Integrated LED photoelectric glass mounting structure
By using an integrated LED optoelectronic glass installation structure and integrating the guide structure and positioning components, the problems of low installation efficiency and stress concentration are solved, achieving efficient and stable LED optoelectronic glass installation.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- FUJIAN TONGHUI OPTOELECTRONICS CO LTD
- Filing Date
- 2025-06-24
- Publication Date
- 2026-07-14
AI Technical Summary
The existing frame-type installation method results in low installation efficiency of LED optoelectronic glass and is prone to causing local stress concentration, increasing the probability of damage.
The integrated LED optoelectronic glass mounting structure includes a fixed part and a movable part. By utilizing a guide structure, positioning components and fixing components, the integrated design improves installation efficiency and stability and avoids stress concentration.
It improves the installation efficiency and stability of LED optoelectronic glass, reduces the probability of damage, and enhances the ease of operation and clamping and fixing effect.
Smart Images

Figure CN224501438U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of LED optoelectronic glass technology, specifically to an integrated LED optoelectronic glass mounting structure. Background Technology
[0002] LED optoelectronic glass, as a smart material integrating LED display technology and transparent glass substrate, exhibits unique transparent display and dynamic lighting functions in fields such as building curtain walls and commercial displays. Currently, the industry mainly adopts four installation methods: frame-type, point-supported, adhesive-bonded, and modular. Among them, frame-type installation has become the preferred solution for large-area splicing scenarios due to its excellent load-bearing performance.
[0003] Existing frame-type installation methods typically employ multi-point bolt locking mechanisms, requiring multiple bolt tightenings at each edge of a single LED optoelectronic glass panel. This reduces installation efficiency and makes it difficult to accurately control the torque consistency of all bolts, easily leading to localized stress concentration in the LED optoelectronic glass and increasing the probability of damage. Based on this, this application proposes an integrated LED optoelectronic glass installation structure. Utility Model Content
[0004] This utility model provides an integrated LED optoelectronic glass mounting structure, which solves the problems mentioned in the background art, such as the low installation efficiency of using bolts to lock the LED optoelectronic glass, the easy occurrence of local stress concentration in the LED optoelectronic glass, and the increased probability of damage to the LED optoelectronic glass.
[0005] This utility model provides the following technical solution: an integrated LED optoelectronic glass mounting structure, including a fixed part and a movable part. A guide structure is provided on one side of the fixed part. The movable part is movably connected to the middle of the guide structure, and a positioning groove is provided in the middle of the guide structure. Support blocks for supporting LED optoelectronic glass are symmetrically arranged on the side of the fixed part near the movable part. A fixing groove is provided at the end of the support block away from the fixed part. The movable part is a hollow structure. A fixing component adapted to the support block is provided in the inner cavity of the movable part. A positioning component adapted to the positioning groove is provided in the inner cavity of the movable part. The power input end of the fixing component and the power input end of the positioning component are connected through a handle.
[0006] Preferably, the guide structure includes a guide block connected to the fixing part, and guide blocks are provided at both ends on one side of the fixing part. A guide sleeve is movably fitted around the outer ring of the guide block. The guide block and the guide sleeve are connected by a first spring. The two guide sleeves are connected by a connecting shaft. Positioning grooves are provided at both ends of the top of the connecting shaft.
[0007] Preferably, the fixing assembly includes a plug rod movably connected to the inner cavity of the movable part and a positioning block movably connected to the inner cavity of the movable part. The plug rod is connected to the movable part via a second spring, and the end of the plug rod is adapted to the fixing groove. The plug rod is connected to the handle via a pull rope. The positioning block is connected to the movable part via a third spring.
[0008] Preferably, positioning blocks are provided at both ends of the inner cavity of the movable part, and an insertion hole that is adapted to both the positioning block and the support block is provided on the side of the inner cavity of the movable part near the support block, and the positioning block and the insertion hole are on the same straight line.
[0009] Preferably, the positioning component includes a positioning sleeve adapted to the positioning groove and a push rod movably connected to the movable part. The positioning block is movably connected to the inner cavity of the positioning sleeve. The positioning sleeve is connected to the movable part through a fourth spring. The push rod is connected to the handle.
