Product Description

Flexible Beam Coupling Shaft Coupling

 

Description of Flexible Beam Coupling Shaft Coupling

1. One-piece metallic beam coupling
2. Zero backlash, flexible shaft
3. Spiral and parallel cut designs available
4. Accommodates misalignment and shaft endplay
5. Identical clockwise and counterclockwise rotation
6. Available in aluminum or stainless steel
7. Multiple bore and shaft connecting configurations
 

Parameter of Flexible Beam Coupling Shaft Coupling

Model	D (mm)	L (mm)	d1-d2 (mm)	hex screw	L1 (mm)	L2 (mm)	L3 (mm)	Fasten Torque (n.m)
LR-D-D15L20	15	20	3.0-8.0	M3.	2.5	2	0.4	1.2
LR-D-D19L25	19	25	6.0-10.0	M3.	3	2	0.4	1.2
LR-D-D25L30	25	30	8.0-12.0	M4	4	2	0.4	2.5
LR-D-D30L35	30	35	8.0-18.0	M4	4	2.5	0.5	2.5
LR-D-D35L40	35	40	8.0-22.0	M5	5	2.5	0.5	5
LR-D-D40L45	40	45	10.0-28.0	M6	6	3.5	0.6	8

Model	Max bore (mm)	Rated Torque (n.m)	Max Torque (n.m)	Max speed (rpm)	Moment of Inertia (kg.m2)	Permissible Radial Deviation (degree)	Permissible Angular Deviation (degree)
LR-D-D15L20	8	0.5	1	30000	2.5*10-7	0.05	0.5
LR-D-D19L25	10	1	2	25000	5.8*10-7	0.05	0.5
LR-D-D25L30	12	1.5	3	18000	1.8*10-6	0.05	0.5
LR-D-D30L35	18	2	4	16000	4.7*10-6	0.05	0.5
LR-D-D35L40	22	3	6	14000	1.1*10-5	0.05	0.5
LR-D-D40L45	28	6	12	12000	2.3*10-5	0.05	0.5

Model	D (mm)	L (mm)	d1-d2 (mm)	Fasten Torque (n.m)
LT-D-D15L20	15	20	4.0-5.0	0.7
LT-D-D19L25	19	25	6.0-10.0	0.7
LT-D-D25L30	25	30	8.0-12.0	0.7
LT-D-D30L35	30	35	8.0-18.0	1.7
LT-D-D35L40	35	40	8.0-22.0	4
LT-D-D40L45	40	45	10.0-28.0	4

Model	Max bore (mm)	Rated Torque (n.m)	Max Torque (n.m)	Max speed (rpm)	Moment of Inertia (kg.m2)	Permissible Radial Deviation (degree)	Permissible Angular Deviation (degree)
LT-D-D15L20	5	0.5	1	30000	2.5*10-7	0.05	0.5
LT-D-D19L25	10	1	2	25000	5.8*10-7	0.05	0.5
LT-D-D25L30	12	1.5	3	18000	1.8*10-6	0.05	0.5
LT-D-D30L35	18	2	4	16000	4.7*10-6	0.05	0.5
LT-D-D35L40	22	3	6	14000	1.1*10-5	0.05	0.5
LT-D-D40L45	28	6	12	12000	2.3*10-5	0.05	0.5

 

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Comparison of Beam Couplings to Other Coupling Types in Terms of Backlash and Torsional Stiffness

When considering coupling options for motion control systems, two critical performance characteristics to evaluate are backlash and torsional stiffness. Backlash refers to the amount of rotational play or free movement between the connected shafts, while torsional stiffness indicates a coupling’s ability to resist torsional deformation when transmitting torque. Let’s compare beam couplings to other common coupling types in terms of these factors:

• Beam Couplings:

  Beam couplings generally exhibit low to minimal backlash due to their single or multiple helical beam design. The helical beams provide some flexibility to accommodate misalignment, but they maintain a relatively tight connection between the shafts, resulting in low backlash. This characteristic is especially valuable in precision motion control applications where eliminating play is essential for accurate positioning.

  In terms of torsional stiffness, beam couplings offer moderate to high values. The helical beams provide good torsional rigidity, making them suitable for applications that demand precise torque transmission and minimal torsional deflection. However, compared to other types like disc or jaw couplings, beam couplings may have slightly lower torsional stiffness.

• Disc Couplings:

  Disc couplings are known for their excellent torsional stiffness, providing robust torque transmission and minimal torsional deformation. They are ideal for applications requiring high precision and where torsional rigidity is critical.

  Regarding backlash, disc couplings typically have low to negligible values. Their design allows for precise and direct transmission of torque between the shafts, resulting in minimal rotational play.

• Jaw Couplings:

  Jaw couplings offer low to moderate torsional stiffness, making them suitable for applications with moderate torque requirements. They provide some flexibility to handle misalignment, but their torsional rigidity is not as high as disc couplings or certain types of beam couplings.

  Backlash in jaw couplings can vary depending on the specific design and materials. Some jaw couplings may have slightly more backlash compared to beam or disc couplings due to the elastomeric spider element used in their construction.

• Oldham Couplings:

  Oldham couplings offer low backlash performance due to their unique three-piece design, which incorporates two outer hubs and a middle disk. The design allows for consistent torque transmission and minimal play between the shafts.

  Torsional stiffness in Oldham couplings is moderate, providing a balance between flexibility and rigidity. While not as rigid as disc couplings, they still offer reliable torque transmission for various motion control applications.

