Product Description

Hot sale: low noise,no leakage, no additional cost for pump motor coupling electric motor coupling magnetic coupling principle

Please send us following information.
1. Motor output power(KW)
2. Motor speed(RPM)
3. Torque of the mangetic coupling
4. Working pressure of the housing(isolation sleeve)
5. Working temperature of magnetic coupling
6. Technical drawing of the output part connector (usually motor)
7. Technical drawing of the input part connector (usually pump)

Introduction of pump motor coupling electric motor coupling magnetic coupling principle

Magnetic shaft coupling is a new kind of coupling, which connects motor and machine by permanent magnetic force. 

They are consisted of external rotor, internal rotor and isolating covers.

They work in the sealed magnetic drive pumps, which transporting volatile, flammable, explosive and toxic solutions with no leakage. 

These magnetic shaft couplings can be used to connect gear pumps , screw pumps, centrifugal pumps, etc. with all types of electric motor or gear box. 

Magnetic shaft coupling are widely used in various industries and fields, such as chemical, papermaking, foodstuff, pharmacy, and so on. 

Advantages of pump motor coupling electric motor coupling magnetic coupling principle

» Elimination of fluid leakage from the pump shaft.

» Vibrations are not transmitted to the pump.

» No maintenance required for magnetic couplings.

» Using magnetic couplings allows use of standard pumps without expensive mechanical seals.

» No additional cost for purchasing mechanical seal spare parts and maintenance.

 

Technical drawing of pump motor coupling electric motor coupling magnetic coupling principle

Specification of pump motor coupling electric motor coupling magnetic coupling principle

Item

Internal Rotor(mm)

External Rotor(mm)

Isolating Covering(mm)

