Product Description
Types of gas springs
1. Support gas spring
Also called free-type gas spring. Support rod. It is the most widely used gas spring. It mainly plays a supporting role, with only the shortest and longest positions, and cannot stop by itself during the stroke. It is most widely used in mechanical equipment, furniture and other fields.
2. Lockable(Controllable) gas spring
The controllable gas spring can be locked at any position of the entire stroke, mainly through the controller (handle or cable) to achieve the effect, but also through the expansion and contraction of the piston rod. When the controller is adjusted to stop at the desired position, the valve will be closed and the live cooling rod will be locked in the required position. When locking occurs, locking can be achieved. However, if the locking force is exceeded, the locking function will no longer be effective.
3. Damper
Damper features reduce inertia and reduce speed by changing size. Its resistance changes with the speed of operation. The speed of the connected mechanism can be significantly damped.
4. Tensile gas spring
Also known as a traction gas spring, it uses an internal piston rod to achieve basic positioning. It is a special gas spring. The supporting gas spring is in the longest position when it is in a free state. After receiving external force, it moves from the longest position to the shortest position, while the free state of the traction gas spring is at The shortest position, running from the shortest to the longest when being pulled. Traction gas springs also have corresponding free type, self-locking type and so on.
YQ series air bombs are widely used in automobile, household, computer, fitness equipment, textile, printing, food, tobacco, woodworking and other machinery, and can play the role of lifting, suspending, closing and so on.
The product structure is reasonable, and the installation and maintenance are convenient. No external power is needed when working, saving energy. The lifting force is basically constant throughout the working stroke, and the end of the stroke has a buffer mechanism to avoid damage to components. The lifting member can be stopped in any position.
| MODEL | d(mm) | D(mm) | L(mm) | S(mm) | Force(kgf) |
| YQ13 | Φ6 | Φ15 | 100-550 | 50-200 | 5-35 |
| YQ16 | Φ8 | Φ18 | 210-580 | 50-220 | 15-50 |
| YQ20A | Φ10 | Φ22 | 300-700 | 100-300 | 30-80 |
| YQ20B | Φ12 | Φ22 | 400-700 | 100-300 | 40-100 |
| YQ25A | Φ12 | Φ27 | 600-800 | 220-350 | 60-130 |
| YQ25B | Φ14 | Φ28 | 600-900 | 220-350 | 100-300 |
| YQ25C | Φ16 | Φ28 | 600-1200 | 220-900 | 100-300 |
sample.the length, stroke,pressure can be customized
Gas spring installation location selection
There are 2 optional installation styles:
1. AO is less than the length of OB
2. OB is less than the length of AO
• Calculate the approximate stroke of the gas spring used when setting points A and B first:
The AB length after opening the lid minus the AB length after closing is equal to the required air bomb stroke;
Re-calculate whether the selected gas bomb praise is reasonable:
Gas spring stroke x2+80mm=AB length after opening.
Note: If the result obtained is greater than the length of AB, then it is necessary to move point A to point 0 or point B to move to point O to increase the length of point AB, that is, increase the length of the gas spring.
YK series gas springs are suitable for various occasions where the angle and height need t be adjusted. The piston rod can be stopped at any position under human manipulation. YK series gas springs operate flexibly, work stably and reliably. Can be designed and manufactured according to user requirements. For matters needing attention, please refer to the YQ series gas spring.
| MODEL | D(mm) | d1(mm) | L(mm) | S(mm) | Thread diameter | Force(kgf) |
| Lockable YK | Φ22 | Φ10 | 225 | 60 | M10*1 | 300-700 |
| 210 | 50 | |||||
| 200 | 40 | |||||
| 130 | 30 | |||||
| Φ28 | 760 | 280 | 300-900 | |||
| 175 | 50 | |||||
| 170 | 42 | |||||
| 155 | 40 | |||||
| 128 | 28 |
This product is divided into pure oil, pure gas, oil and gas mixing, oil and gas separation and other construction machinery shock absorbers. This product is widely used in the shock absorption of engineering vehicle seats, which can effectively eliminate the vibration caused by the mechanical spring under the action of gravity. The aftershocks make the driver and passengers feel smooth and comfortable.
The oil-gas hybrid shock absorber has a good gas buffering effect and is the first choice shock absorber for modern engineering vehicle seats.
1. Samples can be offered to test before placing orders.
2. Low MOQ. Small orders are accepted.
3. OEM & ODM. Customization service is offered, including logo, laser marking.
4. Outstanding R&D ability,including product development and mould development.
5. Great pre-sales and after sales service.
HangZhou Manjia Youchuang Household Products Co., Ltd. is a professional dampers and gas springs manufacturer which collects research, design, production and sale.
