Damping ring and air conditioner

By designing a shock-absorbing ring with multiple clamping parts of different sizes and an integrated clamping baffle, the problem of the single pipe diameter of existing shock-absorbing rings is solved, achieving universality and efficient installation to adapt to various pipe diameters, and saving materials.

CN116464851BActive Publication Date: 2026-07-03NINGBO AUX ELECTRIC CO LTD +1

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
NINGBO AUX ELECTRIC CO LTD
Filing Date
2022-01-12
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

Existing shock absorbers are limited to a single pipe diameter, have poor versatility, and cannot adapt to pipes of different sizes.

Method used

Design a shock-absorbing ring with multiple clamping parts of different sizes, which are interconnected or connected by gaps. The clamping baffle is an integral structure, and the binding ring is used for fixation, which can be adapted to different pipe diameters.

Benefits of technology

This allows the same shock absorber ring to adapt to various pipe diameters, improving versatility and installation efficiency, saving materials, and reducing production complexity.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application provides a damping ring and an air conditioner, and the damping ring is used for clamping a pipeline and comprises a damping ring body and a plurality of clamping portions which penetrate through the damping ring body in an axial direction, wherein at least two clamping portions are used for clamping pipelines with different diameters. The application solves the technical problem and achieves the technical effect. The application solves the technical problem that the damping ring is matched with a single pipeline diameter and has poor universality, and achieves the technical effect that the same damping ring can be matched with multiple pipeline diameters.
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Description

Technical Field

[0001] This invention relates to the field of air conditioning technology, and more specifically, to a shock-absorbing ring and an air conditioner. Background Technology

[0002] When existing air conditioners are in operation, the vibration of the compressor and refrigerant can cause the air conditioner pipes to vibrate. In particular, when the natural frequency of the pipe system is close to the vibration frequency of the excitation source, the pipe system will resonate, the pipe vibration will intensify, and there may even be a risk of breakage.

[0003] In practice, most air conditioners reduce vibration by adding vibration damping rings to the piping system to change its natural frequency. However, currently commonly used vibration damping rings can only be used with one type of pipe diameter, resulting in limited compatibility and poor versatility. Summary of the Invention

[0004] The problem solved by this invention is the technical issue of the shock absorber ring having a single pipe diameter and poor versatility, thereby achieving the technical effect of the same shock absorber ring being able to be used with multiple pipe diameters.

[0005] To address the aforementioned problems, the present invention provides a shock-absorbing ring for clamping pipelines. The shock-absorbing ring includes: a shock-absorbing ring body; and multiple clamping portions that extend axially through the shock-absorbing ring body; wherein at least two clamping portions are used to clamp pipelines of different diameters.

[0006] Compared with existing technologies, the technical advantages of this solution are as follows: The damping ring body has multiple clamping parts of different sizes, which can be used to clamp pipes of different diameters. When installing pipes, the damping ring in this solution can accommodate pipes of various sizes without the need to change the damping ring according to the pipe. The damping ring has greater versatility, achieving the technical effect of using the same damping ring to accommodate multiple pipe diameters.

[0007] In one embodiment of the present invention, the damping ring body is provided with a slit, which is opened along the side of the damping ring body and is used to communicate at least one of the multiple clamping parts with the outside.

[0008] Compared with existing technologies, the technical advantages of this solution are as follows: When installing the vibration damping ring and pipeline, if the pipeline is not yet connected to other devices and at least one end of the pipeline is free, one end of the pipeline can be inserted into the corresponding clamping part to connect the clamping part to the pipeline. When the pipeline is already fixedly connected and neither end can move freely, the vibration damping ring can be installed by opening a gap and fitting it over the pipeline. The gap facilitates the installation of the vibration damping ring and pipeline, making installation more convenient and efficient.

[0009] In one embodiment of the present invention, at least two adjacent clamping portions among a plurality of clamping portions are interconnected.

[0010] Compared with existing technologies, the technical advantages of this solution are as follows: The damping ring body is equipped with multiple clamping parts, with adjacent clamping parts interconnected. This interconnection saves internal space within the damping ring, resulting in a more compact structure and ensuring sufficient thickness around the clamping parts to maintain the damping effect. Furthermore, during installation, the interconnected clamping parts allow for the insertion of pipes into the damping ring through the gaps. The interconnected clamping parts also allow the pipes to move back and forth between the clamping parts until they are positioned within the appropriate clamping section.

