Tag: Stop and Stay Gas Springs

Posted by: harry | on January 22, 2025

A Friction Piston Gas Sping

Patent No.:CN214999037U Date:2021-04-25

Google Patent: https://patents.google.com/patent/CN214999037U/en?oq=CN214999037U

A Friction Piston Gas Sping
Abstract
This utility model provides a friction piston device, which includes a piston assembly and a closed cavity. A Y-type lip seal is arranged in the closed cavity, where the Y-type lip seal includes an outer lip and an inner lip, and the outer lip abuts against the inner wall of the closed cavity. The piston assembly includes a piston rod, a piston body, and a piston cap, and several flow holes are provided on the piston assembly. Through the inner lip of the Y-type lip seal tightly abutting against the piston body and the outer lip being squeezed by the air pressure in the cavity and the inner wall of the closed cavity, complete friction of the inner lip and sealed belt state frictional motion of the outer lip are formed. Moreover, gas or oil can only flow through the damping structure to form a certain damping force. Therefore, the friction generated by the friction piston device of this utility model achieves the effects of enhancing friction and excellent sealing performance, and at the same time improves work efficiency and service life, thereby solving the problem of poor sealing friction damping effect in the prior art.

This passage describes a patent for a “friction piston device.” Here’s a breakdown of the information:

Device Components:
- The device consists of a piston assembly and a closed cavity.
- The piston assembly contains a piston rod, a piston body, and a piston cap, and has several flow holes.
- The closed cavity has a Y-type lip seal with an outer lip and an inner lip.
Functionality and Working Mechanism:
- The inner lip of the Y-type lip seal tightly abuts the piston body.
- The outer lip is subject to cavity air pressure and squeezing from the cavity’s inner wall, resulting in different types of friction for the inner and outer lips.
- Gas or oil can only flow through a damping structure, creating a damping force.
Advantages:
- The friction generated by this device enhances friction and provides excellent sealing performance.
- It improves work efficiency and service life.
- It aims to address the problem of poor sealing friction damping effect in existing technologies.

This device seems designed to improve the performance of piston systems by using a unique Y-type lip seal configuration and associated friction and damping mechanisms to achieve better sealing and more efficient operation compared to prior art solutions.

Description
A Friction Piston Device
Technical Field
This utility model relates to the field of gas springs, and specifically to a friction piston device.
Background
A gas spring is a component that can realize functions such as support, buffering, and braking. In construction machinery, it is mainly used in parts such as covers and doors. A gas spring mainly consists of a piston rod, a piston, a sealing guide sleeve, a filler, a pressure cylinder, and joints. Among them, the pressure cylinder is a closed cavity filled with an inert gas or an oil-gas mixture, and the pressure inside the cavity is several times or dozens of times the atmospheric pressure.
The O-ring of a traditional gas spring is arranged in the piston groove, and the frictional force between the O-ring and the inner wall of the cylinder body is limited, resulting in problems such as poor sealing friction damping effect, unstable spring speed and compression speed, which reduces the consistency, stability, and service life of the product.
Therefore, there is an urgent need for a gas spring with an enhanced friction piston device to solve the problems of poor sealing friction damping effect and unstable spring speed and compression speed.
Utility Model Content
In view of this, this utility model provides an enhanced friction piston device that can solve at least one of the above problems. Through the frictional motion resistance generated by the extrusion of the outer lip to form a sealing belt state with the inner wall of the closed cavity, and then through the damping force generated by several flow holes and the damping structure on the piston assembly, the effect of enhancing friction and excellent sealing performance is achieved, meeting the working purpose of slow spring speed and slow compression speed.
To achieve the above purpose, this utility model provides the following technical solution: A friction piston device includes a piston assembly and a closed cavity, and the piston assembly moves back and forth in the closed cavity; wherein,
A Y-type lip seal is arranged in the closed cavity, the Y-type lip seal includes an outer lip and an inner lip, the outer lip abuts against the inner wall of the closed cavity, and a distance is preset between the inner lip and the damping hole;
The piston assembly includes a piston rod, a piston body sleeved on the piston rod, and a piston cap. The piston cap includes a left piston cap and a right piston cap. Several flow holes are provided on the piston assembly. The piston body includes a socket part and a stop part. The cross-sectional diameter of one end of the socket part is smaller than that of the other end. A damping structure is provided on the socket part and the piston rod, and the Y-type lip seal shifts by friction between the stop part and the piston cap.

This section of the patent description for the “friction piston device” includes the following key points:

Technical Field and Background:
- The device belongs to the gas spring field, which is used in construction machinery.
- It points out the problems with traditional gas springs, where the O-ring’s limited friction with the cylinder wall leads to poor sealing, unstable speeds, and reduced product quality.
Utility Model Content:
- The friction piston device aims to solve these issues.
- It consists of a piston assembly and a closed cavity, with the piston assembly moving back and forth in the cavity.
- The closed cavity contains a Y-type lip seal with outer and inner lips. The outer lip contacts the cavity wall, and there’s a preset distance between the inner lip and the damping hole.
- The piston assembly has a piston rod, piston body, and piston cap (left and right). It has several flow holes.
- The piston body has a socket part with different cross-sectional diameters at its ends and a damping structure on the socket part and piston rod.
- The Y-type lip seal moves by friction between the stop part and the piston cap.

This design appears to utilize the Y-type lip seal and damping structure to address the problems of traditional gas springs, with the aim of improving friction, sealing, and speed control through the interaction of these components and structures.

In some preferred embodiments, several of the flow holes include several first through holes provided on the stop part and several second through holes provided on the piston cap.
In some preferred embodiments, a first included angle and a second included angle are respectively set between the outer lip and the inner lip and the axis, where the first included angle and the second included angle are greater than zero degrees and less than ninety degrees.
In some preferred embodiments, the damping structure includes a damping hole and a damping gap, the damping hole is provided at one end near the socket part, and the damping gap is provided between the socket part and the piston rod.
In some preferred embodiments, the socket part includes a first socket part and a second socket part, and the first socket part and the second socket part are distributed on both sides of the stop part.
In some preferred embodiments, the Y-type lip seal includes a first Y-type lip seal and a second Y-type lip seal.
In some preferred embodiments, the first Y-type lip seal and the second Y-type lip seal are respectively sleeved on the first socket part and the second socket part.
In some preferred embodiments, the axial height of the outer lip is greater than the axial height of the inner lip.
In some preferred embodiments, the number of the damping holes is one.
In some preferred embodiments, the first through hole and the second through hole are adapted.

Features and Advantages of the Utility Model:
When the piston assembly is performing a compression motion, the Y-type lip seal forms a frictional displacement with the inner wall of the closed cavity and moves towards one end of the socket part (the end with a smaller cross-sectional diameter). The outer lip abuts on the left piston cap, and at this time, the inner lip disengages from the piston body to form an annular gas passing gap, and most of the gas or oil directly flows through several through holes on the piston assembly, enabling the compression motion to be completed easily, conveniently, and quickly, with high work efficiency. When the piston assembly is performing an extension motion, the Y-type lip seal is frictionally displaced to the other end of the socket part (the end with a larger cross-sectional diameter). At this time, the inner lip of the Y-type lip seal is on the piston body, and the outer lip is under the action of air pressure in the cavity and the squeezing of the inner wall of the closed cavity, forming a complete seal of the inner lip, and the outer lip is in a sealed belt state of frictional motion. Moreover, gas or oil can only flow through the damping hole and the damping gap to form a certain damping force. Therefore, the friction generated by the friction piston device of this utility model is much greater than the friction generated by the piston groove with an O-ring in the prior art, achieving the effect of enhancing friction and excellent sealing performance, and at the same time improving work efficiency and service life, thereby solving the problem of poor sealing friction damping effect in the prior art and meeting the working purpose of slow spring speed or slow compression speed.

Here is a detailed explanation of this part of the patent:

Detailed Implementation of the Flow Holes:
- The flow holes are divided into first through holes on the stop part and second through holes on the piston cap, which may play a role in gas or fluid flow during different motion states of the piston assembly.
Angles of the Lips:
- The outer and inner lips have first and second included angles with the axis, which are within a specific range (greater than 0° and less than 90°). These angles might affect the way the lips interact with other parts and the sealing and frictional behavior.
Damping Structure Details:
- The damping structure consists of a damping hole and a damping gap. The damping hole is located near one end of the socket part, and the damping gap is between the socket part and the piston rod. These components contribute to generating damping force during the motion of the device.
Socket Part Configuration:
- The socket part is divided into a first socket part and a second socket part on both sides of the stop part, which may provide more stable support or different functional requirements.
Multiple Y-Type Lip Seals:
- There can be first and second Y-type lip seals that are respectively sleeved on the first and second socket parts, possibly enhancing the sealing function.
Lip Heights:
- The axial height of the outer lip is greater than that of the inner lip, which could influence the sealing and frictional behavior of the device.
Number of Damping Holes:
- There is typically one damping hole, which is part of the damping force generation mechanism.
Matching of Through Holes:
- The first and second through holes are adapted, perhaps for better gas or fluid flow control.