Our technical backbone has been engaged in the R&D and production of dampers for more than 22 years experience. The professional and well trained production department and QC staff could assure the perfect performance of our Dampers products. For the quality assurance rate of over 99.98%, and the stability of delivery time rate more than 99.96%.
Q1. Can I have a sample for testing?
A: Yes, samples are in stock, we will return sample fee back to you once you make a bulk order from us.
Q2. What about the lead time?
A: Sample needs 1-3 days, mass production time needs around 15 days for order quantity more than 10,000 pieces.
Q3. What is your MOQ?
A: Under normal circumstances, the order quantity is 1000 pieces. If you need less than 1,000 pieces, please contact customer service.
Q4. How do you ship the goods and how long does it take to arrive?
A: We usually ship by DHL, UPS, FedEx or TNT. It usually takes 3-5 days to arrive. Shipping time depend on the shipping way you choose.
Q5. Can I print my logo on the product?
A: Yes. Please inform us formally before our production and confirm the design firstly based on our sample. Customized design is available. OEM and ODM are offered.
Q6. Do you offer guarantee for the products?
A: Yes, we offer 1 year warranty to our products.
Q7: How to deal with the faulty?
A: Our products are produced in strict quality control system and the defective rate will be less than 0.2%.During the guarantee period, we will send new dampers with new order for small quantity. For defective batch products, we will repair them and resend them to you or we can discuss the solution.
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| Function: | Pressed, Phonation, Buffer, Drive, Restoration, Measurement |
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| Material: | Alloy |
| Load Type: | Compression |
| Samples: |
US$ 15/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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How does a lift cylinder contribute to energy-efficient lifting?
A lift cylinder plays a significant role in promoting energy-efficient lifting operations. Here’s an explanation of how lift cylinders contribute to energy efficiency:
1. Hydraulic System Efficiency:
Lift cylinders are commonly used in hydraulic systems, which are known for their high efficiency. Hydraulic systems utilize pressurized fluid to transmit power, allowing for smooth and controlled lifting operations. The hydraulic fluid is circulated within the system, and the lift cylinder converts the pressure of the fluid into mechanical force to lift the load. Compared to other mechanical lifting mechanisms, hydraulic systems, including lift cylinders, experience minimal energy loss due to their efficient power transmission.
2. Power-to-Weight Ratio:
Lift cylinders are designed to have a high power-to-weight ratio. This means that they can generate a substantial lifting force relative to their weight. By utilizing lightweight yet durable materials and optimizing the design, lift cylinders can effectively lift heavy loads while minimizing the amount of energy required. The efficient power-to-weight ratio contributes to energy efficiency by reducing the overall power consumption during lifting operations.
3. Load-Specific Design:
Lift cylinders are often engineered to match the specific load requirements of lifting applications. By customizing the design parameters, such as bore size, stroke length, and operating pressure, lift cylinders can be optimized for the intended load capacities and lifting tasks. This load-specific design ensures that the lift cylinder operates at its optimal efficiency, minimizing energy waste and maximizing the lifting performance.
4. Regenerative Systems:
In certain lifting applications, lift cylinders can be integrated into regenerative systems. Regenerative systems capture and store energy that would otherwise be dissipated as heat during the lowering phase of the lifting operation. This stored energy can then be reused to assist in the subsequent lifting process, reducing the overall energy consumption. Regenerative systems enhance energy efficiency by utilizing the otherwise wasted energy to partially power the lifting operation.
5. Control Systems:
Advanced control systems can be implemented in conjunction with lift cylinders to optimize energy efficiency. These control systems, such as proportional valves or variable-speed drives, allow for precise control of the lifting process. By adjusting the flow rate or speed of the hydraulic fluid, operators can match the power output of the lift cylinder to the specific load requirements, minimizing energy waste and improving overall efficiency.
6. Maintenance and Optimization:
Regular maintenance and optimization of lift cylinders are essential for maintaining energy efficiency. Proper lubrication, seal replacements, and overall system inspections help ensure that the lift cylinder operates at its peak performance. By identifying and addressing any issues or inefficiencies, maintenance practices contribute to energy-efficient lifting operations.
In summary, lift cylinders contribute to energy-efficient lifting through hydraulic system efficiency, a high power-to-weight ratio, load-specific design, regenerative systems, control systems, and proper maintenance. By utilizing these features and practices, lift cylinders help minimize energy consumption and enhance overall lifting efficiency.
