Product Description
Product Description
| Capacity | Stroke | Model | Min Height | Outside Diameter | Effective Area | Oil Capacity | Plunger Diameter | Weight | |||
| (Ton) | (mm) | (mm) | (mm) | (cm²) | (cm³) | (mm) | (Kg) | ||||
| Push | Pull | Push | Pull | Push | Pull | ||||||
| 10 | 4. 1 | 254 | CLRG1571 | 409 | 76 | 14.5 | 5.9 | 368 | 149 | 33 | 12 |
| 10 | 4. 1 | 305 | CLRG1012 | 457 | 76 | 14.5 | 5.9 | 442 | 180 | 33 | 14 |
| 50 | 22.6 | 150 | CLRG506 | 325 | 127 | 70.8 | 32.3 | 1062 | 484 | 70 | 30 |
| 50 | 22.6 | 300 | CLRG5012 | 475 | 127 | 70.8 | 32.3 | 2124 | 969 | 70 | 52 |
| 100 | 44 | 50 | CLRG 1002 | 182 | 188 | 132. 7 | 61.9 | 664 | 310 | 95 | 27 |
| 100 | 44 | 100 | CLRG 1004 | 232 | 188 | 132.7 | 61.9 | 1327 | 619 | 95 | 33 |
| 100 | 44 | 150 | CLRG 1006 | 282 | 188 | 132.7 | 61.9 | 1991 | 929 | 95 | 37 |
| 100 | 44 | 200 | CLRG 1008 | 332 | 188 | 132.7 | 61.9 | 2654 | 1238 | 95 | 44 |
| 100 | 44 | 250 | CLRG1571 | 382 | 188 | 132.7 | 61.9 | 3318 | 1548 | 95 | 50 |
| 100 | 44 | 300 | CLRG10012 | 432 | 188 | 132.7 | 61.9 | 3981 | 1857 | 95 | 57 |
| 150 | 67.9 | 50 | CLRG 1502 | 196 | 216 | 201 | 97 | 1005 | 485 | 115 | 47 |
| 150 | 67.9 | 100 | CLRG 1504 | 246 | 216 | 201 | 97 | 2571 | 970 | 115 | 57 |
| 150 | 67.9 | 150 | CLRG1506 | 296 | 216 | 201 | 97 | 3015 | 1455 | 115 | 67 |
| 150 | 67.9 | 200 | CLRG 1508 | 346 | 216 | 201 | 97 | 4571 | 1940 | 115 | 77 |
| 150 | 67.9 | 250 | CLRG15571 | 396 | 216 | 201 | 97 | 5571 | 2425 | 115 | 87 |
| 150 | 67.9 | 300 | CLRG15012 | 446 | 216 | 201 | 97 | 6030 | 2910 | 115 | 97 |
| 200 | 93 | 50 | CLRG2002 | 235 | 242 | 265.9 | 133. 1 | 1329 | 665 | 130 | 67 |
| 200 | 93 | 150 | CLRG2006 | 335 | 242 | 265.9 | 133. 1 | 3988 | 1996 | 130 | 92 |
| 200 | 93 | 250 | CLRG2571 | 435 | 242 | 265.9 | 133. 1 | 6647 | 3327 | 130 | 117 |
| 250 | 107 | 50 | CLRG2502 | 236 | 288 | 366.4 | 152.6 | 1832 | 763 | 165 | 105 |
| 250 | 107 | 150 | CLRG2506 | 336 | 288 | 366.4 | 152. 6 | 5496 | 2289 | 165 | 141 |
| 250 | 107 | 250 | CLRG25571 | 436 | 288 | 366.4 | 152. 6 | 9160 | 3815 | 165 | 176 |
| 300 | 121 | 50 | CLRG3002 | 350 | 325 | 456.2 | 172. 6 | 2281 | 863 | 190 | 204 |
| 300 | 121 | 150 | CLRG3006 | 412 | 325 | 456.2 | 172. 6 | 6843 | 2589 | 190 | 252 |
| 300 | 121 | 250 | CLRG3571 | 512 | 325 | 456.2 | 172. 6 | 11405 | 4315 | 190 | 299 |
| 400 | 138 | 50 | CLRG4002 | 370 | 367 | 559.9 | 196.8 | 2799 | 984 | 215 | 281 |
| 400 | 138 | 150 | CLRG4006 | 470 | 367 | 559.9 | 196.8 | 8399 | 2952 | 215 | 342 |
| 400 | 138 | 250 | CLRG4571 | 570 | 367 | 559.9 | 196.8 | 13998 | 4920 | 215 | 405 |
| 500 | 168 | 50 | CLRG5002 | 400 | 405 | 730. 6 | 239. 7 | 3653 | 1198 | 250 | 411 |
| 500 | 168 | 150 | CLRG5006 | 500 | 405 | 730. 6 | 239. 7 | 10959 | 3595 | 250 | 493 |
| 500 | 168 | 250 | CLRG5571 | 600 | 405 | 730. 6 | 239. 7 | 18265 | 5992 | 250 | 575 |
| 600 | 207 | 50 | CLRG6002 | 445 | 450 | 855.3 | 295.4 | 4277 | 1477 | 267 | 494 |
| 600 | 207 | 150 | CLRG6006 | 545 | 450 | 855.3 | 295.4 | 12830 | 4431 | 267 | 586 |
| 600 | 207 | 250 | CLRG6571 | 645 | 450 | 855.3 | 295.4 | 21383 | 7385 | 267 | 678 |
| 800 | 252 | 50 | CLRG8002 | 695 | 515 | 1164 | 360 | 5820 | 1800 | 320 | 759 |
| 800 | 252 | 150 | CLRG8006 | 595 | 515 | 1164 | 360 | 17460 | 5400 | 320 | 885 |
| 800 | 252 | 250 | CLRG8571 | 695 | 515 | 1164 | 360 | 29100 | 9000 | 320 | 1019 |
| 1000 | 380 | 50 | CLRG 10002 | 535 | 580 | 1465. 7 | 541.7 | 7328 | 2708 | 342 | 1012 |
| 1000 | 380 | 150 | CLRG 10006 | 635 | 580 | 1465. 7 | 541.7 | 21985 | 8125 | 342 | 1168 |