Advantages and Working Mechanism of the Device:

Compression Motion:
- During compression, the Y-type lip seal moves, and the outer lip contacts the left piston cap, creating an annular gas passing gap. Gas or oil flows through the through holes, making compression easy and efficient.
Extension Motion:
- In extension, the Y-type lip seal moves to the other end of the socket part, resulting in complete sealing by the inner lip and frictional motion of the outer lip. Gas or oil can only pass through the damping hole and gap, generating damping force.
Overall Benefits:
- The device generates more friction than traditional piston grooves with O-rings, improving sealing, efficiency, and lifespan, addressing the poor damping issue, and meeting the need for slow motion speeds.

This utility model uses various configurations and interactions of components to optimize the performance of the friction piston device, particularly in terms of friction, sealing, and damping, compared to existing technologies.

Appendix Description
The following figures are used to provide a further understanding of this application, form a part of this application, and are only intended for schematic explanation and illustration of the utility model, not to limit the scope of the utility model. In the figures:
Figure 1 is the air flow diagram of the single enhanced friction piston device during compression motion in Example 1 of this application;
Figure 2 is the air flow diagram of the single enhanced friction piston device during extension motion in Example 1 of this application;
Figure 3 is the left side view of the Y-type lip seal in Example 1 of this application;
Figure 4 is the cross-sectional view along A – A in Figure 4;
Figure 5 is the left side view of the piston body in Example 1 of this application;
Figure 6 is the cross-sectional view along B – B in Figure 6;
Figure 7 is the air flow diagram of the double enhanced friction piston device during compression motion in Example 2 of this application;
Figure 8 is the air flow diagram of the double enhanced friction piston device during extension motion in Example 2 of this application;
Figure 9 is the cross-sectional view of the piston body including the double socket part in Example 2 of this application.

Reference numerals:

Closed cavity; 2. Y-type lip seal; 3. Piston rod; 4. Piston body; 21. Outer lip; 22. Inner lip; 201. First Y-type lip seal; 202. Second Y-type lip seal; 41. Socket part; 42. Stop part; 51. Left piston cap; 52. Right piston cap; 401. First socket part; 402. Second socket part; 410. Damping hole; 420. First through hole; 510. Second left through hole; 520. Second right through hole.

Specific Implementation Mode
The following will disclose several implementation modes of this application through diagrams, and clearly and completely describe the technical solution of the utility model. The accompanying drawings of the specification that form a part of this application are used to provide a further understanding of the utility model. The schematic examples and descriptions of the utility model are used to explain the utility model and do not constitute an improper limitation of the utility model. Based on the examples in the utility model, all other examples obtained by ordinary technicians in the field without creative work fall within the protection scope of the utility model.

It should be noted that unless otherwise defined, the directions of up, down, left, right, inner, and outer mentioned in this article are based on the up, down, left, right, inner, and outer directions shown in Figure 1 of this application example. If the specific posture changes, the directional indication will also change accordingly. The meanings of “multiple” and “several” are two or more. Here, it is explained together that the use of “first”, “second”, “third” and similar words does not indicate any order, quantity, or importance, but is used to distinguish different components. In addition, in various embodiments of the present disclosure, the same or similar reference numerals represent the same or similar components.

In the present utility model, unless otherwise clearly defined and limited, terms such as “connection” and “fixing” should be understood in a broad sense. For example, “fixing” can be a fixed connection, a detachable connection, or an integral connection, unless otherwise clearly limited. For ordinary technicians in the field, the specific meaning of the above terms in the utility model can be understood according to specific circumstances.

In addition, the technical solutions of the various embodiments of the utility model can be combined with each other, but it must be based on what ordinary technicians in the field can achieve. When the combination of technical solutions is contradictory or cannot be realized, it should be considered that such a combination of technical solutions does not exist and is not within the scope of protection required by the utility model.

Here is an explanation of this section of the patent:

Figure Overview:
- The figures provide visual aids to understand different states and components of the friction piston device. Figures 1 and 2 show the air flow during compression and extension motion of the single enhanced friction piston device in Example 1.
- Figures 3 and 4 show different views of the Y-type lip seal. Figures 5 and 6 show the piston body from different perspectives.
- Figures 7 and 8 depict the air flow during motion of the double enhanced friction piston device in Example 2, and Figure 9 shows a cross-section of the piston body with double socket parts.
Reference Numerals:
- Each part of the device is labeled with a unique reference numeral, making it easier to identify and discuss specific components. For example, the closed cavity is 1, and different parts of the Y-type lip seal, piston rod, and piston body have their own reference numbers.
Implementation Mode:
- The specific implementation section aims to describe the technical solution clearly using the figures. It emphasizes that the figures are for understanding the utility model, not for limiting it.
- It clarifies the meaning of directional terms and the use of ordinal words like “first”, “second”, etc., which are used for component distinction.
- It also mentions the broad understanding of terms like “connection” and “fixing” and the conditions for combining different embodiments, ensuring that the patent’s protection scope is clear and reasonable.

This part of the patent uses figures and reference numerals to help understand the structure and function of the friction piston device in different motion states and configurations, and sets rules for interpreting the patent’s terms and combining embodiments.

Example 1
Please refer to Figures 1 to 6. A friction piston device in this example includes a piston assembly and a closed cavity 1. The piston assembly moves back and forth in the closed cavity 1, that is, performs extension or compression motion. Among them, a Y-type lip seal 2 is arranged in the closed cavity 1. As shown in Figures 3 and 4, the Y-type lip seal 2 in this example includes an outer lip 21 and an inner lip 22, and the outer lip 21 abuts against the inner wall of the closed cavity 1. As shown in Figures 1 and 2, the piston assembly includes a piston rod 3, a piston body 4 sleeved on the piston rod 3, and a piston cap. The piston cap includes a left piston cap 51 and a right piston cap 52, and is respectively provided with a second left through hole 510 and a second right through hole 520. The piston cap plays a role of shielding the Y-type lip seal 2 and increasing the force-bearing strength of the piston body 4 in the device. In combination with Figures 5 and 6, the piston body 4 in this example includes a socket part 41 and a stop part 42. One end 411 of the socket part is a cone structure, and the other end 412 is a column structure. As shown in Figure 6, D1 < D2, that is, the cross-sectional diameter of the cone structure gradually decreases along the direction away from the column structure. Further, a damping hole 410 is provided on the socket part 41, and a damping structure such as a damping gap is provided between the socket part 41 and the piston rod 3. Among them, the damping gap is preferably a threaded damping groove. The number of Y-type lip seals 2 in this example is one, and it can be set to two, three, or more according to actual conditions.

As shown in Figure 5, as a specific implementation, several flow holes in this example include several first through holes 420 provided on the stop part 42 and several second through holes provided on the piston cap. Further preferably, the aperture sizes and numbers of the first through holes 420 and the second through holes are adapted. In this example, the number of both the first through holes and the second through holes is 6. Of course, it can be set to 3, 4, or more according to actual conditions.

As shown in Figures 3 and 4, as a specific implementation, the axial height H1 of the outer lip 21 of the Y-type lip seal 2 in this example is greater than the axial height H2 of the inner lip 22. The design of this solution is more conducive to the smooth flow of gas or oil.

As shown in Figure 4, as a specific implementation, a first included angle α and a second included angle β are respectively set between the outer lip 21 and the inner lip 22 and the axis in this example, where the degrees of the first included angle α and the second included angle β are: 0° < α ≤ 45°, 0° < β ≤ 45°. The design of this angle makes the Y-type lip seal have strong elasticity, resistance to friction aging, and good sealing effect.

As a specific implementation, the number of damping holes 410 in this example is one, which is more conducive to the implementation of the damping effect, making the spring speed of the piston assembly stable, the working state stable, and the service life extended.

Combined with the air flow diagrams of the compression motion and extension motion in Figures 1 and 2, the working principle of applying the enhanced friction piston device with a single Y-type lip seal in this example in a gas spring is described as follows:
As shown in Figure 1, when the piston assembly moves to the right during the compression motion in the closed cavity of the gas spring, the Y-type lip seal 2 forms a frictional displacement with the inner wall of the closed cavity 1 and moves to the left, so that the large-diameter end of the outer lip 21 tightly abuts on the left piston cap 51. At this time, the inner lip 22 disengages from the socket part 41 of the piston body 4 to form an annular gas passing gap, and most of the gas flows in from several second right through holes 520 and several first through holes 420, passes through the gas gap, and then directly flows out through several second left through holes 510. At this time, the frictional resistance only comes from the complete sealing belt formed by the extrusion of the outer lip of the Y-type seal and the inner wall of the closed cavity, so that the compression motion is completed easily, conveniently, and quickly, and the work efficiency is high.
As shown in Figure 2, when the piston assembly moves to the left during the extension motion in the closed cavity of the gas spring, the Y-type lip seal 2 is frictionally displaced and moves to the right, so that the small-diameter end of the Y-type lip seal 2 abuts on the right piston cap 52. At this time, the inner lip of the Y-type lip seal 2 is on the piston body, and the outer lip is under the action of air pressure in the cavity and the extrusion of the inner wall of the closed cavity 2, forming a complete seal of the inner lip surface, and the outer lip is in a sealed belt state of frictional motion. At this time, most of the gas flows in from several second left through holes 510 and flows out through the damping hole 410 and the threaded damping groove. This flow path forms a certain damping force. Therefore, through the extrusion of the inner lip and the outer lip of the Y-type lip seal 2 by the piston body 4 and the inner wall of the closed cavity 2 at the same time, the frictional force generated by the double-sided complete frictional sealing belt, together with the gap damping force, is much greater than the frictional force generated by the piston groove with an O-ring in the prior art, achieving the effect of enhancing friction and excellent sealing performance.