[0011] In one embodiment of the present invention, the shock absorber further includes: a clamping baffle, which is disposed between any at least two adjacent clamping portions and is used to separate any at least two adjacent clamping portions; and an opening, which is disposed in the clamping baffle and communicates with each other between at least two adjacent clamping portions.

[0012] Compared with existing technologies, the technical effects achieved by this solution are as follows: the clamping baffles between the clamping parts ensure that each clamping part forms a complete accommodating space for securely clamping the pipeline. Furthermore, the clamping baffle material is an elastic material with strong deformation capacity. When there is a small mismatch between the pipeline size and the size of the clamping part, the deformation of the clamping baffle can adapt to the pipeline size. The openings ensure that the pipeline can move from one clamping part to another through the openings.

[0013] In one embodiment of the present invention, the clamping baffle extends from the damping ring body toward the sidewalls of the plurality of clamping parts and forms an integral structure with the damping ring body.

[0014] Compared with existing technologies, the technical advantages of this solution are: the clamping baffle and the damping ring body are integrated into a single structure, extending directly from the inner wall of the damping ring body, thus saving materials. Furthermore, no additional components need to be installed on the damping ring body, achieving a unified structure, saving materials and eliminating unnecessary processing and installation steps.

[0015] In one embodiment of the invention, the plurality of clamping portions include adjacent circular clamping portions and a first crescent-shaped clamping portion; the clamping baffle includes a first clamping baffle disposed between the circular clamping portions and the first crescent-shaped clamping portions; the first clamping baffle surrounds and defines at least a portion of the edge of the circular clamping portion and surrounds and defines at least a portion of the edge of a first concave arc of the first crescent-shaped clamping portion.

[0016] Compared with existing technologies, the technical effects achieved by this solution are as follows: A first clamping baffle is provided between the first crescent-shaped clamping part and the circular clamping part, separating the two parts into two independent receiving spaces. When a pipe is clamped by the circular clamping part, the first clamping baffle helps to clamp the pipe, facilitating adjustment of the size of the receiving space of the circular clamping part and providing a more secure clamping of the pipe. When a pipe is clamped by the first crescent-shaped clamping part, the first clamping baffle helps to clamp the pipe, facilitating adjustment of the size of the receiving space of the first crescent-shaped clamping part and providing a more secure clamping of the pipe.

[0017] In one embodiment of the present invention, the diameter of the first crescent-shaped clamping portion is larger than the diameter of the circular clamping portion.

[0018] Compared with existing technologies, the technical effects achieved by this solution are as follows: both the circular clamping part and the first crescent-shaped clamping part are used to clamp the pipeline, helping to fix it and reduce vibration. The cross-sectional diameter of the first crescent-shaped clamping part is larger than that of the circular clamping part, which makes it easier for the first crescent-shaped clamping part to clamp pipelines with larger diameters, and for the circular clamping part to clamp pipelines with smaller diameters.

[0019] In one embodiment of the invention, the plurality of clamping portions further include a second crescent-shaped clamping portion; the clamping baffle further includes a second clamping baffle disposed between the first crescent-shaped clamping portion and the second crescent-shaped clamping portion; the second clamping baffle surrounds at least a portion of the edge of a first convex arc defining the first crescent-shaped clamping portion and surrounds at least a portion of the edge of a second concave arc defining the second crescent-shaped clamping portion.

[0020] Compared with existing technologies, the technical effects achieved by this solution are as follows: A second clamping baffle is provided between the first crescent-shaped clamping part and the second crescent-shaped clamping part, separating the two parts into two independent receiving spaces. When a pipe is clamped by the first crescent-shaped clamping part, the second clamping baffle helps to tighten the pipe, facilitating adjustment of the size of the receiving space of the first crescent-shaped clamping part and providing a more secure clamping of the pipe. When a pipe is clamped by the second crescent-shaped clamping part, the second clamping baffle helps to tighten the pipe, facilitating adjustment of the size of the receiving space of the second crescent-shaped clamping part and providing a more secure clamping of the pipe.

[0021] In one embodiment of the present invention, the diameter of the second crescent-shaped clamping part is larger than the diameter of the first crescent-shaped clamping part.

