Product Description
Products Description
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Product Name |
HSG Series Hydraulic Cylinder |
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Work Press |
7/14/16/21/31.5MPa 37.5/63MPa Can be Customized |
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Material |
Aluminum,Cast Iron,45mnb Steel,Stainless Steel |
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Bore Size |
40mm–320mm,Customizable |
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Shaft Diameter |
20mm–220mm,Customizable |
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Stroke Length |
30mm–14100mm,Customizable |
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Rod Surface Hardness |
HRC48-54 |
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Paint Color |
Black,Yellow,Blue,Brown,Customizable |
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Mounting |
Earring,Flange,Clevis.Foot,Trunnion,Customizable |
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Warrenty |
1 Year |
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MOQ |
1 Piece |
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Delivery Time |
7-15 Days,Also depands on specific demands |
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Certification |
ISO9001,CE |
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Company Profile
QIANGLIN HYDRAULIC MACHINERY CO., LTD
| QiangLin is a professional hydraulic equipment manufacturer, mainly engaged in hydraulic system design, manufacture, installation, transformation, sales, and technical services. Our manufacturing facilities are certified to the ISO 9001 standard. We are an approved supplier to many equipment manufacturers in China. We are also partners with many customers from America, Canada, Australia, Germany, England, and other European Countries. Product quality, shorter delivery time, and customer satisfaction are our long-term commitments to our CHINAMFG customers. Hope to be your partner. |
FAQ:
Q1: Are you a trading company or a manufacturer?
A: We have our own factory.
Q2: Are you able to make Non-standard or customized products?
A: Yes, we can.
Q3: How long is your delivery time?
A: Normally, the delivery time is 7 days if we have stock, 15-30 working days if we don’t. but it
also depends on the product
requirements and quantity.
Q4: Do you provide samples? are the samples free or not?
A: Yes, we can provide samples, but they are not free of charge.
Q5: What are your payment terms?
A: 30% deposit T/T or Irrevocable L/C at sight, If you have any questions, please feel free to
contact us.
Q6: What are your After-sales services?
A: Before shipment, Each individual product will be strictly inspected on our factory QC Process
System. In addition, We have a
Customer Service team to respond to customers’ questions within 12 hours. Being helpful in
solving customers’ problems is always our goal. /* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
| Certification: | CE, ISO9001 |
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| Pressure: | High Pressure |
| Work Temperature: | Normal Temperature |
| Customization: |
Available
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Shipping Cost:
Estimated freight per unit. |
about shipping cost and estimated delivery time. |
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| Payment Method: |
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Initial Payment Full Payment |
| Currency: | US$ |
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| Return&refunds: | You can apply for a refund up to 30 days after receipt of the products. |
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How does a lift cylinder handle variations in fluid pressure and flow rate?
A lift cylinder is designed to handle variations in fluid pressure and flow rate in order to ensure smooth and controlled operation. Here’s an explanation of how lift cylinders handle these variations:
1. Fluid Pressure:
Lift cylinders are typically part of a hydraulic system that utilizes pressurized fluid to generate the necessary force for lifting. The lift cylinder is designed to withstand varying fluid pressure levels. When the fluid pressure is increased, the lift cylinder can handle the additional force exerted on its piston. Conversely, when the fluid pressure decreases, the lift cylinder adjusts accordingly and maintains its functionality.
2. Flow Rate:
The flow rate of hydraulic fluid determines the speed at which the lift cylinder extends or retracts. Lift cylinders are designed to accommodate variations in flow rate. By controlling the flow rate of the hydraulic fluid through the use of control valves or flow control devices, operators can adjust the speed of the lift cylinder’s movement. This allows for precise and controlled lifting operations.
3. Control Valves:
Control valves are an integral part of the hydraulic system that regulates the fluid pressure and flow rate. Lift cylinders are often equipped with control valves that enable operators to control the movement of the cylinder by adjusting the pressure and flow of the hydraulic fluid. These valves can be manually operated or automated, providing flexibility in handling variations in fluid pressure and flow rate.
4. Cylinder Design:
Lift cylinders are designed to be robust and durable, capable of withstanding variations in fluid pressure and flow rate. The cylinder’s construction and materials are selected to ensure optimal performance under different operating conditions. Seals and other components within the lift cylinder are designed to maintain their functionality and prevent leakage, even when subjected to changes in fluid pressure and flow rate.
5. Fluid Control Systems:
In more advanced lift cylinder systems, fluid control systems may be employed to handle variations in fluid pressure and flow rate. These systems can include pressure relief valves, flow control valves, or proportional valves. Pressure relief valves protect the lift cylinder and the hydraulic system from excessive pressure, while flow control valves regulate the flow rate of the hydraulic fluid. Proportional valves provide precise control over both pressure and flow, allowing for fine-tuning of the lift cylinder’s movement.
In summary, lift cylinders are designed to handle variations in fluid pressure and flow rate to ensure smooth and controlled lifting operations. With the use of control valves, robust cylinder design, and fluid control systems, lift cylinders can adapt to changes in fluid pressure and flow rate, providing reliable and efficient performance.
How Does a Lift Cylinder Contribute to Load Leveling and Distribution?