It should be noted that the assembly of the piston assembly shown in Figures 1 and 2 in this example is one application form of enhancing friction. According to actual conditions, the piston body and the Y-type lip seal can also be turned 180 degrees together for assembly to form another application form of enhancing friction.

Here is a detailed explanation of this example:

Device Components and Structure:
- Piston Assembly and Closed Cavity: The piston assembly moves back and forth in the closed cavity 1.
- Y-Type Lip Seal: Consists of outer lip 21 and inner lip 22. The outer lip abuts the cavity wall, and its axial height H1 is greater than the inner lip’s height H2, aiding gas/oil flow.
- Piston Body and Cap: The piston body 4 has a socket part 41 (with a cone and a column structure) and a stop part 42. The piston cap has left and right caps (51 and 52) with through holes (510 and 520). The cap also strengthens the piston body.
- Damping Structure: The socket part 41 has a damping hole 410 and a damping gap (preferably a threaded damping groove) between it and the piston rod 3.
- Flow Holes: Include first through holes 420 on the stop part and second through holes on the piston cap. Their sizes and numbers (6 in this case) can be adjusted based on requirements.
- Angles: The outer and inner lips have angles α and β (0° < α ≤ 45°, 0° < β ≤ 45°) with the axis, enhancing elasticity and sealing.
Working Principle and Functionality:
- Compression Motion: During compression, the Y-type lip seal moves left, outer lip contacts left cap, inner lip detaches forming a gap. Gas flows through holes 520, 420, and 510, with friction mainly from the outer lip’s seal, making compression easy.
- Extension Motion: During extension, the Y-type lip seal moves right, with inner lip sealing and outer lip in frictional motion. Gas flows through holes 510, damping hole 410, and damping groove, generating damping force.
- Friction Enhancement: The combination of lip friction and damping force exceeds that of traditional piston-groove with O-ring, improving sealing and friction.
- Flexibility: The assembly can be rotated 180 degrees for another application form, showing versatility.

This example describes the construction and operation of a friction piston device in detail, explaining how different components work together during compression and extension motions, and highlighting its advantages in terms of friction and sealing over existing designs.

Example 2
This example is different from Example 1. As shown in Figures 7 to 9, the number of Y-type lip seals 2 in this example is two, that is, a double enhanced friction piston device. According to actual conditions, it can be set to 3, 4, or more Y-type lip seals, and the number of socket parts of the piston body is consistent with the number of Y-type lip seals.

As a specific implementation, the first Y-type lip seal 201 and the second Y-type lip seal 202 in this example are respectively sleeved on the first socket part 401 and the second socket part 402. Further, the first socket part 401 and the second socket part 402 are respectively arranged on both sides of the stop part 42.

Combined with the air flow diagrams of the compression motion and extension motion of the double enhanced friction piston device shown in Figures 7 and 8, the working principle of applying the double enhanced friction piston device with two Y-type lip seals in this example in a gas spring is described as follows:

As shown in Figure 7, when the piston assembly moves to the right during the compression motion in the gas spring’s closed cavity, both the first Y-type lip seal 201 and the second Y-type lip seal 202 form frictional displacements with the inner wall of the closed cavity 1 and move to the left, so that the large-diameter end of the outer lip of the first Y-type lip seal 201 tightly abuts on the left piston cap 51, and the large-diameter end of the outer lip of the second Y-type lip seal 202 tightly abuts on the stop part 42. At this time, the inner lip of the first Y-type lip seal 201 disengages from the first socket part 401 to form an annular first gas passing gap, and the inner lip of the second Y-type lip seal 202 disengages from the second socket part 402 to form an annular second gas passing gap. Most of the gas flows in from several second right through holes 520, passes through the second gas passing gap, flows into several first through holes 420, and then directly flows out through several second left through holes 510 through the first gas passing gap. At this time, the frictional resistance comes from the first complete sealing belt and the second complete sealing belt formed by the extrusion of the outer lip of the first Y-type seal and the outer lip of the second Y-type seal with the inner wall of the closed cavity respectively. In the case of a closed cavity of the same model, the friction force formed by this double enhanced friction piston device is more than twice that of Example 1. Under the condition of meeting the friction force requirement, the compression motion is completed easily, conveniently, and quickly, and the work efficiency is high.

As shown in Figure 8, when the piston assembly moves to the left during the extension motion in the gas spring’s closed cavity, both the first Y-type lip seal 201 and the second Y-type lip seal 202 form frictional displacements with the inner wall of the closed cavity 1 and move to the right, so that the inner lip and the outer lip of the first Y-type lip seal 201 are simultaneously extruded by the first socket part 401 and the inner wall of the closed cavity 2 to form a first double-sided completely frictional sealing belt, tightly closing the first through holes 420. At the same time, the inner lip and the outer lip of the second Y-type lip seal 202 are simultaneously extruded by the second socket part 402 and the inner wall of the closed cavity 2 to form a second double-sided completely frictional sealing belt, tightly closing the second right through holes. At this time, most of the gas flows in from several second left through holes 510 and flows out through the damping hole 410 and the damping gap. This flow path forms a certain damping force. Therefore, the frictional force generated by the first double-sided completely frictional sealing belt and the second double-sided completely frictional sealing belt, together with the gap damping force, is much greater than the frictional force generated by the piston groove with an O-ring in the prior art, achieving the effect of enhancing friction and excellent sealing performance.

Here is a detailed explanation of Example 2:

Component Variation from Example 1:
- The number of Y-type lip seals is increased to two (first Y-type lip seal 201 and second Y-type lip seal 202), and they are respectively sleeved on first socket part 401 and second socket part 402, which are on both sides of the stop part 42. This can be adjusted to more than two based on actual needs.
Working Principle in Compression Motion:
- During compression, both Y-type lip seals move left. The outer lips of the two seals abut on different parts (left piston cap 51 and stop part 42), creating first and second gas passing gaps. Gas flows through multiple through holes (520, 420, and 510) via these gaps.
- The friction comes from the complete sealing belts formed by the outer lips of both Y-type seals against the cavity wall, and the resulting friction force is more than double that of Example 1, making compression easier and more efficient under the same friction requirements.
Working Principle in Extension Motion:
- During extension, both Y-type lip seals move right. The inner and outer lips of both seals are compressed by their respective socket parts and the cavity wall, forming double-sided completely frictional sealing belts, closing off through holes (420 and second right through holes).
- Gas flows in from second left through holes 510, through the damping hole 410 and damping gap, generating damping force.
- The combined friction from the double-sided sealing belts and damping force exceeds that of traditional piston-groove with O-ring, enhancing friction and sealing performance.

This example shows how increasing the number of Y-type lip seals affects the performance of the friction piston device during compression and extension motions, providing greater friction and sealing compared to Example 1.

Note
It should be noted that the assembly of the piston assembly shown in Figures 7 and 8 in this example is one application form of double enhanced friction. According to actual conditions, the piston body and the Y-type lip seal can also be turned 180 degrees together for assembly to form another application form of double enhanced friction.

Summary
In conclusion, when the piston assembly in this application is performing a compression motion, the Y-type lip seal forms a frictional displacement with the inner wall of the closed cavity and moves towards one end of the socket part. The outer lip abuts on the left piston cap, and at this time, the inner lip disengages from the piston body to form an annular gas passing gap, and most of the gas or oil directly flows through several through holes on the piston assembly, enabling the compression motion to be completed easily, conveniently, and quickly, with high work efficiency. When the piston assembly is performing an extension motion, the Y-type lip seal is frictionally displaced to the other end of the socket part. At this time, the inner lip of the Y-type lip seal tightly abuts on the piston body, and the outer lip is under the action of air pressure in the cavity and the squeezing of the inner wall of the closed cavity, forming a complete seal of the inner lip, and the outer lip is in a sealed belt state of frictional motion. Moreover, gas or oil can only flow through the damping hole and the thread to form a certain damping force. Therefore, the friction generated by the friction piston device of this utility model is far greater than the friction generated by the piston groove with an O-ring in the prior art, achieving the effect of enhancing friction and excellent sealing performance, and at the same time improving work efficiency and service life, thereby solving the problem of poor sealing friction damping effect in the prior art and meeting the working purpose of slow spring speed or slow compression speed.

