Product Description
single acting thin hydraulic jack 50 ton hydraulic jack cylinder ram
Specification
Its design is very compact, it is very suit for the place that closed height and max stroke are the main factor. The plunger of hydraulic jack is welding copper, the facial of plunger rod is plated hard chrome, the kinds of hydraulic jack is never falling off, abrasion resistance is very strong, high temperature paint, its facial is corrosion resistant and strike. Scraper seal of hydraulic cylinder can extend its life. Single acting design, spring return.
Details of RCS Series Low Height Hydraulic Jack
Low height hydraulic jack
1. Lightweight, low profile design for use in confined spaces
2. Plunger wiper reduces contamination, extending cylinder life
3. Grooved plunger end with threaded holes for mounting tilt saddlesIntegral handle on RCS-1002 for easy carrying
4. Plated steel plungers
5. Single-acting, spring return
Technology Parameter:
| Model | Tonnage Ton |
Stroke mm |
Closed height mm |
Extend height mm |
Cylinder In diameter |
Outer diameter mm |
Weight KGS |
| RCS-101 | 10 | 38 | 88 | 126 | 45 | 70 | 4.1 |
| RCS-201 | 20 | 44 | 99 | 143 | 63 | 80 | 5 |
| RCS-302 | 30 | 62 | 118 | 180 | 80 | 95 | 6.8 |
| RCS-502 | 50 | 60 | 122 | 182 | 100 | 127 | 10.9 |
| RCS-1001 | 100 | 45 | 120 | 165 | 140 | 180 | 20 |
| RCS-1002 | 100 | 57 | 141 | 198 | 140 | 180 | 22.7 |
| RCS-1530 | 150 | 30 | 120 | 150 | 180 | 230 | 30 |
| RCS-1545 | 150 | 45 | 140 | 185 | 180 | 230 | 35 |
| RCS-2002 | 200 | 60 | 162 | 222 | 200 | 250 | 55 |
Application:
Our hydraulic jacks have been widely used for industrial field, such as steel plant, cement industry, chemical and refinery, bridge, railway, highway, hydropower station, ship repair, building, construction and maintenance.
Company information:
HangZhou Lead Equipment Co., Ltd. Have been in hydraulic tools industry since 2009. Our main products as follow:
Single acting hydraulic jack/cylinder/ram (10-100 tons)
Single acting hollow hydraulic jack/cylinder/ram (12-100 tons)
Double acting hydraulic jack/cylinder/ram (50-2000 tons)
Double acting hollow hydraulic jack/cylinder/ram (50-2000 tons)
Single acting hydraulic jack/cylinder/ram with lock nut (55-200 tons)
Thin type single acting hydraulic jack/cylinder/ram (10-200 tons)
Ultrathin hydraulic jack/cylinder/ram (10-200 tons)
Flange type hydraulic jack/cylinder/ram (10-630 tons)
Synchronous hydraulic jack (10-1000 tons)
Hydraulic accessories: high pressure oil hose, couplers, seal kits, mainfold, etc.
All the tonnage, stroke, height can be customized according to client’s requirements, supply the best quality and serve. Our warranty is 2 years.
| Type: | Hydraulic Jack |
|---|---|
| Structure: | Piston Cylinder |
| Capacity (Load): | 5-1000 Tons |
| Power Source: | Hydraulic |
| Max Height: | Customized |
| Certification: | CE, ISO 9001:2000, ISO 9001:2008, SGS |
| Customization: |
Available
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How does a hydraulic ram contribute to efficient and powerful force generation?
A hydraulic ram utilizes specific design principles and mechanisms to generate efficient and powerful forces. Here’s a detailed explanation:
1. Water Hammer Effect: The hydraulic ram harnesses the water hammer effect to generate powerful forces. When water flows into the ram during the drive phase, it gains velocity and momentum. As the water reaches a certain pressure threshold, the valve mechanism rapidly closes, creating a water hammer effect. This sudden closure of the valve generates a high-pressure pulse that propels a portion of the water to a higher elevation, producing a powerful force.
2. Momentum Transfer: The hydraulic ram efficiently transfers the momentum of flowing water to generate force. The momentum of the moving water is converted into mechanical work as the water hammer effect occurs. By utilizing the kinetic energy of the water, the hydraulic ram maximizes the efficiency of force generation.
