Product Description
Standard Tie rod Hydraulic Cylinder
TR2008ASAE TR3008ASAE TR4008ASAE
Specificattions:
Part Number | Rod Dia. | Bore x Stroke | Dimensions | Port Size | Pin Size | Weight (lbs) | |
Retracted | Extended | ||||||
GD TR25-2004 | 1 1/8” | 2”*4” | 14 1/4” | 18 1/4” | 3/8NPT | 1” | 15 |
TR25-2006 | 2”*6” | 16 1/4” | 22 1/4” | 16 | |||
TR25-2008 | 2”*8” | 18 1/4” | 26 1/4” | 18 | |||
TR25-2008-ASAE | 2”*8” | 20 1/4” | 28 1/4” | 19 | |||
TR25-2571 | 2”*10” | 20 1/4” | 30 1/4” | 19 | |||
TR25-2012 | 2”*12” | 22 1/4” | 34 1/4” | 20 | |||
TR25-2014 | 2”*14” | 24 1/4” | 38 1/4” | 22 | |||
TR25-2016 | 2”*16” | 26 1/4” | 42 1/4” | 24 | |||
TR25-2018 | 2”*18” | 28 1/4” | 46 1/4” | 26 | |||
TR25-2571 | 2”*20” | 30 1/4” | 50 1/4” | 27 | |||
TR25-2571 | 2”*24” | 34 1/4” | 58 1/4” | 30 | |||
TR25-2030 | 2”*30” | 40 1/4” | 70 1/4” | 35 | |||
TR25-2036 | 2”*36” | 46 1/4” | 82 1/4” | 40 | |||
TR25-2504 | 1 1/8” | 2.5”*4” | 14 1/4” | 18 1/4” | 3/8NPT | 1” | 18 |
TR25-2506 | 2.5”*6” | 16 1/4” | 22 1/4” | 20 | |||
TR25-2508 | 2.5”*8” | 18 1/4” | 26 1/4” | 22 | |||
TR25-2508-ASAE | 2.5”*8” | 20 1/4” | 28 1/4” | 22 | |||
TR25-2510 | 2.5”*10” | 20 1/4” | 30 1/4” | 23 | |||
TR25-2512 | 2.5”*12” | 22 1/4” | 34 1/4” | 25 | |||
TR25-2514 | 2.5”*14” | 24 1/4” | 38 1/4” | 27 | |||
TR25-2516 | 2.5”*16” | 26 1/4” | 42 1/4” | 28 | |||
TR25-2518 | 2.5”*18” | 28 1/4” | 46 1/4” | 29 | |||
TR25-2520 | 2.5”*20” | 30 1/4” | 50 1/4” | 31 | |||
TR25-2524 | 2.5”*24” | 34 1/4” | 58 1/4” | 35 | |||
TR25-2530 | 2.5”*30” | 40 1/4” | 70 1/4” | 45 | |||
TR25-2536 | 2.5”*36” | 46 1/4” | 82 1/4” | 50 | |||
TR25-3004 | 1 1/4” | 3”*4” | 14 1/4” | 18 1/4” | 1/2NPT | 1” | 22 |
TR25-3006 | 3”*6” | 16 1/4” | 22 1/4” | 24 | |||
TR25-3008 | 3”*8” | 18 1/4” | 26 1/4” | 26 | |||
TR25-3008-ASAE | 3”*8” | 20 1/4” | 28 1/4” | 27 | |||
TR25-3571 | 3”*10” | 20 1/4” | 30 1/4” | 28 | |||
TR25-3012 | 3”*12” | 22 1/4” | 34 1/4” | 31 | |||
TR25-3014 | 3”*14” | 24 1/4” | 38 1/4” | 33 | |||
TR25-3016 | 3”*16” | 26 1/4” | 42 1/4” | 35 | |||
TR25-3016-ASAE | 3”*16” | 31 1/4” | 47 1/4” | 1 1/4” | 38 | ||
TR25-3018 | 1 1/2” | 3”*18” | 28 1/4” | 46 1/4” | 1” | 42 | |
TR25-3571 | 3”*20” | 30 1/4” | 50 1/4” | 44 | |||
TR25-3571 | 3”*24” | 34 1/4” | 58 1/4” | 49 | |||
TR25-3030 | 3”*30” | 40 1/4” | 70 1/4” | 58 | |||
GD-TR25-3036 | 3”*36” | 46 1/4” | 82 1/4” | 67 | |||
TR25-3504 | 1 1/4” | 3.5”*4” | 14 1/4” | 18 1/4” | 1/2NPT | 1” | 29 |
TR25-3506 | 3.5”*6” | 16 1/4” | 22 1/4” | 30 | |||
TR25-3508 | 3.5”*8” | 18 1/4” | 26 1/4” | 34 | |||
TR25-3508-ASAE | 3.5”*8” | 20 1/4” | 28 1/4” | 35 | |||
TR25-3510 | 3.5”*10” | 20 1/4” | 30 1/4” | 37 | |||
TR25-3512 | 3.5”*12” | 22 1/4” | 34 1/4” | 39 | |||
TR25-3514 | 3.5”*14” | 24 1/4” | 38 1/4” | 42 | |||
TR25-3516 | 3.5”*16” | 26 1/4” | 42 1/4” | 44 | |||
TR25-3516-ASAE | 1 1/2” | 3.5”*16” | 31 1/4” | 47 1/4” | 1 1/4” | 50 | |