The above description shows and describes the preferred implementation mode of this application. However, as mentioned before, it should be understood that this application is not limited to the form disclosed herein, and should not be regarded as excluding other implementation modes. It can be used in various other combinations, modifications, and environments, and can be modified through the above teachings or technologies or knowledge in related fields within the scope of the concept of this application. Any changes and variations made by those skilled in the art without departing from the spirit and scope of this application shall fall within the protection scope of the appended claims of this application.

Here is a comprehensive explanation of the overall content:

Flexibility of Assembly:
- Just like in Example 1, the assembly in this example (shown in Figures 7 and 8) has flexibility. It can be rotated 180 degrees with the piston body and Y-type lip seal together to form another application form of double enhanced friction, showing the versatility of the design.
Overall Working Mechanism Summary:
- Compression Motion:
  - Y-type lip seal moves and forms a frictional displacement with the cavity wall during compression.
  - Outer lip contacts the left piston cap, inner lip detaches, creating an annular gas passing gap.
  - Gas/oil flows through through holes easily, making compression efficient.
- Extension Motion:
  - Y-type lip seal moves to the other end of the socket part.
  - Inner lip seals against the piston body, outer lip has frictional motion in a sealed belt state due to air pressure and cavity wall squeezing.
  - Damping force is generated by gas/oil flowing through damping holes and threads.
- Advantages:
  - Friction generated by this device is significantly greater than that of traditional piston groove with O-ring.
  - Enhances friction and sealing performance.
  - Improves work efficiency and service life.
  - Solves the problem of poor sealing friction damping effect in existing technology.
  - Meets the requirement of slow motion speeds (spring or compression).
- General Consideration:
  - The application is not limited to the described forms. It allows for various combinations and modifications as long as they stay within the spirit and scope of the patent, emphasizing the adaptability and potential for further development of the design based on the knowledge and technology in related fields.

This summary highlights the key points of the friction piston device’s operation, its advantages, and the flexibility of its design, showing how it improves upon existing technology and its potential for further innovation within the scope of the patent.

Claims (10) – A Friction Piston Gas Sping, invented by LeiYan Gas Spring, a pioneer Chinese Gas Spring Manufacturer.
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A friction piston device, including a piston assembly and a closed cavity, where the piston assembly moves back and forth in the closed cavity; characterized in that
a Y-type lip seal is arranged in the closed cavity, the Y-type lip seal includes an outer lip and an inner lip, and the outer lip abuts against the inner wall of the closed cavity;
the piston assembly includes a piston rod, a piston body sleeved on the piston rod, and a piston cap, several flow holes are provided on the piston assembly, the piston body includes a socket part and a stop part, one end of the socket part is a cone structure, the other end is a column structure, a damping structure is provided on the socket part and the piston rod, and the Y-type lip seal is frictionally displaced between the stop part and the piston cap.

This claim defines the basic structure of the friction piston device. It consists of a piston assembly and a closed cavity. The piston assembly moves within the cavity. The Y-type lip seal within the cavity has an outer lip that contacts the cavity’s inner wall and an inner lip. The piston assembly includes a piston rod, piston body, and piston cap, with flow holes. The piston body’s socket part has a cone structure at one end and a column structure at the other, and there’s a damping structure on the socket part and piston rod. The Y-type lip seal moves by friction between the stop part and the piston cap.

A friction piston device according to claim 1, characterized in that several of the flow holes include several first through holes provided on the stop part and several second through holes provided on the piston cap.

This claim elaborates on the flow holes mentioned in claim 1, specifying that they include first through holes on the stop part and second through holes on the piston cap.

A friction piston device according to claim 2, characterized in that the first through hole and the second through hole are adapted.

This claim further clarifies that the first and second through holes are adapted to each other, perhaps meaning they have similar sizes or configurations to work together effectively.

A damping device friction piston device according to claim 1, characterized in that the axial height of the outer lip is greater than the axial height of the inner lip.

This claim indicates a size difference between the outer and inner lips of the Y-type lip seal, which might affect the device’s performance, perhaps related to fluid flow or sealing.

A friction piston device according to claim 1, characterized in that a first included angle and a second included angle are respectively set between the outer lip and the inner lip and the axis, where the degrees of the first included angle and the second included angle are greater than zero degrees and not greater than forty-five degrees.

This claim sets the range of angles between the lips and the axis, which could influence the way the Y-type lip seal interacts with other parts, affecting factors like sealing and frictional behavior.

A friction piston device according to claim 1, characterized in that the damping structure includes a damping hole and a damping gap, the damping hole is provided at one end near the socket part, and the damping gap is provided between the socket part and the piston rod.

This claim details the damping structure, showing its location on the device, with the damping hole near the socket part and the damping gap between the socket part and piston rod, contributing to the device’s damping function.

A friction piston device according to claim 1, characterized in that the number of the damping holes is one.

This claim specifies the number of damping holes, which may affect the damping effect and overall performance of the device.

A friction piston device according to claim 1, characterized in that the Y-type lip seal includes a first Y-type lip seal and a second Y-type lip seal.

This claim introduces the possibility of having multiple Y-type lip seals, which could enhance the sealing or other functions of the device.

A friction piston device according to claim 8, characterized in that the socket part includes a first socket part and a second socket part, and the first socket part and the second socket part are respectively arranged on both sides of the stop part.

This claim describes the structure of the socket part in the case of having multiple Y-type lip seals, with the first and second socket parts located on either side of the stop part.

A friction piston device according to claim 9, characterized in that the first Y-type lip seal and the second Y-type lip seal are respectively sleeved on the first socket part and the second socket part.

This claim shows how the multiple Y-type lip seals are arranged on the corresponding socket parts, completing the detailed configuration of the device when using multiple seals.

These claims collectively define the various aspects of the friction piston device, from its basic structure to specific features and configurations. They protect different elements of the device’s design and function, outlining its components and how they interact to achieve the desired performance characteristics, such as enhanced friction, good sealing, and damping effects.

Posted in Patents | No Comments »
Tags: balancing gas spring, gas spring patent, Stop and Stay Gas Springs

Posted by: harry | on January 22, 2025

A Chronic Obstructive Pulmonary Stop Gas Spring

Patent No.:CN214742960U Date:2021-04-25

Google Patent: https://patents.google.com/patent/CN214742960U/en?oq=CN214742960U

China Patent: http://epub.cnipa.gov.cn/

A Chronic Obstructive Pulmonary Stop Gas Spring
Abstract
This utility model provides a chronic obstructive pulmonary stop gas spring. The gas spring includes a closed cavity, a piston assembly arranged within the closed cavity, and a stop member. The piston assembly comprises a piston body and a piston rod, and the stop member is sleeved on the piston rod. The stop member includes an integrally connected shaft shoulder and a stop part, and the stop part is provided with a stop protrusion at one end away from the shaft shoulder. Through the stiction friction surfaces and frictional force between the stop member of the gas spring and the closed cavity or the piston rod, deceleration and stopping are achieved without the need for any power source. It has the advantages of simple structure, ingenious design concept, low processing difficulty of components, and meets many applications in various fields.

Description
A Chronic Obstructive Pulmonary Stop gas spring
Technical Field
This utility model relates to the field of gas springs, and specifically to a chronic obstructive pulmonary stop gas spring.
Background
A gas spring is a component that can realize functions such as support, buffering, braking, height and angle adjustment. In construction machinery, it is mainly used in parts such as covers and doors. A gas spring mainly consists of a piston rod, a piston, a sealing guide sleeve, a filler, a pressure cylinder, and joints. Among them, the pressure cylinder is a closed cavity filled with an inert gas or an oil-gas mixture, and the pressure inside the cavity is several times or dozens of times the atmospheric pressure.
When some gas springs are used in specific applications, they are required to have a stop performance when fully extended or fully compressed. The so-called stop means that they stop at the end position of the extension and compression stroke and cannot move, and they can only be displaced by applying a specified large external force, and this stop is not locking, and there is no need to set a locking gas spring. Currently, the stop members used on the market have the disadvantages of complex composition and structure, high processing difficulty, and limited application fields.
Therefore, there is an urgent need to design a stop gas spring with a simple structure, low component processing difficulty, and capable of meeting applications in multiple fields.
Utility Model Content
In view of this, this utility model provides a chronic obstructive pulmonary stop gas spring that realizes without any power source, only by using the stiction friction surfaces and frictional force between components, and has the advantages of simple structure, low component processing difficulty, and being able to meet applications in multiple fields.
To achieve the above purpose, this utility model provides the following technical solution: A chronic obstructive pulmonary stop gas spring includes a closed cavity, a piston assembly arranged in the closed cavity, and a stop member. The piston assembly includes a piston body and a piston rod, the stop member is sleeved on the piston rod, the stop member includes an integrally connected shaft shoulder and a stop part, a stop protrusion is provided on one end of the stop part away from the shaft shoulder, and an inner protrusion is provided on the inner wall of the closed cavity 1.

