backlash, which is the play or free movement that can occur when reversing the rotational direction. Excessive backlash can lead to inaccuracies in signal transmission and motion control.
  • Compactness: The design should aim for a compact form to fit within space-constrained environments while still providing the necessary angular misalignment compensation.
  • Material Selection: The choice of materials impacts the coupling’s ability to handle misalignment. Flexible materials like elastomers or certain metals can better accommodate angular deviations.

In summary, the design of an encoder coupling directly influences its capacity to handle angular misalignment, ensuring smooth signal transmission and accurate motion control.

shaft coupling

Role of Encoder Couplings in Motion Control and Automation

An encoder coupling is a crucial component in motion control and automation systems, used to facilitate precise position and speed sensing:

It connects the shafts of a motor and an encoder, allowing the accurate transmission of rotational motion while maintaining precise alignment. The primary functions and usage of an encoder coupling include:

  • Rotational Precision: Encoder couplings ensure that the rotational motion of the motor shaft is accurately transmitted to the encoder, preserving the exact position and speed information.
  • Misalignment Compensation: They can accommodate slight misalignments between the motor and the encoder shafts, which can occur due to manufacturing tolerances or shaft deflection during operation.
  • Torsional Stiffness: Encoder couplings maintain torsional stiffness to ensure minimal torsional deformation during motion, preventing signal inaccuracies and maintaining synchronization.
  • Signal Integrity: Maintaining precise alignment helps preserve the integrity of the electrical signals generated by the encoder, ensuring accurate position and speed measurements.
  • Reduced Wear: By minimizing misalignment and torsional stress, encoder couplings help reduce wear and extend the lifespan of both the motor and the encoder.

Overall, encoder couplings are essential for achieving accurate motion control and automation, enabling precise positioning and speed control in various applications such as robotics, CNC machines, conveyor systems, and more.

China manufacturer Gd Encoder Shaft Coupling Spring Coupling Gd-16 X35  China manufacturer Gd Encoder Shaft Coupling Spring Coupling Gd-16 X35
editor by CX 2024-01-16