Product Description
TPED/CE/EN/ISO/DOT/BV/SGS 2L/5L/7L/8L/10L/14L/20L small portable seamless steel gas cylinders filled with oxygen gas,co2 gas, argon gas,helium gas,mixture gas.etc.
Type | (mm) Outside Diameter |
(L) Water Capacity |
(mm) () Height (Withoutvalve) |
(Kg) (,) Weight(Without valve,cap) |
(Mpa) Working Pressure |
(mm) Design Wall Thickness |
Material Grades |
ISO102-1.8-150 | 102 | 1.8 | 325 | 3.5 | 150 | 3 | 37Mn |
ISO102-3-150 | 3 | 498 | 5.2 | ||||
ISO102-3.4-150 | 3.4 | 555 | 5.7 | ||||
ISO102-4.4-150 | 4.4 | 700 | 7.2 | ||||
ISO108-1.4-150 | 108 | 1.4 | 240 | 2.9 | 150 | 3.2 | 37Mn |
ISO108-1.8-150 | 1.8 | 285 | 3.3 | ||||
ISO108-2-150 | 2 | 310 | 3.6 | ||||
ISO108-3-150 | 3 | 437 | 4.9 | ||||
ISO108-3.6-150 | 3.6 | 515 | 5.7 | ||||
ISO108-4-150 | 4 | 565 | 6.2 | ||||
ISO108-5-150 | 5 | 692 | 7.5 | ||||
ISO140-3.4-150 | 140 | 3.4 | 321 | 5.8 | 150 | 4.1 | 37Mn |
ISO140-4-150 | 4 | 365 | 6.4 | ||||
ISO140-5-150 | 5 | 440 | 7.6 | ||||
ISO140-6-150 | 6 | 515 | 8.8 | ||||
ISO140-6.3-150 | 6.3 | 545 | 9.2 | ||||
ISO140-6.7-150 | 6.7 | 567 | 9.5 | ||||
ISO140-7-150 | 7 | 595 | 9.9 | ||||
ISO140-7.5-150 | 7.5 | 632 | 10.5 | ||||
ISO140-8-150 | 8 | 665 | 11 | ||||
ISO140-9-150 | 9 | 745 | 12.2 | ||||
ISO140-10-150 | 10 | 830 | 13.5 | ||||
ISO140-11-150 | 11 | 885 | 14.3 | ||||
ISO140-13.4-150 | 13.4 | 1070 | 17.1 | ||||
ISO140-14-150 | 14 | 1115 | 17.7 | ||||
ISO159-7-150 | 159 | 7 | 495 | 9.8 | 150 | 4.7 | 37Mn |
ISO159-8-150 | 8 | 554 | 10.8 | ||||
ISO159-9-150 | 9 | 610 | 11.7 | ||||
ISO159-10-150 | 10 | 665 | 12.7 | ||||
ISO159-11-150 | 11 | 722 | 13.7 | ||||
ISO159-12-150 | 12 | 790 | 14.8 | ||||
ISO159-12.5-150 | 12.5 | 802 | 15 | ||||
ISO159-13-150 | 13 | 833 | 15.6 | ||||
ISO159-13.4-150 | 13.4 | 855 | 16 | ||||
ISO159-13.7-150 | 13.7 | 878 | 16.3 | ||||
ISO159-14-150 | 14 | 890 | 16.5 | ||||
ISO159-15-150 | 15 | 945 | 17.5 | ||||
ISO159-16-150 | 16 | 1000 | 18.4 | ||||
ISO180-8-150 | 180 | 8 | 480 | 13.8 | 150 | 5.3 | 37Mn |
ISO180-10-150 | 10 | 570 | 16.1 | ||||
ISO180-12-150 | 12 | 660 | 18.3 | ||||
ISO180-15-150 | 15 | 790 | 21.6 | ||||
ISO180-20-150 | 20 | 1015 | 27.2 | ||||
ISO180-21-150 | 21 | 1061 | 28.3 | ||||
ISO180-21.6-150 | 21.6 | 1087 | 29 | ||||
ISO180-22.3-150 | 22.3 | 1100 | 29.4 | ||||
ISO219-20-150 | 219 | 20 | 705 | 27.8 | 150 | 6.1 | 37Mn |
ISO219-25-150 | 25 | 855 | 32.8 | ||||
ISO219-27-150 | 27 | 915 | 34.8 | ||||
ISO219-36-150 | 36 | 1185 | 43.9 | ||||
ISO219-38-150 | 38 | 1245 | 45.9 | ||||
ISO219-40-150 | 40 | 1305 | 47.8 | ||||
ISO219-45-150 | 45 | 1455 | 52.9 | ||||
ISO219-46.7-150 | 46.7 | 1505 | 54.6 | ||||
ISO219-50-150 | 50 | 1605 | 57.9 |
RECORD OF HYDROSTATIC TESTS ON CYLINDERS Time≥ 60S | ||||||||