This passage describes a patent for a gas spring called a “chronic obstructive pulmonary stop gas spring .” It first explains the technical field, which is related to gas springs. Then it details the background of gas springs, including their components and typical applications in construction machinery. It further points out the need for stop performance in some gas spring applications, which means the spring should stop at the end of its extension or compression stroke and require a certain external force to move from that position without being locked. It mentions the drawbacks of existing stop members on the market, such as complex structures and high processing difficulty. The gas spring proposed by the utility model aims to address these issues by using simple components and relying on friction and stiction between parts to achieve the stopping function. The gas spring consists of a closed cavity, a piston assembly (with a piston body and piston rod), and a stop member. The stop member has an integrated shaft shoulder and stop part, with a stop protrusion at one end of the stop part. Additionally, there is an inner protrusion on the inner wall of the closed cavity. These features are designed to work together to achieve the desired stopping functionality without the need for external power sources and with the benefits of simplicity and wide applicability.

In one preferred embodiment, the stop member is provided with a first through opening and a second through opening along its axial direction, and the first through opening and the second through opening are arranged symmetrically.
In one preferred embodiment, the stop protrusion is a curved protrusion along the outer periphery of the stop part.
In one preferred embodiment, the inner wall of the closed cavity is provided with a first inner protrusion, a second inner protrusion, and a third inner protrusion, and a curved groove adapted to the curved protrusion is formed between the second inner protrusion and the third inner protrusion.
In one preferred embodiment, a circular hole adapted to the shaft diameter of the connecting end of the piston rod is opened in the middle of the shaft shoulder.
In one preferred embodiment, an annular groove is provided on the side surface of the shaft shoulder.
In one preferred embodiment, an annular protrusion adapted to the annular groove is provided on the inner wall of the closed cavity.
In one preferred embodiment, the stop protrusion is a double conical inner protrusion along the inner periphery of the stop part.
In one preferred embodiment, a first annular groove and a second annular groove are opened at one end of the piston rod near the piston body, and a first elastic retaining ring and a second elastic retaining ring are placed in the first annular groove and the second annular groove respectively.
In one preferred embodiment, the cross-sectional shapes of the first elastic retaining ring and the second elastic retaining ring are both elliptical.

Features and Advantages of the Utility Model:
On one hand, the utility model makes the stop member move with the movement of the piston assembly by abutting the shaft shoulder of the stop member on the piston body and fixedly connecting it with the piston rod. When the piston assembly moves, the stop protrusion undergoes two brief decelerations when passing through the first inner protrusion and the second inner protrusion on the inner wall of the closed cavity, and finally moves to the end of the stroke, so that the stop protrusion stops in the annular groove of the closed cavity and remains stationary. On the other hand, the annular protrusion in the closed cavity is fixedly clamped in the annular groove on the shaft shoulder of the stop member, making the stop member stationary. When the piston assembly moves, the first elastic retaining ring and the second elastic retaining ring on the piston rod generate two brief decelerations when they come into contact with the stop protrusion, and finally move to the end of the stroke, so that the stop protrusion stops and remains stationary between the piston body and the first elastic retaining ring. Therefore, the utility model realizes deceleration and stopping through the stiction friction surfaces and frictional force between the stop member of the gas spring and the closed cavity or the piston rod, without any power source, has a simple structure, low processing difficulty of components, and can meet applications in multiple fields, solving the problems of complex composition and structure, high processing difficulty, and limited application fields of the stop gas spring in the prior art.

This section of the patent further elaborates on several preferred embodiments of the “chronic obstructive pulmonary stop gas spring .” It details various features and configurations of the gas spring :

Axial Openings in the Stop Member: The stop member has symmetric first and second through openings along its axial direction. These openings might serve different purposes such as facilitating fluid flow, reducing weight, or interacting with other parts of the gas spring in a specific way, but the patent doesn’t specify their exact function here.
Stop Protrusion Shapes: There are different descriptions of the stop protrusion. It can be a curved protrusion along the outer periphery of the stop part, which could interact with corresponding curved grooves in the closed cavity to achieve stopping. Another option is a double conical inner protrusion along the inner periphery of the stop part, which might interact with other parts in a different manner for the stopping function.
Inner and Annular Features: The inner wall of the closed cavity has multiple inner protrusions and grooves, and there are corresponding annular grooves and protrusions on the shaft shoulder of the stop member. These are designed to work together for better stopping and positioning. For example, the annular groove on the shaft shoulder and the annular protrusion on the cavity wall can interlock to hold the stop member in place.
Elastic Retaining Rings: The piston rod near the piston body has first and second annular grooves where elliptical cross-sectioned elastic retaining rings are placed. These rings, when interacting with the stop protrusion, contribute to the stopping mechanism by causing brief decelerations and finally stopping the movement of the gas spring.

Overall, the utility model utilizes these various features and interactions between the stop member, piston assembly, and the closed cavity to achieve deceleration and stopping. The design aims to overcome the issues of complexity and limited applicability found in existing stop gas springs by using simple structures and relying on friction and stiction forces, without needing an external power source. The described mechanisms and interactions provide multiple ways for the gas spring to achieve the desired stopping function at different stages of motion, enhancing its functionality and versatility in different fields of application.

Reference numerals:

Closed cavity; 2. Piston assembly; 3. P stop member; 3′. P’ stop member; 11. First inner protrusion; 12. Second inner protrusion; 13. Third inner protrusion; 21. Piston body; 22. Piston rod; 31. P shaft shoulder; 32. P connection part; 31′. P’ shaft shoulder; 32′. P’ connection part; 310. Annular groove; 311. Circular hole; 312. First through opening; 313. Second through opening; 320. Double conical inner protrusion; 321. Curved protrusion.

It should be noted that unless otherwise defined, the directions of up, down, left, right, inner, and outer mentioned in this article are based on the up, down, left, right, inner, and outer directions shown in Figure 1 of this application example. If the specific posture changes, the directional indication will also change accordingly. The meanings of “multiple” and “several” are two or more. Here, it is explained together that the use of “first”, “second”, “third” and similar words does not indicate any order, quantity, or importance, but is only used to distinguish different components. In addition, in various embodiments of the present disclosure, the same or similar reference numerals represent the same or similar components.

This section of the patent provides a detailed description of the figures and reference numerals used to illustrate the “chronic obstructive pulmonary stop gas spring.” Here’s a breakdown of the information:

Figure Overview:
- Figure 1 shows the assembly structure of the gas spring in Example 1. It gives an overall view of how the different parts of the gas spring fit together.
- Figure 2 is the right side view of the P stop member in Example 1, helping to visualize its shape from a particular perspective.
- Figure 3 is a sectional view along A – A in Figure 2, providing insights into the internal structure of the P stop member.
- Similar to the above, Figure 4 shows the assembly of the gas spring in Example 2, Figure 5 shows the left side view of the P’ stop member, and Figure 6 is the sectional view of the P’ stop member.
Reference Numerals:
- Each part of the gas spring is labeled with a unique reference numeral for easy identification. For example, the closed cavity is labeled as 1, and different parts of the piston assembly and stop member have their own numerals. This makes it easier to discuss and understand specific parts of the gas spring in both the text and the figures.
Implementation Mode:
- The specific implementation section aims to clearly and completely describe the technical solution of the utility model using the figures. It emphasizes that the figures are for understanding the utility model and not for limiting it.
- It also clarifies the meaning of directional terms and the use of words like “first”, “second”, etc., which are used for component distinction rather than indicating importance or order. This ensures that readers can correctly interpret the information provided in the patent and understand how the gas spring works based on the figures and the accompanying text.
- It further states that the patent’s protection scope includes all other examples that can be obtained by ordinary technicians without creative work, based on the provided examples.

Example 1
Please refer to Figures 1 to 3. A chronic obstructive pulmonary stop gas spring in this example includes a closed cavity 1, a piston assembly 2 arranged in the closed cavity, and a P stop member 3. The piston assembly 2 includes a piston body 21 and a piston rod 22, and the P stop member 3 is sleeved on the piston rod 22. The P stop member 3 includes an integrally connected P shaft shoulder 31 and a P stop part 32, and a stop protrusion is provided on the P stop part 32 at one end away from the P shaft shoulder 31. Further, as shown in Figure 3, the stop protrusion in this example is a curved protrusion 321 along the outer periphery of the P stop part 32. Furthermore, the inner wall of the closed cavity 1 is provided with inner protrusions. More specifically, as shown in Figure 1, the inner wall of the closed cavity 1 in this example is provided with a first inner protrusion 11, a second inner protrusion 12, and a third inner protrusion 13, and a curved groove adapted to the curved protrusion 321 is formed between the second inner protrusion 12 and the third inner protrusion 13.

It should be noted that by abutting the P shaft shoulder 31 of the P stop member 3 on the piston body 21 and fixedly connecting it with the piston rod 22, the P stop member 3 moves with the movement of the piston assembly. When the piston assembly 2 performs an extension movement, the curved protrusion 321 passes through the first inner protrusion 11 and the second inner protrusion 12 on the inner wall of the closed cavity 1 in sequence, resulting in two brief decelerations, and finally moves to the end of the stroke, so that the curved protrusion 321 stops in the annular groove of the closed cavity 1 and remains stationary, thereby realizing the stop function of the extension movement. When performing a compression movement, a certain external force needs to be applied to shift it.

