Product Description
Product Description
| Bore of cylinder's first stage | Stroke | Upper mouting | Upper mouting | Mounting dimension | Working pressure | ||
| Diameter of the hole | Deep | Diameter of the hole | Deep | ||||
| 5 | 84.00 | 1.63 | 1.50 | 2.00 | 7.00 | 41.09 | 2500 |
| 6 | 120.06 | 2.00 | 2.00 | 2.00 | 7.00 | 52.62 | 2500 |
| 7 | 120.00 | 2.00 | 2.00 | 2.00 | 8.25 | 53.12 | 2500 |
| 8.125 | 234.00 | 2.00 | 2.00 | 2.00 | 9.50 | 64.62 | 2500 |
| 9.375 | 235.00 | 2.00 | 2.00 | 2.00 | 10.88 | 65.44 | 2500 |
| L2 | L3 | L4 | L5 | L6 | ØA | Fitting | Workable container length | Rear suspension length | Lift angle | Lift capacity | Oil tank volume |
| 65 | 360 | 60 | 325 | 1585 | Ø60 | G1 | 4700-5300 | 800 | 47-52° | 43 | 80 |
| 65 | 360 | 60 | 325 | 1270 | Ø60 | G1 | 4700-5300 | 800 | 47-52° | 31 | 80 |
| 65 | 360 | 60 | 325 | 1390 | Ø60 | G1 | 5300-6000 | 800 | 47-52° | 36 | 80 |
| 65 | 360 | 60 | 325 | 1510 | Ø60 | G1 | 5800-6500 | 800 | 47-52° | 36 | 80 |
| 65 | 360 | 60 | 325 | 1385 | Ø60 | G1 | 5300-5800 | 800 | 47-52° | 53 | 80 |
| 65 | 360 | 60 | 325 | 1505 | Ø60 | G1 | 5800-6500 | 800 | 47-52° | 53 | 100 |
| 65 | 360 | 60 | 325 | 1580 | Ø60 | G1 | 6200-6800 | 800 | 47-52° | 58 | 100 |
| 65 | 360 | 60 | 325 | 1655 | Ø60 | G1 | 6600-7200 | 800 | 47-52° | 58 | 100 |
| 65 | 360 | 60 | 325 | 1125 | Ø60 | G1 | 5000-5500 | 800 | 47-52° | 46 | 80 |
| 65 | 360 | 60 | 325 | 1165 | Ø60 | G1 | 5300-6000 | 800 | 47-52° | 46 | 80 |
| 65 | 360 | 60 | 325 | 1265 | Ø60 | G1 | 5800-6500 | 800 | 47-52° | 49 | 80 |
| 65 | 360 | 60 | 325 | 1340 | Ø60 | G1 | 6200-6800 | 800 | 47-52° | 49 | 80 |
| 65 | 360 | 60 | 325 | 1385 | Ø60 | G1 | 6600-7200 | 800 | 47-52° | 49 | 80 |
| 65 | 360 | 65 | 325 | 1455 | Ø60 | G1 | 5600-6300 | 800 | 47-52° | 66 | 120 |
| 65 | 360 | 65 | 325 | 1505 | Ø60 | G1 | 5800-6500 | 800 | 47-52° | 66 | 120 |
| 65 | 360 | 65 | 325 | 1580 | Ø60 | G1 | 6200-6800 | 800 | 47-52° | 70 | 120 |
| 65 | 360 | 65 | 325 | 1655 | Ø60 | G1 | 6600-7200 | 800 | 47-52° | 70 | 120 |
| 65 | 360 | 65 | 325 | 1750 | Ø60 | G1 | 7200-8000 | 1000 | 47-52° | 70 | 135 |
| 65 | 360 | 65 | 325 | 1270 | Ø60 | G1 | 7200-8000 | 1000 | 47-52° | 49 | 120 |
| 65 | 360 | 65 | 325 | 1675 | Ø65 | G1 | 6600-7200 | 800 | 47-52° | 92 | 165 |
| 65 | 360 | 65 | 325 | 1770 | Ø65 | G1 | 7200-8000 | 1000 | 47-52° | 96 | 165 |
| 65 | 360 | 65 | 325 | 1870 | Ø65 | G1 | 8000-8500 | 1000 | 47-52° | 96 | 185 |
| 65 | 360 | 65 | 325 | 1770 | Ø65 | G1 | 8700-9500 | 1000 | 47-52° | 88 | 185 |
Company Profile
Certifications
Packaging & Shipping
FAQ
Q1: Can your cylinders with HYVA ones ?