A

B

C

D

E

F

G

Shaft Pin

H

I

J

L

N

M

P

Q

R

S

T

U

GME03-3LM00

Φ35

–

Φ10

26

–

18

–

M6X12

Φ42

Φ60

Φ50

46

6-M4

Φ40

Φ50

4-Φ5.4

Φ38

Φ60

6

6

GME03-5MM00

Φ42

–

Φ12

27

4

18

13.8

M6X16

Φ49

Φ72

Φ60

46

4-Φ6.7

Φ52

Φ60

4-Φ6.7

Φ44

Φ74

8

8

GME03-16LM00

Φ56

–

Φ12

45

4

25

13.8

M6X16

Φ63

Φ89

Φ80

75

6-M5

Φ70

Φ75

4-Φ6.7

Φ58

Φ89

8

8

GME03-16LM01

Φ56

–

Φ12

45

4

25

13.8

M6X16

Φ63

Φ89

Φ80

75

4-M5

Φ70

Φ75

4-Φ6.7

Φ58

Φ89

6

10

GME03-16MM00

Φ56

–

Φ12

45

4

25

13.8

M6X16

Φ63

Φ89

Φ80

75

6-M5

Φ70

Φ75

4-Φ6.7

Φ58

Φ89

8

8

GME03-22LM00

Φ88

–

Φ20

29

6

25

22.8

M8X20

Φ97

Φ122

Φ110

70

8-M6

Φ98

Φ108

6-Φ6.7

Φ91

Φ122

8

8

GME03-30LM00

Φ88

–

Φ20

48

6

30

22.8

M8X20

Φ97

Φ122

Φ110

81

8-M6

Φ98

Φ108

6-Φ6.7

Φ91

Φ122

8

8

GME03-40LM00

Φ101

–

Φ25

49

8

28

28.3

M10X20

Φ109

Φ140

Φ124

83

8-M8

Φ110

Φ126

8-Φ6.7

Φ103

Φ140

12

6

GME03-50LM00

Φ107

–

Φ20

70

6

30

22.8

M6X16

Φ113.4

Φ145

Φ135

80

4-M6

Φ126

Φ133

12-Φ8.7

Φ109

Φ153

12

15

GME03-65LM00

Φ101

–

Φ25

77

8

45

28.3

M10X20

Φ109

Φ140

Φ124

111

8-M8

Φ110

Φ126

8-Φ6.7

Φ103

Φ140

12

6

GME03-80LM00

Φ106

–

Φ32

65

10

21

36.5

M6X25

Φ115

Φ145

Φ135

82

4-M6

Φ127

Φ135

6-Φ8.7

Φ110

Φ153

13

18

GME03-80LM00

Φ141

Φ92

Φ40

65

12

45

43.3

M12X25

Φ152

Φ180

Φ168

100

8-M8

Φ154

Φ164

8-Φ6.7

Φ145

Φ180

12

8

GME03-100LM00

Φ131

Φ82

Φ32

80

10

24.5

35.3

M8X35

Φ139

Φ170

Φ160

100

4-M6

Φ152

Φ158

8-Φ8.7

Φ133

Φ178

14

21

GME03-110LH00

Φ141

Φ92

Φ40

85

10

50

43.3

M12X25

Φ152

Φ184

Φ168

115

12-M8

Φ156

Φ164

12-Φ6.7

Φ145

Φ180

12

3

GME03-110LM00

Φ141

Φ92

Φ35

80

10

55

38.3

M12X25

Φ152

Φ180

Φ168

115

12-M8

Φ154

Φ164

12-Φ6.7

Φ145

Φ180

12

3

GME03-140LM00

Φ141

Φ92

Φ40

110

12

80

43.3

M12X25

Φ152

Φ190

Φ170

145

12-M10

Φ154

Φ164

12-Φ6.7

Φ145

Φ180

12

3

GME03-180LM00

Φ141

Φ92

Φ40

140

12

95

43.3

M12X25

Φ152

Φ190

Φ170

175

12-M10

Φ154

Φ164

12-Φ6.7

Φ145

Φ180

12

3

GME03-220LM00

Φ141

Φ92

Φ48

160

14

110

51.8

M12X25

Φ152

Φ190

Φ170

195

12-M10

Φ154

Φ164

12-Φ6.7

Φ145

Φ180

12

3

GME03-300LM00

Φ162

–

Φ65

100

18

60

69.4

Φ170

Φ198

Φ188

123

12-M6

Φ180

Φ192

12-Φ11

Φ163.5

Φ218

16

10

GME03-400LH00

Φ195

–

Φ70

127

20

107

79.9

M12X25

Φ203

Φ234

Φ222

152

6-M6

Φ212

Φ164

12-Φ11

Φ198

Φ278

16

22

Application of pump motor coupling electric motor coupling magnetic coupling principle

The ability to hermetically separate 2 areas whilst continuing to transmit mechanical power from one to the other makes these couplings ideal for applications where prevention of cross contamination is essential. For instance: hydraulic sectors, dosing systems, compressors, sterilizers, industrial ovens, biotechnology, subsea equipment, pharmaceutical industry, chemical industry, food industry, generators and mixers.

 

 

 

Operation principles of pump motor coupling electric motor coupling magnetic coupling principle

The magnetic coupling works by using the power generated by permanent magnets. No external power supply is needed. These are permanent magnets not electro magnets.

 

Packing Method of pump motor coupling electric motor coupling magnetic coupling principle

Double strength corrugated Carton and Wood case Sea Packing.

 

 

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Maintenance Requirements for Magnetic Couplings to Ensure Long-Term Performance

Magnetic couplings are designed to be low-maintenance compared to traditional mechanical couplings. However, some maintenance practices can help ensure their long-term performance and reliability. Here are the key maintenance requirements for magnetic couplings:

1. Regular Inspection:

   Perform regular visual inspections of the magnetic coupling to check for signs of wear, damage, or misalignment. Look for any unusual noises or vibrations during operation, which may indicate a potential issue that requires attention.

2. Cleanliness:

   Keep the magnetic coupling and surrounding area clean and free from dirt, debris, or contaminants. Foreign particles on the coupling’s surface can affect its magnetic performance and lead to energy losses.

3. Lubrication:

   Magnetic couplings do not require traditional lubrication since they operate without physical contact. However, some couplings may have bearings or other components that require lubrication. Refer to the manufacturer’s guidelines for specific lubrication requirements.

4. Environmental Considerations:

   Ensure that the operating environment of the magnetic coupling is within the specified limits provided by the manufacturer. Extreme temperatures, aggressive chemicals, or other harsh conditions can affect the performance and longevity of the coupling.

5. Alignment Check:

   Periodically check the alignment of the driving and driven shafts. Although magnetic couplings can tolerate some misalignment, ensuring proper alignment will optimize efficiency and reduce stress on the coupling components.

6. Torque and Speed Limits:

   Adhere to the specified torque and speed limits for the magnetic coupling based on the application requirements. Operating the coupling beyond its rated capacity can lead to premature failure.

7. Overload Protection:

   If the application involves occasional overloads, consider incorporating overload protection features, such as torque limiters or slip mechanisms, to prevent damage to the coupling and connected equipment.

8. Regular Maintenance Schedule:

   Establish a regular maintenance schedule based on the manufacturer’s recommendations. Periodic inspections, cleaning, and other maintenance tasks can help identify and address potential issues before they escalate.

9. Expert Support:

   When in doubt or if encountering any significant issues, seek assistance from the magnetic coupling manufacturer or a qualified engineer. They can provide guidance on maintenance best practices and address any specific concerns related to the coupling’s performance.

By following these maintenance requirements, you can ensure the long-term performance, reliability, and efficiency of the magnetic coupling in your application.

How do Magnetic Couplings Contribute to the Overall System Reliability and Prevent Mechanical Wear?

