A method for installing a modified vitrified microsphere composite board

By using the drying support mechanism and positioning components of the installation device, the problems of insufficient adhesive curing and unstable installation of vitrified microsphere composite panels on damp walls are solved, achieving rapid curing and accurate installation.

CN117868440BActive Publication Date: 2026-07-07五矿二十三冶建设集团有限公司

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
五矿二十三冶建设集团有限公司
Filing Date
2024-02-01
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

In existing technologies, when vitrified microsphere composite panels are installed on damp walls, the adhesive curing effect is affected, and problems such as detachment and displacement are prone to occur during installation.

Method used

The wall surface is dried using a drying support mechanism in the installation device. The positioning and lifting components work together to ensure that the composite panel is dry and supported before the adhesive is applied. Drying gas is used to accelerate the curing of the adhesive, and the positioning components ensure installation accuracy.

Benefits of technology

It effectively reduces the impact of moisture on the adhesive, improves the curing speed of the adhesive, avoids the sagging and displacement of the composite board, increases the convenience and accuracy of installation, and improves installation efficiency.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

The application discloses a kind of installation methods of modified vitrified microsphere composite board, specifically includes the following steps: first, the installation device is moved to wall body outside, the dry support mechanism in installation device is used to carry out dry treatment to wall body surface, after processing, adhesive is applied on wall body surface;The most edge installed composite board body is positioned using the positioning member in installation device, after composite board body is pasted on wall body surface, again dry using dry support mechanism to support composite board body and press tightly and dry again, accelerate adhesive solidification speed;The present application can dry the surface of wall body before adhesive is applied by combining dry support mechanism, wall body and composite board body, reduce the influence of humidity on adhesive application, and support and press tightly the composite board body pasted on adhesive, to avoid the situation of falling off, at the same time, dry gas can accelerate the solidification speed of composite board body and adhesive, the dry gas spray range can be adjusted, to expand the dry treatment range of wall body.
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Description

Technical Field

[0001] This invention belongs to the field of installation technology for modified vitrified microsphere composite panels, specifically relating to an installation method for modified vitrified microsphere composite panels. Background Technology

[0002] Modified vitrified microsphere composite board is a heat-insulating and waterproof board made by using expanded vitrified microspheres as aggregate, adding waterproofing agents and binders, and then processing them through processes such as formulation, screening, pressure molding, and drying. Modified vitrified microsphere composite board needs to be installed on the wall using adhesives.

[0003] For example, a high-strength composite panel and its installation method are disclosed in CN112572686A. The composite panel includes a first aerogel felt layer, a second aerogel felt layer, a PE board layer, and wedge components. The PE board layer comprises several layers of PE boards bonded together. The first aerogel felt layer is disposed at the upper end of the PE board layer, and the second aerogel felt layer is disposed at the lower end of the PE board layer. The wedge components have a U-shaped cross-section, with the U-shaped openings of the two wedge components facing each other. The PE board layer is disposed within the U-shaped openings of the two wedge components. During installation, the PE boards are installed layer by layer, with each layer installed before proceeding to the next. Finally, all the PE boards are installed between the wedge components on both sides. This invention not only meets the installation strength requirements of the high-strength composite panel but also avoids the problem of detachment.

[0004] In the aforementioned patent, the natural curing of the vitrified microsphere composite board on the adhesive takes a relatively long time. At the same time, there is a lack of corresponding drying treatment measures for the wall surface, which means that the dampness of the wall surface will affect the curing degree of the adhesive, thus affecting the installation and bonding effect of the vitrified microsphere composite board. To address this issue, we propose an installation method for a modified vitrified microsphere composite board. Summary of the Invention

[0005] The purpose of this invention is to provide an installation method for modified vitrified microsphere composite panels, in order to solve the problems mentioned in the background art, such as the potential for damp walls to affect the curing effect of adhesives and the solidification rate of vitrified microsphere composite panels and adhesives.