As shown in Figures 2 and 3, as a specific implementation, the P stop member 3 in this example is provided with a first through opening 312 and a second through opening 313 along its axial direction, and the first through opening 312 and the second through opening 313 are symmetrically arranged. More specifically, a circular hole 311 adapted to the shaft diameter of the connecting end of the piston rod 22 is opened in the middle of the P shaft shoulder 31 in this example.

It should be noted that the P stop part 32 of the P stop member 3 in this example is composed of two symmetrical three-dimensional elastic semicircular sectors, and a curved protrusion 321 is provided on the outer diameter edge of each three-dimensional elastic semicircular sector at one end away from the P shaft shoulder 31. Among them, the width and thickness of the three-dimensional elastic semicircular sector are determined according to the actual designed stopping force. Similarly, the protrusion height and width of the curved protrusion and the inner protrusion of the closed cavity are also selected and determined according to the actual designed stopping force.

This section describes the first implementation example of the chronic obstructive pulmonary stop gas spring in detail:

gas spring Components and Structure:
- The gas spring consists of a closed cavity 1, a piston assembly 2, and a P stop member 3. The piston assembly has a piston body 21 and a piston rod 22, and the P stop member is sleeved on the piston rod. The P stop member has a P shaft shoulder 31 and a P stop part 32.
- The P stop part 32 has a curved protrusion 321 at one end away from the P shaft shoulder.
- The closed cavity 1 has inner protrusions, specifically, first, second, and third inner protrusions 11, 12, and 13. A curved groove is formed between the second and third inner protrusions to fit the curved protrusion of the P stop part.
Movement and Functionality:
- The P stop member 3 moves with the piston assembly through the connection between the P shaft shoulder 31 and the piston body 21 and piston rod 22.
- During the extension movement of the piston assembly 2, the curved protrusion 321 passes through the first and second inner protrusions, causing two decelerations, and finally stops in the annular groove of the closed cavity 1, achieving the stop function for extension. However, for compression movement, an external force is required to move it.
Additional Features:
- The P stop member 3 has symmetric first and second through openings 312 and 313 along its axial direction.
- The P shaft shoulder 31 has a circular hole 311 in the middle that fits the shaft diameter of the piston rod 22.
- The P stop part 32 is made of two symmetrical three-dimensional elastic semicircular sectors, and the size and shape of these sectors, as well as the curved protrusion, are determined based on the designed stopping force, indicating that the design takes into account the required force for stopping in practical applications. This allows for customization of the device’s performance according to different requirements.

Example 2
As shown in Figures 4 to 6, a chronic obstructive pulmonary stop gas spring in this example includes a closed cavity 1, a piston assembly 2 arranged in the closed cavity 1, and a P’ stop member 3′. The piston assembly 2 includes a piston body 21 and a piston rod 22, and the P’ stop member 3′ is sleeved on the piston rod 22. The P’ stop member 3′ includes an integrally connected P’ shaft shoulder 31′ and a P’ stop part 32′, and a stop protrusion is provided on the P’ stop part 32′ at one end away from the P’ shaft shoulder 31′. As shown in Figure 6, further, the stop protrusion in this example is a double conical inner protrusion 320 along the inner periphery of the P’ stop part 32′.

It should be noted that, as shown in Figure 6, the so-called double conical inner protrusion 320 includes an inner conical surface on the left side and a P’ curved protrusion on the right side, and the taper of the inner conical surface is preferably between 20 degrees and 60 degrees, more preferably 42 degrees, and the selection of the angle and height is designed according to the actually required stopping force. Both the P’ stop member 3′ and the P stop member 3 are molded hard plastic parts.

As shown in Figure 6, as a specific implementation, an annular groove 310 is provided on the side surface of the P’ shaft shoulder 31′ in this example. In combination with Figure 4, further, an annular protrusion 15 adapted to the annular groove 310 is provided on the inner wall of the closed cavity 1 in this example.

As shown in Figure 4, as a specific implementation, a first annular groove and a second annular groove are opened at one end of the piston rod 22 near the piston body 21 in this example, and a first elastic retaining ring 41 and a second elastic retaining ring 42 are placed in the first annular groove and the second annular groove respectively. More specifically, the cross-sectional shapes of the first elastic retaining ring 41 and the second elastic retaining ring 42 in this example are both elliptical.

In conclusion, on the one hand, the present application makes the stop member move with the movement of the piston assembly by abutting the shaft shoulder of the stop member on the piston body and fixedly connecting it with the piston rod. When the piston assembly moves, the stop protrusion undergoes two brief decelerations when passing through the first inner protrusion and the second inner protrusion on the inner wall of the closed cavity, and finally moves to the end of the stroke, so that the stop protrusion stops in the annular groove of the closed cavity and remains stationary. On the other hand, the annular protrusion in the closed cavity is fixedly clamped in the annular groove on the shaft shoulder of the stop member, making the stop member stationary. When the piston assembly moves, the first elastic retaining ring and the second elastic retaining ring on the piston rod generate two brief decelerations when they come into contact with the stop protrusion, and finally move to the end of the stroke, so that the stop protrusion stops and remains stationary between the piston body and the first elastic retaining ring. Therefore, the utility model realizes deceleration and stopping through the stiction friction surfaces and frictional force between the stop member of the gas spring and the closed cavity or the piston rod, without any power source, has a simple structure, low processing difficulty of components, ingenious design concept, and can meet applications in multiple fields, solving the problems of complex composition and structure, high processing difficulty, and limited application fields of the stop gas spring in the prior art.

The above description shows and describes the preferred implementation mode of the present application. However, as mentioned earlier, it should be understood that the present application is not limited to the form disclosed herein, and should not be regarded as excluding other implementation modes, but can be used in various other combinations, modifications, and environments, and can be modified through the above teachings or technologies or knowledge in related fields within the scope of the concept of the present application. And any changes and variations made by those skilled in the art without departing from the spirit and scope of the present application shall fall within the protection scope of the appended claims of the present application.

This part of the patent describes the second implementation example of the chronic obstructive pulmonary stop gas spring :

gas spring Components and Structure:
- Similar to Example 1, this gas spring also consists of a closed cavity 1, a piston assembly 2, and a P’ stop member 3′. The P’ stop member has a P’ shaft shoulder 31′ and a P’ stop part 32′, and the P’ stop part has a stop protrusion.
- The stop protrusion in this example is a double conical inner protrusion 320 with an inner conical surface and a P’ curved protrusion, and the taper of the inner conical surface can be adjusted according to the required stopping force, with a preferred range from 20 to 60 degrees and more preferably 42 degrees.
- The P’ shaft shoulder 31′ has an annular groove 310 on its side surface, and the closed cavity 1 has a corresponding annular protrusion 15 to fit with it.
- The piston rod 22 has first and second annular grooves near the piston body 21, and these grooves contain first and second elastic retaining rings 41 and 42 with elliptical cross-sections.
Functionality and Working Principle:
- Similar to the principle in Example 1, the stop member moves with the piston assembly through connections.
- When moving, the stop protrusion passes through certain parts of the cavity’s inner wall (first and second inner protrusions), causing decelerations, and eventually stops in the annular groove of the closed cavity.
- Additionally, the annular protrusion and groove interaction and the interaction between the elastic retaining rings and the stop protrusion also contribute to the stopping mechanism.
- The gas spring uses stiction and friction forces between components to achieve deceleration and stopping without an external power source.
Advantages and Flexibility:
- The gas spring has a simple structure, low processing difficulty, and a clever design concept.
- It can be used in multiple fields, solving the problems of complex structures, high processing difficulty, and limited application fields of existing stop gas springs.
- It also emphasizes that the design is not limited to the disclosed forms and can be modified and combined in various ways while staying within the scope of the patent’s claims, showing the patent’s flexibility and potential for further development.

Claims (10) – A Chronic Obstructive Pulmonary Stop Gas Spring, invented by LeiYan Gas Spring, a pioneer Chinese Gas Spring Manufacturer.

A chronic obstructive pulmonary stop gas spring, characterized in that it includes a closed cavity, a piston assembly arranged in the closed cavity, and a stop member. The piston assembly includes a piston body and a piston rod, the stop member is sleeved on the piston rod, the stop member includes an integrally connected shaft shoulder and a stop part, and a stop protrusion is provided at one end of the stop part away from the shaft shoulder.

This claim defines the basic structure of the chronic obstructive pulmonary stop gas spring, which consists of three main parts: the closed cavity, the piston assembly, and the stop member. The piston assembly contains a piston body and a piston rod, and the stop member is placed over the piston rod. The stop member itself has an integrated shaft shoulder and stop part, with a stop protrusion at one end of the stop part that is away from the shaft shoulder.

A chronic obstructive pulmonary stop gas spring according to claim 1, characterized in that the stop member is provided with a first through opening and a second through opening along its axial direction, and the first through opening and the second through opening are symmetrically arranged.

