Product Description
Industrial Pumps Rolling Bearing Variable Speed Hydraulic Coupling
Application:
Hydraulic coincidence machines which are series of products of extensively applied to steel plant, power plant, mine, etc.. After matching with belt machine, grinding machine and machineries that at odds with the community, such as air blower and water pump, hydraulic coincidence machines have the fine characteristics of flexible transmission and isolated and sprain shaking. In addition to that they can economize on electricity in a large amount and they are the energy-conserving product that the country popularized especially.
Our products range:
+YOTCGP series Variable speed fluid coupling
+YOTCG series Variable speed fluid coupling
+YOTCHP series Variable speed fluid coupling
+YOTCHZ series Variable speed fluid coupling
+YOTCQ series Variable speed fluid coupling
+YOTCHF series Variable speed fluid coupling
+Constant fluid coupling, such YOX, TVA series.
Sample Product Photos:
Feature of Technique:
1.Maximum output speed * in the type No. should be specified in order.
2.The rated slip is 1.5-3%.The maximum total mechanical efficiency>=95%.
3..For centrifugal machine-gal with load characteristics of M a n2 .step less speed regulation over range of 1-1/5 is available.
For constant torque drives with M=C a range of 1-1/3 may be provided.
4.All of these are supported can by rolling bearing or sliding bearing.
YOTCGP TYPE Variable Speed Hydraulic Fluid Coupling Specification:
| type | input rotational speed (r/min) | rotation power (kw) |
| YOTCGP500 | 1000 | 20~65 |
| 1500 | 65~210 | |
| 3000 | 550~1600 | |
| YOTCGP560 | 1000 | 35~105 |
| 1500 | 115~340 | |
| 3000 | 950~2740 | |
| YOTCGP580 | 1000 | 35~105 |
| 1500 | 115~410 | |
| 3000 | 950~3250 | |
| YOTCGP600 | 750 | 20~65 |
| 1000 | 50~150 | |
| 1500 | 170~500 | |
| YOTCGP650 | 750 | 30~95 |
| 1000 | 70~220 | |
| 1500 | 240~700 | |
| YOTCGP700 | 750 | 45~135 |
| 1000 | 110~320 | |
| 1500 | 350~1000 | |
| YOTCGP750 | 600 | 30~100 |
| 750 | 60~190 | |
| 1000 | 145~460 | |
| 1500 | 490~1420 | |
| YOTCGP800 | 600 | 45~130 |
| 750 | 80~250 | |
| 1000 | 200~580 | |
| 1500 | 610~1960 | |
| YOTCGP875 | 600 | 70~200 |
| 750 | 130~410 | |
| 1000 | 310~910 | |
| 1500 | 1060~3060 | |
| YOTCGP920 | 600 | 110~330 |
| 750 | 230~675 | |
| 1000 | 400~1170 | |
| YOTCGP1000 | 600 | 130~500 |
| 750 | 250~1571 | |
| 1000 | 615~1770 | |
| YOTCGP1050 | 500 | 125~365 |
| 600 | 220~640 | |
| 750 | 400~1150 | |
| 1000 | 780~2260 | |
| YOTCGP1150 | 500 | 180~710 |
| 600 | 310~1250 | |
| 750 | 640~1860 | |
| 1000 | 1500~4400 | |
| YOTCGP1250 | 500 | 300~870 |
| 600 | 530~1535 | |
| 750 | 790~2280 | |
| YOTCGP1320 | 500 | 395~1142 |
| 600 | 695~2015 | |
| 750 | 1030~2990 |
Details Photos of YOTCGP Variable Speed hydraulic fluid coupling:
Production Equipment Photos:
Package and Delivery:
Mainly Cooperation Customer:
Power Plant, Cement Mill, Industrial Water Supplier, Raw material yard, ore beneficiation, sinter plant and pellet, coke oven plant, iron making plant, steel making plant.
Successful Projects Feedback:
Note: We also accept the repair work projects, and provide spare parts for variable speed fluid coupling.
If you have any related projects need our proposal, feel free to contact us. /* March 10, 2571 17:59:20 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
How does Misalignment Affect the Performance of Industrial Couplings, and How Can it be Corrected?
Misalignment is one of the most common issues affecting the performance of industrial couplings. When the connected shafts are not properly aligned, it can lead to various problems that can impact the efficiency, reliability, and lifespan of the coupling and the entire mechanical system. Here’s how misalignment affects coupling performance and the methods to correct it:
Effects of Misalignment:
- Increased Stress: Misalignment creates additional stresses on the coupling and connected machinery. This can result in premature wear, fatigue, and potential failure of coupling components.
- Vibration and Noise: Misalignment generates vibrations and noise during operation. Excessive vibrations can damage other system components, reduce precision, and lead to discomfort for operators and personnel.