[0006] To achieve the above objectives, the present invention provides the following technical solution: a method for installing a modified vitrified microsphere composite board, specifically including the following steps:

[0007] 1S. First, move the installation device to the outside of the wall and use the drying support mechanism in the installation device to dry the wall surface. After drying, apply the adhesive to the wall surface.

[0008] 2S. Use the positioning components in the installation device to position the composite panel installed at the outermost edge. After the composite panel is attached to the wall surface, use the drying support mechanism to support and press the composite panel and dry it again to accelerate the curing speed of the adhesive.

[0009] 3S. When the composite board is gradually attached and installed upwards, the lifting component in the installation device is used to change the height of the drying support mechanism pressing and supporting the composite board.

[0010] Preferably, the installation device further includes a base, a lifting plate is provided above the base, the drying support mechanism is rotatably installed in the lifting plate, the drying support mechanism includes a mounting rod rotatably installed in the lifting plate, two rotating plates are rotatably sleeved on the mounting rod, a heating plate is provided at the rear end of the rotating plate, an air pump is provided on the upper surface of the heating plate, a plurality of drying air ports are provided on the rear surface of the heating plate along its length, and a support member for supporting the composite board is provided below the heating plate;

[0011] Heating wires are horizontally arranged inside the heating plate;

[0012] The supporting component includes a supporting plate located below the drying air inlet and supporting and pressing the composite plate body;

[0013] The rotating plate is equipped with a drive cylinder at its front end to drive its rotation.

[0014] Preferably, the outer end of the heating plate is vertically provided with a side plate, and the support member further includes a rotating shaft rotatably installed between the two side plates. A stabilizing seat is fixedly sleeved on the rotating shaft, and a telescopic cylinder is embedded inside the stabilizing seat. The rear end of the telescopic cylinder is rotatably connected to the front surface of the support plate.

[0015] Preferably, the support member further includes a drive motor fixed to the inner side of the right side plate, a fixed gear is provided on the rotating shaft, and a lower gear that meshes with the fixed gear is provided at the left end of the drive motor.

[0016] Preferably, a driving component is provided between the front end of the rotating plate and the lifting plate. The driving component includes a collar embedded in the rotating plate and rotatably sleeved on the mounting rod. A rectangular sliding hole is provided at the front end of the rotating plate along its length direction, and a guide slider is slidably disposed in the rectangular sliding hole.

[0017] Preferably, the piston rod inside the drive cylinder is rotatably connected to the lower surface of the guide slider, and a fixed base plate is provided at the bottom of the drive cylinder and fixed to the front surface of the lifting plate.

[0018] Preferably, the lifting component includes a fixed guide rail that is vertically fixed to the upper surface of the base and passes through the side of the lifting plate. A support shaft is provided on the outer side of the upper end of the fixed guide rail of the lifting plate. A guide wheel is fixedly sleeved on the support shaft. A cable that passes around the guide wheel is provided on the upper surface of the outer end of the lifting plate.

[0019] Preferably, a winding motor is provided on the upper surface of the base, located outside the fixed guide rail, and a take-up wheel is provided at the rear end of the winding motor, with the outer end of the cable wound around the take-up wheel.

[0020] Preferably, the rear surface of the outer end of the lifting plate is provided with a positioning component for positioning the composite plate. The positioning component includes a positioning plate vertically located outside the support plate. A horizontal rail is provided on the rear surface of the lifting plate. A sliding sleeve is sleeved on the horizontal rail. A vertical plate is provided on the upper surface of the sliding sleeve. A fixing lug is provided on the outer side of the positioning plate.

[0021] Preferably, a movable rod is fixed to the front surface of the fixed lug and extends through the vertical plate, and an elastic element is sleeved on the movable rod.

