Product Description
Our company produces all series of hydraulic cylinders, including engineering cylinders, tie rod cylinders, earring cylinders, multi-section cylinders, flange cylinders, high pressure cylinders, heavy-duty cylinders, HSG series hydraulic cylinders, single-acting cylinders, two-way cylinders, and other non-standard customized hydraulic product. After years of practice, our company has accumulated rich experience in processing and installation. The parts are precision CNC machined by all series of horizontal lathe, and the seals are made of CHINAMFG imported famous brand products. The products are continuously improved and improved, and the quality and accuracy are reliable and stable. Our cylinder products have been exported to the Middle East. , Asia, Europe and the United States and other places, we have more than 10 years of cooperation with oil cylinder customers.
In order to achieve maximum quality control, 80% of our parts are produced by ourselves, among which we can process super-large hydraulic cylinder body parts and telescopic shaft parts with our large horizontal lathes, we can even turn hydraulic cylinders with a length of more than 11 meters, and The surface finish of the shaft cylinder can reach Ra1.6 directly through the lathe.
Our main products :
tie rod cylinder, welding cylinder, double-acting cylinder, single-acting cylinder, piston cylinder, plunger cylinder, single-rod cylinder, double-rod cylinder, etc.;
Technical parameters: The cylinder diameter is 32~320mm, the stroke is 5~6000mm, and the working pressure is 2.5~31Mpa;
The installation methods include flange, single ear, double ear, foot seat, hinge shaft, welded pipe, etc., and provide rod end connectors, including Y-type joint, I-type joint, joint bearing, welded pipe, etc.;
Workshop overview:
Our sheet metal fabrication workshop equipped with a series of cutting machines, including laser cutter, flame cutter, water jet cutter, and plasma cutter, with these advanced CNC machine we can cut the materials with high efficiency and high accuracy.
| Laser Cutting | Plasma Cutting | Flame Cutting | Water-jet Cutting | |
| Cutting Depth | 25mm | 100mm | 450mm | 250mm |
| Cutting Width | 3500mm | 4000mm | 6000mm | 3500mm |
| Cutting Length | 28000mm | 20000mm | 20000mm | 10000mm |
| Accuracy | ±0.2mm | ±1mm | ±0.8mm |
We have a series of imported CNC Machining equipment, including large gantry machining center, horizontal boring and milling machine, turning and milling compound center, large vertical lathe machining center, heavy horizontal lathe machining center, dmulti-hole drilling and other machining equipment facilities.
Our processing capabilities are as follows:
| Gantry Machining Center | Max Height:4000mm | Max Width:4500mm | Max Length: 12000mm | ||
| Large Boring Mill | X: 15000mm | Y:4000mm | Z+W:900+1000 mm | Max Weight: 250T | Bore Tool Dia: 280mm |
| Truning and Milling center | Height: 4500mm | Weight: 350T | Max Diameter:11000mm | ||
| Vertical Lathe | Height: 4000mm | Weight: 50T | Max Diameter: 5000mm | ||
| Horizontal Lathe | Max Length: 12m | Weight: 50T | |||
| Deep hole drilling | X:3000mm | Y:2500mm | Z:700mm | Hole Dia: 16-80mm | Depth: 700mm |
| Multi-hole drilling | X:7000mm | Y:3000mm | Z:700mm | Hole Dia:2-120mm | Depth: 320mm |
We have a complete welding platform, including plasma welding, strip surfacing, argon arc welding, TIG welding, laser welding, hand arc welding, and submerged arc welding equipment clusters. Welding methods include tube-sheet strip surfacing, automatic submerged arc welding, carbon dioxide gas shielded welding, argon tungsten arc welding, electrode arc welding, plasma welding, etc. The materials that can be welded are carbon steel, alloy steel, stainless steel, and non-ferrous metals such as copper, aluminum, and titanium.
