A composite fireproof insulation board laminating device

By using lifting components, elastic components, and negative pressure adsorption devices, the problems of board breakage, warping, and slippage in the composite fireproof insulation board lamination device have been solved, achieving uniform pressure distribution, stable edge positioning, and efficient material handling, thereby improving lamination quality and production efficiency.

CN224408673UActive Publication Date: 2026-06-26SHANDONG YUZE ENERGY SAVING TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHANDONG YUZE ENERGY SAVING TECHNOLOGY CO LTD
Filing Date
2025-06-23
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

Existing composite fireproof insulation board lamination devices are prone to board breakage when the pressure is too high, uneven pressure distribution, improper edge treatment leading to warping defects, lack of effective fixing measures, easy slippage and misalignment during lamination, and inconvenience in material handling.

Method used

Employing lifting components, elastic components, limiting components, and negative pressure adsorption devices, the system uses buffering, positioning, and fixing measures to ensure uniform pressure distribution, stable edge pressure, prevent slippage and misalignment, and simplify material handling operations.

Benefits of technology

It improves lamination accuracy and stability, enhances edge bonding strength, prevents warping and slippage, and increases production efficiency. It is suitable for boards of different specifications.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

The utility model discloses a kind of composite fireproof insulation board laminating device, the utility model relates to thermal insulation board laminating technical field.It is laminated mechanism for composite fireproof insulation board and is provided on the mounting base, laminated mechanism includes: press-fit component, including the support rod fixed with both side walls of mounting base, the upper end of the support rod is provided with the mounting plate connected by lifting assembly, the lower end surface of the mounting plate is provided with the pressure plate main body connected by elastic component, the lower end inside of the pressure plate main body is provided with rectangular frame slot, the inside of the rectangular frame slot is provided with the rectangular pressure plate connected by telescopic component, the utility model is driven rectangular pressure plate telescopic by second hydraulic rod, realize the pertinence pressure to the edge of thermal insulation board, since the edge of thermal insulation board is prone to the problem of not firm combination when laminating, can effectively improve the compaction degree and bonding strength of edge, avoid edge curling, delamination and other quality problems.
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Description

Technical Field

[0001] This utility model relates to the field of thermal insulation board lamination technology, specifically a composite fireproof thermal insulation board lamination device. Background Technology

[0002] With the increasing demands for building energy conservation and fire safety, composite fireproof insulation boards have been widely used in building exterior wall insulation and industrial equipment insulation due to their excellent thermal insulation and fire resistance properties. The lamination process, a key step in the production of composite fireproof insulation boards, directly affects the bonding strength, flatness, and overall performance of the boards.

[0003] Composite fireproof insulation board laminating devices typically use hydraulic rods for downward driving lamination. However, directly lowering the pressure plate with hydraulic rods can easily lead to excessive pressure, causing damage to the board and uneven pressure distribution, thus affecting product quality. Furthermore, existing devices often neglect the special requirements of the insulation board edges, resulting in insufficient force on the edges during lamination and a tendency for warping defects. Additionally, the lack of effective fixing measures makes slippage and misalignment during lamination more likely. Moreover, the tight adhesion between the insulation board and the base surface after lamination hinders material removal. Therefore, this utility model provides a composite fireproof insulation board laminating device. Utility Model Content

[0004] To address the shortcomings of existing technologies, this utility model provides a composite fireproof insulation board lamination device. This solves the problems of directly lowering the pressure plate using hydraulic rods, which can easily lead to excessive pressure causing board breakage, uneven pressure distribution affecting product quality, and neglecting the special requirements of insulation board edges. Furthermore, existing devices often overlook the edge treatment, resulting in insufficient force on the edges during lamination, leading to warping defects. Additionally, the lack of effective fixing measures makes slippage and misalignment during lamination easy, and the tight adhesion between the insulation board and the base surface after lamination hinders material handling.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a composite fireproof insulation board laminating device, comprising a mounting base, wherein a laminating mechanism for the composite fireproof insulation board is provided on the mounting base, and the laminating mechanism includes:

[0006] The pressing assembly includes a mounting base with support rods fixed to both sides of the mounting base. The upper end of the support rods is provided with a mounting plate connected by a lifting assembly. The lower end of the mounting plate is provided with a pressure plate body connected by an elastic assembly. The lower end of the pressure plate body is provided with a rectangular frame groove. A rectangular pressure plate connected by a telescopic assembly is provided inside the rectangular frame groove.