[0010] Preferably, the axes of the second spring, the third spring, and the fourth spring are perpendicular to each other.
[0011] Compared with the prior art, the present invention has the following beneficial effects:
[0012] 1. This integrated LED optoelectronic glass mounting structure adopts an integrated design, combining multiple components into a single whole, improving ease of use and installation efficiency of the LED optoelectronic glass; and by controlling the movement distance of the moving part, the distance between the moving part and the fixed part is fixed when they are locked, thereby ensuring that the clamping force of the moving part and the fixed part on the LED optoelectronic glass is fixed during installation, ensuring the installation and fixing stability of the LED optoelectronic glass, avoiding local stress concentration, and reducing the probability of damage to the LED optoelectronic glass.
[0013] 2. This integrated LED optoelectronic glass mounting structure allows the handle to release the locking of the support block by the insert rod, and facilitates the operator to move the movable part away from the fixed part and rotate the movable part, improving the ease of operation of the mounting structure; through the setting of positioning components and fixing components, the positioning block can limit the positioning sleeve, preventing the positioning sleeve from separating from the positioning groove, and improving the locking reliability of the movable part. Attached Figure Description
[0014] Figure 1 This is a front view of the structure of this utility model;
[0015] Figure 2 This is a bottom view of the structure of this utility model;
[0016] Figure 3 This is a schematic cross-sectional view of the structure of this utility model;
[0017] Figure 4 This is an exploded view of the structure of this utility model;
[0018] Figure 5 This is a schematic cross-sectional view of the movable part of the structure of this utility model;
[0019] Figure 6 This is a schematic diagram of how the structure of this utility model clamps and fixes the LED optoelectronic glass.
[0020] In the diagram: 1. Fixed part; 2. Movable part; 3. Guide sleeve; 4. Handle; 5. Guide block; 6. Support block; 7. Push rod; 8. Fourth spring; 9. Positioning sleeve; 10. Positioning block; 11. Insert rod; 12. Pull rope; 13. Third spring; 14. Connecting shaft; 15. Second spring; 16. Positioning groove; 17. First spring; 18. Fixed groove. Detailed Implementation
[0021] 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.
[0022] This utility model provides embodiments: Please refer to Figures 1-6 The integrated LED optoelectronic glass mounting structure adopts an integrated design, including a fixed part 1 and a movable part 2. A guide structure is provided on one side of the fixed part 1. The guide structure includes a guide block 5 connected to the fixed part 1. Guide blocks 5 are provided at both ends of one side of the fixed part 1. A guide sleeve 3 is movably fitted on the outer ring of the guide block 5. The guide block 5 and the guide sleeve 3 are connected by a first spring 17. With the setting of the first spring 17, the guide sleeve 3 can move in the direction of the guide block 5 under the action of external force. When the restriction on the guide sleeve 3 is released, the guide sleeve 3 can move away from the guide block 5 under the action of the rebound force of the first spring 17, and the guide sleeve 3 can quickly achieve reset.
[0023] Two guide sleeves 3 are connected by a connecting shaft 14, and both ends of the top of the connecting shaft 14 are provided with positioning grooves 16. A movable part 2 is movably fitted onto the outer ring of the connecting shaft 14. Under external force, the movable part 2 can rotate around the connecting shaft 14 as its axis. A support block 6 for supporting the LED photoelectric glass is symmetrically arranged on the side of the fixed part 1 near the movable part 2. When the movable part 2 is relative to... Figures 1 to 6When rotated 90 degrees as shown, the support block 6 is located above the movable part 2, which makes it convenient for the staff to place the LED photoelectric glass to be installed on the support block 6. The support block 6 supports and limits the LED photoelectric glass, and there is damping between the movable part 2 and the connecting shaft 14. Under the action of external force, the movable part 2 can rotate, releasing the restriction on the movable part 2, and the position of the movable part 2 can remain unchanged.