TR25-3518 | 1 1/4” | 3.5”*18” | 28 1/4” | 46 1/4” | 1” | 47 | |
TR25-3520 | 3.5”*20” | 30 1/4” | 50 1/4” | 49 | |||
TR25-3524 | 1 1/2” | 3.5”*24” | 34 1/4” | 58 1/4” | 58 | ||
TR25-3530 | 3.5”*30” | 40 1/4” | 70 1/4” | 70 | |||
TR25-3536 | 3.5”*36” | 46 1/4” | 82 1/4” | 72 | |||
TR25-4004 | 1 1/4” | 4”*4” | 14 1/4” | 18 1/4” | 1/2NPT | 1” | 33 |
TR25-4006 | 4”*6” | 16 1/4” | 22 1/4” | 36 | |||
TR25-4008 | 4”*8” | 18 1/4” | 26 1/4” | 39 | |||
TR25-4008-ASAE | 4”*8” | 20 1/4” | 28 1/4” | 41 | |||
TR25-4571 | 4”*10” | 20 1/4” | 30 1/4” | 42 | |||
TR25-4012 | 4”*12” | 22 1/4” | 34 1/4” | 45 | |||
GD-TR25-4014 | 4”*14” | 24 1/4” | 38 1/4” | 47 | |||
TR25-4016 | 4”*16” | 26 1/4” | 42 1/4” | 49 | |||
TR25-4016-ASAE | 2” | 4”*16” | 31 1/4” | 47 1/4” | 1 1/4” | 63 | |
TR25-4018 | 1 1/2” | 4”*18” | 28 1/4” | 46 1/4” | 1” | 55 | |
TR25-4571 | 4”*20” | 30 1/4” | 50 1/4” | 58 | |||
TR25-4571-150 | 4”*24” | 34 1/4” | 58 1/4” | 64 | |||
TR25-4571-175 | 1 3/4” | 4”*24” | 34 1/4” | 58 1/4” | 68 | ||
TR25-4571-200 | 2” | 4”*24” | 34 1/4” | 58 1/4” | 73 | ||
TR25-4030 | 4”*30” | 40 1/4” | 70 1/4” | 84 | |||
TR25-4036 | 4”*36” | 46 1/4” | 82 1/4” | 95 | |||
TR25-5004 | 1 1/2” | 5”*4” | 16 1/4” | 20 1/4” | 1/2NPT | 1” | 53 |
GD-TR25-5006 | 5”*6” | 18 1/4” | 24 1/4” | 55 | |||
TR25-5008 | 5”*8” | 20 1/4” | 28 1/4” | 64 | |||
TR25-5571 | 5”*10” | 22 1/4” | 32 1/4” | 68 | |||
TR25-5012 | 2” | 5”*12” | 24 1/4” | 36 1/4” | 77 | ||
TR25-5014 | 5”*14” | 26 1/4” | 40 1/4” | 82 | |||
TR25-5016 | 5”*16” | 28 1/4” | 44 1/4” | 87 | |||
TR25-5016-ASAE | 5”*16” | 31 1/4” | 47 1/4” | 1 1/4” | 90 | ||
TR25-5018 | 5”*18” | 30 1/4” | 48 1/4” | 1” | 92 | ||
TR25-5571 | 5”*20” | 32 1/4” | 52 1/4” | 96 | |||
TR25-5571 | 5”*24” | 36 1/4” | 60 1/4” | 106 | |||
TR25-5030 | 5”*30” | 42 1/4” | 72 1/4” | 121 | |||
GD-TR25-5036 | 5”*36” | 48 1/4” | 84 1/4” | 136 |
PART NUMBER | INSIDER DIAMETER | OUTSIDER DIAMETER | *A | B | *C | *D | *E | F | G | H | 1 | *J | ROD THREAD | PORT |
TR2.5-20- | 2.00″ | 2.37″ | 10.25″ | 2.00″ | 1.01″ | 2.00″ | 3.75″ | 2.25n | 1.12″ | 2.06″ | 2.12″ | 2.62″ | 1.125-12 UNF | 3/8-NPT |
TR2.5-25- | 2.50″ | 2.87″ | 10.25″ | 2.00″ | 1.01″ | 2.25″ | 3.75″ | 2.25″ | 1.12″ | 2.06″ | 2.12″ | 2.62″ | 1.125-12 UNF | 3/8-NPT |
TR2.5-30- | 3.00″ | 3.37″ | 10.25″ | 2.00″ | 1.01″ | 2.25″ | 3.75″ | 2.25″ | 1.12″ | 2.06″ | 2.12″ | 2.62″ | 1.250-12 UNF | 1/2-NPT |
TR2.5-35- | 3.50″ | 3.87″ | 10.25″ | 2.00″ | 1.01″ | 2.25″ | 3.62″ | 2.50″ | 1.12″ | 2.06″ | 2.12″ | 2.62″ | 1.250-12 UNF | 1/2-NPT |
TR2.5-40- | 4.00″ | 4.37″ | 10.25″ | 2.25″ | 1.01″ | 2.25″ | 3.56″ | 2.62″ | 1.12″ | 2.06″ | 2.12″ | 2.62″ | 1.250-12 UNF | 1/2-NPT |
TR2.5-50- | 5.00″ | 5.37″ | 12.25″ | 2.87″ | 1.26″ | 2.75″ | 4.18″ | 3.50″ | 1.12″ | 2.25″ | 2.12″ | 3.31″ | 1.500-12 UNF | 1/2-NPT |
