Product Description

GIC Spline Shaft Coupling Motor Couplings

Description of GIC Spline Shaft Coupling Motor Couplings
>Integrated structure, the overall use of high-strength aluminum alloy materials
>Elastic action compensates radial, angular and axial deviation
>No gap shaft and sleeve connection, suitable for CHINAMFG and reverse rotation
>Designed for encoder and stepper motor
>Fastening method of clamping screw

 

Catalogue of GIC Spline Shaft Coupling Motor Couplings

 

 

model parameter

common bore diameter d1,d2

ΦD

L

L1

L2

F

M

tightening screw torque
(N.M)

GIC-12xl8.5

2,3,4,5,6

12

18.5

0.55

1.3

2.5

M2.5

1

GIC-16xl6

3,4,5,6,6.35

16

16

0.55

1.4

3.18

M2.5

1

GIC-16×23

3,4,5,6,6.35

16

23

0.55

1.4

3.18

M2.5

1

GIC-19×23

3,4,5,6,6.35,7,8

19

23

0.55

1.4

3.18

M2.5

1

GIC-20×20

4,5,6,6.35,7,8,10

20

20

0.55

1.5

3.75

M2.5

1

GIC-20×26

4,5,6,6.35,7,8,10

20

26

0.55

1.5

3.75

M3

1.5

GIC-25×25

5,6,6.35,7,8,9,9.525,10,11,12

25

25

0.6

1.7

4.84

M3

1.5

GIC-25×31

5,6,6.35,7,8,9,9.525,10,11,12

25

31

0.6

1.8

4.46

M3

1.5

GIC-28.5×38

6,6.35,8,9,9.525,10,11,12,12.7,14

28.5

38

0.8

2.1

5.62

M4

2.5

GIC-32×32

8,9,9.525,10,11,12,12.7,14,15,16

32

32

0.8

2.3

6.07

M4

2.5

GIC-32×41

8,9,9.525,10,11,12,12.7,14,15,16

32

41

0.8

2.3

6.02

M4

2.5

GIC-38×41

8,9,9.525,10,11,12,14,15,16,17,18,19

38

41

0.8

2.7

5.32

M5

7

GIC-40×50

8,9,9.525,10,11,12,14,15,16,17,18,19,20

40

50

0.8

2.7

6.2

M5

7

GIC-40×56

8,10,11,12,12.7,14,15,16,17,18,19,20

40

56

0.8

2.7

8.5

M5

7

GIC-42×50

10,11,12,12.7,14,15,16,17,18,19,20,22,24

42

50

0.8

2.7

6.2

M5

7

GIC-50×50

10,12,12.7,14,15,16,17,18,19,20,22,24,25,28

50

50

0.8

2.9

7.22

M6

12

GIC-50×71

10,12,12.7,14,15,16,17,18,19,20,222425,28

50

71

0.8

3.3

8.5

M6

12

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)

weight

(g)

GIC-12xl8.5

0.5

0.1

2

±0.2

11000

60

4.8

GIC-16xl6

0.5

0.1

2

±0.2

10000

80

8

GIC-16×23

0.5

0.1

2

±0.2

9500

80

9.3

GIC-19×23

1

0.1

2

±0.2

9500

80

13

GIC-20×20

1

0.1

2

±0.2

10000

170

14

GIC-20×26

1

0.1

2

±0.2

7600

170

16.5

GIC-25×25

2

0.15

2

±0.2

6100

780

26

GIC-25×31

2

0.15

2

±0.2

6100

380

29

GIC-28.5×38

3

0.15

2

±0.2

5500

400

51

GIC-32×32

4

0.15

2

±0.2

5000

1100

56

GIC-32×41

4

0.15

2

±0.2

500

500

65

GIC-38×41

6.5

0.2

2

±0.2

650

650

107

GIC-40×50

6.5

0.2

2

±0.2

600

650

135

GIC-40×56

8

0.2

2

±0.2

800

800

142

GIC-42×50

8.5

0.2

2

±0.2

800

850

135

GIC-50×50

20

0.2

2

±0.2

1000

1000

220

GIC-50×71

20

0.2

2

±0.2

1000

1000

330

 

 

 

 

 

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spline coupling

What are the key differences between rigid and flexible mechanical couplings?

Rigid and flexible mechanical couplings are two main types of couplings used in various engineering applications. They differ significantly in their design and capabilities, each offering distinct advantages and limitations:

1. Design and Construction:

Rigid Couplings: Rigid couplings are solid and inflexible, typically made from materials like steel or aluminum. They have a compact design and provide a direct, non-flexible connection between the shafts.

Flexible Couplings: Flexible couplings are designed to provide some degree of flexibility between the connected shafts. They often consist of elements made from elastomers, rubber, or flexible materials that can bend or deform.

2. Misalignment Compensation:

Rigid Couplings: Rigid couplings are not designed to accommodate misalignment between the shafts. Precise alignment is critical for their effective operation.

Flexible Couplings: Flexible couplings can compensate for axial, radial, and angular misalignments between the shafts, allowing them to remain connected even when not perfectly aligned.

3. Torque Transmission:

Rigid Couplings: Rigid couplings provide an efficient and direct transfer of torque between the shafts. They are ideal for high-torque applications.

Flexible Couplings: Flexible couplings transmit torque between the shafts while allowing for some torsional flexibility. The torque transmission may not be as efficient as in rigid couplings, but they are suitable for applications with moderate torque requirements.

4. Vibration Damping:

Rigid Couplings: Rigid couplings do not have inherent vibration damping properties.