Magnetic couplings offer several advantages that contribute to the overall system reliability and prevent mechanical wear. These benefits are a result of their non-contact power transmission principle and unique design features. Here’s how magnetic couplings achieve this:

1. No Physical Contact:

   Magnetic couplings operate without any physical contact between the driving and driven components. Unlike traditional mechanical couplings that rely on friction and wear-prone components, magnetic couplings use magnetic fields to transfer torque and power. This absence of physical contact eliminates mechanical wear and reduces the need for regular maintenance and replacement of wearing parts.

2. Hermetic Sealing:

   Magnetic couplings often feature a hermetic sealing design that prevents fluid leakage. The driving and driven components are separated by a sealed containment shell, which ensures that there is no direct exposure to the environment or the fluid being handled. This hermetic sealing not only prevents leakage but also protects sensitive components from contamination and external influences, enhancing the overall system reliability.

3. Reduced Friction Losses:

   Since there is no physical contact between the coupling’s components, magnetic couplings experience minimal friction losses during operation. The reduction in frictional forces translates to higher efficiency and lower energy consumption compared to traditional couplings with sliding or rolling elements.

4. Tolerance to Misalignment:

   Magnetic couplings can accommodate a certain degree of misalignment between the driving and driven components. This misalignment tolerance helps to minimize stress on the coupling and connected equipment, reducing the risk of premature wear or failure in situations where perfect alignment may not be achievable or maintained over time.

5. Overload Protection:

   Some magnetic couplings are designed with built-in overload protection features. In case of excessive torque or sudden overloads, these couplings can disengage or slip, preventing damage to the coupling and the connected machinery. This overload protection contributes to the long-term reliability of the system by avoiding potential catastrophic failures.

6. No Lubrication Required:

   Unlike many traditional mechanical couplings that need regular lubrication to reduce friction and wear, magnetic couplings do not require lubrication. The absence of lubricants simplifies maintenance and eliminates the risk of lubricant contamination in sensitive applications.

Overall, magnetic couplings offer a reliable and efficient solution for various applications, especially in industries where the prevention of mechanical wear, fluid leakage, and frequent maintenance are essential considerations. Their non-contact design, hermetic sealing, and tolerance to misalignment make them an attractive choice for critical systems that demand high reliability and performance.

How to Select the Right Magnetic Coupling for Specific Fluid Handling Systems

Selecting the right magnetic coupling for fluid handling systems requires careful consideration of various factors to ensure optimal performance and reliability. Here are the key steps to help you make the right choice:

1. Fluid Properties:

   Understand the properties of the fluid being handled, including its viscosity, temperature, and corrosiveness. High-viscosity fluids may require magnetic couplings with stronger torque capabilities, while corrosive fluids may necessitate materials with excellent chemical resistance, such as stainless steel or specialized coatings.

2. Flow Rate and Pressure:

   Assess the required flow rate and system pressure. Magnetic couplings must be capable of transmitting the necessary torque to handle the fluid flow at the desired pressure levels. High-pressure systems may require magnetic couplings with enhanced strength and reliability.

3. Misalignment Compensation:

   Consider the potential misalignment between the motor and pump shafts. Magnetic couplings are known for their ability to accommodate misalignment to some extent. Assess the expected misalignment in your fluid handling system and choose a coupling with appropriate flexibility to compensate for it.

4. Sealing Requirements:

   Examine the sealing requirements of the fluid handling system. Magnetic couplings can provide hermetic sealing, preventing fluid leakage or contamination in critical applications. Ensure that the chosen coupling offers the necessary level of sealing to suit your system’s needs.

5. Torque and Speed Ratings:

   Check the torque and speed ratings of the magnetic coupling. Ensure that the selected coupling can handle the required torque and speed for your fluid handling application. High-speed pumps may require magnetic couplings specifically designed to minimize eddy current losses.

6. Environmental Conditions:

   Consider the environmental conditions in which the magnetic coupling will operate. Factors such as temperature extremes, humidity, and exposure to harsh chemicals can impact the coupling’s performance and lifespan. Choose a coupling that is designed to withstand the specific environmental challenges.

7. System Integration:

   Ensure that the magnetic coupling can be easily integrated into your fluid handling system. Consider factors such as coupling dimensions, mounting options, and alignment procedures. A well-integrated coupling will simplify installation and maintenance processes.

8. Manufacturer Reputation:

   Work with reputable manufacturers with a proven track record in producing high-quality magnetic couplings for fluid handling systems. Check for certifications and industry compliance to ensure the coupling meets required standards.

By carefully evaluating these factors and selecting a magnetic coupling that aligns with the specific fluid handling system requirements, you can ensure reliable and efficient operation while minimizing the risk of downtime and maintenance issues.

editor by CX 2024-04-08