*FOR 8.00″ ASAE STROKE :*A= 12.25n AND FOR 16.00″ ASAE STROKE:*A= 15.50″ | ||||||||||||||
*FOR 8.00″ STROKE :*E= 5.75″(2.0(T TO 3.00″ BORE) *E= 5.62n(3.50″ BORE) *E = 5.56″(4.0(T BORE) | ||||||||||||||
*FOR 16.00″ ASAE STROKE: *E = 9.00″(2.00″ TO 3.00B BORE) *E = 8.87″(3.50″ BORE) *E = 8.81″(4.00″ BORE) | ||||||||||||||
*FOR TTR2.5-2518 TO TTR2.5-2536: ROD THREAD= 1.125-12 UNF | ||||||||||||||
*FOR TTR2.5-4016-ASAE TO TR2.5-4036:*D= 2.50″ *J = 2.75″ *RODTHREAD= 1.500-12 UNF | ||||||||||||||
*FOR 16.00’ASAE STROKE:*C = 1.26* | ||||||||||||||
SEAL TEMPERATURE RANGE: -30°C/+100°C(-22°F/+212°F) | ||||||||||||||
SEAL MAXIMUM SPEED:3 FT/SEC | ||||||||||||||
MAXIMUM RETRACTED WORKING PRESSURE= 2500 PSI | ||||||||||||||
DIMENSIONS A AND E ARE FOR REFERENCES ONLY AS CLEVIS IS ADJUSTABLE |
Packaging
We use metal case/plywood case /carton or as Customer’s requirements
Delivery time:30-40 days
Hydraulic cylinders can be built according to your drawings or technical requirement.
Sample order are acceptable.
Certification: | GS, RoHS, CE, ISO9001 |
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Pressure: | Medium Pressure |
Work Temperature: | Normal Temperature |
Samples: |
US$ 30/Piece
1 Piece(Min.Order) | Order Sample |
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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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Can hydraulic cylinders be used for precise operations like CNC machining or molding?
Yes, hydraulic cylinders can be used for precise operations like CNC machining or molding. While hydraulic systems are commonly associated with heavy-duty applications, they can also provide the necessary precision and control required for precise operations in CNC machining and molding processes. Here’s a detailed explanation of how hydraulic cylinders can be utilized for such precise operations:
1. Force and Control:
– Hydraulic cylinders are capable of generating substantial force, which is essential for precise operations in CNC machining and molding. By using hydraulic pressure, the cylinders can deliver the required force to cut or shape materials accurately or exert pressure for molding operations. The hydraulic system allows precise control over the force applied, ensuring consistent and reliable performance.
2. Adjustable Speed and Positioning:
– Hydraulic cylinders offer adjustable speed and precise positioning capabilities, making them suitable for precise operations. By controlling the flow of hydraulic fluid, the speed of the cylinder’s movement can be adjusted according to specific requirements. This adaptability allows for fine-tuning the machining or molding process, achieving the desired precision in material removal or shaping. Hydraulic systems also enable accurate positioning of tools or molds, ensuring precise operations.
