A heat-conducting tempered glass lamination equipment

By combining the heating platform, the lamination mechanism, and the thermal conductivity adjustment components, the problems of heating uniformity and low thermal conductivity efficiency in the production of thermally conductive tempered glass are solved, achieving efficient lamination and convenient operation, and making it suitable for a variety of application scenarios.

CN224465432UActive Publication Date: 2026-07-07TIANJIN BAITAI GLASS

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
TIANJIN BAITAI GLASS
Filing Date
2025-06-10
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Existing laminating equipment suffers from problems such as poor heating uniformity, low thermal conductivity, and insufficient temperature and pressure control precision in the production of thermally conductive tempered glass, which affect product quality and high-end applications.

Method used

The design employs a combination of a heating platform, a clamping mechanism, and a heat conduction adjustment component. The heat conduction adjustment component is unfolded or folded by a drive motor, enabling synchronous operation of the heating platform and the clamping mechanism. The automatic laying and winding of the heat-conducting film, combined with the design of heat dissipation holes, ensures temperature uniformity and pressing effect.

Benefits of technology

It improves the heating uniformity and heat conduction efficiency of the laminating equipment, achieves precise temperature and pressure control, simplifies the operation process, reduces the size of the equipment, and facilitates handling and storage.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a kind of heat-conducting toughened glass lamination equipment, it includes heating table, lamination mechanism and heat-conducting adjusting assembly. Driving motor is equipped in heating table, is connected by transmission rod and sliding block, fixed frame and guide rod are equipped in lamination mechanism, and sliding block is cooperated with compression module to realize up and down adjustment. Heat-conducting adjusting assembly is made of first adjusting plate and second adjusting plate, which are arranged in cross, and can drive lamination mechanism to unfold or fold. Compression module includes first pressing plate and second pressing plate, and is internally provided with heat-conducting groove, heat-conducting wheel and heat-conducting film, and uses elastic member to automatically wind heat-conducting film. The equipment works cooperatively through heat-conducting adjusting assembly and compression module, solves the problem of uneven heat distribution and complex operation, improves lamination effect and use convenience, simultaneously has automatic winding and folding function, is convenient for carrying and storage, and has strong practicality.
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Description

Technical Field

[0001] This utility model relates to the technical field of glass processing equipment, and in particular to a thermally conductive tempered glass lamination device. Background Technology

[0002] Tempered glass is widely used in construction, automotive, and home appliance industries due to its high strength and safety, while thermally conductive tempered glass further expands its application scenarios due to its excellent thermal conductivity. However, the lamination process is a crucial step in the production of thermally conductive tempered glass. Existing lamination equipment typically uses traditional heating and pressurization methods to bond the glass and the film, but these devices have several shortcomings in practical applications. For example, traditional equipment suffers from poor heating uniformity, easily leading to air bubbles or weak adhesion in the lamination layer; simultaneously, the equipment has low thermal conductivity, increasing production time and energy consumption. Furthermore, existing equipment has limited precision in controlling temperature and pressure during operation, making it difficult to meet the stringent requirements of high-end products for lamination quality. These problems not only affect the performance of thermally conductive tempered glass but also limit its application in high-precision fields. Therefore, developing a thermally conductive tempered glass lamination equipment that can improve heating uniformity, enhance thermal conductivity, and achieve precise temperature and pressure control has become an urgent technical challenge. Utility Model Content

[0003] The purpose of this utility model is to provide a thermally conductive tempered glass lamination device that solves the problems mentioned in the background art.

