Product Description

KASHON hydraulic cylinders are available in hundreds of different mechanical or hydraulic cylinders configurations.; Whatever the industrial application; lifting,; pushing,; pulling and available in range of force capacities,; stroke lengths or size restrictions.; Single or double acting,; hollow plunger,; or low height,; you can be sure that CHINAMFG has the hydraulic cylinder to suit your high force application.; 
Features:;
Hollow plunger cylinders provide versatility in testing,; maintenance and tensioning applications.;
Hollow plunger design allows for both,; pull and push forces
Single-acting,; spring return
Cylinders are nickel-plated,; floating center tube on models over 20 tons increases product life
Baked enamel finish for increased corrosion resistance
Collar threads for easy fixturing
RCH-120 cylinders include AR-630 coupler and has 1/4″ NPTF port
RCH-121 and RCH-1211 cylinders have FZ-1630 reducer and AR-630 coupler,; all other models feature CR-4-5086-4100 for pre-sales   
Q2:; How to make payment? 
A2:; Once order confirmed,; we will prepare proforma invoice with our banking details.; 
Q3:; How long does it take to process orders?
A3:;It usually takes 10-14 business days to process most orders for no stock,; if stock available,; only take 2- 3 business days.;
Q4:; What is the packing method? 
A4:; For small piece,; we use carton box; for big piece,; we use exporting grade plywood case.;
Q5:; How to ship?
A5:; Sea freight,; Air freight or International express(DHL,; FEDEX,;UPS.;.;.;); all are available.;
Q6:; What is the warranty
A6:; 12 months against B/L date

Type: Hydraulic Jack
Structure: Hydraulic Jack
Capacity (Load): 21-30T
Power Source: Hydraulic
Max Height: 330mm
Certification: CE, ISO 9001:2008
Customization:
Available

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hydraulic cylinder

How does a hydraulic ram manage variations in load capacity and weight?

A hydraulic ram employs various mechanisms and design features to effectively manage variations in load capacity and weight. Here’s a detailed explanation:

1. Pressure Adjustments: Hydraulic rams can manage variations in load capacity by adjusting the operating pressure. By regulating the pressure within the hydraulic system, the force output of the ram can be controlled. This allows the ram to accommodate different load capacities and weights by adjusting the pressure accordingly. Pressure can be adjusted using pressure control valves or regulators.

2. Piston and Cylinder Design: The design of the piston and cylinder in a hydraulic ram contributes to managing variations in load capacity. The piston area determines the force output of the ram, while the cylinder diameter determines the load-carrying capacity. By selecting the appropriate piston and cylinder sizes, the hydraulic ram can be tailored to handle different load capacities and weights. Larger piston and cylinder sizes are used for heavier loads, while smaller sizes are suitable for lighter loads.

3. Mechanical Advantage: Hydraulic rams can leverage mechanical advantage to manage variations in load capacity and weight. By incorporating mechanical systems such as levers, linkages, or gears, the force applied to the hydraulic ram can be multiplied. This mechanical advantage allows the ram to handle higher load capacities and weights than what the hydraulic pressure alone would be able to achieve.

4. Accumulators: Hydraulic rams can utilize accumulators to manage variations in load capacity. An accumulator is a device that stores hydraulic energy in the form of pressurized fluid. During periods of low demand, excess hydraulic energy can be stored in the accumulator. When there is a sudden increase in load capacity or weight, the stored energy can be released to supplement the hydraulic ram’s force output, ensuring smooth operation and efficient management of variations in load.

5. Control Systems: Advanced hydraulic ram systems can incorporate control systems to manage variations in load capacity and weight. These control systems can monitor the load conditions and adjust the hydraulic pressure, flow rate, or other parameters accordingly. By continuously adapting to changes in load, the hydraulic ram can optimize its performance and maintain consistent force output, regardless of variations in load capacity and weight.

6. Safety Features: Hydraulic rams may include safety features to protect against excessive loads or weight. These features can include overload protection mechanisms, such as pressure relief valves or limit switches, which prevent the hydraulic ram from operating beyond its safe load capacity. By incorporating such safety features, hydraulic rams can effectively manage variations in load while ensuring operational safety.

Through pressure adjustments, piston and cylinder design, mechanical advantage, accumulators, control systems, and safety features, hydraulic rams can efficiently manage variations in load capacity and weight. This versatility makes hydraulic rams suitable for a wide range of applications where load variations are encountered.

hydraulic cylinder

How does a hydraulic ram contribute to energy-efficient force generation?

A hydraulic ram plays a significant role in energy-efficient force generation. Here’s a detailed explanation:

1. Force Multiplication: One of the key advantages of a hydraulic ram is its ability to multiply force. Hydraulic rams utilize the principle of Pascal’s law, which states that pressure exerted on a fluid in a confined space is transmitted equally in all directions. By applying a relatively small force to a small piston or plunger, hydraulic rams can generate a significantly larger force at a larger output piston or plunger. This force multiplication allows for the efficient generation of high forces with relatively low input forces, resulting in energy savings.

