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: | Medium Pressure |
| Work Temperature: | High Temperature |
| Acting Way: | Double Acting |
| Working Method: | Rotary |
| Adjusted Form: | Switching Type |
| Samples: |
US$ 2500/Ton
1 Ton(Min.Order) | |
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| Customization: |
Available
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How do rotary cylinders contribute to precise rotational control?
Rotary cylinders play a crucial role in achieving precise rotational control in various applications. Here’s a detailed explanation:
1. Actuation Methods: Rotary cylinders utilize hydraulic or pneumatic actuation methods to generate rotational motion. These actuation methods offer precise control over the application of force, allowing for accurate and controlled rotation.
2. Control Valves: Control valves are used to regulate the fluid flow into and out of the rotary cylinder. By adjusting the valve settings, the rotational speed and direction can be precisely controlled, enabling precise rotational control.
3. Feedback Systems: Some rotary cylinders incorporate feedback systems, such as position sensors or encoders, to provide real-time information about the cylinder’s rotational position. This feedback enables precise control over the rotational movement, allowing for accurate positioning and synchronization with other system components.
4. Stroke Adjustment: Rotary cylinders often have adjustable stroke lengths, which allow for precise control over the range of rotational movement. By adjusting the stroke, the rotational angle can be precisely controlled, enabling precise rotational control for specific applications.
5. Positioning Guides: Rotary cylinders may feature positioning guides, such as grooves or slots, that help guide and stabilize the rotational movement. These guides ensure precise alignment and minimize deviations or wobbling during operation, contributing to precise rotational control.
6. Precision Manufacturing: Rotary cylinders are manufactured with high precision to ensure smooth and accurate rotation. The use of high-quality materials, precision machining, and tight tolerances contribute to precise rotational control, minimizing unwanted variations or errors.
7. Integration with Control Systems: Rotary cylinders can be seamlessly integrated with control systems, allowing for precise control over the rotational motion. They can be programmed and synchronized with other system components, such as sensors, actuators, and PLCs, to achieve precise rotational control in complex automation processes.
These factors combined contribute to the precise rotational control achieved through the utilization of rotary cylinders. It’s important to consult manufacturers’ documentation and guidelines for specific information on the capabilities and limitations of rotary cylinders in achieving precise rotational control.
How do rotary cylinders contribute to controlled and precise rotation?
Rotary cylinders play a significant role in achieving controlled and precise rotation in various applications. Here’s a detailed explanation:
1. Fluid-Powered Actuation: Rotary cylinders utilize hydraulic or pneumatic fluid to generate rotary motion. By controlling the flow of fluid into and out of the cylinder, the rotation can be precisely regulated. This fluid-powered actuation allows for smooth and controlled rotation with high accuracy.
2. Adjustable Pressure and Flow: The pressure and flow of the fluid supplied to the rotary cylinder can be adjusted to control the rotational speed and torque. By varying the pressure or flow rate, the cylinder’s rotational characteristics can be fine-tuned to achieve the desired level of control and precision.
3. Position Feedback Devices: To enhance control and precision, rotary cylinders can be equipped with position feedback devices such as rotary encoders or potentiometers. These devices provide real-time feedback on the cylinder’s rotational position, allowing for accurate positioning and control over the rotation.
4. Servo Control Systems: Rotary cylinders can be integrated into servo control systems, which offer advanced control capabilities. Servo systems use feedback signals to continuously monitor and adjust the cylinder’s position, speed, and torque. This closed-loop control mechanism enables precise rotation and ensures the desired positional accuracy is maintained.
5. Speed and Acceleration Control: Rotary cylinders provide control over the rotation speed and acceleration. By adjusting the fluid flow rate or pressure, the rotational velocity and acceleration can be precisely controlled. This feature is particularly beneficial in applications that require smooth and gradual acceleration or deceleration to prevent jerky movements or damage to the equipment.
6. Positioning Accuracy: Rotary cylinders offer excellent positioning accuracy, allowing for precise angular displacement. By combining precise control of fluid flow and feedback from position sensors, the cylinder can accurately reach and maintain specific rotational positions. This level of positioning accuracy is crucial in applications that require precise alignment or synchronization with other components or processes.
7. Repeatability: Rotary cylinders exhibit high repeatability, meaning they can repeatedly achieve the same rotational position with minimal variation. This characteristic is essential in tasks that require consistent and repeatable rotational movements, such as assembly, indexing, or machining processes.
8. Compatibility with Control Systems: Rotary cylinders can be seamlessly integrated into various control systems, such as programmable logic controllers (PLCs) or computer numerical control (CNC) systems. This compatibility enables precise coordination and synchronization of rotary motion with other machine operations, ensuring controlled and precise rotation within the overall system.
9. Compact and Lightweight Design: Rotary cylinders are often designed to be compact and lightweight, reducing rotational inertia and enabling faster response times. This design characteristic contributes to the overall control and precision of the rotation.
10. Customization and Optimization: Manufacturers offer a wide range of rotary cylinder models with different performance characteristics. This allows users to select the most suitable cylinder based on their specific control and precision requirements. Customization options further enhance the ability to tailor the cylinder’s performance to meet specific application needs.
By incorporating these features and technologies, rotary cylinders contribute to controlled and precise rotation in a wide range of industrial and automation applications.
Can rotary cylinders be used for both rotary motion and linear motion?
No, rotary cylinders are specifically designed for generating rotary motion and are not typically used for linear motion. Here’s a detailed explanation:
Rotary Motion:
Rotary cylinders, also known as rotary actuators, are primarily used to convert fluid power into rotational motion. They are designed to generate torque and rotate around a central axis. The rotational movement can be in a full 360-degree rotation or limited to a specific angle depending on the application and the design of the cylinder.
Linear Motion:
For linear motion, a different type of actuator, such as linear cylinders or linear actuators, is used. Linear cylinders are specifically designed to generate linear motion by extending or retracting a piston rod in a linear path. These actuators are commonly used in applications where straight-line movement is required, such as pushing, pulling, lifting, or sliding objects.
Differences:
The design and internal mechanism of rotary cylinders are optimized for rotational motion, while linear cylinders are designed to provide linear motion. These two types of actuators have different structures and operating principles to fulfill their respective purposes.
While rotary cylinders cannot directly produce linear motion, they can be part of a system that combines both rotary and linear motion. For example, in some applications, a rotary cylinder can be used to generate rotational motion, which is then converted into linear motion using additional mechanisms such as racks, gears, or linkages.
It’s important to choose the appropriate type of actuator based on the desired motion requirements of the specific application. Manufacturers’ documentation and guidelines should be consulted to determine the most suitable actuator for a particular motion requirement.
editor by CX 2024-01-01