A curved shell structure shock absorbing connector

By designing a curved shell structure shock-absorbing connector, the problem of the TV wall mount not being able to be adjusted in all directions was solved, enabling multi-directional adjustment and shock absorption, thus improving the user experience.

CN224470015UActive Publication Date: 2026-07-07CHENGDU BOYAN NEW MATERIAL TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
CHENGDU BOYAN NEW MATERIAL TECH CO LTD
Filing Date
2025-09-16
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Existing TV wall mounts cannot be fully adjusted, which makes it inconvenient to use the monitor when using a gaming chair as the screen cannot be adjusted freely.

Method used

A curved shell structure damping connector was designed, including components such as a connecting block, a T-shaped slide bar, a sleeve, an arc block, and a slider. Through sliding and rotational connection, it can achieve multi-faceted adjustment and limiting, thereby enhancing stability and damping effect.

Benefits of technology

The curved shell allows for multi-faceted adjustment, making it easy to use. It also improves stability and enhances the user experience through limiting and shock absorption functions.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a curved surface shell structure damping connecting piece, specifically related to supporting accessory related technical field, including curved surface shell body, the lower surface of curved surface shell body is provided with connecting mechanism, the connecting mechanism includes connecting block no.
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Description

Technical Field

[0001] This utility model relates to the technical field of support accessories, and more specifically, it relates to a shock-absorbing connector for a curved shell structure. Background Technology

[0002] With technological advancements, curved screen TVs are gaining popularity due to their unrestricted viewing angles, excellent contrast, and enhanced immersive experience. However, because the back of a curved screen TV is curved, while existing TV wall mounts have flat mounting surfaces;

[0003] A search revealed that publication number CN221324072U discloses a TV wall mount suitable for curved screen TVs. This mount uses a base plate assembly, a folding arm assembly, and a mounting plate assembly to fix the TV to the wall. The support member features a movable design consisting of several sleeves and connectors inserted into adjacent sleeves. Both ends of the support member can move away from the wall, allowing the support member to exhibit a curvature similar to the back of a curved screen. This effectively improves the fit between the TV wall mount and the back of the curved screen TV, avoiding the need for extended screws and improving overall structural stability. The inventors discovered the following problems with the existing technology during the development of this invention:

[0004] However, since most computer cases cannot be fully adjusted after being connected, and most people use gaming chairs when using computers, the screen cannot be adjusted according to their preferences after adjusting the gaming chair, which makes it inconvenient to use.

[0005] Therefore, a curved shell structure vibration damping connector is proposed to address the above problems. Utility Model Content

[0006] In order to overcome the above-mentioned defects of the prior art, the present invention provides a curved shell structure shock-absorbing connector to solve the problems mentioned in the background art.

[0007] To achieve the above objectives, this utility model provides the following technical solution: a curved shell structure shock-absorbing connector, comprising a curved shell body, a connecting mechanism provided on the lower surface of the curved shell body, the connecting mechanism comprising a first connecting block, the first connecting block being fixedly connected to the lower surface of the curved shell body, a second connecting block penetrating through the rear surface of the first connecting block and being slidably connected to the second connecting block, a bolt penetrating through the outer arc surface of the first connecting block and being rotatably connected to the bolt, the bolt penetrating through the second connecting block and being threadedly connected to the second connecting block, a T-shaped sliding rod slidably connected to the inner surface of the first connecting block, a sleeve slidably connected to the outer arc surface of the T-shaped sliding rod, and an arc-shaped block fixedly connected to the lower surface of the sleeve.

[0008] Preferably, a slider is provided on the lower surface of the curved shell body, and a U-shaped plate is slidably connected to the lower surface of the slider.

[0009] Preferably, the upper surface of the slider is provided with a groove, and the groove is rotatably connected to the arc-shaped block.

[0010] Preferably, the outer arc surface of the sleeve is provided with a fixing mechanism, the fixing mechanism including a positioning block, the positioning block being fixedly connected to the outer arc surface of the sleeve, a tapered rod penetrating through the left surface of the positioning block and being slidably connected to the tapered rod, the tapered rod being fixedly connected to one end of the first spring, and the positioning block being fixedly connected to the other end of the first spring.

[0011] Preferably, the outer arc surface of the T-shaped slide bar has circular grooves arranged in a linear array, and the circular grooves are slidably connected to the tapered rod.