[0022] Compared with existing technologies, the technical effects achieved by this solution are as follows: both the second crescent-shaped clamping part and the first crescent-shaped clamping part are used to clamp the pipeline, helping to fix it and reduce vibration. The cross-sectional diameter of the first crescent-shaped clamping part is smaller than that of the second crescent-shaped clamping part, which makes it easier for the second crescent-shaped clamping part to clamp pipelines with larger diameters, and for the first crescent-shaped clamping part to clamp pipelines with smaller diameters.

[0023] In one embodiment of the present invention, the shock absorber further includes a binding ring, which is disposed on the outer side of the shock absorber body and surrounds the outer side, and the binding ring is recessed relative to the surface of the shock absorber body.

[0024] Compared with existing technologies, the technical advantages achieved by this solution are as follows: A binding ring is provided on the outer surface of the shock absorber ring away from the clamping part, and the binding ring is recessed towards the clamping part. The shock absorber ring and the pipeline can be fixed in place by tying a rope to the binding ring.

[0025] In one embodiment of the present invention, the air conditioner includes: a pipe; and a shock-absorbing ring as described above, the shock-absorbing ring being used to clamp the pipe.

[0026] Compared with existing technologies, the technical effects achieved by this solution are as follows: The piping is installed on the air conditioner for the transport and flow of substances within the air conditioner. A vibration damping ring, as described above, is fitted onto the piping, effectively reducing vibration intensity within the air conditioner's piping. Furthermore, the vibration damping ring in this solution can be fitted onto pipes of different sizes, offering greater adaptability. It eliminates the need to manufacture other types of vibration damping rings, saving materials, improving material versatility, reducing complexity, and increasing production efficiency.

[0027] By adopting the technical solution of the present invention, the following technical effects can be achieved:

[0028] (1) By using clamping spaces of different sizes to accommodate different pipe diameters, the same shock absorber ring can be used for multiple pipe diameters, thereby improving the versatility of the shock absorber ring and improving production and assembly.

[0029] (2) The pipe diameter is fixed by clamping the baffle wall, and finally the pipe is further tightened and fixed by wire binding to ensure that the shock absorber ring does not loosen and improve stability;

[0030] (3) Multiple clamping spaces with different pipe diameters are designed inside the shock absorber ring, which reduces complexity and material management costs. Attached Figure Description

[0031] Figure 1 This is a schematic diagram of a shock-absorbing ring provided by the present invention.

[0032] Figure 2 This is one of the schematic diagrams of the cross-section of a damping ring.

[0033] Figure 3 This is the second schematic diagram of the cross-section of the damping ring.

[0034] Figure 4 This is a schematic diagram of the side structure of the shock absorber ring.

[0035] Figure 5 This is a schematic diagram of an air conditioner module.

[0036] Explanation of reference numerals in the attached figures:

[0037] 100-Damping ring; 110-Damping ring body; 111-Gap; 120-Multiple clamping parts; 121-Circular clamping part; 122-First crescent-shaped clamping part; 122a-First concave arc; 122b-First convex arc; 123-Second crescent-shaped clamping part; 123a-Second concave arc; 130-Clamping baffle; 130a-Opening; 131-First clamping baffle; 132-Second clamping baffle; 140-Binding ring; 200-Pipeline; 300-Air conditioner. Detailed Implementation

[0038] To make the above-mentioned objects, features and advantages of the present invention more apparent and understandable, specific embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

[0039] Example 1:

[0040] In one specific embodiment, see Figure 1 A shock-absorbing ring 100 is provided for clamping a pipe 200. The shock-absorbing ring 100 includes: a shock-absorbing ring body 110; a plurality of clamping parts 120, which penetrate the shock-absorbing ring body 110 axially; wherein at least two clamping parts are used to clamp pipes of different diameters.

[0041] In this embodiment, the pipeline 200 frequently vibrates during operation, causing wear. Therefore, a shock-absorbing ring 100 is used. The shock-absorbing ring 100 is fitted over the pipeline 200, and when the pipeline 200 vibrates, the shock-absorbing ring 100 acts as a damping agent. After the pipeline 200 is clamped by the shock-absorbing ring 100, it can be secured by binding the ring 100. The shock-absorbing ring 100 is generally made of an elastic material, such as rubber.