| 1000 | 380 | 250 | CLRG10571 | 735 | 580 | 1465. 7 | 541.7 | 36418 | 13543 | 342 | 1325 |
Company Profile
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FAQ
Q: How to order?
A: Inquire with us→ sample customization→ use scenario inform→ receive our product design recommendation→ negotiate details→ confirm the sample→ CHINAMFG the contract/deposit→mass production→ the goods are ready→ balance/delivery→ further cooperation.
Q: How about the sample order?
A: We can provide the sample price, please contact us for details.
Q: Which shipping method is available?
A: By sea, by air, or by express (DHL, UPS, FedEx). Other shipping methods are also available, please contact us for details.
Q: How long is the delivery [production] and shipment?
A: The delivery time depends on the quantity you ordered. Shipped from the factory, within 3 days for standard parts and within 10 days for non-standard parts.
Q: My package is missing some products, what can I do?
A: Please contact our support team, we will confirm the contents of your order with the packaging, and compensate for the shipment. We apologize for the inconvenience.
Q: How to confirm the payment?
A: We accept T/T payment method. The first type is 30% deposit order confirmed, and the remaining 70% is paid before shipment, and the second type is 100% paid before shipment. Other payment methods are also acceptable, please contact us before you pay by other payment methods.
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| Certification: | CE, ISO9001 |
|---|---|
| Pressure: | High Pressure |
| Work Temperature: | Normal Temperature |
| Acting Way: | Double Acting |
| Working Method: | Straight Trip |
| Adjusted Form: | Switching Type |
| Customization: |
Available
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|---|
Are there any emerging trends in hydraulic cylinder technology, such as smart features?
Yes, there are several emerging trends in hydraulic cylinder technology, including the integration of smart features. As industries continue to adopt advanced technologies and seek greater efficiency, hydraulic cylinders are being equipped with innovative capabilities to enhance their performance and provide additional benefits. Here are some of the emerging trends in hydraulic cylinder technology:
1. Sensor Integration:
– One of the significant trends in hydraulic cylinder technology is the integration of sensors. Sensors can be embedded within the hydraulic cylinder to monitor various parameters such as pressure, temperature, position, and load. These sensors provide real-time data, allowing for condition monitoring, predictive maintenance, and improved operational control. By collecting and analyzing data, operators can optimize the performance of hydraulic systems, detect potential issues in advance, and prevent failures, resulting in increased reliability and reduced downtime.
2. Connectivity and IoT:
– Hydraulic cylinders are being integrated into the Internet of Things (IoT) ecosystem, enabling connectivity and data exchange. By connecting hydraulic cylinders to a network, operators can remotely monitor and control their performance. IoT-enabled hydraulic cylinders facilitate features such as remote diagnostics, performance optimization, and predictive maintenance. The connectivity aspect allows for better integration with overall equipment systems and enables data-driven decision-making for improved efficiency and productivity.