[0012] Preferably, a rotating shaft is fixedly connected to the left surface of the arc-shaped block, and triangular grooves are formed in a circular array on the left surface of the rotating shaft. A triangular block is slidably connected to the inner surface of the triangular groove. The triangular block passes through the slider and is slidably connected to the slider. The triangular block is fixedly connected to one end of the second spring, and the slider is fixedly connected to the other end of the second spring. A pin passes through the left surface of the slider and is slidably connected to the pin. The pin passes through the triangular block and is slidably connected to the triangular block.

[0013] Preferably, the upper surface of the U-shaped plate has screw holes arranged in a linear array, and the rear surface of the slider is provided with a mounting plate.

[0014] The technical effects and advantages of this utility model are as follows:

[0015] 1. Compared with the prior art, this curved shell structure shock-absorbing connector, through the setting of connecting block one, connecting block two, T-shaped slide bar and slider, can support the curved shell body while making multi-faceted adjustments to the curved shell body, making the curved shell body more convenient to use.

[0016] 2. Compared with the prior art, this curved shell structure shock-absorbing connector, through the setting of positioning blocks, conical rods, circular grooves, triangular blocks and rotating shafts, can limit the adjustment of the curved shell body, ensure that the adjusted curved shell body has the function of shock absorption, and effectively improve the stability of the entire curved shell body. Attached Figure Description

[0017] Figure 1 This is a schematic diagram of the overall structure of this utility model.

[0018] Figure 2 For the present utility model Figure 1 Schematic diagram of part A in the middle.

[0019] Figure 3 For the present utility model Figure 1 Schematic diagram of part B in the middle section.

[0020] Figure 4 This is a schematic diagram showing the positional relationship between connecting block one and connecting block two of this utility model.

[0021] The attached figures are labeled as follows: 1. Curved shell body; 2. Connecting mechanism; 21. Connecting block one; 22. Connecting block two; 23. Bolt; 24. T-shaped slide bar; 25. Sleeve; 26. Arc-shaped block; 27. Slider; 28. U-shaped plate; 29. ​​Groove; 3. Fixing mechanism; 31. Positioning block; 32. Tapered rod; 33. Spring one; 34. Circular groove; 35. Rotating shaft; 36. Triangular groove; 37. Triangular block; 38. Spring two; 39. Pin; 310. Screw hole; 311. Mounting plate. Detailed Implementation

[0022] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0023] Example 1

[0024] As attached Figures 1 to 4The illustrated curved shell structure vibration damping connector includes a curved shell body 1. A connecting mechanism 2 is provided on the lower surface of the curved shell body 1. The connecting mechanism 2 includes a first connecting block 21, which is fixedly connected to the lower surface of the curved shell body 1. A second connecting block 22 passes through the rear surface of the first connecting block 21 and is slidably connected to the second connecting block 22. Damping material can be added at the sliding connection between the first connecting block 21 and the second connecting block 22. The damping material can dissipate vibration energy and reduce vibration transmission when the two slide relative to each other. At the same time, a damping device can also be provided at the sliding part of the T-shaped slide bar 24 and the sleeve 25 to further enhance the vibration damping performance. The first connecting block 21 is tightly fixedly connected to the lower surface of the curved shell body 1, providing a stable foundation for the entire connecting mechanism 2. Connecting block 22 penetrates the rear surface of connecting block 1 21, forming a sliding connection. This connection allows connecting block 22 to slide flexibly on connecting block 1 21, increasing the adjustability of the structure. Bolt 23 penetrates the outer arc surface of connecting block 1 21 and is rotatably connected to bolt 23. Bolt 23 penetrates connecting block 22 and is threadedly connected to connecting block 22. T-shaped slide rod 24 is slidably connected to the inner surface of connecting block 1 21. The unique shape design of T-shaped slide rod 24 ensures its stability when sliding on the inner surface of connecting block 1 21 and prevents it from easily coming off. Sleeve 25 is slidably connected to the outer arc surface of T-shaped slide rod 24, allowing sleeve 25 to move flexibly along the outer arc surface of T-shaped slide rod 24. An arc-shaped block 26 is fixedly connected to the lower surface of the sleeve 25. The design of the arc-shaped block 26 can not only buffer vibration to a certain extent, but also cooperate with other components to achieve specific connection functions. The outer arc surface of the T-shaped slide rod 24 is slidably connected to the sleeve 25, and the lower surface of the sleeve 25 is fixedly connected to the arc-shaped block 26. The lower surface of the curved shell body 1 is provided with a slider 27. This connection method allows the curved shell body 1 to slide relative to the U-shaped plate 28 to a certain extent, providing additional shock absorption space for the entire structure. The upper surface of slider 27 has a groove 29, which is rotatably connected to arc-shaped block 26. This rotatable connection allows arc-shaped block 26 to rotate flexibly within the groove 29, further enhancing the flexibility and adaptability of the structure. When subjected to vibration, it can better disperse and absorb energy, achieving a good shock absorption effect. A U-shaped plate 28 is slidably connected to the lower surface of slider 27. The upper surface of slider 27 also has a groove 29, which is rotatably connected to arc-shaped block 26. The curved shell body 1 is made of high-strength alloy material and manufactured using precision casting technology to ensure the accuracy of its curved shape and structural strength. Components such as connecting block 1 21, connecting block 22, T-shaped slide rod 24, sleeve 25, arc-shaped block 26, slider 27, and U-shaped plate 28 can be made of suitable metal materials according to actual needs. CNC machining technology is used to ensure the dimensional accuracy and fit accuracy of each component, thereby guaranteeing the performance and reliability of the entire shock-absorbing connector.