[0024] Positioning components are provided at both ends of the inner cavity of the movable part 2. Each positioning component includes a positioning sleeve 9 adapted to the positioning groove 16 and a push rod 7 movably connected to the movable part 2. The positioning sleeve 9 is connected to the movable part 2 via a fourth spring 8, and the push rod 7 is connected to a handle 4. The handle 4 drives the push rod 7 to press the positioning sleeve 9. When the positioning sleeve 9 aligns with the positioning groove 16, under the pressing force of the push rod 7, the bottom end of the positioning sleeve 9 can be inserted into the positioning groove 16, thus positioning the movable part 2. At this time, the movable part 2 cannot rotate, and there is damping between the push rod 7 and the movable part 2. Under the action of this damping force, the restriction on the handle 4 is released, and the position of the push rod 7 remains unchanged. The damping between the push rod 7 and the movable part 2 can be set according to requirements and is not limited here. When the push rod 7 separates from the movable part 2, under the rebound force of the fourth spring 8, the positioning sleeve 9 can separate from the positioning groove 16, releasing the restriction on the movable part 2 and facilitating the flipping of the movable part 2.
[0025] Both ends of the movable part 2 near the support block 6 are provided with insertion holes. The support block 6 can be inserted into the inner cavity of the movable part 2 through the insertion holes. The inner cavity of the movable part 2 is provided with a fixing component adapted to the support block 6. The fixing component includes an insertion rod 11 movably connected to the inner cavity of the movable part 2 and a positioning block 10 movably connected to the inner cavity of the movable part 2. The positioning block 10 is connected to the movable part 2 through a third spring 13. Both ends of the inner cavity of the movable part 2 are provided with positioning blocks 10. The inner cavity of the movable part 2 near the support block 6 is provided with insertion holes adapted to both the positioning block 10 and the support block 6. The positioning block 10 and the insertion hole are on the same straight line. The positioning block 10 is movably connected to the inner cavity of the positioning sleeve 9. When the movable part 2 is separated from the fixed part 1, the end of the positioning block 10 away from the third spring 13 is located in the inner cavity of the insertion hole. When the support block 6 is inserted into the inner cavity of the movable part 2 through the insertion hole, the support block 6 will squeeze the positioning block 10, the positioning block 10 will move away from the insertion hole, and the end of the positioning block 10 close to the third spring 13 will move into the inner cavity of the positioning sleeve 9.
[0026] The insertion rod 11 is connected to the movable part 2 via the second spring 15. The end of the insertion rod 11 is adapted to the fixing groove 18. The insertion rod 11 is connected to the handle 4 via the pull rope 12. During the insertion process of the support block 6, when the fixing groove 18 is aligned with the end of the insertion rod 11, the end of the insertion rod 11 is inserted into the fixing groove 18 under the action of the rebound force of the second spring 15. The insertion rod 11 is used to fix the support block 6. At this time, the movable part 2 and the fixing part 1 are locked. When the movable part 2 and the fixing part 1 are locked, the movable part 2 and the fixing part 1 can clamp and fix the LED optoelectronic glass.
[0027] The axes of the second spring 15, the third spring 13, and the fourth spring 8 are perpendicular to each other.
[0028] In addition, buffer pads are provided on the outer surfaces of both the movable part 2 and the fixed part 1. The buffer pads are used to improve the uniformity of the clamping pressure distribution and the clamping stability of the LED optoelectronic glass. The material of the buffer pads can be set according to the requirements and is not limited here.
[0029] In summary, this integrated LED optoelectronic glass mounting structure adopts an integrated design, combining multiple components into a single unit, improving ease of use and installation efficiency of the LED optoelectronic glass. In use, after the fixing part 1 is fixed in a suitable position using conventional techniques, the operator rotates the movable part 2 until the top of the support block 6 is above the movable part 2, facilitating contact between the LED optoelectronic glass and the support block 6. After the LED optoelectronic glass is supported by the support block 6, the operator rotates the movable part 2 until it is in a vertical position. At this point, the positioning sleeve 9 is aligned with the positioning groove 16. The operator then presses down on the handle 4 until it contacts the movable part 2. During the downward movement of the handle 4, the push rod 11 compresses the positioning sleeve 9. When the handle 4 stops moving, the bottom end of the positioning sleeve 9 is located within the positioning groove 16. The positioning sleeve 9 then compresses the movable part... 2. Limiting the movement: After the handle 4 contacts the top of the movable part 2, the user pushes the movable part 2 until it can no longer be pushed. The cooperation between the movable part 2 and the fixed part 1 achieves clamping and fixing of the LED optoelectronic glass, enabling rapid installation of the LED optoelectronic glass. During the movement of the movable part 2, the end of the support block 6 away from the fixed part 1 is inserted into the insertion hole and presses the positioning block 10. When the fixing groove 18 is aligned with the insertion rod 11, under the action of the rebound force of the second spring 15, the end of the insertion rod 11 is inserted into the fixing groove 18. The insertion rod 11 and the support block 6 achieve mechanical locking between the movable part 2 and the fixed part 1. At this time, the movable part 2 can no longer move.