3. Energy-Efficient Designs:
– With the increasing focus on sustainability and energy efficiency, hydraulic cylinder technology is evolving to incorporate energy-saving features. Manufacturers are developing hydraulic cylinders with improved sealing technologies, reduced friction, and optimized fluid flow dynamics. These advancements minimize energy losses and increase overall system efficiency. Energy-efficient hydraulic cylinders contribute to reduced power consumption, lower operating costs, and a smaller environmental footprint.
4. Advanced Materials and Coatings:
– The use of advanced materials and coatings is another emerging trend in hydraulic cylinder technology. Manufacturers are exploring lightweight materials, such as composites and alloys, to reduce the overall weight of hydraulic cylinders without compromising strength and durability. Furthermore, specialized coatings and surface treatments are being applied to improve corrosion resistance, wear resistance, and lifespan. These advancements enhance the longevity and reliability of hydraulic cylinders, particularly in demanding environments.
5. Intelligent Control Systems:
– Hydraulic cylinder technology is embracing intelligent control systems that optimize performance and enable advanced functionalities. These systems utilize algorithms, machine learning, and artificial intelligence to automate processes, adapt to changing conditions, and optimize hydraulic cylinder movements. Intelligent control systems can adjust parameters in real-time, ensuring precise and efficient operation. This trend allows for increased automation, improved productivity, and enhanced safety in hydraulic system applications.
6. Predictive Maintenance:
– Predictive maintenance is gaining prominence in hydraulic cylinder technology. By utilizing data collected from sensors and monitoring systems, predictive maintenance algorithms can analyze the condition and performance of hydraulic cylinders. This analysis helps to identify potential failures or degradation in advance, enabling proactive maintenance actions. Predictive maintenance reduces unplanned downtime, extends the lifespan of hydraulic cylinders, and optimizes maintenance schedules, resulting in cost savings and improved equipment availability.
7. Enhanced Safety Features:
– Hydraulic cylinder technology is incorporating enhanced safety features to improve operator and equipment safety. These features include integrated safety valves, load monitoring systems, and emergency stop functionalities. Safety systems in hydraulic cylinders help prevent accidents, protect against overloads, and ensure reliable operation. The integration of advanced safety features contributes to safer working environments and compliance with stringent safety regulations.
These emerging trends in hydraulic cylinder technology demonstrate the industry’s focus on innovation, performance optimization, and sustainability. The integration of smart features, connectivity, advanced materials, and predictive maintenance capabilities enables hydraulic cylinders to operate more efficiently, provide real-time insights, and enhance overall system performance. As technology continues to advance, hydraulic cylinder technology is expected to evolve further, offering increased functionality and efficiency for various industries and applications.
Handling the Challenges of Minimizing Fluid Leaks and Contamination in Hydraulic Cylinders
Hydraulic cylinders face challenges when it comes to minimizing fluid leaks and contamination, as these issues can impact the performance, reliability, and lifespan of the system. However, there are several measures and design considerations that help address these challenges effectively. Let’s explore how hydraulic cylinders handle the challenges of minimizing fluid leaks and contamination:
- Sealing Systems: Hydraulic cylinders employ advanced sealing systems to prevent fluid leaks. These systems typically include various types of seals, such as piston seals, rod seals, and wiper seals. The seals are designed to create a tight and reliable barrier between the moving components of the cylinder and the external environment, minimizing the risk of fluid leakage.
- Seal Material Selection: The choice of seal materials is crucial in minimizing fluid leaks and contamination. Hydraulic cylinder manufacturers carefully select seal materials that are compatible with the hydraulic fluid used and resistant to wear, abrasion, and chemical degradation. This ensures the longevity and effectiveness of the seals, reducing the likelihood of leaks or premature seal failure.
- Proper Installation and Maintenance: Ensuring proper installation and regular maintenance of hydraulic cylinders is essential for minimizing fluid leaks and contamination. During installation, attention should be given to proper alignment, torqueing of bolts, and adherence to recommended procedures. Regular maintenance includes inspecting seals, replacing worn-out components, and addressing any signs of leakage promptly. Proper maintenance practices help identify and rectify issues before they escalate and cause significant problems.
