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.
Certification: | ISO9001, IATF 16949:2016 |
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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) | |
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Customization: |
Available
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Can telescopic cylinders be repaired or maintained when necessary?
Yes, telescopic cylinders can be repaired and maintained when necessary. Here's a detailed explanation:
Repairability:
Telescopic cylinders are designed with repairability in mind. The modular construction of telescopic cylinders allows for individual components or stages to be replaced or repaired as needed. If a specific part of the cylinder becomes damaged or worn out, it can be disassembled and repaired or replaced, minimizing downtime and cost compared to replacing the entire cylinder.
Maintenance:
Maintenance is essential to ensure the optimal performance and longevity of telescopic cylinders. Regular maintenance practices may include:
- Inspection: Periodic visual inspections to check for any signs of damage, wear, or leakage.
- Lubrication: Applying lubricants to the moving parts of the cylinder to reduce friction and extend component life.
- Cleaning: Removing dirt, debris, and contaminants that may affect the cylinder's operation.
- Seal replacement: Replacing worn or damaged seals to maintain proper sealing and prevent fluid leakage.
- Pressure testing: Conducting pressure tests to ensure the cylinder's integrity and identify any potential issues.
- Alignment and adjustment: Verifying proper alignment and making necessary adjustments to ensure smooth operation and prevent excessive wear.
Depending on the specific application and operating conditions, maintenance intervals and procedures may vary. It's important to follow the manufacturer's maintenance recommendations and guidelines for the telescopic cylinder to ensure effective maintenance practices.
Professional expertise:
Repairing and maintaining telescopic cylinders often require professional expertise. It is recommended to engage qualified technicians or service personnel with experience in hydraulic systems and telescopic cylinder repairs. They have the knowledge and tools necessary to accurately diagnose issues, perform repairs, and conduct maintenance tasks in a safe and efficient manner.
Manufacturer support:
Manufacturers of telescopic cylinders typically provide support for repair and maintenance. They may offer technical documentation, repair manuals, and access to replacement parts to facilitate the repair process. Consulting the manufacturer's resources and seeking their assistance can ensure that repairs and maintenance are carried out correctly and in accordance with the cylinder's specifications.
By implementing proper repair and maintenance practices, telescopic cylinders can be kept in good working condition, extending their service life and maintaining reliable performance.
It's important to note that repair and maintenance should be performed by qualified individuals and comply with relevant safety guidelines and industry standards.
How do telescopic cylinders contribute to stable and safe equipment operation?
Telescopic cylinders play a significant role in ensuring stable and safe equipment operation. Here's a detailed explanation:
Load distribution:
Telescopic cylinders assist in distributing the load evenly across the equipment. As the cylinders extend or retract, they provide support and help maintain the balance of the load. This load distribution is crucial for preventing equipment instability, reducing the risk of tipping or tilting, and ensuring safe operation.
Weight management:
Telescopic cylinders aid in managing the weight distribution of equipment during various operations. By extending or retracting the cylinders selectively, operators can control the positioning and center of gravity of the load. This helps mitigate the risk of equipment imbalance, enhances stability, and promotes safe equipment operation.
Controlled movements:
Telescopic cylinders enable controlled and precise movements of equipment components. The hydraulic control system regulates the extension and retraction of the cylinders, allowing operators to adjust the speed, force, and position of the movement. This precise control minimizes sudden or jerky motions, reduces the likelihood of equipment instability, and enhances overall safety during operation.
Shock absorption:
Telescopic cylinders provide a level of shock absorption during equipment operation. The design of the cylinders, along with the hydraulic system, helps absorb and dampen sudden shocks or impacts that may occur during material handling or terrain traversal. This shock absorption capability reduces stress on the equipment, minimizes the risk of component failure or damage, and contributes to safe and smooth operation.
Operator safety:
Telescopic cylinders contribute to operator safety by providing stability and control. The stable operation of equipment facilitated by the cylinders reduces the risk of accidents or operator injury caused by equipment instability, tipping, or excessive vibrations. Additionally, the precise control over equipment movements enhances operator confidence and minimizes the likelihood of human error during operation.
Monitoring and feedback:
Telescopic cylinders can be integrated with monitoring systems that provide real-time feedback on cylinder performance, load distribution, and equipment stability. This information allows operators to make informed decisions, take corrective actions if necessary, and ensure ongoing safe operation.
Overall, telescopic cylinders contribute to stable and safe equipment operation through load distribution, weight management, controlled movements, shock absorption, operator safety, and monitoring capabilities. Their role in maintaining equipment stability and providing precise control enhances operational safety and reduces the risk of accidents or equipment failure.
It's important to consult the equipment manufacturer's documentation and guidelines for specific information on the integration, operation, and maintenance of telescopic cylinders to ensure safe equipment usage.
How does a telescopic cylinder handle variations in extension and retraction?
A telescopic cylinder is designed to handle variations in extension and retraction through its inherent structure and hydraulic system. Here's a detailed explanation:
Handling variations in extension:
When extending a telescopic cylinder, each stage or sleeve extends successively, one inside the other, to achieve the desired stroke length. This nested structure allows for incremental extension, providing flexibility in adapting to different extension requirements. The hydraulic system supplies pressurized fluid to each stage's piston, generating the necessary force for extension. The internal flow paths in the cylinder ensure synchronized movement of the stages, allowing for controlled and precise extension.
Handling variations in retraction:
During retraction, the telescopic cylinder stages retract in the reverse order of extension. The hydraulic system controls the flow of fluid to each stage, allowing for controlled retraction. The nested structure of the cylinder ensures that each stage retracts smoothly inside the preceding stage. The hydraulic pressure and flow are regulated to prevent rapid or uncontrolled retraction, ensuring safe and stable operation.
Compensating for variations:
Telescopic cylinders are designed to compensate for variations in extension and retraction through their hydraulic control systems. The hydraulic system can be adjusted to vary the flow rate, pressure, or force applied to each stage, allowing for fine-tuning and accommodating different extension and retraction requirements. Additionally, the locking mechanisms incorporated in telescopic cylinders help maintain the extended position securely, compensating for external forces or variations in loads.
Overall, the nested structure, hydraulic system, and locking mechanisms of telescopic cylinders provide the necessary flexibility and control to handle variations in extension and retraction. This enables the cylinders to adapt to different operating conditions, loads, and stroke length requirements in various applications.
It's important to follow the manufacturer's guidelines and recommendations for proper operation, maintenance, and adjustment of telescopic cylinders to ensure their reliable and safe performance.
editor by CX 2023-11-18