2. Power Transmission: Hydraulic rams are part of a hydraulic system that efficiently transmits power from a prime mover, such as an electric motor or an internal combustion engine. The hydraulic system uses pressurized fluid to transmit power through pipelines to the hydraulic ram. The fluid acts as a medium to transfer energy from the prime mover to the ram. Hydraulic systems have high power transmission efficiency, minimizing energy losses during power transfer. This efficiency contributes to energy-efficient force generation in hydraulic rams.

3. Variable Force and Speed Control: Hydraulic rams offer the ability to control and adjust the force and speed of operation. By regulating the flow of hydraulic fluid into the ram, the force exerted by the ram can be precisely controlled. This allows for matching the force output to the specific requirements of the task at hand, avoiding unnecessary energy consumption. Additionally, the speed of the ram can be adjusted by controlling the flow rate of the hydraulic fluid. By optimizing the force and speed of operation, hydraulic rams ensure energy-efficient force generation.

4. Regenerative Energy: Hydraulic systems can incorporate regenerative circuits to capture and reuse energy that would otherwise be wasted. Regenerative circuits allow the hydraulic fluid, which carries potential energy, to flow back into the system after completing a task. This energy can be stored or redirected for future use, reducing the overall energy consumption of the hydraulic system. By implementing regenerative circuits, hydraulic rams contribute to energy efficiency by harnessing and recycling energy that would have otherwise been dissipated.

5. Compact Design and Light Weight: Hydraulic rams are compact and lightweight compared to other force generation mechanisms. Their compact design reduces the amount of material required for construction, resulting in lower energy consumption during the manufacturing process. The lightweight nature of hydraulic rams also contributes to reduced energy requirements for transportation and installation. The combination of compact design and light weight makes hydraulic rams an energy-efficient choice for force generation in various applications.

6. System Integration: Hydraulic rams can be easily integrated into complex hydraulic systems, allowing for efficient overall system design. The integration of hydraulic rams with other components, such as valves, pumps, and accumulators, enables precise control and optimization of the force generation process. Proper system design and integration ensure that hydraulic rams operate at their highest efficiency, minimizing energy waste and maximizing force generation capabilities.

In summary, hydraulic rams contribute to energy-efficient force generation through force multiplication, efficient power transmission, variable force and speed control, regenerative energy utilization, compact design and light weight, as well as system integration. These features make hydraulic rams a preferred choice in applications where energy efficiency and precise force generation are essential.

hydraulic cylinder

How does a hydraulic ram handle variations in hydraulic pressure?

A hydraulic ram is designed to handle variations in hydraulic pressure through the use of specific components and mechanisms. Here’s a detailed explanation:

1. Air Vessel: The air vessel, also known as the air chamber or air dome, is a crucial component in a hydraulic ram. It contains compressed air, which acts as a cushioning medium. When the hydraulic ram is in operation, variations in hydraulic pressure cause fluctuations in water flow. The air vessel absorbs these pressure fluctuations by compressing or expanding the air inside it. This helps maintain a more constant and steady flow of water through the ram.

2. Valve Mechanism: The valve mechanism in a hydraulic ram plays a significant role in handling variations in hydraulic pressure. During the drive phase, the valve opens, allowing water to enter the ram. As the water flows in, it gains velocity and momentum. When the hydraulic pressure reaches a certain threshold, the valve closes rapidly, creating a water hammer effect.

This water hammer effect generates a high-pressure pulse that lifts a portion of the water to a higher elevation. The valve opening and closing are controlled by the pressure differentials and the design of the valve mechanism. This mechanism helps regulate and stabilize the hydraulic pressure within the ram, enabling it to handle variations in pressure.

3. Waste Valve (Optional): Some hydraulic ram designs incorporate a waste valve. The waste valve serves as a safety mechanism to handle excessive pressure build-up. If the pressure inside the ram becomes too high, the waste valve opens, allowing excess water or air to escape. This prevents damage to the hydraulic ram and ensures its safe operation.

4. Seals and Gaskets: Seals and gaskets are essential components that prevent leakage of water or air from the hydraulic ram. They help maintain the necessary pressure differentials and ensure that variations in hydraulic pressure are effectively managed. By preventing leaks, the seals and gaskets contribute to the overall efficiency and performance of the hydraulic ram.

By utilizing these components and mechanisms, a hydraulic ram can effectively handle variations in hydraulic pressure. The air vessel, valve mechanism, optional waste valve, and sealing elements work together to maintain a stable flow and prevent damage to the ram, ensuring its reliable and efficient operation.

China wholesaler High Quality 30 Ton One Way Hollow Plunger Hydraulic RAM   manufacturer China wholesaler High Quality 30 Ton One Way Hollow Plunger Hydraulic RAM   manufacturer
editor by CX 2024-02-13