[0007] The limiting component includes a movable groove on the upper surface of the mounting base, with a limiting protrusion slidably connected inside the movable groove, and four sets of negative pressure shells embedded in the center of the mounting base.

[0008] Preferably, the lifting assembly includes a support rod with a top rod fixed at the top, a first hydraulic rod fixed through the center of the top rod, and a mounting plate located at the telescopic end of the first hydraulic rod.

[0009] Preferably, the elastic component includes a damping spring uniformly fixed to the lower end face of the mounting plate, the pressure plate body is located at the end of the damping spring, the inner ring of the damping spring is provided with a damping support rod fixed to the pressure plate body, positioning blocks are fixed at the four ends of the mounting plate, and positioning slide rails that are slidably connected to the positioning blocks are fixed at the four ends of the pressure plate body.

[0010] Preferably, the telescopic assembly includes a second hydraulic rod fixed to the top of a rectangular frame groove, a rectangular pressure plate located at the telescopic end of the second hydraulic rod, and the rectangular pressure plate being slidably connected to the rectangular frame groove.

[0011] Preferably, an electric push rod is fixedly installed inside the support rod, and a connecting plate is fixed to the telescopic end of the electric push rod. The connecting plate is slidably connected to both sides of the mounting base, and the two sides of the connecting plate are fixedly connected to the limiting protrusions. The connecting plate is configured in two sets, and the two sets of connecting plates are symmetrically distributed about the mounting base.

[0012] Preferably, the lower end of the negative pressure outer shell extends into the interior of the mounting base and is fixed with a cavity outer shell. The lower end of the mounting base is fixed with a vacuum pump, and the output end of the vacuum pump is fixed with a conduit, which is in a flow connection with the cavity outer shell.

[0013] Beneficial effects

[0014] This utility model provides a composite fireproof and heat-insulating board lamination device. Compared with the prior art, it has the following advantages:

[0015] Firstly, this utility model adapts to insulation boards of different thicknesses by adjusting the lifting height of the mounting plate. The elastic component composed of shock-absorbing springs and damping rods acts as a buffer when the main body of the pressure plate contacts the insulation board, preventing excessive pressure from damaging the board. At the same time, it allows the main body of the pressure plate to gradually conform to the surface of the board, ensuring uniform pressure distribution. Furthermore, the positioning block and positioning slide rail work together to improve the stability and verticality of the downward movement of the main body of the pressure plate, thereby enhancing the lamination accuracy.

[0016] Secondly, this utility model uses a second hydraulic rod to drive the rectangular pressure plate to extend and retract, thereby achieving targeted pressure on the edge of the insulation board. Since the edge of the insulation board is prone to poor bonding during lamination, this invention can effectively improve the compaction and bonding strength of the edge, avoiding quality problems such as edge lifting and delamination.

[0017] Thirdly, this utility model uses an electric push rod to drive the movement of the limiting protrusions, which can quickly and accurately position insulation boards of different specifications. Two sets of symmetrically distributed connecting plates and limiting protrusions limit the insulation boards from both sides, preventing lateral displacement of the boards during lamination, ensuring the accuracy of the lamination position, and thus improving product quality. Then, the negative pressure adsorption effect can firmly fix the insulation boards, preventing the boards from sliding or misaligning due to pressure during lamination. It is especially suitable for boards with smooth surfaces that are difficult to position, further improving the lamination quality and stability. The bidirectional vacuum pump can switch between suction and exhaust modes. When suctioning, the boards are adsorbed and fixed; when exhausting, the boards are loosened, simplifying the operation process and improving production efficiency. Attached Figure Description

[0018] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0019] Figure 2 This is a schematic diagram of the limiting protrusion connection structure of this utility model;

[0020] Figure 3 This is a schematic diagram of the negative pressure outer shell connection structure of this utility model;

[0021] Figure 4 This is a schematic diagram of the shock-absorbing spring connection structure of this utility model;

[0022] Figure 5 This is a schematic diagram of the internal connection structure of the pressure plate body of this utility model.