- Reduced Power Transmission: Misalignment reduces the effective torque transmission capacity of the coupling. As a result, the system may not achieve the desired level of performance or may experience frequent slip-offs.
- Temperature Rise: Misalignment causes additional friction and heat generation in the coupling. This can lead to an increase in operating temperature, potentially compromising the lubrication and reducing the coupling’s life.
- Uneven Wear: Misalignment causes uneven loading on coupling elements, resulting in uneven wear and potentially leading to the failure of certain parts.
Methods to Correct Misalignment:
- Shaft Realignment: The most effective method to correct misalignment is to perform a shaft realignment. This involves adjusting the position of one or both shafts to ensure they are co-linear and concentric. Precision alignment tools such as laser alignment systems or dial indicators are commonly used for this purpose.
- Flexible Couplings: For applications where misalignment is inevitable due to factors such as thermal expansion or dynamic loads, flexible couplings can be used. Flexible couplings, like diaphragm couplings or elastomeric couplings, can accommodate small misalignments and reduce the stress on the system.
- Spacer Couplings: Spacer couplings can be used to create space between the shaft ends, allowing for adjustments and realignments without disassembling the entire coupling assembly.
- Torque Limiting Couplings: Torque limiting couplings can protect the machinery from excessive torque during misalignment or shock loads. They disengage temporarily when the torque exceeds a predefined limit, preventing damage to the coupling and other components.
- Periodic Maintenance: Regular maintenance and inspections should be performed to monitor the coupling’s alignment and address any changes or misalignments that may occur during operation.
Correcting misalignment is crucial for ensuring optimal performance and longevity of industrial couplings. Proper alignment minimizes stress, reduces wear, and enhances power transmission efficiency. Whether through precision alignment methods or using flexible couplings, addressing misalignment proactively can prevent costly repairs, downtime, and potential safety hazards in industrial systems.
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.
How do Rigid Couplings Differ from Flexible Couplings in Industrial Applications?
In industrial applications, rigid couplings and flexible couplings serve different purposes and have distinct characteristics that make them suitable for various scenarios. Here’s a detailed comparison of rigid couplings and flexible couplings:
Rigid Couplings:
- Design: Rigid couplings are solid, one-piece couplings that do not have any flexible elements. They are typically made from materials like steel, aluminum, or other rigid materials.
- Torque Transmission: Rigid couplings provide a direct and efficient torque transmission between the connected shafts. There is little to no torsional flexibility, resulting in a more rigid connection.
- Misalignment Compensation: Rigid couplings are not designed to accommodate misalignments between the shafts. Proper alignment during installation is crucial to avoid issues like increased wear, vibrations, and premature failures.
- Applications: Rigid couplings are commonly used in applications where precise alignment is feasible, and misalignments are minimal or controlled. They are often found in machines that require high-precision positioning and where torsional rigidity is critical.
- Advantages: Rigid couplings offer high torque capacity, precise shaft alignment, and superior torsional stiffness. They are also straightforward to install and require minimal maintenance.
- Disadvantages: The lack of flexibility makes rigid couplings unsuitable for applications with misalignments or situations where shock absorption is necessary. They may also transmit vibrations and shocks to connected machinery, leading to increased stress and potential failures.
Flexible Couplings:
- Design: Flexible couplings have elements or features that provide some degree of flexibility, allowing them to compensate for misalignments and absorb shocks and vibrations.
- Torque Transmission: Flexible couplings transmit torque while allowing for slight angular and axial misalignments between the shafts. They can dampen vibrations and reduce shocks, protecting the connected machinery.
- Misalignment Compensation: Flexible couplings are specifically designed to accommodate misalignments, including angular, axial, and parallel misalignments. They can help prevent premature wear and failures caused by misalignment.
- Applications: Flexible couplings are used in a wide range of industrial applications where misalignments are common or expected. They are suitable for machinery with dynamic loads, varying operating conditions, and potential shaft movements.
- Advantages: Flexible couplings offer misalignment compensation, vibration dampening, and shock absorption properties. They can improve the overall reliability and lifespan of machinery by reducing stress and wear on components.
- Disadvantages: Flexible couplings may introduce a certain amount of backlash, which can be a concern in precision applications. Some types of flexible couplings have lower torque capacities compared to rigid couplings.
In summary, the choice between rigid couplings and flexible couplings depends on the specific requirements of the industrial application. Rigid couplings are ideal for applications with precise alignment and high torsional rigidity, while flexible couplings excel in scenarios with misalignments, vibrations, and shock forces. Engineers carefully consider the operating conditions, torque requirements, and misalignment factors to select the most appropriate coupling type, ensuring reliable and efficient power transmission in their industrial setups.
editor by CX 2024-02-11