Product Description

Product Description

Detailed Photos

An eccentric CAM manipulator arm is installed on both sides of the stainless steel plate handle type quick connector sleeve. The shaft is inserted into the sleeve and the manipulator arm is pressed down on both sides. The principle of eccentric CAM is applied to force the shaft to sink into contact with the gasket to realize the braking work.
 

The joint has the following features:
1.Simple structure, easy operation, quick connection and opening.
2. Compact size, light weight, good sealing and interchangeability.
3. Adapt to various working conditions, widely used in liquid, powder and other media.
4. The joint is connected with cone tube thread, cone tube external thread, intubation connection, flange connection and other ways.
5. Specification: 1/2″-6″ Working pressure: 1.0MPa-2.0MPa,
6. Operating temperature: -40° C -+250° C.
 

Packaging & Shipping

Certifications

Company Profile

FAQ

Q1: We are interested in your products?
A1: In order to recommend you suitable products, please provide detail information, like size, material, pressure, model.
Q2: Is the requirement for MOQ?
A2. Generally speaking, it depends on your order.
Q3: Payment
A3: Mainly T/T, Western Union & PayPal are applicable for us. Payment Term: 30% prepayment, 70% balance paid before shipping or against copy of BL.
Q4: Can you manufacture different standards valves according to customer requirements?
A4: Yes. We can manufacture API,DIN,GOST,JIS standards for different pressure & temperature & size according to different needs.
Q5: Do you provide samples ?
A5: Yes, we can provide samples.
Q6:How do I receive the goods?
A6:We have professional transport agents, which can deliver goods to various ports, FOB, CIF, DHL, Federal Express, etc. Please provide detailed address, we can also provide door-to-door service for you.
If you want to know more about our products, please contact freely. We will patiently answer your all questions.

/* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1

View More

Are there any Safety Considerations or Guidelines Related to the Installation of Industrial Couplings?

Yes, the installation of industrial couplings requires careful attention to safety considerations and adherence to specific guidelines to ensure the coupling functions correctly and safely. Improper installation can lead to coupling failures, equipment damage, and potential hazards for personnel. Here are some essential safety considerations and guidelines related to the installation of industrial couplings:

• Follow Manufacturer Instructions: Always follow the manufacturer’s installation instructions and guidelines provided with the coupling. Manufacturers have specific recommendations for proper installation, which may vary depending on the coupling type and model.
• Use Proper Tools and Equipment: Use the appropriate tools and equipment for the installation process. Ensure that torque wrenches and other tools are properly calibrated to achieve the correct bolt torque and avoid over-tightening or under-tightening.
• Verify Shaft Alignment: Before installing the coupling, verify the alignment of the connected shafts. Proper shaft alignment is crucial to prevent premature wear, vibration, and misalignment-related issues during operation.
• Ensure Clean Surfaces: Clean and inspect the shaft ends and coupling bore to remove any dirt, debris, or old lubricants. Clean surfaces ensure proper contact and reduce the risk of contamination inside the coupling.
• Check Coupling Fit: Ensure that the coupling fits properly on the shafts and that there is sufficient clearance between the coupling and surrounding components. Avoid interference that could lead to mechanical binding during operation.
• Verify Keyway and Key Fit: If the coupling uses a keyway and key for torque transmission, verify that the key fits securely and accurately in the keyway without any play or gaps.
• Inspect Flexible Elements: For flexible couplings, inspect the flexible elements (e.g., elastomeric inserts or diaphragms) for any damage or defects before installation. Replace damaged elements with new ones as needed.
• Tighten Bolts Gradually: When tightening coupling bolts, follow a gradual tightening sequence in a star or cross pattern to ensure even distribution of the load. This prevents uneven stress on the coupling and shafts.
• Use Locking Devices: Consider using appropriate locking devices, such as split washers, locking nuts, or thread-locking compounds, to prevent bolts from loosening during operation.
• Perform Post-Installation Checks: After installing the coupling, perform post-installation checks to verify proper alignment, bolt tightness, and overall coupling integrity before putting the machinery into full operation.

Following these safety considerations and guidelines is essential to ensure a safe and successful installation of industrial couplings. Regular maintenance and inspections throughout the coupling’s service life are also crucial for identifying potential issues early on and addressing them promptly to prevent accidents or damage to the machinery.

How do Couplings Contribute to the Overall Efficiency and Productivity of Industrial Processes?