[0023] In the diagram: 1. Mounting base; 2. Support rod; 201. Top rod; 202. First hydraulic rod; 203. Mounting plate; 204. Shock-absorbing spring; 205. Damping support rod; 206. Pressure plate body; 207. Positioning block; 208. Positioning slide rail; 3. Rectangular frame groove; 301. Second hydraulic rod; 302. Rectangular pressure plate; 4. Electric push rod; 401. Connecting plate; 402. Movable groove; 403. Limiting protrusion; 5. Negative pressure shell; 501. Cavity shell; 502. Vacuum pump; 503. Conduit. Detailed Implementation

[0024] 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.

[0025] Please see Figures 1-5This utility model provides a technical solution: a composite fireproof insulation board laminating device, including a mounting base 1, on which a laminating mechanism for the composite fireproof insulation board is provided, the laminating mechanism including:

[0026] The pressing assembly includes a mounting base 1 with support rods 2 fixed on both sides. The upper end of the support rods 2 is provided with a mounting plate 203 connected by a lifting assembly. The lower end of the mounting plate 203 is provided with a pressing plate body 206 connected by an elastic assembly. The lower end of the pressing plate body 206 has a rectangular frame groove 3. The rectangular frame groove 3 has a rectangular pressing plate 302 connected by a telescopic assembly inside it.

[0027] The limiting component includes a movable groove 402 opened on the upper surface of the mounting base 1, a limiting protrusion 403 slidably connected inside the movable groove 402, and four sets of negative pressure shells 5 embedded in the center of the mounting base 1.

[0028] In a preferred embodiment, the lifting assembly includes a support rod 2 with a top rod 201 fixed at its top end, a first hydraulic rod 202 fixed through the center of the top rod 201, a mounting plate 203 located at the telescopic end of the first hydraulic rod 202, and an elastic assembly including shock-absorbing springs 204 uniformly fixed to the lower end face of the mounting plate 203, a pressure plate body 206 located at the end of the shock-absorbing springs 204, a damping support rod 205 fixed to the inner ring of the shock-absorbing springs 204 and fixed to the pressure plate body 206, positioning blocks 207 fixed at the four ends of the mounting plate 203, and positioning slide rails 208 slidably connected to the positioning blocks 207 fixed at the four ends of the pressure plate body 206. When the first hydraulic rod 202 is activated, it is fixed to the center of the top rod 201, driving the mounting plate 203 to move downwards. When the mounting plate 203 moves downwards, the shock-absorbing springs 204 and the damping support rods 205 first contact the pressure plate body... When the pressure increases, the damping spring 204 compresses and the damping rod 205 contracts, causing the pressure plate body 206 to slowly approach the surface of the insulation board, achieving initial pressing. The positioning block 207 slides along the positioning slide rail 208 to ensure that the pressure plate body 206 moves vertically downwards and avoids tilting. The first hydraulic rod 202 provides stable downward pressing power, which can precisely control the lifting height of the mounting plate 203 and adapt to insulation boards of different thicknesses. The elastic component composed of the damping spring 204 and the damping rod 205 plays a buffering role when the pressure plate body 206 contacts the insulation board, preventing excessive pressure from damaging the board. At the same time, it allows the pressure plate body 206 to gradually adhere to the surface of the board, ensuring uniform pressure distribution. The cooperation between the positioning block 207 and the positioning slide rail 208 improves the stability and verticality of the downward movement of the pressure plate body 206 and enhances the lamination accuracy.

[0029] In a preferred embodiment, the telescopic component includes a second hydraulic rod 301 fixed to the top of a rectangular frame groove 3, and a rectangular pressure plate 302 located at the telescopic end of the second hydraulic rod 301. The rectangular pressure plate 302 is slidably connected to the rectangular frame groove 3. When the pressure plate body 206 is used to perform overall lamination on the surface of the insulation board, the pressure plate body 206 is in contact with the surface of the insulation board. In order to ensure the stability of the lamination, the rectangular pressure plate 302 is pressed down by the second hydraulic rod 301, so that the rectangular pressure plate 302 slides out along the rectangular frame groove 3 on the lower end face of the pressure plate body 206. After the rectangular pressure plate 302 extends, additional pressure is applied to the edge of the insulation board to enhance the lamination effect at the edge.