S.N | Serial No. | The weight without valve&cap(kg) | Volumetric Capacity(L) | Total expansion(ml) | Permanent expansion(ml) | Percent of Permanent to totalexpanison(%) | Test Pressure 250Bar | Lot and Batch No. |
1 | 20S049001 | 13.7 | 10.3 | 76.8 | 1 | 1.3 | 25 | S05 |
2 | 20S049002 | 13.7 | 10.2 | 78.9 | 1.1 | 1.4 | 25 | S05 |
3 | 20S049003 | 14.1 | 10.2 | 76.0 | 0.6 | 0.8 | 25 | S05 |
4 | 20S049004 | 14.1 | 10.2 | 78.0 | 0.9 | 1.2 | 25 | S05 |
5 | 20S049005 | 14 | 10.2 | 77.0 | 0.7 | 0.9 | 25 | S05 |
6 | 20S049006 | 14.3 | 10.2 | 77.0 | 0.6 | 0.8 | 25 | S05 |
7 | 20S049007 | 13.8 | 10.3 | 77.8 | 1 | 1.3 | 25 | S05 |
8 | 20S049008 | 14 | 10.2 | 76.0 | 0.6 | 0.8 | 25 | S05 |
9 | 20S049009 | 14.1 | 10.2 | 78.0 | 0.7 | 0.9 | 25 | S05 |
10 | 20S049571 | 13.9 | 10.2 | 76.0 | 0.8 | 1.1 | 25 | S05 |
11 | 20S049011 | 14.1 | 10.2 | 79.9 | 0.7 | 0.9 | 25 | S05 |
12 | 20S049012 | 13.9 | 10.1 | 78.1 | 0.8 | 1.0 | 25 | S05 |
13 | 20S049013 | 14 | 10.2 | 78.0 | 0.8 | 1.0 | 25 | S05 |
14 | 20S049014 | 13.9 | 10.1 | 79.1 | 0.7 | 0.9 | 25 | S05 |
15 | 20S049015 | 14 | 10.2 | 77.0 | 0.9 | 1.2 | 25 | S05 |
16 | 20S049016 | 13.9 | 10.2 | 77.0 | 0.8 | 1.0 | 25 | S05 |
17 | 20S049017 | 14 | 10.2 | 78.9 | 0.7 | 0.9 | 25 | S05 |
18 | 20S049018 | 14.1 | 10.2 | 76.0 | 0.6 | 0.8 | 25 | S05 |
19 | 20S049019 | 13.8 | 10.2 | 78.0 | 0.9 | 1.2 | 25 | S05 |
20 | 20S049571 | 14 | 10.2 | 76.0 | 0.7 | 0.9 | 25 | S05 |
21 | 20S049571 | 14 | 10.2 | 79.9 | 0.9 | 1.1 | 25 | S05 |
22 | 20S049571 | 14 | 10.2 | 78.0 | 0.9 | 1.2 | 25 | S05 |
23 | 20S049571 | 13.9 | 10.3 | 78.8 | 0.7 | 0.9 | 25 | S05 |
24 | 20S049571 | 14 | 10.2 | 79.9 | 0.8 | 1.0 | 25 | S05 |
25 | 20S049571 | 14.1 | 10.2 | 79.9 | 0.9 | 1.1 | 25 | S05 |
26 | 20S049026 | 14.1 | 10.2 | 78.0 | 0.8 | 1.0 | 25 | S05 |
27 | 20S049571 | 14 | 10.2 | 77.0 | 0.9 | 1.2 | 25 | S05 |
28 | 20S049571 | 14 | 10.2 | 78.9 | 1 | 1.3 | 25 | S05 |
29 | 20S049571 | 14 | 10.3 | 75.8 | 0.8 | 1.1 | 25 | S05 |
30 | 20S049030 | 13.9 | 10.2 | 78.9 | 0.8 | 1.0 | 25 | S05 |
31 | 20S049031 | 13.9 | 10.1 | 79.1 | 1 | 1.3 | 25 | S05 |
32 | 20S049032 | 14 | 10.3 | 76.8 | 0.9 | 1.2 | 25 | S05 |
33 | 20S049033 | 14 | 10.2 | 76.0 | 0.7 | 0.9 | 25 | S05 |
34 | 20S049034 | 14 | 10.2 | 78.9 | 0.9 | 1.1 | 25 | S05 |
35 | 20S049035 | 13.9 | 10.2 | 79.9 | 1 | 1.3 | 25 | S05 |
36 | 20S049036 | 14 | 10.3 | 76.8 | 1.1 | 1.4 | 25 | S05 |
37 | 20S049037 | 13.8 | 10.2 | 78.9 | 0.6 | 0.8 | 25 | S05 |
38 | 20S049038 | 13.9 | 10.2 | 77.0 | 0.8 | 1.0 | 25 | S05 |
39 | 20S049039 | 13.8 | 10.2 | 78.0 | 0.8 | 1.0 | 25 | S05 |
40 | 20S049040 | 13.9 | 10.2 | 78.9 | 1 | 1.3 | 25 | S05 |
41 | 20S049041 | 14 | 10.2 | 78.0 | 0.7 | 0.9 | 25 | S05 |
42 | 20S049042 | 14.2 | 10.1 | 81.1 | 1.1 | 1.4 | 25 | S05 |
43 | 20S049043 | 14.1 | 10.2 | 78.9 | 0.9 | 1.1 | 25 | S05 |