[0004] This invention is implemented as follows: a heat-conducting tempered glass laminating device includes a heating platform and a laminating mechanism. A heat-conducting adjustment component is provided between the heating platform and the laminating mechanism, and the heating platform and the laminating mechanism are connected by the heat-conducting adjustment component. When the drive motor on the heating platform rotates in the forward direction, the heat-conducting adjustment component unfolds, moving the laminating mechanism away from the heating platform and simultaneously moving the sliding block on the laminating mechanism, thereby achieving the synchronous unfolding of the pressing module on the heating platform and the laminating mechanism. A drive motor is fixedly connected inside the heating platform, and a transmission rod is provided between the drive motor and the heating platform. One end of the transmission rod... The transmission rod is rotatably connected to the heating platform, and its other end is fixedly connected to the output end of the drive motor. A fixed frame is fixedly connected inside the clamping mechanism, and a guide rod is fixedly connected to the fixed frame and the clamping mechanism. Sliding blocks are sleeved on the outside of both the guide rod and the transmission rod. One of the sliding blocks is slidably connected to the guide rod, and the other sliding block is threadedly connected to the transmission rod. A pressing module is provided on the top of the sliding block. The pressing module can be adjusted up and down as a whole. Combined with the left and right adjustment between the heating platform and the clamping mechanism, the entire clamping equipment is more convenient to operate, improving its flexibility and practicality.

[0005] Preferably, the heat conduction adjustment assembly includes a first adjustment plate, which is rotatably connected to the heating platform. A second adjustment plate is rotatably connected to the top of the first adjustment plate, and the second adjustment plate is rotatably connected to a sliding block. The first and second adjustment plates are of the same specifications and are arranged in a cross pattern. There are a total of three sets of the first and second adjustment plates, which are rotatably connected end to end. In the set closest to the clamping mechanism, the first adjustment plate is rotatably connected to the sliding block on the guide rod, while the second adjustment plate is directly rotatably connected to the clamping mechanism.

[0006] Preferably, both the heating platform and the clamping mechanism have heat dissipation holes inside. Each heating platform and clamping mechanism has two heat dissipation holes. The heat dissipation holes are used to dissipate excess heat and balance the overall temperature to prevent local overheating from affecting the clamping effect.

[0007] Preferably, the pressing module includes a first pressure plate, which is rotatably connected to a sliding block. A first connecting rod is provided between the first pressure plate and the heating table. Under the action of the first connecting rod, when the transmission rod drives the sliding block to move, the first pressure plate on the sliding block will be squeezed or pulled by the first connecting rod, thereby causing the first pressure plate to automatically rotate upward or downward. One end of the first connecting rod is rotatably connected to the heating table, and the other end of the first connecting rod is rotatably connected to the first pressure plate. A first side rod is rotatably connected to one side of the first pressure plate, and a second side rod is rotatably connected to the other side of the first pressure plate. A second pressure plate is rotatably connected between the first side rod and the second side rod. Racks are fixedly connected to the outside of both the second pressure plate and the first pressure plate, and the two racks mesh with each other. The first side rod and the sliding block are connected by a second connecting rod. One end of the second connecting rod is rotatably connected to the first side rod, and the other end of the second connecting rod is rotatably connected to the sliding block. The four positions of the second connecting rod and the first side rod, the second connecting rod and the sliding block, the first side rod and the first pressure plate, and the first pressure plate and the sliding block form a parallelogram, so that the second connecting rod and the first pressure plate are always parallel to each other. When the first pressure plate rotates, the second connecting rod pushes and pulls the first side rod. With the cooperation of two meshing racks, the first side rod drives the second pressure plate to rotate around the first pressure plate until the second pressure plate and the first pressure plate are in the same straight line or parallel to each other.

[0008] Preferably, both the first and second pressure plates have heat-conducting grooves inside. A rotating shaft is rotatably connected inside the heat-conducting groove. A heat-conducting wheel is sleeved on the outside of the rotating shaft. Multiple heat-conducting wheels are arranged on the rotating shaft and are evenly distributed. The heat-conducting wheels are fixedly connected to the rotating shaft. A heat-conducting film is wound around the outside of the heat-conducting wheels. The heat-conducting film is fixedly connected to the heat-conducting wheels. An elastic element is sleeved on the outside of the rotating shaft and between the heat-conducting grooves and the heat-conducting wheels. One end of the elastic element is fixedly connected to the rotating shaft, and the other end of the elastic element is fixedly connected to the heat-conducting groove. The elastic element is mainly used to drive the rotating shaft to rotate automatically, and the rotating shaft then drives the heat-conducting wheels to rotate and wind up the heat-conducting film.