[0022] Compared with the prior art, the beneficial effects of the present invention are:

[0023] (1) By combining the drying support mechanism, the wall and the composite board, the present invention can dry the wall surface before the adhesive is applied, reduce the influence of moisture on the adhesive application, and support and press the composite board attached to the adhesive to avoid sagging and displacement. At the same time, the drying gas can accelerate the solidification speed of the composite board and the adhesive. The range of the drying gas spray can be rotated and adjusted to expand the drying treatment range of the wall.

[0024] (2) The present invention, through the design of the lifting component, can change the height of the drying air port and the supporting component as the bonding range of the composite board gradually expands, ensuring that the composite board can always be supported, increasing the ease of installation of the composite board and improving the support and adaptation range of the composite board.

[0025] (3) The present invention can position the side of the composite board that is closest to the edge by designing the positioning component, thereby increasing the accuracy of the composite board being attached and installed. At the same time, the positioning plate can be elastically extended and retracted, and can be easily pressed against the wall surface while positioning, thereby increasing the positioning range and convenience of the composite board. Attached Figure Description

[0026] Figure 1 This is a schematic diagram of the structure of the modified vitrified microsphere composite board installation device of the present invention;

[0027] Figure 2 This is a bottom view of the mounting device for the modified vitrified microsphere composite board of the present invention.

[0028] Figure 3 This is a schematic diagram of the installation device of the present invention;

[0029] Figure 4 For the present invention Figure 3 Schematic diagram of the drying support mechanism;

[0030] Figure 5 For the present invention Figure 4 Schematic diagram of the supporting components;

[0031] Figure 6 For the present invention Figure 4 Schematic diagram of the drive component;

[0032] Figure 7 For the present invention Figure 3 Schematic diagram of the lifting component;

[0033] Figure 8 For the present invention Figure 7 Schematic diagram of the positioning component;

[0034] In the diagram: 100, wall; 101, composite panel; 200, drying support mechanism; 201, mounting rod; 202, rotating plate; 203, heating plate; 204, air pump; 205, drying air inlet; 206, support component; 2061, rotating shaft; 2062, stabilizing seat; 2063, telescopic cylinder; 2064, fixed gear; 2065, lower gear; 2066, drive motor; 2067, support plate; 207, drive component; 2071, collar; 2072, rectangular sliding hole; 2073. Drive cylinder; 2074. Fixed base plate; 2075. Guide slider; 208. Side plate; 300. Base; 400. Lifting component; 401. Fixed guide rail; 402. Rewinding motor; 403. Rewinding wheel; 404. Cable; 405. Guide wheel; 500. Positioning component; 501. Positioning plate; 502. Horizontal rail; 503. Sliding sleeve; 504. Movable rod; 505. Fixed lug; 506. Limit bolt; 507. Elastic element; 508. Vertical plate; 600. Lifting plate. Detailed Implementation

[0035] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0036] Example 1

[0037] Please see Figure 1 - Figure 6This invention provides a technical solution: a method for installing a modified vitrified microsphere composite board, specifically including the following steps:

[0038] S1. First, move the installation device to the outside of the wall 100. The installation device includes a drying support mechanism 200, a lifting component 400 and a positioning component 500. Use the drying support mechanism 200 in the installation device to dry the surface of the wall 100. At the same time, the surface of the wall 100 can be cleaned to ensure the cleanliness of the surface of the wall 100. After the treatment, apply the adhesive to the surface of the wall 100.

[0039] S2. Position the composite panel 101 installed at the outermost edge using the positioning component 500 in the installation device. After the composite panel 101 is attached to the surface of the wall 100, use the drying support mechanism 200 to support and press the composite panel 101 and dry it again to accelerate the curing speed of the adhesive.

[0040] S3. When the composite board 101 is gradually attached and installed upwards, the lifting component 400 in the installation device is used to change the height of the drying support mechanism 200 pressing and supporting the composite board 101, thereby increasing the installation support range of the composite board 101.