[0030] The rectangular pressure plate 302 is extended and retracted by the second hydraulic rod 301 to achieve targeted pressure on the edge of the insulation board. Since the edge of the insulation board is prone to poor bonding during lamination, this can effectively improve the compaction and bonding strength of the edge, and avoid quality problems such as edge lifting and delamination.

[0031] In a preferred embodiment, an electric push rod 4 is fixedly inserted through the support rod 2. A connecting plate 401 is fixed to the telescopic end of the electric push rod 4. The connecting plate 401 is slidably connected to both sides of the mounting base 1, and both sides of the connecting plate 401 are fixedly connected to the limiting protrusions 403. Two sets of connecting plates 401 are symmetrically distributed about the mounting base 1. The electric push rod 4 is fixedly inserted through the support rod 2. After activation, its telescopic end drives the connecting plate 401 to slide within both sides of the mounting base 1. The connecting plate 401 and the limiting protrusions 403 are then connected. 3. A fixed connection is established, thereby pushing the limiting protrusion 403 to slide within the movable groove 402. The position of the limiting protrusion 403 is adjusted to laterally limit the insulation board placed on the mounting base 1, ensuring that the board is in the correct position during lamination. The limiting protrusion 403 is moved by the electric push rod 4, which can quickly and accurately position insulation boards of different specifications. Two sets of symmetrically distributed connecting plates 401 and limiting protrusions 403 limit the insulation board from both sides, preventing lateral displacement of the board during lamination, ensuring the accuracy of the lamination position, and thus improving product quality.

[0032] In a preferred embodiment, the lower end of the negative pressure outer shell 5 extends into the interior of the mounting base 1 and is fixed with a cavity shell 501. A vacuum pump 502 is fixed to the lower end of the mounting base 1, and a conduit 503 is fixed to the output end of the vacuum pump 502. The conduit 503 is in a flow connection with the cavity shell 501. The vacuum pump 502 is bidirectional, which can realize bidirectional switching of air intake and exhaust. When the bidirectional vacuum pump 502 is started, it is fixed to the lower end of the mounting base 1 and communicates with the cavity shell 501 through the conduit 503. The vacuum pump 502 draws air from the cavity shell 501, so that a negative pressure is formed inside the negative pressure outer shell 5, thereby adsorbing and fixing the insulation board placed on the mounting base 1. After lamination is completed, the vacuum pump 502 can be switched to the blowing mode to release the adsorption force on the insulation board, making it easier to remove the material.

[0033] The negative pressure adsorption effect can firmly fix the insulation board and prevent the board from sliding or misaligning due to pressure during the lamination process. It is especially suitable for boards with smooth surfaces that are not easy to position, further improving the lamination quality and stability. The bidirectional vacuum pump 502 can switch between suction and exhaust modes. When suctioning, it can adsorb and fix the board, and when exhausting, it can help loosen the board, simplifying the operation process and improving production efficiency. The vacuum pump model is KNF N86KTE.

[0034] Furthermore, any content not described in detail in this specification is existing technology known to those skilled in the art.

[0035] During operation, when using this composite fireproof and heat-insulating board laminating device, first place the board to be laminated on the mounting base 1, then start the electric push rod 4, which passes through the support rod 2, and drive the connecting plate 401 to slide on both sides of the mounting base 1, thereby pushing the limiting protrusions 403 to move in the movable groove 402. The two sets of symmetrically distributed limiting protrusions 403 laterally limit the board from both sides to ensure that the board is in the correct position. Then start the bidirectional vacuum pump 502, which is connected to the cavity shell 501 through the conduit 503, and draw air to create a negative pressure in the shell 501. A negative pressure is formed to firmly adsorb and fix the board. After positioning and fixing are completed, the first hydraulic rod 202 is activated. It is fixed at the center of the top rod 201 and drives the mounting plate 203 to move downward. When the mounting plate 203 moves downward, the shock-absorbing spring 204 and the damping support rod 205 first contact the pressure plate body 206. As the pressure increases, the shock-absorbing spring 204 is compressed and the damping support rod 205 is contracted, which drives the pressure plate body 206 to slowly approach the surface of the insulation board. The positioning block 207 slides along the positioning slide rail 208 to ensure that the pressure plate body 206 moves vertically downward, and the initial pressing is achieved.

