Product Description
Product Description
| Capacity | Stroke | Model | Min Height | Outside Diameter | Effective Area | Oil Capacity | Saddle Diameter | Weight |
| (Ton) | (mm) | (mm) | (mm) | (cm²) | (cm³) | (mm) | (Kg) | |
| 50 | 50 | CLS502A | 128 | 125 | 70.9 | 355 | 71 | 4 |
| 50 | 100 | CLS504A | 178 | 125 | 70.9 | 709 | 71 | 18 |
| 50 | 150 | CLS506 | 228 | 125 | 70.9 | 1064 | 71 | 23 |
| 50 | 200 | CLS508A | 278 | 125 | 70. 9 | 1418 | 71 | 28 |
| 50 | 250 | CLS5571A | 328 | 125 | 70. 9 | 1773 | 71 | 33 |
| 50 | 300 | CLS5012A | 378 | 125 | 70. 9 | 2127 | 71 | 38 |
| 100 | 50 | CLS1002A | 143 | 164 | 132. 7 | 664 | 71 | 24 |
| 100 | 100 | CLS1004 | 193 | 164 | 132.7 | 1327 | 71 | 32 |
| 100 | 150 | CLS1006 | 243 | 164 | 132 7 | 1991 | 71 | 40 |
| 100 | 200 | CLS1008A | 293 | 164 | 132. 7 | 2654 | 71 | 49 |
| 100 | 250 | CLS1571 | 343 | 164 | 132 7 | 3318 | 71 | 58 |
| 100 | 300 | CLS10012 | 393 | 164 | 132.7 | 3981 | 71 | 66 |
| 150 | 50 | CLS1502 | 165 | 209 | 201 | 1005 | 130 | 43 |
| 150 | 100 | CLS1504 | 215 | 209 | 201 | 2571 | 130 | 55 |
| 150 | 150 | CLS1506 | 265 | 209 | 201 | 3015 | 130 | 69 |
| 150 | 200 | CLS1508 | 315 | 209 | 201 | 4571 | 130 | 82 |
| 150 | 250 | CLS15571 | 365 | 209 | 201 | 5571 | 130 | 95 |
| 150 | 300 | CLS15012 | 415 | 209 | 201 | 6030 | 130 | 108 |
| 200 | 50 | CLS2002 | 193 | 235 | 265.9 | 1330 | 130 | 66 |
| 200 | 150 | CLS2006 | 293 | 235 | 265.9 | 3989 | 130 | 101 |
| 200 | 250 | CLS2571A | 393 | 235 | 265.9 | 6648 | 130 | 136 |
| 250 | 50 | CLS2502 | 193 | 275 | 366.4 | 1832 | 150 | 90 |
| 250 | 150 | CLS2506 | 293 | 275 | 366. 4 | 5496 | 150 | 137 |
| 250 | 250 | CLS25571 | 393 | 275 | 366.4 | 9160 | 150 | 184 |
| 300 | 50 | CLS3002 | 235 | 310 | 456.2 | 2281 | 139 | 137 |
| 300 | 150 | CLS3006 | 335 | 310 | 456. 2 | 6843 | 139 | 198 |
| 300 | 250 | CLS3571 | 435 | 310 | 456. 2 | 11405 | 139 | 258 |
| 400 | 50 | CLS4002 | 265 | 350 | 559.9 | 2800 | 159 | 200 |
| 400 | 150 | CLS4006 | 365 | 350 | 559. 9 | 8399 | 159 | 275 |
| 400 | 250 | CLS4571 | 465 | 350 | 559.9 | 13998 | 159 | 352 |
| 500 | 50 | CLS5002 | 295 | 400 | 730. 6 | 3656 | 228 | 289 |
| 500 | 150 | CLS5006 | 395 | 400 | 730. 6 | 10967 | 228 | 390 |
| 500 | 250 | CLS5571 | 495 | 400 | 730. 6 | 18278 | 228 | 489 |
| 600 | 50 | CLS6002 | 310 | 430 | 855. 3 | 4277 | 194 | 350 |
| 600 | 150 | CLS6006 | 410 | 430 | 855.3 | 12830 | 194 | 465 |
| 600 | 250 | CLS6571 | 510 | 430 | 855. 3 | 21383 | 194 | 582 |
| 800 | 50 | CLS8002 | 355 | 505 | 1176.3 | 5882 | 224 | 549 |
| 800 | 150 | CLS8006 | 455 | 505 | 1176.3 | 17645 | 224 | 709 |
| 800 | 250 | CLS8571 | 555 | 505 | 1176.3 | 29408 | 224 | 870 |
| 1000 | 50 | CLS10002 | 385 | 560 | 1465. 7 | 7329 | 360 | 729 |
| 1000 | 150 | CLS10006 | 485 | 560 | 1465.7 | 21986 | 360 | 921 |
| 1000 | 250 | CLS10571 | 585 | 560 | 1465.7 | 36643 | 360 | 1113 |
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: | Single Acting |
| Working Method: | Straight Trip |
| Adjusted Form: | Switching Type |
| Customization: |
Available
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|---|

How does a single-acting hydraulic cylinder contribute to energy-efficient force generation?