[0009] Preferably, a sealing plate is detachably connected inside the heat conduction groove. The sealing plate has a through hole inside, which is used in conjunction with the heat conduction film. The first pressure plate and the second pressure plate are fixed to the sealing plate by screws. The sealing plate can seal the heat conduction groove on the first pressure plate and the second pressure plate to prevent foreign objects from entering the heat conduction groove. The heat conduction film extends directly to the outside through the through hole on the sealing plate.

[0010] Preferably, both the heating platform and the clamping mechanism are fixedly connected to slide rails, and the sliding block has a groove on the side near the slide rail. The groove works in conjunction with the slide rail to limit the movement of the sliding block, making the movement of the sliding block more stable.

[0011] Preferably, the clamping mechanism has a through slot inside, and a roller is rotatably connected inside the through slot. There are two through slots, which are symmetrically distributed. When the drive motor is started, the drive motor will drive the sliding block to move through the transmission rod. The sliding block uses the heat conduction adjustment component to drive the clamping mechanism to move, so that the clamping mechanism moves away from or closer to the heating table, realizing the automatic unfolding and folding of the whole.

[0012] Preferably, a control switch is fixedly connected to the outside of the heating platform, the drive motor is electrically connected to the control switch, the electrical equipment is powered by an external power source, such as a battery, and the start, stop, forward and reverse rotation of the drive motor are controlled by the control switch.

[0013] Compared with the prior art, the beneficial effects of this utility model are:

[0014] 1) When using this thermally conductive tempered glass laminating equipment, start the drive motor to rotate forward. The thermally conductive adjustment component unfolds and drives the laminating mechanism away from the heating table, stretching the thermally conductive film. At the same time, the first and second pressure plates rotate upward to a horizontal position. At this time, the thermally conductive adjustment component is also fully unfolded. Finally, the thermally conductive film is attached to the glass surface to complete the overall laminating operation. After removing the thermally conductive film, control the drive motor to rotate in the opposite direction to fold the whole unit up. This greatly reduces the overall volume in both the horizontal and vertical directions, making it more convenient to transport. Moreover, the operation is simple and quick.

[0015] 2) When this thermally conductive tempered glass laminating equipment is in use, the elastic element drives the rotating shaft and the heat-conducting wheel to rotate. When the laminating equipment is folded as a whole, the thermally conductive film is automatically rolled up. When the laminating equipment is unfolded as a whole, the thermally conductive film can be automatically stretched. There is no need to lay the thermally conductive film separately, which reduces the overall operation steps of the laminating equipment.

[0016] 3) When this thermally conductive tempered glass laminating equipment is in use, the thermally conductive film is rolled up by the thermally conductive roller and then stored in the thermally conductive groove of the first pressure plate and the second pressure plate. The thermally conductive groove is sealed by a sealing plate to prevent foreign objects from entering the thermally conductive groove. The sealing plate has through holes, through which the thermally conductive film can pass directly. Attached Figure Description

[0017] Figure 1 This is a schematic diagram of the overall structure of the present invention, showing the connection relationship between the heating platform, the clamping mechanism, and the heat conduction adjustment component. The unfolded or folded state of the heating platform and the clamping mechanism through the heat conduction adjustment component is clearly visible.

[0018] Figure 2 This is a schematic diagram of the pressing module structure of this utility model, which shows in detail the cooperation relationship between the first pressing plate, the second pressing plate, the rack, the heat-conducting groove and the heat-conducting wheel, as well as the sealing effect of the sealing plate on the heat-conducting groove.

[0019] Figure 3 This is a schematic diagram showing the connection between the sliding block, transmission rod, and guide rod of this utility model. It focuses on showing the movement of the sliding block on the transmission rod and guide rod, as well as the limiting fit between the slide rail and the slide groove.