A lift cylinder plays a significant role in load leveling and distribution, ensuring stability and balanced weight distribution in various applications. Here’s a detailed explanation of how a lift cylinder contributes to load leveling and distribution:
- Vertical Force Generation:
- Multi-Cylinder Systems:
- Self-Leveling Mechanisms:
- Force Sensing and Control:
- Structural Support and Stability:
- Customization for Specific Applications:
When a lift cylinder is activated, it generates a vertical force that lifts or supports a load. The force exerted by the cylinder is directly proportional to its hydraulic or pneumatic pressure and the effective area of the piston. By adjusting the pressure or controlling the flow of fluid or gas into the cylinder, the force can be precisely regulated to achieve load leveling and distribution.
In applications where load leveling and distribution are critical, multiple lift cylinders may be used in a system. These cylinders work in synchronization to evenly distribute the load and maintain balance. By connecting the cylinders in parallel or series, the hydraulic or pneumatic pressure can be distributed across all cylinders, ensuring that each cylinder contributes proportionately to the load leveling and distribution process.
Some lift cylinder systems incorporate self-leveling mechanisms to automatically adjust the position and angle of the load. These mechanisms utilize sensors or feedback systems that monitor the load distribution and make real-time adjustments to the lift cylinders. If an imbalance or uneven weight distribution is detected, the self-leveling mechanisms activate the appropriate lift cylinders to counteract the imbalance and restore equilibrium. This contributes to load leveling and distribution, preventing excessive stress on specific areas or components.
Advanced lift cylinder systems may employ force sensing and control technologies to achieve precise load leveling and distribution. Force sensors are integrated into the lifting mechanism, allowing real-time monitoring of the forces exerted by the cylinders. This information is then used to adjust the hydraulic or pneumatic pressure, ensuring that each cylinder contributes optimally to the load distribution. By continuously monitoring and controlling the forces, the lift cylinder system can adapt to changing load conditions and maintain stable load leveling and distribution.
Lift cylinders provide structural support and stability to the load-bearing components in various applications. By evenly distributing the load, the cylinders help prevent excessive stress or strain on specific components. They ensure that the weight is evenly spread across the supporting structure, reducing the risk of structural damage or failure. Lift cylinders also contribute to the overall stability of the system, minimizing unwanted movements or vibrations caused by imbalanced loads.
Lift cylinders can be customized and tailored to specific applications to optimize load leveling and distribution. Factors such as cylinder size, stroke length, bore diameter, and material strength can be selected based on the load characteristics and weight distribution requirements of the particular application. By considering the specific needs of the application, lift cylinders can be designed and implemented to achieve the desired load leveling and distribution performance.
Overall, a lift cylinder is a crucial component in achieving load leveling and distribution in various applications. Whether through vertical force generation, multi-cylinder systems, self-leveling mechanisms, force sensing and control, structural support, or customization, lift cylinders contribute to maintaining stability, balance, and even weight distribution, ensuring optimal performance and safety in diverse industrial and mechanical systems.
How does a lift cylinder handle variations in load weight and pressure?
A lift cylinder is designed to handle variations in load weight and pressure to ensure efficient and safe operation. Here’s an explanation of how a lift cylinder handles these variations:
1. Design Considerations:
Lift cylinders are designed with specific load capacities and pressure ratings in mind. The components, such as the cylinder barrel, piston, and seals, are selected and sized accordingly to handle the anticipated loads and pressures. The design factors in safety margins to accommodate variations in load weight and pressure within the specified operational limits.
2. Hydraulic System:
The hydraulic system that powers the lift cylinder plays a crucial role in handling variations in load weight and pressure. The system includes components such as pumps, valves, and control systems that regulate the flow and pressure of hydraulic fluid. By adjusting the system parameters, such as the pump output or valve settings, the hydraulic system can adapt to different load weights and pressure requirements.
3. Pressure Regulation:
Lift cylinders often incorporate pressure regulation mechanisms to handle variations in load weight and pressure. Pressure relief valves or pressure control valves are commonly used to maintain the desired pressure level within the cylinder. These valves ensure that the pressure does not exceed the specified limits, protecting the cylinder and other components from potential damage.
4. Balanced Design:
Lift cylinders are designed to achieve a balanced configuration that minimizes the impact of load weight variations. The placement of the piston and rod within the cylinder barrel is carefully engineered to distribute the load evenly and maintain stability. This balanced design helps to mitigate the effects of load weight changes on the cylinder’s performance and ensures smooth operation.
5. Control and Monitoring:
Advanced lift cylinder systems may incorporate control and monitoring features to handle variations in load weight and pressure more effectively. Sensors and feedback mechanisms can provide real-time data on load weight and cylinder performance, allowing the system to make adjustments as needed. This enhances the overall control and stability of the lift cylinder in response to changing conditions.
In summary, a lift cylinder handles variations in load weight and pressure through careful design considerations, hydraulic system adjustments, pressure regulation mechanisms, balanced configurations, and control and monitoring features. These aspects work together to ensure that the lift cylinder operates safely and efficiently, accommodating different load requirements while maintaining optimal performance.
editor by CX 2024-04-12