[0036] Finally, after the main body 206 of the pressure plate is attached to the surface of the insulation board, the second hydraulic rod 301 is activated to push the rectangular pressure plate 302 to slide down along the rectangular frame groove 3, applying additional pressure to the edge of the insulation board to enhance the lamination effect at the edge. After lamination is completed, the vacuum pump 502 is switched to the blowing mode to release the adsorption force on the insulation board so that the finished board can be removed.

[0037] It should be noted that, in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such process, method, article, or apparatus.

[0038] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A composite fireproof and heat-insulating board lamination device, comprising a mounting base (1), characterized in that: The mounting base (1) is provided with a lamination mechanism for the composite fireproof insulation board, the lamination mechanism including: The pressing assembly includes a mounting base (1) with support rods (2) fixed on both sides. The upper end of the support rods (2) is provided with a mounting plate (203) connected by a lifting assembly. The lower end of the mounting plate (203) is provided with a pressure plate body (206) connected by an elastic assembly. The lower end of the pressure plate body (206) is provided with a rectangular frame groove (3). The rectangular frame groove (3) is provided with a rectangular pressure plate (302) connected by a telescopic assembly. The limiting component includes an active groove (402) opened on the upper surface of the mounting base (1), a limiting protrusion (403) is slidably connected inside the active groove (402), and four sets of negative pressure shells (5) are embedded in the center of the mounting base (1).

2. The composite fireproof and heat-insulating board laminating device according to claim 1, characterized in that: The lifting assembly includes a support rod (2) with a top rod (201) fixed at the top. A first hydraulic rod (202) is fixed through the center of the top rod (201), and the mounting plate (203) is located at the telescopic end of the first hydraulic rod (202).

3. The composite fireproof and heat-insulating board laminating device according to claim 1, characterized in that: The elastic component includes a shock-absorbing spring (204) uniformly fixed on the lower end face of the mounting plate (203), the pressure plate body (206) is located at the end of the shock-absorbing spring (204), the inner ring of the shock-absorbing spring (204) is provided with a damping support rod (205) fixed to the pressure plate body (206), the four ends of the mounting plate (203) are fixed with positioning blocks (207), and the four ends of the pressure plate body (206) are fixed with positioning slide rails (208) that are slidably connected to the positioning blocks (207).

4. The composite fireproof and heat-insulating board laminating device according to claim 1, characterized in that: The telescopic assembly includes a second hydraulic rod (301) fixed at the top of a rectangular frame groove (3), and a rectangular pressure plate (302) located at the telescopic end of the second hydraulic rod (301). The rectangular pressure plate (302) is slidably connected to the rectangular frame groove (3).

5. The composite fireproof and heat-insulating board laminating device according to claim 1, characterized in that: An electric push rod (4) is fixedly inserted through the inside of the support rod (2). A connecting plate (401) is fixed to the telescopic end of the electric push rod (4). The connecting plate (401) is slidably connected to the inside of the two sides of the mounting base (1). The two sides of the connecting plate (401) are fixedly connected to the limiting protrusion (403). The connecting plate (401) is set in two sets, and the two sets of connecting plates (401) are symmetrically distributed about the mounting base (1).

6. The composite fireproof and heat-insulating board laminating device according to claim 1, characterized in that: The lower end of the negative pressure shell (5) extends into the interior of the mounting base (1) and is fixed with a cavity shell (501). The lower end of the mounting base (1) is fixed with a vacuum pump (502). The output end of the vacuum pump (502) is fixed with a conduit (503), and the conduit (503) is in a flow connection with the cavity shell (501).