Product Description

Good Quality Flexible Beam Coupling for CNC Machine

 

Description of Good Quality Flexible Beam Coupling for CNC Machine

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 Good Quality Flexible Beam Coupling for CNC Machine

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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Torque and Speed Ratings for Different Sizes and Materials of Beam Couplings

The torque and speed ratings of beam couplings vary depending on their size, design, and material composition. Different manufacturers offer beam couplings in various configurations to meet specific application requirements. Here are some general considerations regarding torque and speed ratings for different sizes and materials of beam couplings:

• Size and Design:

  Beam couplings come in different sizes and designs to accommodate various shaft diameters and misalignment compensation needs. Larger beam couplings typically have higher torque ratings, as their size allows for more robust construction and increased torsional rigidity. Likewise, different designs, such as single-beam, multi-beam, or bellows couplings, can affect the torque and speed capabilities.

• Material Composition:

  The choice of material for beam couplings significantly impacts their torque and speed ratings. Common materials used in beam couplings include stainless steel, aluminum, and other high-strength alloys. Stainless steel couplings generally have higher torque ratings and are more suitable for high-speed applications due to their excellent mechanical properties and resistance to wear and corrosion.

• Manufacturer Specifications:

  Each manufacturer provides specific torque and speed ratings for their beam coupling products. These ratings are determined through extensive testing and analysis to ensure reliable and safe operation within the specified limits. Always refer to the manufacturer’s datasheets and technical documentation for accurate and up-to-date information on torque and speed ratings.

• Operating Environment:

  The operating environment can also influence the torque and speed ratings of beam couplings. Factors such as temperature, humidity, and exposure to chemicals or harsh conditions may affect the material properties and performance of the coupling. Consider the application’s specific environment when selecting the appropriate coupling.

It is crucial to choose a beam coupling that matches the torque and speed requirements of your application. Exceeding the rated torque or speed can lead to premature wear, coupling failure, and potential damage to other system components. Conversely, selecting a coupling with excessive torque or speed capacity may result in unnecessary costs and reduced system efficiency.

When selecting a beam coupling, always consult the manufacturer’s documentation and consider the specific application requirements to ensure that the chosen coupling can handle the intended torque and speed levels effectively and safely.

Real-World Examples of Successful Beam Coupling Installations and Their Benefits

Beam couplings have been widely adopted in various industries, and there are numerous real-world examples of successful installations showcasing their benefits. Here are some specific cases:

• Industrial Automation:

  In a factory automation setting, beam couplings are used in robotic arms and automated machinery to transmit torque between motors and actuators. The flexibility of beam couplings helps compensate for minor misalignments, reducing wear on connected components and enhancing system reliability. Additionally, the low inertia of beam couplings enables faster response times, improving the overall efficiency of the automated systems.

• Medical Robotics:

  Medical robots, such as surgical robots and diagnostic equipment, rely on precise and smooth motion control. Beam couplings, with their low backlash and high torsional stiffness, ensure accurate positioning and reduced vibration. The stainless-steel construction of some medical-grade beam couplings makes them suitable for sterilization processes, ensuring compliance with medical industry requirements.

• Photonic Systems:

  In optical systems and laser equipment, beam couplings are used to connect stepper motors and motion stages. The damping properties of beam couplings help reduce vibrations, preventing optical misalignment and maintaining the stability of laser beams. This is critical for high-precision applications like laser cutting and micromachining.

• Satellite Components:

  Beam couplings find applications in satellite components, where weight and size constraints are critical. Aluminum or lightweight alloys are used to minimize the overall mass while providing reliable power transmission between actuators and mechanisms. The low inertia of beam couplings contributes to smoother satellite movements and precise adjustments in space.

• Renewable Energy Systems:

  Beam couplings are employed in renewable energy systems, such as solar tracking mechanisms and wind turbine pitch control systems. Their ability to handle harsh environmental conditions, such as wind and weather exposure, ensures consistent and efficient energy production. The use of non-magnetic materials in some couplings prevents interference with sensitive electronics.

The benefits of successful beam coupling installations in these real-world examples include:

• Improved Precision: Beam couplings provide accurate torque transmission, reducing positioning errors and enhancing the precision of motion control systems.
• Enhanced Reliability: The flexibility of beam couplings compensates for misalignments, reducing stress on connected components and extending the lifespan of the motion system.
• Reduced Vibrations: Beam couplings dampen vibrations, leading to smoother movements and preventing resonance-induced failures.
• Weight and Space Savings: In applications with weight and space constraints, beam couplings’ lightweight design is advantageous.
• Cost-Effectiveness: Beam couplings offer a cost-effective solution for motion control, especially when compared to more complex coupling options.

These successful installations demonstrate the versatility and effectiveness of beam couplings across various industries, highlighting their ability to improve motion system performance, reliability, and efficiency.

Beam Coupling: Function and Role in Mechanical Systems

A beam coupling, also known as a helical coupling or helical beam coupling, is a type of flexible coupling used in mechanical systems to connect two shafts while compensating for misalignment and transmitting torque. It consists of one or more helical beams (usually made of metal) that connect the shafts and allow for angular, axial, and parallel misalignment while maintaining a torsionally rigid connection. Here’s how a beam coupling functions in mechanical systems:

Structure:

A beam coupling typically has two ends, each with a helical beam. The beams are oriented at opposite angles to create a helix shape. The beams can vary in number, and some designs may include additional features like slits or keyways to enhance flexibility or improve torque capacity.

Misalignment Compensation:

When the two shafts connected by a beam coupling are misaligned, the helical beams flex, allowing the coupling to compensate for different types of misalignment. Angular misalignment occurs when the shafts are not collinear, axial misalignment when they are not on the same axis, and parallel misalignment when the shafts are not at the same height. The flexibility of the helical beams allows the coupling to accommodate these misalignments, reducing the stresses on the connected components.

Torque Transmission:

The helical beams of a beam coupling efficiently transmit torque from one shaft to the other. The beams twist and deform slightly under the applied torque but return to their original shape once the torque is removed. This torsional rigidity ensures that the coupling efficiently transfers rotational power while minimizing backlash and maintaining accurate positioning in motion control systems.

Damping and Vibration Absorption:

Beam couplings can provide some level of vibration dampening due to their inherent flexibility. The slight deformation of the beams can absorb shocks and vibrations, reducing the transmission of vibrations between the connected shafts.

Applications:

Beam couplings find applications in various mechanical systems, including robotics, CNC machines, stepper motor drives, and other motion control systems. They are especially useful in applications that require moderate misalignment compensation, high torsional rigidity, and low backlash.

Considerations:

While beam couplings offer several advantages, they do have some limitations. They may not be suitable for applications with high misalignment requirements or high torque loads, as excessive misalignment or torque can cause premature wear or failure of the coupling. Additionally, beam couplings may have limited axial stiffness, making them less suitable for applications with significant axial loads.

In summary, a beam coupling is a flexible coupling with helical beams that allows for misalignment compensation, efficient torque transmission, and some vibration dampening. Its design and flexibility make it an excellent choice for various mechanical systems, particularly those that require moderate misalignment compensation and high torsional rigidity.

editor by CX 2024-04-23