[0042] Furthermore, the shock absorber body 110 is cylindrical in shape, but can also be a cuboid, hexagonal prism, or other regular three-dimensional shape suitable for designing the snap-fit ​​proposed in this case. Multiple clamping portions 120 penetrate the shock absorber body 110 along its axis, forming a receiving space capable of clamping pipes of corresponding sizes. Generally, the clamping portions 120 do not penetrate the prototype through-hole of the shock absorber body 110. Multiple clamping portions 120 are provided, with at least two clamping portions 120 having different sizes, and the clamping portions 120 of different sizes can clamp pipes 200 of corresponding sizes. The shock absorber body 110 is provided with multiple clamping portions 120 of different sizes, which can be used to clamp pipes of different diameters. When the diameter of the pipe 200 is large, the pipe 200 is clamped by the clamping part 120 with a larger diameter on the damping ring 100; when the diameter of the pipe 200 is small, the pipe 200 is clamped by the clamping part 120 with a smaller diameter on the damping ring 100.

[0043] In this embodiment, the damping ring body 110 is provided with multiple clamping portions 120, which are of different sizes and can be used to clamp pipes of different diameters. When installing pipes 200, the damping ring 100 of this invention can meet the needs of various pipes 200 of different sizes, without the need to replace the damping ring 100 according to the pipe 200. The damping ring 100 has greater versatility, achieving the technical effect of using the same damping ring to accommodate multiple pipe diameters.

[0044] Example 2:

[0045] In one specific embodiment, see Figure 1 The damping ring body 110 is provided with a slot 111, which is opened along the side of the damping ring body 110. The slot 111 is used to connect at least one of the multiple clamping parts 120 to the outside.

[0046] In this embodiment, the slot 111 is a long and narrow slit formed on the damping ring body 110. The slot 111 extends axially through the damping ring body 110; and the slot 111 on the damping ring body 110 extends inward from the outer surface of the damping ring body 110 until the clamping part 120 is connected to the outer surface of the damping ring body 110, and the clamping part 120 can be connected to the outside through the slot 111.

[0047] Furthermore, when using the damping ring 100, the damping ring body 110 is made of elastic material and is prone to deformation, allowing the pipe 200 to enter the clamping part 120 through the gap 111. Specifically, the damping ring 100 can be opened from the gap 111 to allow the pipe 200 to be placed into the clamping part 120.

[0048] In this embodiment, when installing the shock absorber 100 and the pipe 200, if the pipe 200 is not yet connected to other devices and at least one end of the pipe 200 is free, one end of the pipe 200 can be inserted into the corresponding clamping part 120 to connect the clamping part 120 to the pipe 200. When the pipe 200 is already fixedly connected and neither end can move freely, the shock absorber 100 can be installed by opening the gap 111 and fitting it over the pipe 200. The gap 111 facilitates the installation of the shock absorber 100 and the pipe 200, making installation more convenient and efficient.

[0049] Example 3:

[0050] In one specific embodiment, see Figure 1 At least two adjacent clamping parts among the plurality of clamping parts 120 are interconnected.

[0051] In this embodiment, the damping ring body 110 is provided with a plurality of clamping portions 120, and adjacent clamping portions 120 are interconnected. The interconnection of the clamping portions 120 saves space inside the damping ring 100, making the structure of the clamping portions 120 more compact and ensuring that the damping ring body 110 around the clamping portions 120 has thickness, thus maintaining the damping effect. Furthermore, during installation, the interconnected clamping portions 120 allow the pipe 200 to be installed into the damping ring 100 through the gap 111, and the interconnected clamping portions 120 allow the pipe 200 to move back and forth between the clamping portions 120 until it is positioned within a suitable clamping portion 120.

[0052] Example 4:

[0053] In one specific embodiment, see Figure 1 The shock absorber ring 100 further includes: a clamping baffle 130, which is disposed between any at least two adjacent clamping portions and is used to separate any at least two adjacent clamping portions; and an opening 130a, which is disposed in the clamping baffle 130 and at least two adjacent clamping portions are interconnected through the opening 130a.

