Product Description

Good Quality Double acting hydraulic cylinder

  1. Detail specification:

 

Designed For

Single-acting,double-acting

Max inner tube 

170mm,180mm,195mm,200mm,210mm,etc

Mounting distance

325mm/345mm/425mm or as cutstomers'requirements

Working Pressure

16Mpa-50Mpa

Stroke

750mm-7200mm

Tipping Weight

35-68Ton

Seal Type

Parker,NOK, BUSAK SHAMBAN or as customer's requirement

Piston Rod

Chrome or nickel plated,ground & polished piston rod

Tube

High tensile cold drawn tube, precision honed for extended seal life

 

If you need OEM service,please apply the following details:

Bore  
Rod  
Stroke  
Mounting type  
Working pressure  
Application  
Material

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Certification: GS, CE, ISO9001
Pressure: Medium Pressure
Work Temperature: Normal Temperature
Acting Way: Double Acting
Working Method: Straight Trip
Adjusted Form: Regulated Type
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

What is a hydraulic ram and how does it work?

A hydraulic ram is a type of water pump that utilizes the energy of flowing water to lift a portion of that water to a higher elevation. Here's a detailed explanation of its working principle:

A hydraulic ram consists of several key components:

  • Drive Pipe: The drive pipe is connected to a water source, such as a stream or a river. It carries the flowing water that provides the energy for the hydraulic ram.
  • Delivery Pipe: The delivery pipe carries the water from the hydraulic ram to the desired destination at a higher elevation.
  • Valve: The valve controls the flow of water within the hydraulic ram.
  • Air Vessel: The air vessel acts as an accumulator and helps maintain a constant flow of water.

The working principle of a hydraulic ram can be summarized in the following steps:

1. Water Flow: The hydraulic ram is installed in a location where there is a natural flow of water. As water flows through the drive pipe, it enters the hydraulic ram.

2. Water Hammer Effect: The flowing water gains momentum and velocity as it enters the hydraulic ram. When the water flow is abruptly stopped by the valve, the kinetic energy of the moving water is converted into pressure energy, creating a water hammer effect.

3. Valve Operation: The sudden increase in pressure due to the water hammer effect forces the valve to close, preventing the backward flow of water. This closure allows the pressure to build up in the hydraulic ram.

4. Air Vessel Operation: As the pressure builds up, it compresses the air in the air vessel. The compressed air acts as a cushion, absorbing the pressure fluctuations and maintaining a constant flow of water.

5. Delivery Phase: Once the pressure reaches a certain threshold and the valve closes, the compressed air in the air vessel pushes the water through the delivery pipe, lifting a portion of the water to a higher elevation.

6. Valve Reopening: As the water is pushed out through the delivery pipe, the pressure in the hydraulic ram decreases. This causes the valve to reopen, allowing the cycle to repeat.

7. Continuous Operation: The hydraulic ram operates continuously as long as there is a steady flow of water in the drive pipe. It uses the energy of the flowing water to lift a smaller portion of that water to a higher elevation, without the need for external power sources.

Hydraulic rams are commonly used in areas with a reliable water source and a need for pumping water to a higher elevation. They are particularly useful in remote locations or off-grid settings, where conventional power sources may not be readily available.

China best Good Quality Double Acting Hydraulic Cylinder/Hydraulic RAM   vacuum pump design		China best Good Quality Double Acting Hydraulic Cylinder/Hydraulic RAM   vacuum pump design
editor by CX 2024-02-20