Yes, our cylinders can replace HYVA ones well, with same technical details and mounting sizes
Q2: What's your cylinder's advantages ?
The cylinders are made under strictly quality control processing.
All the raw materials and seals we used are all from world famous companies.
Cost effective
Q3: When your company be established ?
Our company be established in 1996, and we are professional for hydraulic cylinders for more than 25 years.
And we had passed IATF 16949:2016 Quality control system.
Q4: How about the delivery time ?
For samples about 20 days. And 15 to 30 days about mass orders.
Q5: How about the cylinder's quality gurantee ?
We have 1 year quality grantee of the cylinders.
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| Certification: | ISO9001, IATF 16949:2016 |
|---|---|
| Pressure: | High Pressure |
| Work Temperature: | Normal Temperature |
| Acting Way: | Double Acting |
| Working Method: | Straight Trip |
| Adjusted Form: | Regulated Type |
| Samples: |
US$ 1000/Piece
1 Piece(Min.Order) | |
|---|
| Customization: |
Available
|
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|---|
How do telescopic cylinders contribute to energy-efficient equipment operation?
Telescopic cylinders play a significant role in promoting energy-efficient equipment operation. Here's a detailed explanation:
Reduced energy consumption:
Telescopic cylinders are designed to minimize energy consumption during equipment operation. The hydraulic system of telescopic cylinders allows for precise control over the extension and retraction of the cylinder stages. This control enables the equipment to use the minimum amount of hydraulic fluid and energy required to achieve the desired movement or position.
Efficient force transmission:
Telescopic cylinders are engineered to efficiently transmit forces from the hydraulic system to the desired application. The telescopic design allows for a direct and linear transfer of force, reducing energy losses that can occur in more complex mechanical systems. This efficient force transmission ensures that the energy supplied to the telescopic cylinder is effectively utilized to perform the desired work.
Compactness and weight reduction:
Telescopic cylinders offer compactness in equipment design, which contributes to energy efficiency. By retracting the cylinder stages, the overall length of the equipment can be minimized, reducing weight and inertia. This reduction in weight and inertia requires less energy to start and stop the movement of the equipment, resulting in energy savings during operation.
Optimized design:
Telescopic cylinders are designed with efficiency in mind. Manufacturers consider factors such as the cylinder's bore size, rod diameter, and overall construction to ensure optimal performance while minimizing energy requirements. By using lightweight and high-strength materials, optimizing the cylinder's dimensions, and reducing internal friction, telescopic cylinders can operate efficiently and contribute to energy savings.
Controlled motion:
Telescopic cylinders provide precise and controlled motion, allowing equipment operators to perform tasks with accuracy and efficiency. The hydraulic control system in telescopic cylinders enables smooth and proportional extension and retraction, reducing the need for excessive force or multiple adjustments. This controlled motion prevents energy waste and ensures that the equipment operates efficiently.
Applications in energy-efficient equipment:
Telescopic cylinders are utilized in various energy-efficient equipment, such as hybrid or electric-powered machinery. These equipment types rely on the optimization of energy usage to minimize environmental impact and reduce operating costs. Telescopic cylinders contribute to these objectives by providing efficient force transmission, controlled motion, and compact design.
Furthermore, the integration of advanced technologies, such as electronic control systems, sensors, and feedback mechanisms, can enhance the energy efficiency of equipment that incorporates telescopic cylinders. These technologies allow for further optimization of hydraulic system performance, energy recovery, and intelligent control of equipment operations.
Overall, telescopic cylinders contribute to energy-efficient equipment operation through reduced energy consumption, efficient force transmission, compactness and weight reduction, optimized design, and controlled motion. By utilizing telescopic cylinders in equipment design and considering energy-efficient practices, industries can achieve more sustainable and economical operation.
Consulting with equipment manufacturers or industry experts can provide further insights into the energy-saving benefits and applications of telescopic cylinders in specific equipment types.
How do telescopic cylinders handle variations in cylinder size and capacity?