[0025] Specifically: Adjust bolt 23 to position and tighten connecting block 22. Then install the T-shaped slide bar 24, sleeve 25, and arc-shaped block 26 into place. Finally, rotate the arc-shaped block 26 to connect it to the groove 29 on the slider 27, completing the installation of the entire curved shell structure damping connector. After installation, comprehensive debugging and testing are required to ensure that all components are firmly connected, sliding and rotating parts are flexible, and the damping performance meets design requirements.

[0026] Example 2

[0027] Based on Example 1, the solution in Example 1 will be further described in detail below with reference to the specific working method, such as... Figures 1 to 4 As shown in the following detailed description: A fixing mechanism 3 is provided on the outer arc surface of the sleeve 25. The fixing mechanism 3 includes a positioning block 31, which is fixedly connected to the outer arc surface of the sleeve 25. A tapered rod 32 passes through the left surface of the positioning block 31 and is slidably connected to the tapered rod 32. One end of the tapered rod 32 is fixedly connected to a spring 33, and the other end of the positioning block 31 is fixedly connected to the spring 33. The spring 33 acts as an elastic element here. Utilizing its own elastic properties, when the tapered rod 32 is displaced by an external force, the spring 33 can provide a corresponding elastic force, so that the tapered rod 32 can return to its initial position after the external force is removed, thereby ensuring that the fixing mechanism 3 can repeatedly and stably perform its function.

[0028] In a preferred embodiment, the outer arc surface of the T-shaped slide bar 24 is provided with circular grooves 34 in a linear array. The circular grooves 34 are slidably connected to the tapered rod 32. This linear array layout means that the circular grooves 34 are arranged sequentially along a specific straight line direction on the outer arc surface of the T-shaped slide bar 24, according to a certain rule, at equal intervals, or in a certain logical order.

[0029] In a preferred embodiment, a rotating shaft 35 is fixedly connected to the left surface of the arc-shaped block 26. The left surface of the rotating shaft 35 has triangular grooves 36 arranged in a circumferential array. A triangular block 37 is slidably connected to the inner surface of the triangular groove 36. The triangular block 37 passes through the slider 27 and is slidably connected to the slider 27. One end of the triangular block 37 is fixedly connected to the second spring 38, and the other end of the slider 27 is fixedly connected to the second spring 38. A pin 39 passes through the left surface of the slider 27 and is slidably connected to the pin 39. The pin 39 passes through the triangular block 37 and is slidably connected to the triangular block 37. This design allows the pin 39 to play an adjustment and positioning role between the slider 27 and the triangular block 37. By controlling the position of the pin 39, the sliding state of the triangular block 37 in the triangular groove 36 can be flexibly adjusted, thereby achieving precise control of the motion state of the entire mechanical structure.

[0030] In a preferred embodiment, the upper surface of the U-shaped plate 28 is provided with screw holes 310 in a linear array, and the rear surface of the slider 27 is provided with a mounting plate 311. The presence of the mounting plate 311 can further expand the function of the slider 27. It may be used to install other related parts, sensors or actuators, etc., by mounting these components on the mounting plate 311.