[0020] The attached figures are labeled as follows: 1. Heating table; 2. Clamping mechanism; 3. Heat conduction adjustment component; 4. Drive motor; 5. Transmission rod; 6. Fixing frame; 7. Guide rod; 8. Sliding block; 9. Pressing module; 10. First adjusting plate; 11. Second adjusting plate; 12. Heat dissipation hole; 13. First pressure plate; 14. First connecting rod; 15. First side rod; 16. Second side rod; 17. Second pressure plate; 18. Rack; 19. Heat conduction groove; 20. Rotating shaft; 21. Heat conduction wheel; 22. Heat conduction film; 23. Elastic element; 24. Sealing plate; 25. Through hole; 26. Slide rail; 27. Slide groove; 28. Through groove; 29. ​​Roller; 30. Control switch. Detailed Implementation

[0021] This utility model provides a thermally conductive tempered glass lamination device, the overall structure of which is as follows: Figure 1 As shown, the device includes a heating platform 1, a clamping mechanism 2, and a heat-conducting adjustment component 3 disposed between the two. The heating platform 1 and the clamping mechanism 2 achieve the function of unfolding or folding through the heat-conducting adjustment component 3, thereby optimizing the convenience and flexibility of the clamping operation. The specific embodiments of this utility model are described in detail below with reference to the accompanying drawings.

[0022] like Figure 1 As shown, a drive motor 4 is fixedly connected inside the heating platform 1, and the drive motor 4 is connected to the heating platform 1 via a transmission rod 5. One end of the transmission rod 5 is rotatably connected to the heating platform 1, and the other end is fixedly connected to the output end of the drive motor 4. The start and stop of the drive motor 4 are controlled by a control switch 30, which is fixed outside the heating platform 1 and electrically connected to the drive motor 4. The drive motor 4 is powered by an external power source, such as a battery. When the drive motor 4 rotates forward, the transmission rod 5 rotates accordingly, causing the sliding block 8 to move along the transmission rod 5. The sliding block 8 has a groove 27 inside, which works in conjunction with the slide rail 26 fixed inside the heating platform 1 and the clamping mechanism 2 to ensure that the sliding block 8 maintains stable operation during movement and avoids shaking or deviation.

[0023] The clamping mechanism 2 has a fixed frame 6 internally connected to it, and a guide rod 7 is mounted on the fixed frame 6. Sliding blocks 8 are fitted onto the outside of both the guide rod 7 and the transmission rod 5. One sliding block 8 is slidably connected to the guide rod 7, and the other sliding block 8 is threadedly connected to the transmission rod 5. A pressing module 9 is mounted on the top of the sliding block 8, and the pressing module 9 is used to press the heat-conducting film 22. Figure 2As shown, the pressing module 9 includes a first pressing plate 13 and a second pressing plate 17. The first pressing plate 13 is rotatably connected to the sliding block 8 and connected to the heating table 1 via a first connecting rod 14. One end of the first connecting rod 14 is rotatably connected to the heating table 1, and the other end is rotatably connected to the first pressing plate 13. When the transmission rod 5 drives the sliding block 8 to move, the first pressing plate 13 on the sliding block 8 will be squeezed or pulled by the first connecting rod 14, thereby causing the first pressing plate 13 to automatically rotate upward or downward. A first side rod 15 is rotatably connected to one side of the first pressing plate 13, and a second side rod 16 is rotatably connected to the other side. A second pressing plate 17 is rotatably connected between the first side rod 15 and the second side rod 16. Both the first pressing plate 13 and the second pressing plate 17 are fixedly connected to the outside of the racks 18, and the two racks 18 mesh with each other. A second connecting rod 16 is provided between the first side rod 15 and the sliding block 8. One end of the second connecting rod 16 is rotatably connected to the first side rod 15, and the other end is rotatably connected to the sliding block 8. The second link 16 and the first pressure plate 13 always remain parallel. When the first pressure plate 13 rotates, the second link 16 pushes and pulls the first side rod 15, and with the cooperation of the two racks 18, drives the second pressure plate 17 to rotate around the first pressure plate 13 until the second pressure plate 17 and the first pressure plate 13 are in the same straight line or parallel to each other.