This claim further elaborates on the stop member by adding the feature of having first and second through openings that are symmetrically placed along its axial direction. These openings could potentially serve various purposes, such as facilitating fluid flow, reducing weight, or interacting with other components, although the specific function is not detailed here.

A chronic obstructive pulmonary stop gas spring according to claim 1, characterized in that the stop protrusion is a curved protrusion along the outer periphery of the stop part.

Here, the shape of the stop protrusion is specified as a curved protrusion located along the outer periphery of the stop part. This specific shape may play a crucial role in the interaction with other parts of the gas spring for achieving the desired stopping functionality.

A chronic obstructive pulmonary stop gas spring according to claim 3, characterized in that the inner wall of the closed cavity is provided with a first inner protrusion, a second inner protrusion, and a third inner protrusion, and a curved groove adapted to the curved protrusion is formed between the second inner protrusion and the third inner protrusion.

This claim builds on claim 3 by describing the inner wall of the closed cavity. It includes multiple inner protrusions, and between the second and third inner protrusions, there is a curved groove that is designed to fit with the curved protrusion of the stop member. This interaction between the curved groove and the curved protrusion is likely part of the stopping mechanism.

A chronic obstructive pulmonary stop gas spring according to claim 1, characterized in that a circular hole adapted to the shaft diameter of the connecting end of the piston rod is opened in the middle of the shaft shoulder.

This claim focuses on the shaft shoulder of the stop member, stating that there is a circular hole in its middle that is sized to fit the shaft diameter of the piston rod’s connecting end. This might be relevant for proper alignment, attachment, or some other mechanical function related to the interaction between the stop member and the piston rod.

A chronic obstructive pulmonary stop gas spring according to claim 1, characterized in that an annular groove is provided on the side surface of the shaft shoulder.

This claim adds an annular groove to the shaft shoulder of the stop member, which could potentially interact with other parts of the gas spring, perhaps for locking, guiding, or providing some form of mechanical interaction.

A chronic obstructive pulmonary stop gas spring according to claim 6, characterized in that an annular protrusion adapted to the annular groove is provided on the inner wall of the closed cavity.

This claim complements claim 6 by providing a corresponding annular protrusion on the inner wall of the closed cavity. The annular protrusion and the annular groove are designed to interact, possibly for a locking or stabilizing function.

A chronic obstructive pulmonary stop gas spring according to claim 1, characterized in that the stop protrusion is a double conical inner protrusion along the inner periphery of the stop part.

This claim offers an alternative shape for the stop protrusion, which is a double conical inner protrusion along the inner periphery of the stop part. Different from the curved protrusion in claim 3, this shape might have different mechanical properties and interactions with other parts of the gas spring.

A chronic obstructive pulmonary stop gas spring according to claim 8, characterized in that a first annular groove and a second annular groove are opened at one end of the piston rod near the piston body, and a first elastic retaining ring and a second elastic retaining ring are placed in the first annular groove and the second annular groove respectively.

Building on claim 8, this claim introduces the concept of annular grooves on the piston rod near the piston body and the placement of elastic retaining rings within them. These elastic retaining rings might contribute to the stopping mechanism, perhaps by providing additional resistance or control during the motion of the gas spring.

A chronic obstructive pulmonary stop gas spring according to claim 9, characterized in that the cross-sectional shapes of the first elastic retaining ring and the second elastic retaining ring are both elliptical.

This final claim specifies the cross-sectional shape of the elastic retaining rings as elliptical, which could affect their mechanical behavior, such as how they interact with other parts of the gas spring, possibly influencing the force distribution and stopping function of the gas spring.

These claims collectively define the various elements and features of the chronic obstructive pulmonary stop gas spring , outlining different aspects of its structure, and potentially how these features interact to achieve the desired stopping functionality. Each claim builds upon or modifies the basic gas spring described in claim 1, providing a comprehensive description of the possible configurations and characteristics of the gas spring while also protecting different aspects of the invention through patent rights.

Posted in Patents | No Comments »
Tags: leiyan gas spring patent, Stop and Stay Gas Springs

Posted by: harry | on January 10, 2025

A Window Damper with Buffering Assistance during Compression

Patent No.:CN208858845U Date:2018-09-11

Google Patent: https://patents.google.com/patent/CN208858845U/en?oq=CN208858845U

China Patent: http://epub.cnipa.gov.cn/

Abstract

This utility model provides a window damper with buffering and assisting force during compression, including: a hollow piston rod assembly rod, a guide sleeve, a cylinder, a movable locking rod, a return spring, a locking block, a locking block rubber sleeve, and a positioning clamp sleeve. Using this utility model, when the car window is opened, the damper extends, at which point the return spring is in a reset state. When the locking block rubber sleeve enters the narrow cavity part of the cylinder from the wide cavity part of the cylinder, it generates a certain amount of friction with the inner wall of the narrow cavity part of the cylinder, allowing the window to stop at any angle; after the window is fully opened, if the wind blows the window, the damper will enter a compressed state. At this point, the return spring is first compressed, and the elliptical ball-shaped part on the movable locking rod moves, entering the narrow cavity part of the locking block from the wide cavity part, causing the locking block to expand outward, further increasing the friction between the locking block rubber sleeve and the narrow cavity part of the cylinder. This ensures that the opened window is not easily closed by the wind, providing a buffering and assisting force.

Description – A Window Damper with Buffering Assistance during Compression

Technical Field

This utility model belongs to the technical field of dampers, particularly to a window damper with buffering and assisting force during compression.

Background Technology

When operating windows, it’s often necessary to connect a positioning component to maintain the window’s stable state. In existing technology, the components generally used are linkage mechanisms, which, when the window is propped open, can easily be blown back by the wind, failing to effectively maintain the window’s stable open state.

Summary of the Utility Model

The objective of this utility model is to propose a damper with different damping forces during stretching and compression processes, making it easy to open the window, while preventing the window from closing at will when encountering a certain amount of wind.

This utility model provides a window damper with buffering assistance during compression, which includes a hollow piston rod, a cylinder, a movable locking rod, a return spring, a locking block, a locking block rubber sleeve, and a positioning clamp sleeve.

The cylinder’s middle part is designed with a cylinder diameter expansion opening, which divides the inner cavity of the cylinder into a front narrow cavity part and a rear wide cavity part. The movable locking rod is installed inside the cylinder’s inner cavity, with the front end of the movable locking rod coaxially connected to the hollow piston rod assembly. At the connection point of the movable locking rod and the hollow piston rod assembly, there is a spring positioning boss, whose diameter is smaller than the inner diameter of the cylinder’s narrow cavity part.

The return spring is installed on the movable locking rod, behind the spring positioning boss, and the back part of the movable locking rod is designed with an elliptical ball protrusion. The locking block is fitted outside the elliptical ball protrusion, with an internal stepped transition opening inside the locking block, which divides the internal cavity of the locking block into a front wide cavity part and a rear narrow cavity part.

The locking block rubber sleeve fits outside the locking block, with its diameter smaller than the cylinder’s wide cavity part and larger than the cylinder’s narrow cavity part. The positioning clamp sleeve is fixed at a corresponding position on the back end of the movable locking rod, with its diameter larger than the inner diameter of the cylinder’s narrow cavity part.

When the damper stretches, the locking block rubber sleeve moves from the cylinder’s wide cavity part into the narrow cavity part, creating friction with the inner wall of the narrow cavity part. This friction is greater than or equal to the maximum compression force value of the return spring.

When using this utility model, during window opening, the damper is in the stretching motion, with the locking block rubber sleeve creating friction with the inner wall of the cylinder’s narrow cavity part. This friction force is greater than or equal to the maximum compression force value of the return spring. When the window stops at any angle, if wind moves the window, the damper enters a compressed state. The return spring first compresses, moving the elliptical ball protrusion on the movable locking rod from the wide cavity part of the locking block into the narrow cavity part, expanding the locking block outward. This increases the friction between the locking block rubber sleeve and the narrow cavity part of the cylinder, preventing the window from being easily closed by the wind, providing buffering and resistance.

Further Details

Furthermore, the movable locking rod on the front side of the positioning clamp sleeve is also equipped with an anti-slip buffer rubber ring.

Further, a guide sleeve is installed at the front end opening of the cylinder. The inner diameter of the guide sleeve and the outer diameter of the hollow piston rod are slide-fitted.

Additionally, a slot is provided on the outer wall of the guide sleeve, and it is connected to the front end opening of the cylinder through the slot.

Furthermore, a rear block connecting piece is installed at the rear end opening of the cylinder.

The portion of the rear block connecting piece located inside the cylinder has a circular groove that is coaxial with the movable locking rod.

Further, the cylinder diameter expansion opening and the stepped transition opening are both arc-shaped transitions.

Additional aspects and advantages of this utility model will be partially illustrated in the following description, partially become apparent from the description, or be learned through the practice of this utility model.

Description of Drawings

Figure 1 is a schematic structural diagram of a window damper with buffering assistance during compression according to an embodiment of this utility model.

Figure 2 is a schematic structural diagram of the stretched state of the window damper with buffering assistance during compression according to an embodiment of this utility model.

