Product Description

Product Description

CNC Machining Milling Turning Aluminum Stainless Steel Low Force Link Slimline Strain Sensor Connect Body Liner Stage  Liner Stage Thread Adaptor Beam Coupling

Product Parameters

Processing CNC Machining, CNC Milling and Turning, Drilling, Grinding, Stamping, Tapping, Bending
Surface Finishing Electroplating, Anodizing, Polishing, Chrome Plating, Zinc plating, Nickel plating, Electrophoresis, Sandblasting, Passivation, Powder Coating, Painting, etc.
Certification standards ISO9001:2015  IAFT16949:2016
Service type OEM and ODM
Tolerance +/-0.005mm
Surface Roughness Ra0.8
Dimensions According to Customer’s Drawing
Processing Equipments CNC Machining Center, CNC Milling Machine, CNC Turning Machine, CNC Gantry, Vertical CNC center, Horizantal CNC center, Drilling Machine,Grinding Machine, etc.
Testing Equipments CMM,Laser Precision Detection Projector, Pull Tester, Automatic Optical Inspector, Salt Spray Tester, Durometer, Tensile Machine Calipers
Application Automotive industry, Medical DeviceS, UAV Industry, Communication Electronics Appliance, Robot, Mold Components Processed and Fixrure, 0il, Gas and Other Heavy Equipments.
Drawing Format PDF/JPEG/AI/PSD/CAD/Dwg/Step/LGS
MOQ 1 piece
QC Policy 100% inspection with report, random inspection before shipment, third-party inspections can be provided CHINAMFG request
Packaging PE bags or bubble bags, boxes, cartons, pallet or as per customers’ requirements
Trade Terms EXW, FOB, CIF, As per customers’ request
Payment Terms L/C, T/T, D/P, Western Union, Paypal, Money Gram, etc.
Delivery Time 7-14 working days after deposit payment received for samples,official orders negotiable
Production Capacity 1000000pcs/Months

 

Company Profile

Production Line

 

 

Equipments List

Certifications

FAQ

1: Are You a Manufacturer?
Yes, we specialize in manufacturing of CNC machining parts over 20 years.

2. When Can I Get the Price?
Quotation will be provid within 24 hours after inquiry is received with full product information and drawing.

3: How Long is Your Delivery Time?
It’s depends on the products requirements ang quantity. Normally the mass order lead time is around 14-20days.

4: How Can You Asure the Quality?
100% inspection and we could provide full inspection reports as customer requests before shipment.

5: Do You Provide Samples ? 
Yes, we can provide samples, please provide full product information and drawing.

6: Why Choose Us?
We have advanced technology and equipment, world-class team for techincal and aftersales service. We provide high quality product ,competitive price with fast lead time

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clamp coupling

Temperature and Environmental Limits for Various Beam Coupling Materials

The temperature and environmental limits of beam coupling materials depend on their specific composition and properties. Different materials have varying degrees of resistance to temperature extremes, chemicals, humidity, and other environmental factors. Here are some common beam coupling materials and their associated temperature and environmental limits:

  • 1. Stainless Steel:

    Stainless steel beam couplings are known for their excellent mechanical properties and resistance to corrosion. They can typically operate within a wide temperature range, from -40°C to 300°C (-40°F to 572°F). Stainless steel is also resistant to most chemicals, making it suitable for various environments, including industrial and outdoor applications.

  • 2. Aluminum:

    Aluminum beam couplings offer lightweight construction and moderate mechanical properties. They have a more limited temperature range compared to stainless steel, typically operating between -20°C to 120°C (-4°F to 248°F). While aluminum has good corrosion resistance in certain environments, it is not as durable as stainless steel in harsh conditions.

  • 3. Brass:

    Brass beam couplings have reasonable mechanical properties and corrosion resistance. They are suitable for applications with temperatures ranging from -20°C to 100°C (-4°F to 212°F). Brass is more susceptible to corrosion in certain environments, so it is essential to consider the specific application’s conditions.