[0024] Both the first pressure plate 13 and the second pressure plate 17 have heat-conducting grooves 19 inside. A rotating shaft 20 is rotatably connected inside the heat-conducting groove 19. Multiple heat-conducting wheels 21 are sleeved on the outside of the rotating shaft 20, equidistantly distributed and fixedly connected to the rotating shaft 20. A heat-conducting film 22 is wound around the outside of the heat-conducting wheels 21 and fixedly connected to them. An elastic element 23 is sleeved outside the rotating shaft 20, located between the heat-conducting groove 19 and the heat-conducting wheels 21. One end of the elastic element 23 is fixedly connected to the rotating shaft 20, and the other end is fixedly connected to the heat-conducting groove 19. The main function of the elastic element 23 is to drive the rotating shaft 20 to rotate automatically, which in turn drives the heat-conducting wheels 21 to rotate, thereby winding up the heat-conducting film 22. A sealing plate 24 is detachably connected inside the heat-conducting groove 19. A through hole 25 is opened inside the sealing plate 24, which is used in conjunction with the heat-conducting film 22. The first pressure plate 13 and the second pressure plate 17 are fixed to the sealing plate 24 by screws. The sealing plate 24 can seal the heat conduction groove 19 to prevent foreign matter from entering the heat conduction groove 19. The heat conduction film 22 extends directly to the outside through the through hole 25 on the sealing plate 24.

[0025] The heat conduction adjustment assembly 3 includes a first adjustment plate 10 and a second adjustment plate 11. The first adjustment plate 10 is rotatably connected to the heating platform 1, and the second adjustment plate 11 is rotatably connected to the top of the first adjustment plate 10. The second adjustment plate 11 is rotatably connected to the sliding block 8. The first adjustment plate 10 and the second adjustment plate 11 are of the same specifications and are arranged in a cross pattern, with a total of three sets, rotatably connected end to end. In the set closest to the clamping mechanism 2, the first adjustment plate 10 is rotatably connected to the sliding block 8 on the guide rod 7, while the second adjustment plate 11 is directly rotatably connected to the clamping mechanism 2. When the drive motor 4 rotates in the forward direction, the heat conduction adjustment assembly 3 unfolds, moving the clamping mechanism 2 away from the heating platform 1 and simultaneously moving the sliding block 8, thereby achieving the synchronous unfolding of the pressing module 9 on the heating platform 1 and the clamping mechanism 2.

[0026] Both the heating platform 1 and the clamping mechanism 2 have two heat dissipation holes 12 inside. These holes 12 are used to dissipate excess heat and balance the overall temperature, preventing localized overheating from affecting the clamping effect. The clamping mechanism 2 has two through slots 28 inside, with rollers 29 rotatably connected to them. These two through slots 28 are symmetrically distributed. When the drive motor 4 starts, it moves the sliding block 8 via the transmission rod 5. The sliding block 8, through the heat-conducting adjustment component 3, moves the clamping mechanism 2, causing it to move away from or closer to the heating platform 1, thus achieving the automatic unfolding and folding function of the entire assembly.

[0027] In practical applications, the operation process of the thermally conductive tempered glass laminating equipment of this utility model is as follows: First, place the equipment in the working area, power the drive motor 4 through an external power supply, and start the drive motor 4 through the control switch 30. When the drive motor 4 rotates in the forward direction, the transmission rod 5 rotates accordingly, driving the sliding block 8 to move along the transmission rod 5. The movement of the sliding block 8 is transmitted to the laminating mechanism 2 through the thermally conductive adjustment component 3, causing the laminating mechanism 2 to gradually move away from the heating table 1, while the pressing module 9 on the sliding block 8 also unfolds. During this process, the first pressure plate 13 and the second pressure plate 17 automatically rotate upward under the action of the first connecting rod 14 and the second connecting rod 16 until they reach a horizontal state. At the same time, the thermally conductive film 22 is gradually stretched by the thermally conductive wheel 21 driven by the elastic element 23, and the thermally conductive film 22 extends out from the thermally conductive groove 19 and adheres to the glass surface to be processed. After the laminating operation is completed, the drive motor 4 can be rotated in the reverse direction through the control switch 30. At this time, the thermally conductive adjustment component 3 is folded, the laminating mechanism 2 moves closer to the heating table 1, and the entire equipment returns to its initial state, making it easy to transport and store.