[0041] In this embodiment, preferably, the installation device further includes a base 300, with casters on its lower surface and a lifting plate 600 above it. The lifting plate 600 can be U-shaped to facilitate support of the drying support mechanism 200. The drying support mechanism 200 is rotatably mounted in the lifting plate 600. Using the drying support mechanism 200, the surface of the wall 100 can be dried before the adhesive is applied, reducing the impact of moisture on the adhesive application. It also supports and presses the composite board 101 adhered to the adhesive, preventing sagging or shifting. Simultaneously, the drying gas accelerates the solidification speed of the composite board 101 and the adhesive. The drying gas spray range can be rotatably adjusted to expand the drying treatment range of the wall 100. The drying support mechanism 200 includes a caster rotatably mounted in the lifting plate 600. The mounting rod 201 in the 00 has two rotating plates 202 rotatably mounted on it. The rotating plates 202 can rotate around the mounting rod 201 to change the height of the rear drying air port 205, increase the working range of the drying air port 205, and reduce the influence of the height of the base 300 and the lifting plate 600 in the installation device. A heating plate 203 is provided at the rear end of the rotating plate 202. An air pump 204 is provided on the upper surface of the heating plate 203. Multiple drying air ports 205 are provided along the length of the rear surface of the heating plate 203. Each drying air port 205 consists of three drying nozzles, which are distributed in a forked manner. As the rotating plate 202 rotates, the surface of the wall 100 can be dried continuously. A support member 206 supporting the composite plate 101 is provided below the heating plate 203.

[0042] Heating wires are horizontally arranged inside the heating plate 203. The heating plate 203 is hollow inside, which makes it convenient to install multiple heating wires inside. The heating wires can heat the gas entering the heating plate 203, so that the gas maintains a certain temperature when it is discharged, which is convenient for drying the wall 100.

[0043] The support member 206 includes a support plate 2067 located below the drying air port 205 and supporting and pressing the composite plate 101. The support plate 2067 is rotatably connected to the telescopic cylinder 2063, which facilitates the rotation of the rotating plate 202. The support plate 2067 is easy to fit against the surface of the composite plate 101 for support and pressing.

[0044] The front end of the rotating plate 202 is provided with a drive cylinder 2073 to drive its rotation. The drive cylinder 2073 drives the front end of the rotating plate 202 to rotate upward, thereby causing the rear end of the rotating plate 202 to rotate downward and approach the bottom of the wall 100, so that the drying air port 205 can dry the bottom of the wall 100.

[0045] In this embodiment, preferably, a side plate 208 is vertically arranged at the outer end of the heating plate 203, and the two are connected by screws for easy disassembly and assembly. The support member 206 also includes a rotating shaft 2061 rotatably installed between the two side plates 208. A stabilizing seat 2062 is fixedly sleeved on the rotating shaft 2061. The stabilizing seat 2062 facilitates the support of the telescopic cylinder 2063. The telescopic cylinder 2063 is embedded inside the stabilizing seat 2062. The rear end of the telescopic cylinder 2063 is rotatably connected to the front surface of the support plate 2067. The longitudinal position of the support plate 2067 can be changed by the extension and retraction of the piston rod, and the rotatable connection facilitates the adjustment of the angle of the support plate 2067.

[0046] In this embodiment, preferably, the support member 206 further includes a drive motor 2066 fixed to the inner side of the right side plate 208, a fixed gear 2064 is provided on the rotating shaft 2061, and a lower gear 2065 that meshes with the fixed gear 2064 is provided at the left end of the drive motor 2066. The two meshing connections can drive the rotating shaft 2061 to rotate.