Flexible Couplings: Flexible couplings can dampen vibrations and shocks caused by imbalances or dynamic loads, reducing wear on connected components and enhancing system stability.

5. Applications:

Rigid Couplings: Rigid couplings are commonly used in applications where precise alignment is critical, such as in machine tools, gearboxes, and other systems requiring high precision.

Flexible Couplings: Flexible couplings find applications in various industries, including pumps, compressors, conveyor systems, automotive powertrains, and wherever misalignment compensation or vibration absorption is needed.

6. Maintenance:

Rigid Couplings: Rigid couplings generally require less maintenance due to their solid and simple design.

Flexible Couplings: Flexible couplings may require occasional maintenance, such as checking and replacing the flexible elements to ensure proper functioning.

In summary, the choice between rigid and flexible couplings depends on the specific requirements of the application. Rigid couplings offer excellent torque transmission and precision but require precise alignment. Flexible couplings accommodate misalignment and dampen vibrations, making them suitable for a wider range of applications but may have slightly lower torque transmission efficiency compared to rigid couplings.

“`spline coupling

Do mechanical couplings require regular maintenance, and if so, how often?

Yes, mechanical couplings do require regular maintenance to ensure their optimal performance and longevity. The frequency of maintenance depends on various factors, including the type of coupling, the application’s operating conditions, and the manufacturer’s recommendations. Here are some general guidelines for the maintenance of mechanical couplings:

1. Visual Inspection:

Perform regular visual inspections of the coupling to check for signs of wear, damage, or misalignment. Inspect for any corrosion, cracks, or wear on the coupling components.

2. Lubrication:

Some mechanical couplings, especially those with moving parts or sliding surfaces, require periodic lubrication. Follow the manufacturer’s recommendations regarding the type and frequency of lubrication.

3. Torque Verification:

Check the tightness of fasteners, such as set screws or bolts, to ensure that the coupling is securely attached to the shafts. Loose fasteners can lead to misalignment and reduced performance.

4. Alignment Check:

Regularly check the alignment of the connected shafts to ensure that the coupling is operating within its design limits. Misalignment can lead to premature wear and reduced coupling efficiency.

5. Replacement of Worn Components:

If any coupling components show signs of wear or damage beyond acceptable limits, replace them promptly to prevent further issues.

6. Operating Condition Analysis:

Monitor the operating conditions of the mechanical system and assess whether any changes have occurred that may affect the coupling’s performance. Environmental conditions, load variations, and other factors can impact the coupling’s wear rate.

7. Manufacturer’s Guidelines:

Always follow the maintenance recommendations provided by the coupling manufacturer. The manufacturer’s guidelines may include specific inspection intervals and maintenance procedures tailored to the coupling type and application.

The maintenance frequency for mechanical couplings can vary from monthly inspections for high-demand applications to annual inspections for less demanding conditions. In some cases, couplings in critical systems may require more frequent inspections to ensure their reliability.

Implementing a proactive maintenance program for mechanical couplings helps identify potential issues early and prevents unexpected failures that can lead to costly downtime and repairs. Regular maintenance extends the life of the coupling, improves system efficiency, and enhances overall operational safety.

“`spline coupling

What is a mechanical coupling and its significance in engineering applications?

A mechanical coupling is a device used to connect two rotating shafts or components in a mechanical system to transmit torque and motion between them. It plays a crucial role in various engineering applications by providing a reliable and efficient means of power transmission. The significance of mechanical couplings in engineering applications can be understood through the following points:

1. Torque Transmission:

One of the primary functions of a mechanical coupling is to transmit torque from one shaft to another. This allows for the transfer of power between different components of a machine or system.

2. Misalignment Compensation:

Mechanical couplings can accommodate certain degrees of misalignment between connected shafts. This is crucial in real-world applications where perfect alignment may not always be achievable or maintained due to various factors.

3. Vibration Damping:

Some mechanical couplings, especially flexible couplings, help dampen vibrations caused by imbalances or load fluctuations. This feature prevents excessive wear on components and improves the overall stability and performance of the system.

4. Shock Absorption:

In systems subject to sudden shocks or impacts, mechanical couplings with certain flexibility can absorb and dissipate the energy, protecting the connected equipment from damage.

5. Load Distribution:

By connecting two shafts, a mechanical coupling can evenly distribute the load between them. This ensures that both shafts share the torque and forces, preventing premature wear on a single shaft.

6. Versatility:

Mechanical couplings come in various types and designs, each tailored to specific applications. This versatility allows engineers to choose the most suitable coupling based on factors such as load requirements, speed, misalignment tolerance, and environmental conditions.

7. Maintenance and Repair:

In engineering applications, mechanical couplings are generally modular and easy to replace, simplifying maintenance and repair tasks. This helps reduce downtime and improves the overall efficiency of the system.

8. Reducing Overload:

In scenarios where the connected components experience overload or excessive torque, certain types of mechanical couplings can act as a safety feature by slipping or disengaging before damage occurs, protecting the system from catastrophic failure.

Overall, mechanical couplings are essential components in various engineering applications, including industrial machinery, automotive systems, power transmission, robotics, and many others. Their ability to reliably connect rotating shafts, transmit torque, and compensate for misalignment contributes significantly to the smooth and efficient operation of mechanical systems.

“`
China Good quality Gic Spline Shaft Coupling Motor Couplings   spline couplingChina Good quality Gic Spline Shaft Coupling Motor Couplings   spline coupling
editor by CX 2024-02-16