44 | 20S049044 | 13.9 | 10.1 | 81.1 | 0.8 | 1.0 | 25 | S05 |
45 | 20S049045 | 13.9 | 10.2 | 78.9 | 0.9 | 1.1 | 25 | S05 |
46 | 20S049046 | 14.1 | 10.2 | 78.9 | 1 | 1.3 | 25 | S05 |
47 | 20S049047 | 13.9 | 10.2 | 79.9 | 0.9 | 1.1 | 25 | S05 |
48 | 20S049048 | 13.9 | 10.1 | 81.1 | 0.9 | 1.1 | 25 | S05 |
49 | 20S049049 | 13.6 | 10.4 | 75.7 | 1 | 1.3 | 25 | S05 |
50 | 20S049050 | 13.9 | 10.1 | 77.1 | 0.8 | 1.0 | 25 | S05 |
Material: | Steel |
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Usage: | Oxygen Gas and Nitrogen Cylinder |
Structure: | Gas – Liquid Damping Cylinder |
Power: | Hydraulic |
Standard: | Standard |
Pressure Direction: | Single-acting Cylinder |
Customization: |
Available
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What advancements in hydraulic cylinder technology have improved energy efficiency?
Advancements in hydraulic cylinder technology have led to significant improvements in energy efficiency, allowing hydraulic systems to operate more efficiently and reduce energy consumption. These advancements aim to minimize energy losses, optimize system performance, and enhance overall efficiency. Here’s a detailed explanation of some key advancements in hydraulic cylinder technology that have improved energy efficiency:
1. Efficient Hydraulic Circuit Design:
– The design of hydraulic circuits has evolved to improve energy efficiency. Advancements in circuit design techniques, such as load-sensing, pressure-compensated systems, or variable displacement pumps, help match the hydraulic power output to the actual load requirements. These designs reduce unnecessary energy consumption by adjusting the flow and pressure levels according to the system demands, rather than operating at a fixed high pressure.
2. High-Efficiency Hydraulic Fluids:
– The development of high-efficiency hydraulic fluids, such as low-viscosity or synthetic fluids, has contributed to improved energy efficiency. These fluids offer lower internal friction and reduced resistance to flow, resulting in decreased energy losses within the system. Additionally, advanced fluid additives and formulations enhance lubrication properties, reducing friction and optimizing the overall efficiency of hydraulic cylinders.
3. Advanced Sealing Technologies:
– Seal technology has advanced significantly, leading to improved energy efficiency in hydraulic cylinders. High-performance seals, such as low-friction or low-leakage seals, minimize internal leakage and friction losses. Reduced internal leakage helps maintain system pressure more effectively, resulting in less energy waste. Additionally, innovative sealing materials and designs enhance durability and extend seal life, reducing the need for frequent maintenance and replacement.