Telescopic cylinders are designed to handle variations in cylinder size and capacity effectively. Here's a detailed explanation:
Modular design:
Telescopic cylinders feature a modular design that allows for flexibility in cylinder size and capacity. They consist of multiple stages or sections that retract inside one another, similar to a telescope. The number of stages can vary depending on the desired extended length and capacity of the cylinder. This modular design enables telescopic cylinders to be customized according to specific requirements.
Variable stroke length:
Telescopic cylinders offer the advantage of variable stroke length. The stroke length refers to the distance the cylinder can extend and retract. By adjusting the stroke length, the effective size and capacity of the telescopic cylinder can be modified. This flexibility allows for accommodating variations in the size and capacity requirements of different applications.
Increased capacity with additional stages:
Telescopic cylinders can handle variations in capacity by adding more stages to the cylinder. Each stage contributes to the overall capacity of the cylinder. By including additional stages, the cylinder's capacity can be increased to handle higher loads or operate in more demanding conditions. This scalability makes telescopic cylinders suitable for a wide range of applications with varying capacity needs.
Proportional force distribution:
Telescopic cylinders distribute the applied force proportionally across the stages. As the cylinder extends, each stage contributes to supporting the load and transmitting the force. The force distribution ensures that the load is evenly distributed among the stages, allowing the cylinder to handle variations in capacity effectively.
Hydraulic control system:
Telescopic cylinders rely on a hydraulic control system for operation. The system allows for precise control over the extension and retraction of each stage. By adjusting the hydraulic pressure and flow, operators can regulate the movement and force exerted by the cylinder, ensuring optimal performance and capacity utilization.
Overall, telescopic cylinders handle variations in cylinder size and capacity through their modular design, variable stroke length, ability to add stages for increased capacity, proportional force distribution, and hydraulic control system. These features make telescopic cylinders adaptable to different applications and enable them to effectively handle varying size and capacity requirements.
It's important to consult the equipment manufacturer's documentation and guidelines for specific information on the size, capacity, and operational considerations of telescopic cylinders.
How does a telescopic cylinder contribute to precise reach and positioning?
A telescopic cylinder plays a crucial role in achieving precise reach and positioning in various applications. Here's a detailed explanation:
Nested structure:
The nested structure of a telescopic cylinder, consisting of multiple stages or sleeves that retract inside one another, enables precise reach and positioning. Each stage can be extended or retracted individually, allowing for incremental adjustments in the cylinder's length. This modular design provides fine-tuning capabilities, enabling operators to achieve the desired reach and positioning with accuracy.
Controlled extension and retraction:
The hydraulic control system of a telescopic cylinder ensures controlled extension and retraction of the stages. By regulating the flow of hydraulic fluid to each stage, operators can precisely control the speed and movement of the cylinder. This control allows for smooth and gradual extension or retraction, facilitating precise reach and positioning without abrupt or jerky movements.
Adjustable stroke length:
Telescopic cylinders offer the advantage of adjustable stroke length. The hydraulic system can be adjusted to vary the extension and retraction distance, allowing for customization based on the specific reach and positioning requirements of the application. This adjustability enables operators to adapt the cylinder's stroke length to different tasks and working conditions, ensuring precise and optimized reach.
Position feedback systems:
In some applications, telescopic cylinders may be equipped with position feedback systems. These systems utilize sensors or transducers to provide real-time feedback on the cylinder's extension or retraction position. By monitoring the position, operators can precisely track and control the reach and positioning of the cylinder, enhancing accuracy and repeatability.
Stability and rigidity:
Telescopic cylinders are designed to maintain stability and rigidity during operation. The nested structure, along with the hydraulic system, helps minimize unwanted oscillations or vibrations that could affect reach and positioning accuracy. This stability ensures that the cylinder maintains its intended position without undesired movement or deflection.
Overall, a telescopic cylinder contributes to precise reach and positioning through its nested structure, controlled extension and retraction, adjustable stroke length, position feedback systems (if equipped), and stability. These features enable operators to achieve accurate and repeatable reach and positioning in various applications.
It's important to consult the manufacturer's guidelines and specifications, as well as follow proper maintenance practices, to ensure the reliable and precise performance of telescopic cylinders in achieving reach and positioning requirements.
editor by Dream 2024-04-24