[0028] In summary, the thermally conductive tempered glass laminating equipment of this utility model achieves uniform heat distribution, excellent bonding effect of the laminating layer, and simple operation through reasonable structural design and component matching. It also has the advantages of small size and easy handling, and is suitable for a variety of application scenarios, thus having high practical value.

[0029] The above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Any modifications, equivalent substitutions and improvements made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.

Claims

1. A heat-conducting tempered glass laminating device, comprising a heating table (1) and a laminating mechanism (2), characterized in that: A heat conduction adjustment component (3) is provided between the heating platform (1) and the clamping mechanism (2). A drive motor (4) is fixedly connected inside the heating platform (1). A transmission rod (5) is provided between the drive motor (4) and the heating platform (1). One end of the transmission rod (5) is rotatably connected to the heating platform (1), and the other end is fixedly connected to the output end of the drive motor (4). A fixing frame (6) is fixedly connected inside the clamping mechanism (2). A guide rod (7) is fixedly connected between the fixing frame (6) and the clamping mechanism (2). Sliding blocks (8) are sleeved on the outside of both the guide rod (7) and the transmission rod (5). One of the sliding blocks (8) is slidably connected to the guide rod (7), and the other sliding block (8) is threadedly connected to the transmission rod (5). A pressing module (9) is provided on the top of the sliding block (8).

2. The thermally conductive tempered glass laminating equipment according to claim 1, characterized in that: The heat conduction adjustment component (3) includes a first adjustment plate (10), which is rotatably connected to the heating platform (1). A second adjustment plate (11) is rotatably connected to the top of the first adjustment plate (10). The second adjustment plate (11) is rotatably connected to the sliding block (8). The first adjustment plate (10) and the second adjustment plate (11) are of the same specifications and are arranged in a cross pattern. A total of three sets are provided and are rotatably connected end to end.

3. The thermally conductive tempered glass laminating equipment according to claim 1, characterized in that: Both the heating platform (1) and the clamping mechanism (2) have two heat dissipation holes (12) inside.

4. The thermally conductive tempered glass laminating equipment according to claim 1, characterized in that: The pressing module (9) includes a first pressing plate (13), which is rotatably connected to a sliding block (8). A first connecting rod (14) is provided between the first pressing plate (13) and the heating table (1). One end of the first connecting rod (14) is rotatably connected to the heating table (1), and the other end is rotatably connected to the first pressing plate (13). A first side rod (15) is rotatably connected to one side of the first pressing plate (13), and a second side rod (16) is rotatably connected to the other side. A second pressing plate (17) is rotatably connected between the first side rod (15) and the second side rod (16). A rack (18) is fixedly connected to the outside of both the second pressing plate (17) and the first pressing plate (13), and the two racks (18) mesh with each other.

5. The thermally conductive tempered glass laminating equipment according to claim 4, characterized in that: The first pressure plate (13) and the second pressure plate (17) are both provided with heat-conducting grooves (19). A rotating shaft (20) is rotatably connected inside the heat-conducting groove (19). Multiple heat-conducting wheels (21) are sleeved on the outside of the rotating shaft (20). The heat-conducting wheels (21) are fixedly connected to the rotating shaft (20). A heat-conducting film (22) is wound around the outside of the heat-conducting wheels (21). An elastic element (23) is sleeved on the outside of the rotating shaft (20) and between the heat-conducting groove (19) and the heat-conducting wheels (21).

6. The thermally conductive tempered glass laminating equipment according to claim 5, characterized in that: The heat-conducting groove (19) is detachably connected to a sealing plate (24), and the sealing plate (24) has a through hole (25) inside, which is used in conjunction with the heat-conducting film (22).

7. The thermally conductive tempered glass laminating equipment according to claim 1, characterized in that: The heating table (1) and the clamping mechanism (2) are both fixedly connected to slide rails (26). The sliding block (8) has a groove (27) on the side near the slide rail (26) inside. The groove (27) works in conjunction with the slide rail (26).