4. Electro-Hydraulic Control Systems:
– The integration of advanced electro-hydraulic control systems has greatly contributed to energy efficiency improvements. By combining electronic control with hydraulic power, these systems enable precise control over cylinder operation, optimizing energy usage. Proportional or servo valves, along with position or force feedback sensors, allow for accurate and responsive control, ensuring that hydraulic cylinders operate at the required level of performance while minimizing energy waste.
5. Energy Recovery Systems:
– Energy recovery systems, such as hydraulic accumulators, have been increasingly utilized to improve energy efficiency in hydraulic cylinder applications. Accumulators store excess energy during low-demand periods and release it when there is a peak demand, reducing the need for the hydraulic pump to provide the full power continuously. By utilizing stored energy, these systems can significantly reduce energy consumption and improve overall system efficiency.
6. Smart Monitoring and Control:
– Advancements in smart monitoring and control technologies have enabled real-time monitoring of hydraulic systems, allowing for optimized energy usage. Integrated sensors, data analytics, and control algorithms provide insights into system performance and energy consumption, enabling operators to make informed decisions and adjustments. By identifying inefficiencies or suboptimal operating conditions, energy consumption can be minimized, leading to improved energy efficiency.
7. System Integration and Optimization:
– The integration and optimization of hydraulic systems as a whole have played a significant role in improving energy efficiency. By considering the entire system layout, component sizing, and interaction between different elements, engineers can design hydraulic systems that operate in the most energy-efficient manner. Proper sizing of components, minimizing pressure drops, and reducing unnecessary piping or valve restrictions all contribute to improved energy efficiency of hydraulic cylinders.
8. Research and Development:
– Ongoing research and development efforts in the field of hydraulic cylinder technology continue to drive energy efficiency advancements. Innovations in materials, component design, system modeling, and simulation techniques help identify areas for improvement and optimize energy usage. Additionally, collaboration between industry stakeholders, research institutions, and regulatory bodies fosters the development of energy-efficient hydraulic cylinder technologies.
In summary, advancements in hydraulic cylinder technology have resulted in notable improvements in energy efficiency. Efficient hydraulic circuit designs, high-efficiency hydraulic fluids, advanced sealing technologies, electro-hydraulic control systems, energy recovery systems, smart monitoring and control, system integration and optimization, as well as ongoing research and development efforts, all contribute to reducing energy consumption and enhancing the overall energy efficiency of hydraulic cylinders. These advancements not only benefit the environment but also offer cost savings and improved performance in various hydraulic applications.
Handling the Challenges of Minimizing Fluid Leaks and Contamination in Hydraulic Cylinders
Hydraulic cylinders face challenges when it comes to minimizing fluid leaks and contamination, as these issues can impact the performance, reliability, and lifespan of the system. However, there are several measures and design considerations that help address these challenges effectively. Let’s explore how hydraulic cylinders handle the challenges of minimizing fluid leaks and contamination:
- Sealing Systems: Hydraulic cylinders employ advanced sealing systems to prevent fluid leaks. These systems typically include various types of seals, such as piston seals, rod seals, and wiper seals. The seals are designed to create a tight and reliable barrier between the moving components of the cylinder and the external environment, minimizing the risk of fluid leakage.
- Seal Material Selection: The choice of seal materials is crucial in minimizing fluid leaks and contamination. Hydraulic cylinder manufacturers carefully select seal materials that are compatible with the hydraulic fluid used and resistant to wear, abrasion, and chemical degradation. This ensures the longevity and effectiveness of the seals, reducing the likelihood of leaks or premature seal failure.
- Proper Installation and Maintenance: Ensuring proper installation and regular maintenance of hydraulic cylinders is essential for minimizing fluid leaks and contamination. During installation, attention should be given to proper alignment, torqueing of bolts, and adherence to recommended procedures. Regular maintenance includes inspecting seals, replacing worn-out components, and addressing any signs of leakage promptly. Proper maintenance practices help identify and rectify issues before they escalate and cause significant problems.
- Contamination Control: Hydraulic cylinders incorporate measures to control contamination and maintain fluid cleanliness. This includes the use of filtration systems, such as in-line filters, to remove particles and contaminants from the hydraulic fluid. Additionally, hydraulic reservoirs often have breathers and desiccant filters to prevent moisture and airborne contaminants from entering the system. By controlling contamination, hydraulic cylinders minimize the risk of damage to internal components and maintain optimal system performance.