[0054] In this embodiment, the multiple clamping portions 120 in the above embodiments are arranged in a compact structure, and adjacent clamping portions 120 are interconnected. A clamping baffle 130 is provided between the connected clamping portions 120 to prevent large-area connection between them. The clamping baffle 130 ensures that each clamping portion 120 can form a complete space to accommodate the pipe 200, and the integrity of each clamping portion 120 is not compromised due to interconnection. Furthermore, the clamping baffle 130 has the effect of fixing the pipe 200 within the clamping portion 120. Further, an opening 130a is provided on the clamping baffle 130, which also ensures communication between the clamping portions 120. This ensures that the pipe 200 can move from one clamping portion to another through the opening 130a.

[0055] In this embodiment, the clamping baffles 130 between the clamping portions 120 ensure that each clamping portion 120 forms a complete receiving space for securely clamping the pipe 200. Furthermore, the clamping baffles 130 are made of an elastic material with strong deformation capacity. When there is a small mismatch between the dimensions of the pipe 200 and the clamping portion 120, the deformation of the clamping baffles 130 can accommodate the dimensions of the pipe 200. The opening 130a ensures that the pipe 200 can move from one clamping portion to another through the opening 130a.

[0056] Example 5:

[0057] In one specific embodiment, see Figure 1 The clamping baffle 130 extends from the damping ring body 110 toward the side wall of the plurality of clamping parts 120 and forms an integral structure with the damping ring body 110.

[0058] In this embodiment, the clamping baffle 130 and the damping ring body 110 are an integral structure, extending directly from the inner wall of the damping ring body 110, saving materials. Furthermore, no additional components need to be installed on the damping ring body 110, achieving an integrated structure, saving materials and eliminating unnecessary processing and installation steps.

[0059] Example 6:

[0060] In one specific embodiment, see Figure 1 The plurality of clamping portions 120 include adjacent circular clamping portions 121 and first crescent-shaped clamping portions 122; the clamping baffle 130 includes a first clamping baffle 131 disposed between the circular clamping portions 121 and the first crescent-shaped clamping portions 122; the first clamping baffle 131 surrounds and defines at least a portion of the edge of the circular clamping portion 121, and surrounds and defines at least a portion of the edge of the first concave arc 122a of the first crescent-shaped clamping portion 122. The diameter of the first crescent-shaped clamping portion 122 is larger than the diameter of the circular clamping portion 121.

[0061] In this embodiment, multiple clamping portions 120 are interconnected. Specifically, the multiple clamping portions 120 are arranged sequentially according to the diameter of the through hole cross-section, forming a structure in which adjacent clamping portions are connected. Among them, the clamping portion with the smallest cross-sectional diameter is the circular clamping portion 121, and the clamping portion adjacent to and connected to the circular clamping portion 121 is the first crescent-shaped clamping portion 122. The circular clamping portion 121 has a circular cross-section and the smallest diameter. The cross-sectional diameter of the first crescent-shaped clamping portion 122 is larger than that of the circular clamping portion 121, and the first crescent-shaped clamping portion 122 is connected to the circular clamping portion 121.

[0062] Furthermore, a first clamping baffle 131 is provided between the first crescent-shaped clamping part 122 and the circular clamping part 121. The first clamping baffle 131 separates the first crescent-shaped clamping part 122 from the circular clamping part 121, forming two independent receiving spaces.

[0063] Furthermore, the circular clamping portion 121 has a circular cross-section, and at least a portion of its edge is surrounded by the first clamping baffle 131; the first crescent-shaped clamping portion 122 has a crescent-shaped cross-section, and the first concave arc 122a of the crescent shape is formed by the first clamping baffle 131. Specifically, the first clamping baffle 131 is arc-shaped, with one side of the arc being concave relative to the circular clamping portion 121 and convex relative to the first crescent-shaped clamping portion 122. The concave side is integrally formed with the circular clamping portion 121 to form a circular cross-section, and the convex side is integrally formed with the first crescent-shaped clamping portion 122 to form a crescent-shaped cross-section.

[0064] In this embodiment, both the circular clamping part 121 and the first crescent-shaped clamping part 122 are used to clamp the pipe 200, helping to fix it and dampen vibration. The cross-sectional diameter of the first crescent-shaped clamping part 122 is larger than that of the circular clamping part 121, making it easier for the first crescent-shaped clamping part 122 to clamp pipes 200 with larger diameters, and for the circular clamping part 121 to clamp pipes 200 with smaller diameters. When a pipe 200 is clamped by the circular clamping part 121, the first clamping baffle 131 helps to tighten the pipe 200, making it easier to adjust the size of the accommodating space of the circular clamping part 121 for a more secure clamping of the pipe 200. When a pipe 200 is clamped by the first crescent-shaped clamping part 122, the first clamping baffle 131 helps to tighten the pipe 200, making it easier to adjust the size of the accommodating space of the first crescent-shaped clamping part 122 for a more secure clamping of the pipe 200.