In summary, beam couplings offer low to minimal backlash and moderate to high torsional stiffness, making them suitable for precision motion control applications that require a balance between flexibility and rigidity. Disc couplings provide excellent torsional stiffness and low backlash, making them an ideal choice for high-precision applications. Jaw couplings and Oldham couplings offer moderate performance in both backlash and torsional stiffness and are well-suited for applications with moderate torque and misalignment compensation requirements.

When selecting a coupling type, consider the specific needs of your application, such as the required precision, torque capacity, and misalignment compensation. Each coupling type has its advantages and limitations, and choosing the right one will contribute to the overall performance and reliability of your motion control system.

Safety Considerations for Installing or Using Beam Couplings in Industrial Setups

When installing or using beam couplings in industrial setups, several safety considerations should be taken into account to ensure the safe and reliable operation of the motion control systems. Here are some important safety considerations:

• Proper Installation:

  Ensure that beam couplings are correctly installed according to the manufacturer’s instructions. Follow the recommended torque values for tightening set screws or clamps to avoid over-tightening or under-tightening, which could lead to coupling failure or excessive wear.

• Shaft Alignment:

  Accurate shaft alignment is crucial to prevent unnecessary stress on the coupling and connected components. Misalignment can lead to premature wear, vibrations, and reduced system performance. Utilize alignment tools and techniques to achieve precise shaft alignment within the coupling’s specified tolerances.

• Overloading:

  Avoid exceeding the beam coupling’s rated torque capacity or maximum axial load. Overloading the coupling can lead to deformation, coupling failure, or damage to connected equipment. Ensure that the coupling is appropriately sized for the application’s torque requirements.

• Regular Inspection:

  Perform routine inspections of beam couplings to check for signs of wear, damage, or misalignment. Address any issues promptly and replace worn or damaged couplings to prevent unexpected failures.

• Environmental Conditions:

  Consider the operating environment when selecting beam couplings. Different materials offer varying levels of resistance to corrosion, temperature extremes, and other environmental factors. Choose a material that can withstand the specific conditions of the industrial setup.

• Protective Enclosures:

  If the beam couplings are exposed to moving parts or hazardous equipment, consider using protective enclosures or guards to prevent accidental contact and ensure operator safety.

• Regular Maintenance:

  Follow a regular maintenance schedule for the entire motion control system, including beam couplings. Lubricate moving parts as recommended by the manufacturer and replace worn components to maintain reliable operation.

• Training and Awareness:

  Ensure that personnel involved in the installation, operation, and maintenance of the motion control system are properly trained and aware of safety procedures. Emphasize the importance of following safety guidelines to prevent accidents and injuries.

By taking these safety considerations into account, industrial setups can enhance the safety and efficiency of their motion control systems. Regular maintenance, proper installation, and adherence to safety guidelines are essential to ensuring the longevity and reliable performance of beam couplings and the overall safety of the workplace.

Advantages of Using Beam Couplings in Precision Positioning Systems

Beam couplings offer several advantages when used in precision positioning systems. These advantages make them a popular choice for applications that demand accurate motion control and positioning. Here are the key benefits of using beam couplings in precision positioning systems:

• 1. Misalignment Compensation:

  Beam couplings are designed to provide flexible connections between shafts, allowing them to compensate for various types of misalignment, including angular, axial, and parallel misalignment. In precision positioning systems, where accurate alignment is critical for maintaining positioning accuracy, beam couplings help prevent unnecessary stress on the components caused by misalignment, reducing wear and ensuring consistent performance.

• 2. Torsional Rigidity:

  Beam couplings offer high torsional rigidity, meaning they effectively transmit torque without significant torsional deformation. This rigidity is essential for maintaining precise motion control and minimizing backlash in precision positioning systems. It ensures that the desired position is accurately maintained without undue twisting or torsional deflection.

• 3. Low Inertia:

  Beam couplings have a compact and lightweight design, resulting in low rotational inertia. Low inertia is crucial in precision positioning systems, as it allows for rapid and accurate changes in direction and speed. The low inertia of beam couplings helps improve the system’s response time and overall dynamic performance.

• 4. Zero Backlash:

  Beam couplings can provide backlash-free performance when correctly installed and utilized within their specified torque and speed ratings. This characteristic is particularly valuable in precision positioning systems, where any play or backlash can result in position errors and reduced accuracy.

• 5. Vibration Dampening:

  Beam couplings exhibit some degree of vibration dampening due to their flexible design. This feature is beneficial in precision positioning systems, where damping vibrations can reduce mechanical resonances, improve stability, and minimize settling times, resulting in smoother and more precise motion.

• 6. Long Service Life:

  High-quality beam couplings made from durable materials have excellent resistance to wear and fatigue. With proper installation and maintenance, beam couplings can have a long service life, providing reliable and consistent performance in precision positioning systems.

• 7. Easy Installation:

  Beam couplings are relatively easy to install and do not require elaborate alignment procedures. Their flexible design allows for some misalignment tolerance during installation, making the setup process more straightforward and efficient.

• 8. Cost-Effective:

  Beam couplings offer an excellent balance of performance and cost-effectiveness. Compared to some other types of precision couplings, beam couplings often provide a more budget-friendly solution without compromising on essential performance characteristics.

In summary, beam couplings offer significant advantages in precision positioning systems, including misalignment compensation, torsional rigidity, low inertia, zero backlash, vibration dampening, long service life, easy installation, and cost-effectiveness. These advantages contribute to the overall accuracy, stability, and reliability of precision motion control applications, making beam couplings a popular choice for demanding positioning tasks.

editor by CX 2024-02-11