[0047] In this embodiment, preferably, a driving component 207 is provided between the front end of the rotating plate 202 and the lifting plate 600. By providing the driving component 207, the rotating plate 202 can be rotated using a mechanical structure, thereby changing the angle of the subsequent drying air port 205. The driving component 207 includes a collar 2071 embedded in the rotating plate 202 and rotatably sleeved on the mounting rod 201. A rectangular sliding hole 2072 is provided at the front end of the rotating plate 202 along its length direction. A guide slider 2075 is slidably provided in the rectangular sliding hole 2072. The guide slider 2075 is I-shaped, so that it is slidably connected to the rectangular sliding hole 2072 without disengaging. The piston rod inside the driving cylinder 2073 is rotatably connected to the lower surface of the guide slider 2075. The rotatable connection between the two facilitates the adaptation to the angle change of the rotating plate 202. A fixed base plate 2074 is provided at the bottom of the driving cylinder 2073 and fixed to the front surface of the lifting plate 600. A support frame is provided between the two to increase the installation strength of the driving cylinder 2073.

[0048] In summary, during use, the entire installation device can be moved close to the wall 100. When the position is suitable, the drive cylinder 2073 operates, and the internal piston rod extends, causing the rotating plate 202 to rotate upward around the mounting rod 201. The piston rod pushes the guide slider 2075 to slide in the rectangular sliding hole 2072. The rear end of the rotating plate 202 drives the drying air port 205 closer to the bottom of the wall 100. The air pump 204 operates to draw outside air into the heating plate 203, which is then heated by the internal heating wire. The heated gas is sprayed out through the drying air port 205 and acts on the wall 100, starting the drying process from the bottom of the wall 100. As the internal piston rod of the drive cylinder 2073 retracts, it causes the front end of the rotating plate 202 to rotate downward, while the rear end of the rotating plate 202 rotates upward, causing the drying air port 205 to gradually and evenly dry the wall 100. After drying, the drying process is gradually completed on the wall 100. Adhesive is applied to the surface of the composite board 101. After application, the composite board 101 is attached to the adhesive. Once attached, the drive cylinder 2073 operates, causing the rotating plate 202 to rotate. The drying air port 205 at the rear end is located at the composite board 101. The heated drying gas accelerates the solidification speed of the composite board 101 and the adhesive. Simultaneously, the drive motor 2066 operates, causing the lower gear 2065 to rotate. The fixed gear 2064 and the rotating shaft 2061 mesh with it rotate, changing the angle between the telescopic cylinder 2063 and the vertical direction, thereby changing the angle of the support plate 2067. As the telescopic cylinder 2063 operates, the internal piston rod drives the support plate 2067 to extend and press against the composite board 101, preventing the adhesive from sagging or shifting during solidification. This increases the ease of installation of the composite board 101, improves the adhesive solidification rate, and thus improves the installation efficiency of the composite board 101.

[0049] Example 2

[0050] Reference Figure 7This is the second embodiment of the present invention, which differs from the previous embodiment in that...

[0051] In this embodiment, preferably, the lifting component 400 includes a fixed guide rail 401 vertically fixed to the upper surface of the base 300 and passing through the side of the lifting plate 600. A groove is provided on the side of the lifting plate 600 for the fixed guide rail 401 to pass through. The fixed guide rail 401 can guide and limit the lifting plate 600. The lifting component 400 can adjust the height of the drying support mechanism 200 as the installation area of ​​the composite board 101 gradually increases, increasing the ease of installation of the composite board 101. A support shaft is provided on the outer side of the upper end, and a guide wheel 405 is fixedly sleeved on the support shaft. The guide wheel 405 can guide the cable 404. A cable 404 is provided on the upper surface of the outer end of the lifting plate 600, which passes around the guide wheel 405. As the length of the cable 404 decreases, it drives the lifting plate 600 to move upward. A winding motor 402 located outside the fixed guide rail 401 is provided on the upper surface of the base 300. A take-up wheel 403 is provided at the rear end of the winding motor 402, and the outer end of the cable 404 is wound around the take-up wheel 403.

[0052] In summary, when adjusting the support height of the composite board 101 during use, the winding motor 402 operates, driving the take-up wheel 403 to rotate. As the take-up wheel 403 rotates, the cable 404 is gradually wound around it, and the length of the cable 404 gradually shortens. The inner end of the cable 404 drives the lifting plate 600 to gradually move upward, thereby gradually raising the height of the drying support mechanism 200 installed on the lifting plate 600. This height is adjusted as the height of the composite board 101 increases, increasing the convenience of pressing and drying the composite board 101.