3. Integrated Feedback Systems:
– Advanced hydraulic systems can incorporate feedback sensors and control mechanisms to enhance precision in CNC machining and molding. These sensors provide real-time information about the position, speed, and force exerted by the hydraulic cylinders. The control system processes this data and adjusts the flow of hydraulic fluid accordingly, allowing for precise and accurate control over the operations. The feedback systems help maintain consistent performance and compensate for any deviations, ensuring high precision.
4. Damping and Vibration Control:
– Hydraulic cylinders can be equipped with damping mechanisms to minimize vibrations and ensure stability during CNC machining or molding operations. Vibrations can negatively impact precision by causing tool chatter or material deformation. By incorporating cushioning or damping features, hydraulic cylinders help absorb shocks and suppress vibrations, resulting in smoother and more accurate operations.
5. Customization and Adaptability:
– Hydraulic cylinders can be customized and adapted to meet the specific requirements of CNC machining or molding processes. Engineers can design cylinders with unique dimensions, stroke lengths, mounting options, and sealing arrangements to fit into equipment or systems with precise specifications. Customized hydraulic cylinders ensure optimal performance and compatibility for precise operations, enabling seamless integration into CNC machines or molding equipment.
6. Energy Efficiency:
– Hydraulic systems can be designed to be energy-efficient, contributing to cost savings in CNC machining or molding operations. By utilizing variable speed pumps, efficient control valves, and well-designed hydraulic circuits, energy consumption can be optimized. This efficiency reduces heat generation, leading to improved stability and precision in operations while minimizing energy costs.
7. Maintenance and Calibration:
– Regular maintenance and calibration of hydraulic systems are essential to maintain their precision in CNC machining or molding applications. Proper lubrication, inspection of seals, and replacement of worn-out components help ensure optimal performance. Regular calibration of control systems and feedback sensors ensures accurate readings and reliable operation, contributing to precision in machining or molding processes.
In summary, hydraulic cylinders can be effectively used for precise operations like CNC machining or molding. Their ability to generate substantial force, adjustable speed and positioning, integration with feedback systems, damping and vibration control, customization and adaptability, energy efficiency, and proper maintenance contribute to achieving the required precision in these operations. By leveraging the strengths of hydraulic systems, manufacturers can enhance the accuracy and reliability of CNC machining or molding processes, resulting in high-quality products and improved productivity.
Integration of Hydraulic Cylinders with Equipment Requiring Rapid and Dynamic Movements
Hydraulic cylinders can indeed be integrated with equipment that requires rapid and dynamic movements. While hydraulic systems are generally known for their ability to provide high force and precise control, they can also be designed and optimized for applications that demand fast and dynamic motion. Let’s explore how hydraulic cylinders can be integrated with such equipment:
- High-Speed Hydraulic Systems: Hydraulic cylinders can be part of high-speed hydraulic systems designed specifically for rapid and dynamic movements. These systems incorporate features such as high-flow valves, optimized hydraulic circuitry, and responsive control systems. By carefully engineering the system components and hydraulic parameters, it is possible to achieve the desired speed and responsiveness, enabling the equipment to perform rapid movements.
- Valve Control: The control of hydraulic cylinders plays a crucial role in achieving rapid and dynamic movements. Proportional or servo valves can be used to precisely control the flow of hydraulic fluid into and out of the cylinder. These valves offer fast response times and precise flow control, allowing for rapid acceleration and deceleration of the cylinder’s piston. By adjusting the valve settings and optimizing the control algorithms, equipment can be designed to execute dynamic movements with high speed and accuracy.
- Optimized Cylinder Design: The design of hydraulic cylinders can be optimized to facilitate rapid and dynamic movements. Lightweight materials, such as aluminum alloys or composite materials, can be used to reduce the moving mass of the cylinder, enabling faster acceleration and deceleration. Additionally, the cylinder’s internal components, such as the piston and seals, can be designed for low friction to minimize energy losses and enhance responsiveness. These design optimizations contribute to the overall speed and dynamic performance of the equipment.
- Accumulator Integration: Hydraulic accumulators can be integrated into the system to enhance the dynamic capabilities of hydraulic cylinders. Accumulators store pressurized hydraulic fluid, which can be rapidly released to supplement the flow from the pump during high-demand situations. This stored energy can provide an extra boost of power, allowing for faster and more dynamic movements. By strategically sizing and configuring the accumulator, the system can be optimized for the specific rapid and dynamic requirements of the equipment.