[0065] Example 7:

[0066] In one specific embodiment, see Figure 1The plurality of clamping portions 120 further include a second crescent-shaped clamping portion 123; the clamping baffle 130 further includes a second clamping baffle 132 disposed between the first crescent-shaped clamping portion 122 and the second crescent-shaped clamping portion 123; the second clamping baffle 132 surrounds and defines at least a portion of the edge of the first outwardly convex arc 122b of the first crescent-shaped clamping portion 122, and surrounds and defines at least a portion of the edge of the second inwardly concave arc 123a of the second crescent-shaped clamping portion 123. The diameter of the second crescent-shaped clamping portion 123 is larger than the diameter of the first crescent-shaped clamping portion 122.

[0067] In this embodiment, multiple clamping portions 120 are interconnected. Specifically, the multiple clamping portions 120 are arranged sequentially according to the diameter of the through hole cross-section, forming a structure in which adjacent clamping portions are connected. The clamping portion adjacent to the first crescent-shaped clamping portion 122 in the above embodiment is the second crescent-shaped clamping portion 123; the two are adjacent and connected. Both the first crescent-shaped clamping portion 122 and the second crescent-shaped clamping portion 123 have crescent-shaped cross-sections. The cross-sectional area of ​​the first crescent-shaped clamping portion 122 is smaller than that of the second crescent-shaped clamping portion 123, and the second crescent-shaped clamping portion 123 is adapted to pipes 200 with larger diameters. In conjunction with the previous embodiment, one side of the first crescent-shaped clamping portion 122 is adjacent to and connected to the circular clamping portion 121, and the other side is adjacent to and connected to the second crescent-shaped clamping portion 123.

[0068] Furthermore, a second clamping baffle 132 is provided between the first crescent-shaped clamping part 122 and the second crescent-shaped clamping part 123, which separates the first crescent-shaped clamping part 122 and the second crescent-shaped clamping part 123, forming two independent receiving spaces.

[0069] Furthermore, at least a portion of the edge of the second crescent-shaped clamping portion 123 is surrounded by the second clamping baffle 132; the cross-section of the first crescent-shaped clamping portion 122 is crescent-shaped, and the second concave arc 123a of the crescent shape is formed by the second clamping baffle 132. Specifically, the second clamping baffle 132 is arc-shaped, with one side of the arc being concave relative to the first crescent-shaped clamping portion 122 and convex relative to the second crescent-shaped clamping portion 123. The concave side is integrally formed with the first crescent-shaped clamping portion 122 to form a circular arc surface, and the convex side is integrally formed with the second crescent-shaped clamping portion 123 to form a crescent-shaped cross-section.

[0070] In this embodiment, both the second crescent-shaped clamping part 123 and the first crescent-shaped clamping part 122 are used to clamp the pipe 200, helping to fix it and dampen vibration. The cross-sectional diameter of the first crescent-shaped clamping part 122 is smaller than that of the second crescent-shaped clamping part 123, which makes it easier for the second crescent-shaped clamping part 123 to clamp pipes 200 with larger diameters, and for the first crescent-shaped clamping part 122 to clamp pipes 200 with smaller diameters. When a pipe 200 is clamped by the first crescent-shaped clamping part 122, the second clamping baffle 132 can help to clamp the pipe 200 tightly, making it easy to adjust the size of the accommodating space of the first crescent-shaped clamping part 122 for a more secure clamping of the pipe 200. When a pipe 200 is clamped by the second crescent-shaped clamping part 123, the second clamping baffle 132 can help clamp the pipe 200, making it easier to adjust the size of the accommodating space of the second crescent-shaped clamping part 123, and clamping the pipe 200 more securely.

[0071] Example 8:

[0072] In one specific embodiment, see Figure 1 The shock absorber 100 also includes a binding ring 140, which is located on the outer side of the shock absorber body 110 and surrounds the outer side. The binding ring 140 is recessed relative to the surface of the shock absorber body 110.