  • 4. Plastic/Polymer:

    Beam couplings made from plastic or polymer materials offer lightweight and cost-effective solutions. However, their temperature limits are more restricted compared to metal couplings. They typically operate between -30°C to 80°C (-22°F to 176°F). These couplings may not be suitable for high-temperature or chemically aggressive environments.

  • 5. Carbon Steel:

    Carbon steel beam couplings are known for their strength and mechanical properties. They generally operate between -40°C to 120°C (-40°F to 248°F). Carbon steel is vulnerable to corrosion, so it may not be ideal for applications in corrosive or humid environments without proper protection.

It’s crucial to consider the temperature and environmental conditions of your specific application when selecting a beam coupling material. Choosing a material that can withstand the intended operating conditions will ensure the longevity and reliable performance of the coupling.

Additionally, keep in mind that various beam coupling manufacturers may offer specific variations of materials with different properties and limits. Always refer to the manufacturer’s datasheets and technical documentation for precise information on the temperature and environmental limits of their beam coupling products.

clamp coupling

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.

clamp coupling

Differences between Single-Beam and Multi-Beam Couplings

Single-beam and multi-beam couplings are two common types of beam couplings used in motion control applications. While they both provide flexibility for misalignment compensation, they have distinct differences in design and performance. Let’s explore these differences:

  • Structure:

    A single-beam coupling consists of a single helical beam that connects the two shafts. It is a straightforward design with a single helix providing angular misalignment compensation. On the other hand, a multi-beam coupling has multiple helical beams arranged in parallel around the circumference of the coupling. The multiple beams increase its flexibility and enable compensation for angular, axial, and parallel misalignment.

  • Misalignment Compensation:

    Both single-beam and multi-beam couplings are capable of compensating for misalignment between connected shafts. However, the level of compensation differs between the two types. Single-beam couplings are more suitable for applications with primarily angular misalignment. They can handle small amounts of axial and parallel misalignment but are less effective than multi-beam couplings in this regard. Multi-beam couplings, with their multiple beams, can efficiently accommodate more extensive misalignment in all three axes, making them suitable for applications with more complex misalignment requirements.

  • Torsional Rigidity:

    Single-beam couplings typically have lower torsional rigidity compared to multi-beam couplings. This means that single-beam couplings may exhibit slightly more torsional flexibility and compliance under torque compared to their multi-beam counterparts. As a result, multi-beam couplings are often preferred in applications where high torsional rigidity is essential to maintain precise motion control and minimize backlash.

  • Applications:

    The choice between single-beam and multi-beam couplings depends on the specific requirements of the application. Single-beam couplings are commonly used in applications where space is limited, and primarily angular misalignment needs to be compensated. They are suitable for less demanding misalignment scenarios and can be found in various motion control systems, including small automation machinery and robotics.

    Multi-beam couplings are chosen for applications that require more comprehensive misalignment compensation. They excel in situations where misalignment can occur in multiple axes and are often used in precision motion control systems, optical equipment, and applications with high torsional rigidity and accuracy requirements.

In summary, single-beam and multi-beam couplings both offer flexibility for misalignment compensation in motion control systems. Single-beam couplings are simple, space-efficient, and suitable for applications with primarily angular misalignment. On the other hand, multi-beam couplings provide enhanced misalignment compensation in all three axes and offer higher torsional rigidity, making them ideal for precision applications with more complex misalignment requirements.

China Professional CNC Machining Milling Turning Aluminum Stainless Steel Low Force Link Slimline Strain Sensor Connect Body Liner Stage Liner Stage Thread Adaptor Beam Coupling  China Professional CNC Machining Milling Turning Aluminum Stainless Steel Low Force Link Slimline Strain Sensor Connect Body Liner Stage Liner Stage Thread Adaptor Beam Coupling
editor by CX 2024-05-09