- Environmental Protection: Hydraulic cylinders may be equipped with protective features to safeguard against external contaminants. For example, bellows or protective boots can be installed to shield the rod and seals from debris, dirt, or moisture present in the operating environment. These protective measures help extend the life of the seals and enhance the overall reliability of the hydraulic cylinder.
In summary, hydraulic cylinders employ sealing systems, appropriate seal materials, proper installation and maintenance practices, contamination control measures, and environmental protection features to handle the challenges of minimizing fluid leaks and contamination. By implementing these measures, manufacturers can ensure reliable and long-lasting hydraulic cylinder performance, minimize the risk of fluid leakage, and maintain the cleanliness of the hydraulic system.
Can you explain the role and significance of hydraulic cylinders in machinery?
Hydraulic cylinders play a crucial role in machinery across various industries. They are essential components that provide controlled and powerful linear motion, enabling the operation of heavy equipment and facilitating numerous tasks. The role and significance of hydraulic cylinders in machinery can be explained in detail as follows:
Role of Hydraulic Cylinders:
– Conversion of Hydraulic Energy: Hydraulic cylinders convert hydraulic energy, typically in the form of pressurized hydraulic fluid, into linear force and motion. This conversion allows machinery to perform tasks such as lifting, pushing, pulling, clamping, tilting, and controlling various mechanisms.
– Generation of Linear Motion: Hydraulic cylinders generate linear motion by utilizing the principles of Pascal’s law. When hydraulic fluid is directed into one side of the cylinder, it applies pressure on the piston, resulting in linear movement of the piston and the attached piston rod. This linear motion can be used to actuate other components within the machinery or directly perform the required task.
– Force Generation: Hydraulic cylinders are capable of generating high forces due to the hydraulic pressure applied to the piston. The force output of a hydraulic cylinder depends on the surface area of the piston and the pressure of the hydraulic fluid. This force allows machinery to exert significant power for lifting heavy loads, applying pressure, or overcoming resistance.
– Precise Control: Hydraulic cylinders offer precise control over the linear motion and force exerted. By regulating the flow of hydraulic fluid, the speed and direction of the cylinder’s movement can be accurately adjusted. This level of control is crucial in machinery that requires precise positioning, delicate movements, or synchronization of multiple cylinders.
– Integration with Hydraulic Systems: Hydraulic cylinders are integral parts of hydraulic systems used in machinery. They work in conjunction with hydraulic pumps, valves, and actuators to create a complete hydraulic circuit. This integration allows for efficient power transmission, control, and coordination of various machine functions.
Significance of Hydraulic Cylinders:
– Heavy Equipment Operation: Hydraulic cylinders are vital in heavy machinery used in construction, mining, agriculture, material handling, and other industries. They enable the lifting and movement of heavy loads, the operation of attachments, and the performance of tasks that require high force and precision.
– Versatility and Adaptability: Hydraulic cylinders are versatile components that can be designed and tailored to meet specific machinery requirements. They can be integrated into various types of equipment and customized based on factors such as force capacity, stroke length, speed, and mounting options. This adaptability makes hydraulic cylinders suitable for diverse applications.
– Durability and Reliability: Hydraulic cylinders are built to withstand rigorous operating conditions, including high pressures, heavy loads, and continuous use. They are designed with robust materials, precise machining, and effective sealing systems to ensure durability and reliability over extended periods of operation.
– Safety and Load Control: Hydraulic cylinders provide safe and controlled operation in machinery. They offer overload protection mechanisms, such as relief valves, to prevent damage caused by excessive force or pressure. Additionally, hydraulic cylinders allow for precise load control, minimizing the risk of accidents during lifting, lowering, or positioning of heavy loads.
– 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.
– Energy Efficiency: Hydraulic cylinders contribute to energy efficiency in machinery. The use of hydraulic systems allows 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, reducing energy consumption.
Overall, hydraulic cylinders play a vital role in machinery by providing controlled and powerful linear motion. Their significance lies in their ability to convert hydraulic energy, generate high forces, offer precise control, integrate with hydraulic systems, and facilitate the operation of heavy equipment across various industries. Hydraulic cylinders contribute to increased productivity, safety, and efficiency in machinery applications, making them indispensable components in modern-day engineering.
editor by CX 2023-12-03