[0031] The working process of this utility model is as follows: First, the sleeve 25 is fitted onto the outer arc surface of the T-shaped slide rod 24 and can slide, allowing the sleeve 25 to move along the direction of the T-shaped slide rod 24 under the constraint of the connecting block 1 21. At the same time, the T-shaped slide rod 24 can rotate in a relatively loose state through the connecting block 1 21 and the connecting block 22, making adjustment more convenient. When the tapered rod 32 is inserted into the circular groove 34 under the action of the spring 1 33, it can prevent the sleeve 25 from sliding relative to the positioning block 31, thereby fixing the relative position of the sleeve 25 and the connecting block 1 21, ensuring that the connecting mechanism 2 works stably in the set state. At the same time, the T-shaped slide rod 24 can slide freely up and down inside the sleeve 25, and the circular groove 34 will squeeze the tapered rod 24. The curved surface of the conical rod 32 causes the conical rod 32 to stretch the spring 33 and move out of the circular groove 34. After the T-shaped slide rod 24 comes to a stop, the spring 33 springs the conical rod 32 back into the circular groove 34, limiting the T-shaped slide rod 24 and thus limiting the height of the entire curved shell body 1. At the same time, in conjunction with the triangular block 37, after the pin 39 is pulled out of the triangular block 37, when the rotating shaft 35 rotates through the arc block 26, it will squeeze the inclined surface of the triangular block 37. After the arc block 26 comes to a stop, the triangular block 37 is springed into the triangular groove 36 by the elastic force of the spring 38, and the pin 39 is reinserted into the triangular block 37. The above is the working principle of this kind of curved shell structure shock-absorbing connector.

Claims

1. A vibration damping connector for a curved shell structure, comprising a curved shell body (1), characterized in that: The lower surface of the curved shell body (1) is provided with a connecting mechanism (2). The connecting mechanism (2) includes a connecting block one (21). The connecting block one (21) is fixedly connected to the lower surface of the curved shell body (1). The rear surface of the connecting block one (21) is penetrated by a connecting block two (22) and is slidably connected to the connecting block two (22). The outer arc surface of the connecting block one (21) is penetrated by a bolt (23) and is rotatably connected to the bolt (23). The bolt (23) penetrates the connecting block two (22) and is threadedly connected to the connecting block two (22). The inner surface of the connecting block one (21) is slidably connected to a T-shaped slide rod (24). The outer arc surface of the T-shaped slide rod (24) is slidably connected to a sleeve (25). The lower surface of the sleeve (25) is fixedly connected to an arc-shaped block (26).

2. The shock-absorbing connector for a curved shell structure according to claim 1, characterized in that: The lower surface of the curved shell body (1) is provided with a slider (27), and a U-shaped plate (28) is slidably connected to the lower surface of the slider (27).

3. The shock-absorbing connector for a curved shell structure according to claim 2, characterized in that: The upper surface of the slider (27) is provided with a groove (29), and the groove (29) is rotatably connected to the arc block (26).

4. A vibration damping connector for a curved shell structure according to claim 3, characterized in that: The outer arc surface of the sleeve (25) is provided with a fixing mechanism (3). The fixing mechanism (3) includes a positioning block (31). The positioning block (31) is fixedly connected to the outer arc surface of the sleeve (25). A tapered rod (32) passes through the left surface of the positioning block (31) and is slidably connected to the tapered rod (32). The tapered rod (32) is fixedly connected to one end of the spring (33). The positioning block (31) is fixedly connected to the other end of the spring (33).

5. A vibration damping connector for a curved shell structure according to claim 4, characterized in that: The outer arc surface of the T-shaped slide bar (24) is provided with circular grooves (34) in a linear array, and the circular grooves (34) are slidably connected to the tapered rod (32).

6. A vibration damping connector for a curved shell structure according to claim 5, characterized in that: A rotating shaft (35) is fixedly connected to the left surface of the arc-shaped block (26). A triangular groove (36) is formed in a circular array on the left surface of the rotating shaft (35). A triangular block (37) is slidably connected to the inner surface of the triangular groove (36). The triangular block (37) passes through the slider (27) and is slidably connected to the slider (27). The triangular block (37) is fixedly connected to one end of the second spring (38). The slider (27) is fixedly connected to the other end of the second spring (38). A pin (39) passes through the left surface of the slider (27) and is slidably connected to the pin (39). The pin (39) passes through the triangular block (37) and is slidably connected to the triangular block (37).

7. A vibration damping connector for a curved shell structure according to claim 6, characterized in that: The upper surface of the U-shaped plate (28) is provided with screw holes (310) in a linear array, and the rear surface of the slider (27) is provided with a mounting plate (311).