A single-acting hydraulic cylinder contributes to energy-efficient force generation through its design and operating principles. Here’s a detailed explanation:
1. Unidirectional Force: Single-acting hydraulic cylinders generate force in one direction, typically in the extension stroke. This unidirectional force generation eliminates the need for hydraulic fluid to exert force in the opposite direction, resulting in energy savings. The hydraulic system only needs to supply fluid to extend the cylinder, while the retraction of the piston is achieved through the force of gravity or other external means, reducing the overall energy consumption.
2. Reduced Fluid Volume: Single-acting hydraulic cylinders require a smaller volume of hydraulic fluid compared to double-acting cylinders. Since these cylinders operate primarily in one direction, the fluid volume needed for extension strokes is lower. This reduction in fluid volume leads to energy savings in terms of pumping and circulating the hydraulic fluid.
3. Lower Pumping Requirements: The unidirectional force generation of single-acting hydraulic cylinders reduces the workload on the hydraulic pump. As the pump only needs to supply fluid for extension strokes, the pump size and power requirements can be optimized, leading to energy efficiency. This is particularly beneficial in applications where the hydraulic system is powered by electric motors or other energy sources.
4. Gravity-Assisted Retraction: Single-acting hydraulic cylinders often utilize the force of gravity or external forces to retract the piston during the return stroke. By leveraging these external forces, the hydraulic system can minimize the energy required for retraction. This is particularly advantageous in applications where the weight of the load or other external factors can assist in the retraction process.
5. System Optimization: Single-acting hydraulic cylinders allow for system optimization to maximize energy efficiency. By carefully selecting cylinder sizes, operating pressures, and flow rates, the hydraulic system can be designed to match the specific force requirements of the application. This optimization ensures that the system operates at its most energy-efficient operating point, minimizing energy waste and maximizing overall system performance.
6. Regenerative Systems: In certain applications, single-acting hydraulic cylinders can be integrated into regenerative hydraulic systems. These systems capture and reuse the energy generated during the retraction stroke, effectively recycling the energy that would otherwise be dissipated. By harnessing this regenerative energy, the overall energy efficiency of the system is significantly improved.
By employing these energy-efficient design and operating principles, single-acting hydraulic cylinders contribute to reduced energy consumption and improved overall system efficiency.
How does a single-acting hydraulic cylinder contribute to precise force control in heavy machinery?
A single-acting hydraulic cylinder plays a crucial role in achieving precise force control in heavy machinery. Here’s a detailed explanation:
Heavy machinery often requires accurate and controlled application of force for various operations, such as lifting, pushing, or pressing. Single-acting hydraulic cylinders offer several features that enable precise force control in heavy machinery. Here are some key points on how single-acting hydraulic cylinders contribute to precise force control:
1. Single-Direction Force: Single-acting hydraulic cylinders generate force in a single direction, typically the extension stroke. This characteristic allows for precise control over the force applied during the extension of the cylinder. By regulating the hydraulic pressure supplied to the cylinder, the force exerted can be precisely adjusted to match the requirements of the task at hand. This allows for fine-tuning and accurate force control in heavy machinery operations.
2. Pressure Regulation: The hydraulic system associated with a single-acting hydraulic cylinder allows for precise regulation of hydraulic pressure. Pressure control valves, such as flow control valves or pressure relief valves, can be incorporated into the hydraulic circuit to manage the pressure supplied to the cylinder. These valves enable operators to adjust the hydraulic pressure according to the desired force requirements, ensuring precise force control during operation.
3. Load-Sensing Systems: In some advanced heavy machinery applications, load-sensing systems can be integrated with single-acting hydraulic cylinders to achieve precise force control. Load-sensing systems measure the load or resistance encountered by the cylinder and adjust the hydraulic pressure accordingly to maintain a consistent force. This real-time feedback mechanism ensures that the force remains constant, even when the load or resistance changes, resulting in precise force control throughout the operation.
4. Force Feedback: Single-acting hydraulic cylinders can be equipped with force feedback mechanisms to provide operators with information about the force being exerted. Load cells or pressure transducers can be installed to measure the force at the cylinder or at specific points in the machinery. This feedback allows operators to monitor and adjust the force output, ensuring precise control and preventing excessive or insufficient force application.