To ensure that the quality strictly meets the requirements, we have special quality inspectors to supervise and review the product quality for all projects, and we are equipped with a variety of inspection methods. For welding, we have magnetic particle inspection, X-ray inspection and other methods to inspect the weld quality. For precision machined products, we use advanced three-coordinate testing equipment to check product size, flatness, parallelism, concentricity, etc. For precision machined surfaces, we will also use special testing equipment to check that the surface roughness perfectly meets the acceptance criteria. Moreover, we will custom make inspection methods to serve for their project.
Inspection Facilites:
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| Certification: | ISO9001 |
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| Pressure: | Low Pressure |
| Work Temperature: | High Temperature |
| Acting Way: | Single Acting |
| Working Method: | Rotary |
| Adjusted Form: | Regulated Type |
| Samples: |
US$ 2500/Ton
1 Ton(Min.Order) | |
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| Customization: |
Available
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How do rotary cylinders manage variations in hydraulic pressure and flow rate?
Rotary cylinders are designed to effectively manage variations in hydraulic pressure and flow rate. Here’s a detailed explanation:
1. Pressure Regulation: Rotary cylinders incorporate various mechanisms to manage variations in hydraulic pressure. These mechanisms include pressure relief valves, pressure control valves, and flow control valves. Pressure relief valves are designed to protect the cylinder and the hydraulic system from excessive pressure by diverting excess fluid flow back to the reservoir. Pressure control valves, such as pressure reducing valves or pressure sequence valves, are used to regulate the pressure applied to the rotary cylinder. These valves ensure that the cylinder operates within the desired pressure range, accommodating variations in the hydraulic system.
2. Flow Control: Rotary cylinders also utilize flow control mechanisms to manage variations in hydraulic flow rate. Flow control valves, such as flow restrictors or flow control regulators, are employed to control the amount of fluid flowing into or out of the cylinder. By adjusting the opening of these valves, the flow rate can be regulated, allowing for precise control of the cylinder’s rotational speed or angular displacement. Flow control valves help manage variations in flow rate and optimize the cylinder’s performance.
3. Proportional Control: Proportional control valves are often used in conjunction with rotary cylinders to manage variations in pressure and flow rate. These valves provide continuous and precise control over the hydraulic pressure and flow by adjusting the valve opening proportionally to the input signal. Proportional control allows for real-time adjustments in response to changing operational requirements, ensuring accurate and efficient management of pressure and flow variations.
4. Feedback Devices: Rotary cylinders can incorporate feedback devices, such as pressure sensors and flow sensors, to monitor and provide feedback on the hydraulic pressure and flow rate. These sensors provide real-time information about the operating conditions, allowing for dynamic adjustments to maintain desired pressure and flow levels. Feedback devices help ensure the stability and consistency of the cylinder’s performance, even in the presence of variations in hydraulic pressure and flow rate.
5. Accumulators: In some cases, rotary cylinders can utilize hydraulic accumulators to manage variations in pressure and flow rate. Accumulators store hydraulic energy in the form of pressurized fluid, which can be released when needed to compensate for fluctuations in pressure or flow. By providing an additional source of energy, accumulators help maintain consistent pressure and flow, preventing adverse effects caused by sudden changes in hydraulic conditions.
6. System Design and Optimization: Proper system design and optimization play a crucial role in managing variations in hydraulic pressure and flow rate. This includes selecting appropriate components, sizing the hydraulic lines, and ensuring proper fluid filtration and conditioning. By designing the hydraulic system to match the requirements of the rotary cylinder and the application, variations in pressure and flow rate can be effectively managed, resulting in optimal performance.
By employing these strategies and mechanisms, rotary cylinders can effectively manage variations in hydraulic pressure and flow rate, ensuring reliable and consistent performance in a wide range of applications.
Can rotary cylinders be repaired or maintained when needed?
Yes, rotary cylinders can be repaired and maintained when needed to ensure their optimal performance and longevity. Here’s a detailed explanation:
1. Routine Maintenance: Regular maintenance is essential to keep rotary cylinders in good working condition. This includes tasks such as cleaning, lubrication, and inspection of components. Routine maintenance helps prevent issues and prolongs the cylinder’s lifespan.