[0073] In this embodiment, a binding ring 140 is provided on the outer surface of the shock-absorbing ring 100 away from the clamping part 120, and the binding ring 140 is recessed towards the clamping part 120. The shock-absorbing ring 100 and the pipeline 200 can be fixed by binding the rope to the binding ring 140.

[0074] Example 9:

[0075] In one specific embodiment, see Figure 1 The air conditioner 300 includes: a pipe 200; and a shock absorber 100, as described above, which is used to clamp the pipe 200.

[0076] In this embodiment, the pipe 200 is installed on the air conditioner 300 for the transport and flow of materials within the air conditioner 300. A vibration damping ring 100 is fitted onto the pipe 200. This vibration damping ring 100 is the same as described in the previous embodiment, which can reduce the vibration intensity of the pipe 200 within the air conditioner 300, effectively reducing vibration. Furthermore, the vibration damping ring 100 in this embodiment can be fitted onto pipes 200 of different sizes, offering greater adaptability. It eliminates the need to process other types of vibration damping rings, saving materials, improving material versatility, reducing complexity, and increasing production efficiency.

[0077] While the present invention has been disclosed above, it is not limited thereto. Any person skilled in the art can make various modifications and alterations without departing from the spirit and scope of the invention; therefore, the scope of protection of the present invention should be determined by the scope defined in the claims.

Claims

1. A shock-absorbing ring, characterized in that, The damping ring (100) is used to clamp the pipeline (200), and the damping ring (100) includes: The damping ring body (110); Multiple clamping portions (120) extend axially through the damping ring body (110); the multiple clamping portions (120) include adjacent circular clamping portions (121) and a first crescent-shaped clamping portion (122), the diameter of the first crescent-shaped clamping portion (122) being larger than the diameter of the circular clamping portion (121); A clamping baffle (130) is disposed between any at least two adjacent clamping portions and is used to separate the at least two adjacent clamping portions; the clamping baffle (130) is made of an elastic material; the clamping baffle (130) includes a first clamping baffle (131) disposed between the circular clamping portion (121) and the first crescent-shaped clamping portion (122), the first clamping baffle (131) being able to adjust the size of the accommodating space of the circular clamping portion (121); An opening (130a) is provided on the clamping baffle (130), and the at least two adjacent clamping parts are interconnected through the opening (130a). At least two of the clamping parts (120) are used to clamp pipes (200) of different diameters, and the pipes (200) can move back and forth between the clamping parts (120).

2. The shock absorber ring according to claim 1, characterized in that, The damping ring body (110) is provided with a slot (111), which is opened along the side of the damping ring body (110). The slot (111) is used to connect at least one of the plurality of clamping parts (120) to the outside.

3. The shock absorber ring according to claim 1, characterized in that, At least two adjacent clamping parts (120) are interconnected.

4. The shock absorber ring according to claim 3, characterized in that, The clamping baffle (130) extends from the damping ring body (110) toward the sidewalls of the plurality of clamping parts (120) and forms an integral structure with the damping ring body (110).

5. The shock absorber ring according to claim 3, characterized in that, The first clamping barrier (131) surrounds and defines at least a portion of the edge of the circular clamping portion (121), and surrounds and defines at least a portion of the edge of the first concave arc (122a) of the first crescent-shaped clamping portion (122).

6. The shock absorber ring according to claim 5, characterized in that, The plurality of clamping portions (120) further include a second crescent-shaped clamping portion (123); the clamping baffle (130) further includes a second clamping baffle (132) disposed between the first crescent-shaped clamping portion (122) and the second crescent-shaped clamping portion (123); The second clamping barrier (132) surrounds and defines at least a portion of the edge of the first convex arc (122b) of the first crescent-shaped clamping portion (122), and surrounds and defines at least a portion of the edge of the second concave arc (123a) of the second crescent-shaped clamping portion (123).

7. The shock absorber ring according to any one of claims 1 to 6, characterized in that, The damping ring (100) also includes: A strapping ring (140) is provided on the outer side of the shock absorber body (110) and surrounds the outer side. The strapping ring (140) is recessed relative to the surface of the shock absorber body (110).

8. An air conditioner, characterized in that, The air conditioner (300) includes: a pipe (200); and a shock-absorbing ring (100) as described in any one of claims 1 to 7, the shock-absorbing ring (100) being used to clamp the pipe (200).