[0053] Example 3

[0054] Reference Figure 8 This is the third embodiment of the present invention, which differs from the previous two embodiments in that...

[0055] In this embodiment, preferably, a positioning member 500 for positioning the composite panel 101 is provided on the rear surface of the outer end of the lifting plate 600. Using the positioning member 500, the side of the composite panel 101 that is closest to the outermost edge can be positioned, increasing the accuracy of the composite panel 101's installation position. Simultaneously, the positioning plate 501 is elastically extendable, allowing it to be easily pressed against the surface of the wall 100 while positioning, increasing the positioning range and convenience of the composite panel 101. The positioning member 500 includes a positioning plate 501 vertically located outside the support plate 2067, and a horizontal rail 502 is provided on the rear surface of the lifting plate 600. The horizontal rail 502 can move with the lifting plate 600. The height is adjustable, so the length of the positioning plate 501 can be disassembled and replaced as needed. A sliding sleeve 503 is fitted on the horizontal rail 502, and a limit bolt 506 is provided between the two to adjust the distance between the two positioning plates 501. A vertical plate 508 is provided on the upper surface of the sliding sleeve 503. The vertical plate 508 supports and guides the movable rod 504. A fixed lug 505 is provided on the outer side of the positioning plate 501. A movable rod 504 that passes through the vertical plate 508 is fixed on the front surface of the fixed lug 505. An elastic element 507 is fitted on the movable rod 504. The two ends of the elastic element 507 are fixed to the fixed lug 505 and the surface of the vertical plate 508, respectively.

[0056] In summary, during use, when the installation device approaches the wall 100, the rear end of the positioning plate 501 first contacts the surface of the wall 100. As the installation device gradually approaches, the positioning plate 501, restricted by the wall 100, moves forward, causing the movable rod 504 to move forward. The elastic element 507 is compressed, allowing the positioning plate 501 to regain its elasticity when it is no longer restricted. When the positioning plate 501 is in contact with the surface of the wall 100, the right end of the composite plate 101 contacts the inner side of the positioning plate 501 during the installation of the composite plate 101, ensuring that the side of the composite plate 101 is in complete contact with the positioning plate 501. This guarantees the accuracy of the installation position of the composite plate 101 and increases the flatness and aesthetics of the subsequent bonding of the composite plate 101.

[0057] In use, the installation device is moved to a suitable position outside the wall 100. The surface of the wall 100 is first dried using the drying support mechanism 200. After drying, adhesive is applied to the surface of the wall 100. When the composite panel 101 is installed on the adhesive, the positioning component 500 positions the outermost edge of the composite panel 101. At the same time, when the composite panel 101 is attached to the adhesive, the support component 206 supports and presses the composite panel 101 tightly. Meanwhile, the drying gas sprayed from the drying port 205 is used to dry the composite panel 101 and the adhesive, thereby accelerating the solidification speed of the composite panel 101 and the adhesive, thus increasing the installation and solidification efficiency of the composite panel 101. As the area of ​​the composite panel 101 increases, the height of the drying support mechanism 200 is adjusted using the lifting component 400 to increase the ease of installation of the composite panel 101.