2. Seal Replacement: Seals are critical components of rotary cylinders and may require periodic replacement due to wear or damage. Replacing seals at recommended intervals helps maintain proper sealing and prevent fluid leaks.
3. Component Replacement: In case of component failure or damage, individual components of the rotary cylinder can be replaced. This may include piston rods, seals, bearings, or other internal parts. Replacement parts should be sourced from reputable manufacturers or suppliers to ensure compatibility and quality.
4. Fluid Flush and Filter Replacement: Over time, hydraulic or pneumatic fluid used in rotary cylinders may become contaminated with particles or degrade in quality. Performing fluid flushes and replacing filters at recommended intervals helps maintain the cleanliness and performance of the fluid and extends the life of the rotary cylinder.
5. Repairs: In the event of major damage or malfunction, rotary cylinders can be repaired. Skilled technicians or authorized service centers can diagnose the issue, disassemble the cylinder, and perform repairs such as welding, re-machining, or replacing damaged parts. It is important to follow proper repair procedures and use appropriate techniques to ensure the cylinder’s integrity and performance.
6. Reconditioning: Rotary cylinders that have undergone extensive use or have been in operation for a long time may benefit from reconditioning. Reconditioning involves thorough inspection, cleaning, and refurbishment of the cylinder to restore its performance and functionality. This process may include repairs, replacement of worn components, and performance testing.
7. Documentation and Guidelines: Manufacturers provide documentation, guidelines, and technical specifications for their rotary cylinders. These resources often include information on maintenance procedures, recommended service intervals, and troubleshooting guidance. Following the manufacturer’s recommendations ensures that maintenance and repairs are carried out correctly.
It is important to note that the extent of repair and maintenance that can be performed on a rotary cylinder may vary depending on factors such as its design, complexity, and availability of spare parts. It is recommended to consult the manufacturer’s documentation or seek assistance from qualified professionals for specific repair and maintenance needs.
How does a rotary cylinder differ from other types of hydraulic cylinders?
A rotary cylinder differs from other types of hydraulic cylinders in several ways. Here’s a detailed explanation:
Principle of Operation:
A rotary cylinder is designed to convert fluid power into rotational motion, while other types of hydraulic cylinders primarily provide linear motion. While standard hydraulic cylinders extend and retract in a straight line, a rotary cylinder generates rotary or swinging motion.
Mechanism:
Rotary cylinders utilize different mechanisms to produce rotary motion. They may employ rack-and-pinion mechanisms, vane mechanisms, or gear mechanisms, depending on the specific design. In contrast, other types of hydraulic cylinders typically use a piston and cylinder arrangement to generate linear motion.
Direction of Motion:
Rotary cylinders produce rotational motion around a fixed axis or pivot point. The direction of rotation can be clockwise or counterclockwise, depending on the design and configuration of the cylinder. In contrast, other hydraulic cylinders provide linear motion in a straight line, either extending or retracting along the axis of the cylinder.
Applications:
Rotary cylinders are commonly used in applications where rotational movement is required, such as rotary indexing tables, robotic arms, and conveyor systems. They are suitable for tasks that involve swinging, rotating, or indexing motions. On the other hand, other types of hydraulic cylinders are used in applications that primarily require linear motion, such as lifting, pushing, or pulling.
Advantages and Disadvantages:
Rotary cylinders offer certain advantages over other types of hydraulic cylinders. They provide compact and efficient means of generating rotary motion, allowing for versatile applications. Rotary cylinders can deliver high torque output and precise control over rotational motion. However, one potential disadvantage is that they may have a more complex design and require additional components compared to standard hydraulic cylinders.
Fluid Medium:
Rotary cylinders can be powered by either hydraulic fluid or compressed air, depending on the specific design and application. Other types of hydraulic cylinders also utilize hydraulic fluid as the power medium. The choice of fluid medium depends on factors such as the desired force and speed, environmental considerations, and system requirements.
It’s important to consult the manufacturer’s documentation and guidelines for specific information on the selection, installation, and operation of rotary cylinders and other types of hydraulic cylinders for different applications.
editor by CX 2024-01-09