Figure 3 is a schematic structural diagram of the compressed state of the window damper with buffering assistance during compression according to an embodiment of this utility model.

Reference Marked in the Drawings:

1 – Hollow piston rod assembly 2 – Guide sleeve 2 – Slot 3 – Cylinder 31 – Cylinder diameter expansion opening 4 – Movable locking rod 41 – Spring positioning boss 42 – Elliptical ball protrusion 5 – Return spring 6 – Locking block 61 – Stepped transition opening 7 – Locking block rubber sleeve 8 – Anti-slip buffer rubber ring 9 – Positioning clamp sleeve 10 – Rear block connecting piece 101 – Groove

Specific Embodiments

The embodiments of this utility model are described in detail below. The examples of the embodiments are shown in the drawings, where the same or similar reference numbers indicate the same or similar elements or elements having the same or similar functions. The embodiments described below with reference to the drawings are exemplary and are intended to explain this utility model rather than to limit it.

The embodiments of this utility model provide a window damper with buffering assistance during compression, as shown in Figure 1, including a hollow piston rod assembly (1), a cylinder (3), a movable locking rod (4), a return spring (5), a locking block (6), a locking block rubber sleeve (7), and a positioning clamp sleeve (9).

When describing this utility model, the position of the hollow piston rod assembly (1) is considered the front, and the position of the positioning clamp sleeve (9) is considered the rear. The middle part of the cylinder (3) is provided with a cylinder diameter expansion opening (31), which divides the inner cavity of the cylinder (3) into a front narrow cavity part and a rear wide cavity part. The movable locking rod (4) can move telescopically inside the inner cavity of the cylinder (3). The front end of the movable locking rod (4) is coaxially connected to the hollow piston rod assembly (1). At the connection point of the movable locking rod (4) and the hollow piston rod assembly (1), a spring positioning boss (41) is designed, with a diameter smaller than the inner diameter of the cylinder’s narrow cavity part. The return spring (5) is installed on the movable locking rod (4) behind the spring positioning boss (41). The back part of the movable locking rod (4) is also designed with an elliptical ball protrusion (42).

The locking block (6) is fitted outside the elliptical ball protrusion (42), with an internal stepped transition opening (61) inside the locking block (6), dividing its internal cavity into a front wide cavity part and a rear narrow cavity part. The locking block rubber sleeve (7) is fitted outside the locking block (6), with a diameter smaller than the cylinder’s wide cavity part but slightly larger than the cylinder’s narrow cavity part. Preferably, the locking block is made of high-tenacity elastic material. The positioning clamp sleeve (9) is fixedly connected to the rear end of the movable locking rod (4), with a diameter smaller than the internal diameter of the cylinder’s narrow cavity part. The positioning clamp sleeve prevents the movable locking rod from slipping out and stays in the cylinder’s wide cavity part when the car window is closed.

When the damper stretches, the locking block rubber sleeve (7) moves from the cylinder’s wide cavity part into the narrow cavity part, creating a certain amount of friction with the inner wall of the narrow cavity part. This friction amount is determined based on different car window weights, ensuring it’s light enough for the window to stay open at any angle but also greater or equal to the maximum compression force value of the return spring (5).

Preferably, the cylinder diameter expansion opening (31) and the stepped transition opening (61) are both arc-shaped transitions to ensure smooth movement of the locking block rubber sleeve and the elliptical ball protrusion without causing jamming.

When using this utility model, as shown in Figure 2, the damper is in the stretched state when the window is opened. The locking block rubber sleeve (7) moves from the cylinder’s wide cavity part into the narrow cavity part, creating the necessary friction with the inner wall of the cylinder’s narrow cavity part. This friction amount is determined based on the car window’s size and weight but also must be greater or equal to the maximum compression force value of the return spring (5) for the window to stay in place at any position. When the window is fully opened, if wind moves the window, as shown in Figure 3, the damper enters a compressed state. At this point, the return spring (5) is compressed, and the elliptical ball protrusion (42) moves from the wide cavity part of the locking block (6) into the narrow cavity part, causing the locking block (6) to expand outward. This increases the friction between the locking block rubber sleeve (7) and the narrow cavity part of the cylinder, preventing the opened window from being closed by the wind and providing buffering assistance.

Further Implementation of the Utility Model

In one aspect of the embodiments of this utility model, an anti-slip buffer rubber ring (8) is also installed on the movable locking rod (4) at the front side of the positioning clamp sleeve (9). The anti-slip buffer rubber ring compensates for the excessive movement caused by the assembly gap of components like the locking block and mitigates the impact on the positioning clamp sleeve.

In one aspect of the embodiments of this utility model, a guide sleeve (2) is connected to the front end opening of the cylinder (3). The inner diameter of the guide sleeve (2) is slide-fitted with the diameter of the hollow piston rod assembly (1). A slot (21) is designed on the outer wall of the guide sleeve (2), and the guide sleeve (2) is pressed and positioned connected to the front end opening of the cylinder (3) through the slot (21). The setup of the guide sleeve and the slot ensures the precise coaxial connection of the hollow piston rod assembly and the front end of the cylinder, enhancing tensile strength and movement stability.

In one aspect of the embodiments of this utility model, a rear block connecting piece (10) is connected to the rear end opening of the cylinder (3). Portions of the rear block connecting piece (10) within the cylinder (3) have a circular groove (101) coaxial with the movable locking rod. The design of the rear block connecting piece serves a dual purpose: it connects the damper to the window and limits the position of the movable locking rod within the cylinder. When the window is closed under human force, the locking block and locking block rubber sleeve are fully retracted into the wide cavity part of the cylinder. The return spring naturally opens in the wide cavity part of the cylinder, and the elliptical ball protrusion retracts into the wide cavity part of the locking block.

Although the embodiments of this utility model have been shown and described above, it is understood that the above embodiments are exemplary and not to be construed as limiting this utility model. Those skilled in the field can make variations, modifications, replacements, and alterations to the above embodiments within the scope of this utility model.

Claims – A Window Damper with Buffering Assistance during Compression, invented by LeiYan Gas Spring, a pioneer Chinese Gas Spring Manufacture

A window damper with buffering assistance during compression, characterized by:
- A hollow piston rod assembly, a cylinder, a movable locking rod, a return spring, a locking block, a locking block rubber sleeve, and a positioning clamp sleeve;
- The middle part of the cylinder is provided with a cylinder diameter expansion opening, which divides the inner cavity of the cylinder into a front narrow cavity part and a rear wide cavity part;
- The movable locking rod is telescopically installed inside the inner cavity of the cylinder, with the front end of the movable locking rod coaxially connected to the hollow piston rod assembly. The rear side of the connection point between the movable locking rod and the hollow piston rod assembly is provided with a spring positioning boss. The diameter of the spring positioning boss is smaller than the inner diameter of the cylinder’s narrow cavity part. The return spring is installed on the movable locking rod behind the spring positioning boss. The movable locking rod on the rear side of the return spring is also provided with an elliptical ball protrusion;
- The locking block is sleeved on the outer side of the elliptical ball protrusion, and the internal cavity of the locking block is provided with a stepped transition opening, dividing its internal cavity into a front wide cavity part and a rear narrow cavity part. The locking block rubber sleeve is sleeved on the outer side of the locking block. The outer diameter of the locking block rubber sleeve is smaller than the inner diameter of the cylinder’s wide cavity part but larger than the inner diameter of the cylinder’s narrow cavity part;
- The positioning clamp sleeve is fixedly connected to the rear end of the movable locking rod, and its outer diameter is larger than the inner diameter of the cylinder’s narrow cavity part;
- When the damper stretches, the locking block rubber sleeve moves from the cylinder’s wide cavity part into the narrow cavity part, creating friction with the inner wall of the narrow cavity part. This friction force is greater than or equal to the maximum compression force of the return spring.
The window damper with buffering assistance during compression according to claim 1, characterized by:
- The positioning clamp sleeve’s front side of the movable locking rod is also fitted with an anti-slip buffer rubber ring.
The window damper with buffering assistance during compression according to claim 1, characterized by:
- A guide sleeve is fixed at the front end opening of the cylinder. The inner diameter of the guide sleeve is greater than that of the hollow piston rod assembly, which slides within the guide sleeve.
The window damper with buffering assistance during compression according to claim 3, characterized by:
- A slot is provided on the outer wall of the guide sleeve, and the guide sleeve is fastened to the front end opening of the cylinder through the slot.
The window damper with buffering assistance during compression according to claim 1, characterized by:
- A rear block connecting piece is connected to the rear end opening of the cylinder.
The window damper with buffering assistance during compression according to claim 5, characterized by:
- Portions of the rear block connecting piece within the cylinder have a circular groove that is coaxial with the movable locking rod.
The window damper with buffering assistance during compression according to any of claims 1-6, characterized by:
- Both the cylinder diameter expansion opening and the stepped transition opening are arc-shaped transitions.

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Tags: A Window Damper, compression gas spring, gas spring patent, Stop and Stay Gas Springs

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