Couplings play a crucial role in enhancing the overall efficiency and productivity of industrial processes by facilitating reliable power transmission and ensuring smooth operation of machinery. Their contributions can be summarized as follows:

• Power Transmission: Couplings efficiently transfer mechanical power between connected shafts, allowing motors to drive various industrial equipment and processes. By maintaining a strong and dependable connection, couplings minimize power losses during transmission, ensuring that the maximum power generated by the motor is effectively utilized in the machinery.
• Torsional Flexibility: Many couplings, such as elastomeric couplings and diaphragm couplings, offer torsional flexibility. This flexibility helps dampen vibrations and shocks generated during machinery operation, protecting both the machinery and the surrounding structures from undue stress. Reduced vibrations also lead to smoother operations, less wear on components, and improved precision in industrial processes.
• Misalignment Compensation: Couplings can accommodate misalignment between connected shafts, whether it’s due to thermal expansion, manufacturing tolerances, or dynamic loads. This ability to compensate for misalignment reduces the need for precision shaft alignment during installation and ensures continuous power transmission even under changing operating conditions. Consequently, machinery downtime is reduced, and maintenance efforts are optimized.
• Overload Protection: Certain couplings, such as torque-limiting couplings and overload couplings, provide protection against sudden torque spikes and overloads. These couplings disengage temporarily when the torque exceeds a preset limit, preventing damage to machinery components and protecting the entire system from catastrophic failures.
• Reduction of Noise and Vibrations: Vibrations and noise can be detrimental to both the machinery and the work environment. By effectively dampening vibrations, couplings contribute to a quieter workplace and improve the overall comfort and safety for operators and personnel.
• Flexible Design and Application: Industrial couplings come in various types and sizes, offering versatility in design and application. This flexibility allows engineers and designers to choose the most suitable coupling for specific industrial processes, optimizing performance and productivity. Whether it’s a high-speed application, a heavy-duty process, or an environment with challenging operating conditions, there is a coupling to meet the requirements.
• Easy Maintenance: Couplings that are properly selected and installed require minimal maintenance. Many couplings are designed with features that facilitate easy access for inspections, lubrication, and replacement if needed. This ease of maintenance reduces downtime and ensures continuous operation of industrial processes.
• Extended Machinery Lifespan: By reducing stress on machinery components, dampening vibrations, and offering protection against overload conditions, couplings contribute to extending the overall lifespan of industrial equipment. This leads to higher return on investment and cost savings in the long run.

In conclusion, industrial couplings are essential components that significantly contribute to the overall efficiency and productivity of industrial processes. By ensuring reliable power transmission, accommodating misalignment, providing overload protection, and dampening vibrations, couplings optimize machinery performance, reduce downtime, and enhance the overall industrial process efficiency.

What is Industrial Coupling, and How Does It Work in Mechanical Systems?

In mechanical systems, an industrial coupling is a device used to connect two shafts together to transmit torque and motion from one shaft to the other. Couplings are essential components that enable the efficient transfer of power between rotating machinery while accommodating various operating conditions and misalignments. They play a crucial role in connecting motors, engines, gearboxes, and other equipment within industrial applications.

The primary function of an industrial coupling is to join two shafts in such a way that they can rotate together while allowing some degree of flexibility to accommodate misalignment, vibrations, and other dynamic forces. This flexibility is vital in preventing excessive stress and wear on the connected machinery, as well as mitigating the risk of premature failures.

There are various types of industrial couplings available, each designed for specific applications and operating conditions. Some common types of industrial couplings include:

• 1. Diaphragm Couplings: Diaphragm couplings, as discussed in previous answers, use a thin flexible diaphragm to transmit torque between the shafts. They can accommodate misalignments and dampen vibrations, making them suitable for various industrial applications.
• 2. Gear Couplings: Gear couplings use gear teeth to transmit torque and are known for their high torque capacity and rigid construction. They are commonly used in heavy-duty applications, such as steel mills and mining equipment.
• 3. Grid Couplings: Grid couplings use a grid of spring-like elements to transmit torque. They are versatile and can absorb shock loads, making them suitable for applications with varying loads and high shock forces.
• 4. Jaw Couplings: Jaw couplings use elastomeric elements to connect the shafts and are known for their simplicity and ease of installation. They are commonly used in small to medium-sized machinery.
• 5. Disc Couplings: Disc couplings use thin metal discs to transmit torque and compensate for misalignments. They are often used in precision applications and systems that require low backlash.

Regardless of the specific type, the working principle of an industrial coupling involves connecting the shaft ends and ensuring a firm grip between them. When torque is applied to one shaft, the coupling transmits that torque to the other shaft, causing both shafts to rotate together at the same speed. The coupling’s design allows for some degree of flexibility, which permits the shafts to compensate for misalignments, axial movements, and vibrations. This flexibility helps protect the connected equipment from stress and damage, promoting smooth operation and extending the lifespan of the machinery.

In summary, industrial couplings are critical components in mechanical systems that facilitate the transfer of torque and motion between rotating shafts. They provide flexibility, misalignment compensation, and vibration dampening, making them essential for reliable and efficient power transmission in various industrial applications.

editor by CX 2024-03-27