- System Feedback and Control: To achieve precise and dynamic movements, hydraulic systems can incorporate feedback sensors and advanced control algorithms. Position sensors, such as linear potentiometers or magnetostrictive sensors, provide real-time position feedback of the hydraulic cylinder. This information can be used in closed-loop control systems to maintain precise positioning and execute rapid movements. Advanced control algorithms can optimize the control signals sent to the valves, ensuring smooth and dynamic motion while minimizing overshooting or oscillations.
In summary, hydraulic cylinders can be integrated with equipment that requires rapid and dynamic movements by utilizing high-speed hydraulic systems, employing responsive valve control, optimizing cylinder design, integrating accumulators, and incorporating feedback sensors and advanced control algorithms. These measures enable hydraulic systems to deliver the speed, responsiveness, and precision necessary for equipment operating in dynamic environments. By leveraging the capabilities of hydraulic cylinders, manufacturers can design and integrate systems that meet the requirements of applications demanding rapid and dynamic movements.
What benefits do hydraulic cylinders offer for tasks requiring heavy lifting or movement?
Hydraulic cylinders offer numerous benefits for tasks that involve heavy lifting or movement. Their unique design and characteristics make them well-suited for applications that require substantial force, precise control, and reliable operation. Here are the detailed benefits that hydraulic cylinders provide for such tasks:
1. High Force Generation:
– Hydraulic cylinders are capable of generating significant amounts of force. By utilizing hydraulic pressure, which can be easily amplified, hydraulic cylinders can exert substantial force to lift and move heavy loads. The force output of a hydraulic cylinder is directly proportional to the hydraulic pressure and the surface area of the piston. This high force capability makes hydraulic cylinders ideal for tasks that involve heavy lifting, pushing, or pulling.
2. Precise Control:
– Hydraulic cylinders offer precise control over the force and motion they generate. By regulating the flow of hydraulic fluid into the cylinder, the speed, direction, and position of the cylinder’s movement can be accurately controlled. This level of control is crucial for tasks that require precise positioning, delicate movements, or synchronization of multiple cylinders. It enables operators to perform operations with accuracy and minimize the risk of damage or accidents.
3. Safety:
– Hydraulic cylinders are designed with safety features to ensure the protection of both personnel and equipment. They incorporate overload protection mechanisms, such as relief valves, that prevent excessive force or pressure from damaging the system. Additionally, hydraulic cylinders allow for controlled and gradual movements, reducing the risk of sudden and uncontrolled motions that could pose safety hazards during heavy lifting or movement tasks.
4. Versatility and Adaptability:
– Hydraulic cylinders are versatile components that can be adapted to meet specific requirements. They can be customized based on factors such as force capacity, stroke length, speed, and mounting options, allowing them to be integrated into various types of machinery. This versatility makes hydraulic cylinders suitable for a wide range of applications, including construction, material handling, mining, agriculture, and more.
5. Smooth and Controlled Operation:
– Hydraulic cylinders provide smooth and controlled operation, ensuring efficient and reliable performance during heavy lifting or movement tasks. The hydraulic fluid acts as a cushioning medium, which helps dampen shocks and vibrations, resulting in smoother and quieter operation. This controlled operation also reduces the risk of damage to the load being lifted or the surrounding equipment.
6. Compact Design:
– Hydraulic cylinders offer a high power-to-size ratio, allowing for compact machinery design. Their relatively small size, compared to the forces they can generate, makes them suitable for applications where space is limited or weight restrictions apply. This compact design enables the integration of hydraulic cylinders into different types of equipment without compromising performance or efficiency.
7. Durability and Reliability:
– Hydraulic cylinders are built to withstand rigorous operating conditions and provide long-term reliability. They are constructed with robust materials, precise machining, and effective sealing systems to ensure durability and prevent fluid leakage. Hydraulic cylinders can withstand high pressures, heavy loads, and continuous use, making them suitable for demanding tasks involving heavy lifting or movement.
8. Energy Efficiency:
– Hydraulic cylinders contribute to energy efficiency in tasks requiring heavy lifting or movement. Hydraulic systems allow for the transfer of power over long distances without significant power losses. Additionally, hydraulic cylinders can incorporate energy-saving features such as load-sensing technology and regenerative circuits, which reduce energy consumption by optimizing the use of hydraulic fluid.
In summary, hydraulic cylinders offer several benefits for tasks that involve heavy lifting or movement. They provide high force generation, precise control, safety features, versatility, smooth operation, compact design, durability, and energy efficiency. These advantages make hydraulic cylinders indispensable components in various industries where heavy loads need to be lifted, pushed, or moved with accuracy and reliability.
editor by CX 2023-11-18