5. Control Systems: In modern heavy machinery, single-acting hydraulic cylinders can be integrated into sophisticated control systems. These control systems utilize sensors, actuators, and electronic controls to monitor and regulate the force exerted by the cylinders. By employing algorithms and feedback loops, the control systems can achieve precise force control, enabling the machinery to perform complex tasks with accuracy and repeatability.
6. Proportional Valves: Proportional valves are often used in conjunction with single-acting hydraulic cylinders to achieve precise force control. These valves allow for continuously variable control of the hydraulic flow and pressure, enabling fine adjustments in force output. Proportional valves offer high responsiveness and accuracy, making them suitable for applications where precise force control is required.
It is important to design and configure the hydraulic system and control mechanisms in heavy machinery carefully. Factors such as load requirements, speed, system dynamics, and safety considerations need to be taken into account to achieve optimal force control.
In summary, single-acting hydraulic cylinders contribute to precise force control in heavy machinery through their single-direction force generation, pressure regulation capabilities, integration with load-sensing systems, force feedback mechanisms, utilization within control systems, and the use of proportional valves. These features enable operators to achieve accurate and controlled force application, resulting in precise force control in heavy machinery operations.
What safety considerations should be kept in mind when using single-acting hydraulic cylinders?
When using single-acting hydraulic cylinders, several important safety considerations should be kept in mind to ensure the well-being of personnel and the proper functioning of the equipment. Here’s a detailed explanation:
1. Pressure and Force Limitations: It is crucial to understand and adhere to the recommended pressure and force limitations specified by the manufacturer for the single-acting hydraulic cylinder. Exceeding these limits can lead to equipment failure, hydraulic fluid leaks, or other hazardous situations. Always operate the cylinder within its designed capacity to prevent accidents or damage.
2. Proper Installation: Ensure that the single-acting hydraulic cylinder is correctly installed according to the manufacturer’s instructions. This includes proper alignment, secure mounting, and appropriate connections. Improper installation can result in misaligned forces, leakage, or unexpected movements, posing safety risks.
3. Inspection and Maintenance: Regularly inspect the single-acting hydraulic cylinder for any signs of wear, damage, or leakage. Maintain a scheduled maintenance program to address any issues promptly. Neglecting maintenance can compromise the cylinder’s performance, leading to potential safety hazards or equipment failure.
4. Fluid Compatibility: Ensure that the hydraulic fluid used in the system is compatible with the single-acting hydraulic cylinder and other components. Using the wrong type of fluid can cause seal degradation, reduced performance, or system malfunctions. Consult the manufacturer’s recommendations and follow proper fluid selection and maintenance practices.
5. Leak Prevention: Monitor the hydraulic system for any signs of leaks, especially around the single-acting hydraulic cylinder. Leaking hydraulic fluid can create slippery surfaces and increase the risk of accidents. Address any leaks promptly by replacing damaged seals or components and ensure that proper containment measures are in place.
6. Overload Protection: Implement suitable overload protection mechanisms to prevent excessive forces or loads from damaging the single-acting hydraulic cylinder. This may include incorporating relief valves, pressure-limiting devices, or load-sensing controls. Overload protection helps prevent equipment failure, potential injuries, or structural damage.
7. Lockout/Tagout Procedures: When performing maintenance, repair, or any work involving the single-acting hydraulic cylinder, adhere to lockout/tagout procedures. Lockout/tagout ensures that the hydraulic system is safely de-energized and secured, preventing accidental activation or release of stored energy. This protects personnel from injury during maintenance activities.
8. Operator Training and Awareness: Ensure that operators receive proper training on the safe operation of single-acting hydraulic cylinders. They should be aware of the potential hazards, proper handling techniques, and emergency procedures. Promote a culture of safety and encourage operators to report any safety concerns or incidents promptly.
9. Personal Protective Equipment (PPE): Provide appropriate personal protective equipment, such as gloves, safety glasses, or protective clothing, to personnel working with or around the single-acting hydraulic cylinder. PPE helps protect against potential hazards, including hydraulic fluid contact, flying debris, or unexpected movements.
In summary, when using single-acting hydraulic cylinders, it is essential to consider pressure and force limitations, proper installation, inspection and maintenance, fluid compatibility, leak prevention, overload protection, lockout/tagout procedures, operator training and awareness, and the use of personal protective equipment. Adhering to these safety considerations promotes a safe working environment and ensures the reliable and secure operation of the hydraulic system.
editor by CX 2024-04-10