3. Energy Recovery: One of the key features of a hydraulic ram is its ability to recover and reuse energy. As the water hammer effect occurs and the high-pressure pulse lifts a portion of the water, the remaining water in the ram’s drive pipe decelerates. This deceleration allows the kinetic energy of the water to be converted back into potential energy, which can be used to pump a new cycle of water. This energy recovery mechanism enhances the overall efficiency of the hydraulic ram.
4. Mechanical Advantage: A hydraulic ram incorporates mechanical advantage through its design. The valve mechanism and other components are optimized to multiply the force generated by the water hammer effect. By leveraging mechanical advantage, the hydraulic ram can produce a more powerful force output compared to the input force from the flowing water.
5. Self-Sustaining Operation: A hydraulic ram operates in a self-sustaining manner, requiring minimal external power sources. Once the ram is set up and primed with water, it can continue to operate using the energy of flowing water. This self-sustainability contributes to the efficiency of force generation, as it eliminates the need for continuous external energy input.
6. Simple and Robust Design: The design of a hydraulic ram is relatively simple and robust, enabling efficient force generation. The absence of complex components reduces friction and energy losses. Additionally, the robust design ensures durability and long-term reliability, making hydraulic rams suitable for various applications.
Through the water hammer effect, momentum transfer, energy recovery, mechanical advantage, self-sustaining operation, and a simple yet robust design, a hydraulic ram maximizes the efficiency and power of force generation. These features make hydraulic rams an effective and reliable choice for pumping water and harnessing hydraulic power.
How does a hydraulic ram handle variations in environmental conditions?
A hydraulic ram is designed to handle variations in environmental conditions effectively. Here’s a detailed explanation:
1. Temperature: Hydraulic rams are designed to operate within a wide temperature range. The hydraulic fluids used in the system are formulated to maintain their viscosity and performance under different temperature conditions. Additionally, hydraulic systems may incorporate temperature control mechanisms, such as coolers or heaters, to regulate the fluid temperature and ensure optimal operation. This enables hydraulic rams to handle variations in temperature without significant impact on their performance.
2. Moisture and Humidity: Hydraulic rams are typically sealed to prevent moisture or humidity from entering the system. Seals and gaskets are used to create a barrier against external contaminants. Additionally, hydraulic systems may include desiccant breathers or moisture-absorbing elements to maintain dry and clean hydraulic fluid. These measures help protect the hydraulic ram from moisture-related issues such as corrosion or reduced lubrication, allowing it to operate reliably in humid environments.
3. Dust and Contaminants: Hydraulic rams are designed to withstand dust and contaminants commonly found in various environments. The use of air filters, hydraulic filters, and breathers helps prevent the ingress of particles into the hydraulic system. Regular maintenance, including filter replacement and system cleaning, ensures the hydraulic ram remains free from excessive contamination. By minimizing the impact of dust and contaminants, hydraulic rams can maintain their performance and longevity even in harsh or dirty environments.
4. Shock and Vibration: Hydraulic rams are built to handle shock and vibration that may occur during operation. Robust construction, including durable materials and proper mounting techniques, helps absorb and dissipate shocks and vibrations. Additionally, hydraulic systems may incorporate dampening elements or accumulators to further minimize the impact of sudden shocks or vibrations. These features enable hydraulic rams to maintain their stability and functionality even in applications subjected to high levels of vibration or shock.
5. Corrosion Resistance: Hydraulic rams are often designed with corrosion-resistant materials, such as stainless steel or corrosion-resistant coatings. This protects the ram from corrosion caused by exposure to moisture, chemicals, or corrosive environments. Proper maintenance, including regular inspection and cleaning, helps identify and address any signs of corrosion, ensuring the hydraulic ram’s performance and longevity.
6. Environmental Considerations: In certain applications or industries, hydraulic rams may need to comply with specific environmental regulations. For example, they may need to meet certain standards for noise emissions, leakage prevention, or biodegradable hydraulic fluids. Manufacturers take these considerations into account during the design and production of hydraulic rams to ensure compliance and minimize environmental impact.
By incorporating temperature tolerance, moisture and humidity protection, dust and contaminant prevention, shock and vibration absorption, corrosion resistance, and environmental considerations, hydraulic rams are well-equipped to handle variations in environmental conditions. These design features contribute to the reliability, durability, and performance of hydraulic rams in diverse operating environments.
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.
editor by CX 2023-12-11