- Contamination Control: Hydraulic cylinders incorporate measures to control contamination and maintain fluid cleanliness. This includes the use of filtration systems, such as in-line filters, to remove particles and contaminants from the hydraulic fluid. Additionally, hydraulic reservoirs often have breathers and desiccant filters to prevent moisture and airborne contaminants from entering the system. By controlling contamination, hydraulic cylinders minimize the risk of damage to internal components and maintain optimal system performance.
- Environmental Protection: Hydraulic cylinders may be equipped with protective features to safeguard against external contaminants. For example, bellows or protective boots can be installed to shield the rod and seals from debris, dirt, or moisture present in the operating environment. These protective measures help extend the life of the seals and enhance the overall reliability of the hydraulic cylinder.
In summary, hydraulic cylinders employ sealing systems, appropriate seal materials, proper installation and maintenance practices, contamination control measures, and environmental protection features to handle the challenges of minimizing fluid leaks and contamination. By implementing these measures, manufacturers can ensure reliable and long-lasting hydraulic cylinder performance, minimize the risk of fluid leakage, and maintain the cleanliness of the hydraulic system.
How do hydraulic cylinders handle variations in load and pressure during operation?
Hydraulic cylinders are designed to handle variations in load and pressure during operation, making them versatile and efficient in various applications. Hydraulic systems use the principle of transmitting force through incompressible fluid to generate linear motion. Here’s a detailed explanation of how hydraulic cylinders handle variations in load and pressure:
1. Load Handling:
– Hydraulic cylinders are capable of handling different loads by utilizing the principle of Pascal’s law. According to Pascal’s law, when pressure is applied to a fluid in a confined space, the pressure is transmitted equally in all directions. In a hydraulic cylinder, the force applied to the piston results in an equal force output at the rod end of the cylinder. The size of the piston and the pressure exerted determine the force generated by the cylinder. Therefore, hydraulic cylinders can handle a wide range of loads by adjusting the pressure applied to the fluid.
2. Pressure Compensation:
– Hydraulic systems incorporate pressure compensation mechanisms to handle variations in pressure during operation. Pressure compensating valves or regulators are often used to maintain a consistent pressure in the hydraulic system, regardless of load changes. These valves automatically adjust the flow rate or pressure to ensure stable and controlled operation of the hydraulic cylinder. By compensating for pressure variations, hydraulic cylinders can maintain a consistent force output and prevent damage or instability due to excessive pressure.
3. Control Valves:
– Control valves play a crucial role in managing variations in pressure and load during hydraulic cylinder operation. Directional control valves, such as spool valves or poppet valves, control the flow of hydraulic fluid into and out of the cylinder, enabling precise control of the cylinder’s extension and retraction. By adjusting the position of the control valve, the speed and force exerted by the hydraulic cylinder can be regulated to match the load and pressure requirements of the application. Control valves allow for efficient handling of variations in load and pressure by providing fine-tuned control over the hydraulic system.
4. Accumulators:
– Hydraulic accumulators are often used to handle fluctuations in pressure and load. Accumulators store hydraulic fluid under pressure, which can be released or absorbed as needed to compensate for sudden changes in load or pressure. When the load on the hydraulic cylinder decreases, the accumulator releases stored fluid to maintain pressure and prevent pressure spikes. Conversely, when the load on the cylinder increases, the accumulator absorbs excess fluid to maintain system stability. By utilizing accumulators, hydraulic cylinders can effectively handle variations in load and pressure, ensuring smooth and controlled operation.
5. Feedback and Control Systems:
– Advanced hydraulic systems may incorporate feedback and control systems to monitor and adjust the operation of hydraulic cylinders in real-time. Position sensors or pressure sensors provide feedback on the cylinder’s position, force, and pressure, allowing the control system to make continuous adjustments to optimize performance. These systems can automatically adapt to variations in load and pressure, ensuring precise control and efficient operation of the hydraulic cylinder.
6. Design Considerations:
– Proper design considerations, such as selecting the appropriate cylinder size, piston diameter, and rod diameter, are essential for handling variations in load and pressure. The design should account for the maximum anticipated load and pressure conditions to ensure the hydraulic cylinder operates within its specified range. Additionally, the selection of suitable seals, materials, and components that can withstand the anticipated load and pressure variations is crucial for maintaining the reliability and longevity of the hydraulic cylinder.
By utilizing the principles of hydraulic systems, incorporating pressure compensation mechanisms, employing control valves and accumulators, and implementing feedback and control systems, hydraulic cylinders can effectively handle variations in load and pressure during operation. These features and design considerations allow hydraulic cylinders to adapt and perform optimally in a wide range of applications and operating conditions.
editor by CX 2024-01-04