[0058] Although embodiments of the 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 invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A method for installing a modified vitrified microsphere composite board, characterized in that: Specifically, the following steps are included: S1. First, move the installation device to the outside of the wall (100), and use the drying support mechanism (200) in the installation device to dry the surface of the wall (100). After the drying process, apply the adhesive to the surface of the wall (100). S2. Use the positioning component (500) in the installation device to position the composite panel (101) installed at the outermost edge. After the composite panel (101) is attached to the surface of the wall (100), use the drying support mechanism (200) to support and press the composite panel (101) and dry it again to speed up the curing speed of the adhesive. S3. When the composite board (101) is gradually attached and installed upwards, the lifting component (400) in the installation device is used to change the height of the drying support mechanism (200) pressing and supporting the composite board (101). The installation device also includes a base (300), a lifting plate (600) is provided above the base (300), the drying support mechanism (200) is rotatably installed in the lifting plate (600), the drying support mechanism (200) includes an installation rod (201) rotatably installed in the lifting plate (600), two rotating plates (202) are rotatably sleeved on the installation rod (201), a heating plate (203) is provided at the rear end of the rotating plate (202), an air pump (204) is provided on the upper surface of the heating plate (203), a plurality of drying air ports (205) are provided on the rear surface of the heating plate (203) along its length, and a support member (206) for supporting the composite plate (101) is provided below the heating plate (203); Heating wires are horizontally arranged inside the heating plate (203); The support member (206) includes a support plate (2067) located below the drying air inlet (205) and supporting and pressing the composite plate (101); The front end of the rotating plate (202) is provided with a drive cylinder (2073) to drive its rotation; The heating plate (203) has a side plate (208) vertically arranged at its outer end. The support member (206) also includes a rotating shaft (2061) rotatably installed between the two side plates (208). A stabilizing seat (2062) is fixedly sleeved on the rotating shaft (2061). A telescopic cylinder (2063) is embedded inside the stabilizing seat (2062). The rear end of the telescopic cylinder (2063) is rotatably connected to the front surface of the support plate (2067). The support member (206) also includes a drive motor (2066) fixed to the inner side of the right side plate (208), a fixed gear (2064) is provided on the rotating shaft (2061), and a lower gear (2065) meshing with the fixed gear (2064) is provided at the left end of the drive motor (2066). A driving component (207) is provided between the front end of the rotating plate (202) and the lifting plate (600). The driving component (207) includes a collar (2071) embedded in the rotating plate (202) and rotatably sleeved on the mounting rod (201). A rectangular sliding hole (2072) is provided at the front end of the rotating plate (202) along its length direction. A guide slider (2075) is slidably provided in the rectangular sliding hole (2072). The piston rod inside the drive cylinder (2073) is rotatably connected to the lower surface of the guide slider (2075), and a fixed base plate (2074) fixed to the front surface of the lifting plate (600) is provided at the bottom of the drive cylinder (2073). The lifting component (400) includes a fixed guide rail (401) that is vertically fixed to the upper surface of the base (300) and passes through the side of the lifting plate (600). A support shaft is provided on the outer side of the upper end of the fixed guide rail (401), and a guide wheel (405) is fixedly sleeved on the support shaft. A cable (404) that passes around the guide wheel (405) is provided on the upper surface of the outer end of the lifting plate (600).

2. The installation method of the modified vitrified microsphere composite board according to claim 1, characterized in that: The upper surface of the base (300) is provided with a winding motor (402) located outside the fixed guide rail (401), and a take-up wheel (403) is provided at the rear end of the winding motor (402), and the outer end of the cable (404) is wound around the take-up wheel (403).

3. The installation method of the modified vitrified microsphere composite board according to claim 1, characterized in that: The rear surface of the outer end of the lifting plate (600) is provided with a positioning component (500) for positioning the composite plate (101). The positioning component (500) includes a positioning plate (501) located vertically outside the support plate (2067). A horizontal rail (502) is provided on the rear surface of the lifting plate (600). A sliding sleeve (503) is sleeved on the horizontal rail (502). A vertical plate (508) is provided on the upper surface of the sliding sleeve (503). A fixing lug (505) is provided on the outer side of the positioning plate (501).

4. The installation method of the modified vitrified microsphere composite board according to claim 3, characterized in that: The front surface of the fixed lug (505) is fixed with a movable rod (504) that is movable through the upright plate (508), and an elastic element (507) is sleeved on the movable rod (504).