[0030] All standard parts used in this utility model can be purchased from the market, and irregular parts can be customized according to the description and drawings. The specific connection methods of each structure adopt conventional technical means such as bolt connection that are mature in the prior art. The machinery, parts and equipment adopt conventional models in the prior art. The materials of each component can be selected according to the requirements and are not limited here. The contents not described in detail in this specification belong to the prior art known to those skilled in the art. Although the embodiments of this utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and variations can be made to these embodiments without departing from the principles and spirit of this utility model. The scope of this utility model is defined by the appended claims and their equivalents.
Claims
1. An integrated LED optoelectronic glass mounting structure, comprising a fixed part (1) and a movable part (2), characterized in that: A guide structure is provided on one side of the fixed part (1), the movable part (2) is movably connected to the middle of the guide structure, and a positioning groove (16) is provided in the middle of the guide structure. A support block (6) for supporting LED optoelectronic glass is symmetrically provided on the side of the fixed part (1) near the movable part (2). A fixing groove (18) is provided at the end of the support block (6) away from the fixed part (1). The movable part (2) is a hollow structure. A fixing component adapted to the support block (6) is provided in the inner cavity of the movable part (2). A positioning component adapted to the positioning groove (16) is provided in the inner cavity of the movable part (2). The power input end of the fixing component and the power input end of the positioning component are connected through a handle (4).
2. The integrated LED optoelectronic glass mounting structure according to claim 1, characterized in that: The guide structure includes a guide block (5) connected to the fixing part (1). Both ends of one side of the fixing part (1) are provided with guide blocks (5). The outer ring of the guide block (5) is movably fitted with a guide sleeve (3). The guide block (5) and the guide sleeve (3) are connected by a first spring (17). The two guide sleeves (3) are connected by a connecting shaft (14). Both ends of the top of the connecting shaft (14) are provided with positioning grooves (16).
3. The integrated LED optoelectronic glass mounting structure according to claim 1, characterized in that: The fixing assembly includes a plug rod (11) movably connected to the inner cavity of the movable part (2) and a positioning block (10) movably connected to the inner cavity of the movable part (2). The plug rod (11) is connected to the movable part (2) via a second spring (15). The end of the plug rod (11) is adapted to the fixing groove (18). The plug rod (11) is connected to the handle (4) via a pull rope (12). The positioning block (10) is connected to the movable part (2) via a third spring (13).
4. The integrated LED optoelectronic glass mounting structure according to claim 3, characterized in that: Positioning blocks (10) are provided at both ends of the inner cavity of the movable part (2). An insertion hole that is compatible with both the positioning block (10) and the support block (6) is provided on the side of the inner cavity of the movable part (2) near the support block (6). The positioning block (10) and the insertion hole are on the same straight line.
5. The integrated LED optoelectronic glass mounting structure according to claim 4, characterized in that: The positioning assembly includes a positioning sleeve (9) adapted to the positioning groove (16) and a push rod (7) movably connected to the movable part (2). The positioning block (10) is movably connected to the inner cavity of the positioning sleeve (9). The positioning sleeve (9) is connected to the movable part (2) through a fourth spring (8). The push rod (7) is connected to the handle (4).
6. The integrated LED optoelectronic glass mounting structure according to claim 5, characterized in that: The axes of the second spring (15), the third spring (13), and the fourth spring (8) are perpendicular to each other.