How does a lift cylinder handle variations in cylinder stroke length?
A lift cylinder is designed to handle variations in cylinder stroke length through its adjustable rod or piston. The stroke length refers to the distance the cylinder can extend or retract, and it can be adjusted to meet specific requirements in different applications.
In hydraulic lift cylinders, the stroke length can be modified by adjusting the position of the rod or piston within the cylinder. This adjustment is typically achieved by adding or removing spacers or by using adjustable stops. By changing the effective length of the cylinder, the stroke can be increased or decreased accordingly.
The adjustment of the stroke length allows the lift cylinder to accommodate different operational needs. For example, in material handling applications, where varying load sizes are encountered, the stroke length can be adjusted to ensure that the cylinder extends or retracts precisely to the required position. This flexibility enables the lift cylinder to handle a wide range of loads and adapt to different lifting or pushing scenarios.
In addition to adjusting the stroke length, lift cylinders often incorporate position feedback mechanisms. These mechanisms, such as linear transducers or position sensors, provide real-time feedback on the actual position of the cylinder. By monitoring the position, the control system can ensure accurate and precise control over the cylinder’s movement, regardless of the stroke length.
The ability to handle variations in cylinder stroke length is crucial in many industrial applications. It allows for adaptability, efficiency, and improved performance in tasks such as material handling, assembly, and automation. By adjusting the stroke length, lift cylinders can optimize their operation, ensuring that the required force and movement are achieved consistently.
In summary, lift cylinders handle variations in cylinder stroke length through adjustable rods or pistons. This adjustment capability, combined with position feedback mechanisms, enables precise control and adaptability in different applications. By accommodating different stroke lengths, lift cylinders can effectively meet the specific requirements of a wide range of industrial tasks.
What are the safety considerations when using lift cylinders?
When using lift cylinders, it is crucial to prioritize safety to prevent accidents and ensure the well-being of operators and bystanders. Here are some important safety considerations when using lift cylinders:
1. Proper Training:
Operators should receive proper training on the safe operation of lift cylinders. They should be familiar with the equipment’s capabilities, limitations, and recommended operating procedures. Training should include understanding hydraulic systems, load capacities, stability factors, and proper positioning techniques.
2. Inspection and Maintenance:
Routine inspection and maintenance of lift cylinders are essential for identifying any potential safety hazards. Regularly check for leaks, damaged components, loose connections, or signs of hydraulic fluid contamination. Ensure that all safety features, such as pressure relief valves and load holding devices, are functioning correctly.
3. Load Capacity and Stability:
It is crucial to know and adhere to the lift cylinder’s load capacity limits specified by the manufacturer. Overloading the cylinder can lead to equipment failure, instability, or uncontrolled movements. Properly distribute the load to maintain stability and prevent tipping or imbalance.
4. Secure Mounting:
Ensure that the lift cylinder is securely mounted to the equipment or structure. Follow the manufacturer’s guidelines for proper attachment methods and torque specifications. Loose or improper mounting can compromise the stability and safety of the lifting operation.
5. Control of Movement:
Exercise caution and maintain control over the movement of the lift cylinder. Avoid sudden or jerky motions that can destabilize the load or cause the equipment to tip. Use smooth and controlled movements, and be aware of any potential obstacles or hazards in the surrounding area.
6. Personal Protective Equipment (PPE):
Operators and personnel involved in the lifting operation should wear appropriate personal protective equipment, such as safety glasses, gloves, and steel-toed shoes. PPE helps protect against potential hazards, including hydraulic fluid leaks, falling objects, or accidental contact with moving parts.
7. Emergency Procedures:
Establish clear emergency procedures in case of equipment malfunction, hydraulic system failure, or any other unforeseen circumstances. Operators should be trained on how to respond to emergencies, including proper shutdown procedures, communication protocols, and evacuation plans.
8. Environmental Factors:
Consider the environmental conditions in which the lift cylinders are being used. Factors such as extreme temperatures, high humidity, or corrosive atmospheres can affect the cylinder’s performance and safety. Take appropriate measures, such as using protective covers or selecting cylinders with suitable material coatings, to mitigate these risks.
In summary, ensuring safety when using lift cylinders involves proper training, regular inspection and maintenance, adhering to load capacity limits, secure mounting, controlled movement, using personal protective equipment, establishing emergency procedures, and considering environmental factors. By following these safety considerations, the risk of accidents or injuries associated with lift cylinder operations can be minimized.
editor by CX 2024-04-16