CN111945908B

CN111945908B - High-heat-insulation heat-preservation plate and preparation method thereof

Info

Publication number: CN111945908B
Application number: CN202010754951.3A
Authority: CN
Inventors: 赵桂英; 李奕贤; 王勇; 龚魏魏; 王忠光; 张清宇
Original assignee: Xuzhou College of Industrial Technology
Current assignee: Jiangmen Pengmei Lujia Kitchen And Bathroom Technology Co ltd
Priority date: 2020-07-31
Filing date: 2020-07-31
Publication date: 2021-09-28
Anticipated expiration: 2040-07-31
Also published as: CN111945908A

Abstract

The invention discloses a high-heat-insulation heat-preservation plate which comprises a first base plate and a second base plate, wherein two ends of one side of the first base plate are connected with a first connecting plate, one side of the first connecting plate is connected with a first sliding plate, two ends of one side of the second base plate are provided with first clamping grooves, and one side of each first clamping groove is provided with a first sliding groove. According to the invention, the first substrate and the second substrate can be primarily spliced by inserting the second connecting plates and the second sliding plates at two ends of one side of the bump into the second clamping grooves on the inner walls of the corresponding first groove and the second groove, the first connecting plate and the first sliding plate at one side of the first substrate are inserted into the first clamping groove at one side of the second substrate, and the first substrate and the second substrate can be subjected to second-step splicing installation by completing close attachment of the first substrate and one side of the second substrate, so that the first substrate and the second substrate can be spliced, the splicing installation and disassembly are convenient, the splicing efficiency is high, and the requirement of rapid construction can be met.

Description

High-heat-insulation heat-preservation plate and preparation method thereof

Technical Field

The invention relates to the technical field of insulation boards, in particular to a high-heat-insulation board and a preparation method thereof.

Background

Along with the rapid rise of the building industry, the building market is continuously expanding, wherein the roof design is one of core designs in architecture, the traditional roof function is single, the traditional roof is gradually not applicable to the current environment, the living standard of people is continuously improved at present, and the requirement on the living environment is higher and higher, therefore, an architect begins to adopt the insulation board to increase the functionality of the roof, the insulation board takes polystyrene resin as a raw material and other raw and auxiliary materials and polymer, a catalyst is injected simultaneously through heating and mixing, and then the hard foam plastic board is manufactured through extrusion molding, has the moisture-proof and waterproof performances, can reduce the thickness of an outer enclosure structure of a building, and further increases the indoor use area.

At present, but it is when in actual use, current thermal-insulated heated board often the structure is complicated in the use, and then leads to the concatenation inconvenient between the thermal-insulated heated board, and the installation is with dismantling consuming time power, and the concatenation is inefficient, can not satisfy the demand of quick construction, leads to the delay time limit for a project.

Therefore, it is necessary to invent a high thermal insulation board and a preparation method thereof to solve the above problems.

Disclosure of Invention

The invention aims to provide a high heat insulation board and a preparation method thereof, wherein a first substrate and a second substrate can be preliminarily spliced and installed by inserting a second connecting plate and a second sliding plate at two ends of one side of a bump into a second clamping groove on the inner wall of a corresponding first groove and a corresponding second groove, the second sliding plate slides along a second sliding groove on the inner wall of the second clamping groove by moving a splicing plate, the first connecting plates at two ends of one side of the first substrate and the first sliding plate are sequentially inserted into first clamping grooves at two ends of one side of the second substrate, the first sliding plate slides along the first sliding groove on the inner wall of the first clamping groove by moving the first substrate until the first substrate is tightly attached to one side of the second substrate and the splicing plate is overlapped with the first groove and the second groove simultaneously, so that the first substrate and the second substrate can be spliced and installed in a second step, and the splicing of the first substrate and the second substrate can be completed, thereby be convenient for concatenation installation and dismantlement, the concatenation is efficient, can satisfy the demand of quick construction to solve the above-mentioned weak point in the technique.

In order to achieve the above purpose, the invention provides the following technical scheme: in a first aspect, the invention provides a high thermal insulation board, which comprises a first substrate and a second substrate, wherein two ends of one side of the first substrate are symmetrically connected with first connecting plates, the opposite sides of the top ends of the two first connecting plates are both connected with first sliding plates, two ends of one side of the second substrate, which is close to the first substrate, are symmetrically provided with first clamping grooves, the two first clamping grooves are respectively connected with corresponding first connecting plates, the opposite sides of the two first clamping grooves are both provided with first sliding grooves, and the two first sliding grooves are respectively in sliding connection with corresponding first sliding plates;

first recess and second recess have been seted up respectively at first base plate and second base plate one side both ends in opposite directions, every the second draw-in groove has all been seted up on the infrabasal plate of first recess and second recess, every the second spout has all been seted up to bottom one side of second draw-in groove, and two all be equipped with the concatenation subassembly in first recess and the second recess, every the concatenation subassembly all includes splice plate, every one side of splice plate all is connected with the lug, every the lug is kept away from the equal symmetric connection in one side both ends that correspond the splice plate and is had the second connecting plate, every the second connecting plate all is connected with corresponding second draw-in groove, every one side of second connecting plate all is connected with the second slide, every the second slide all with correspond second spout sliding connection.

Preferably, the overall dimension of each splicing plate is matched with the sum of the overall dimensions of the two corresponding first grooves and the second grooves.

Preferably, one side in each first groove and one side in each second groove are connected with a stop block, and the sum of the length sizes of the two corresponding stop blocks and the length sizes of the two corresponding lugs are the same as the length size of the splice plate.

Preferably, the length dimension of the first sliding plate and the length dimension of the first clamping groove are matched, and the length dimension of the second sliding plate and the length dimension of the second clamping groove are matched.

Preferably, the distance between the bottom of the second sliding plate and the top of the corresponding splice plate is equal to the distance between the bottom of the second chute and the top of the first groove.

Preferably, threaded rods are symmetrically arranged at two ends of one side, far away from the convex block, of the splicing plate, and one ends of the two threaded rods sequentially penetrate through the splicing plate, the convex block, the first groove and the second sliding plate and then are connected with the inner wall of the second sliding groove.

Preferably, the first substrate and the second substrate are sequentially composed of a wear-resistant layer, an anti-corrosion layer, a heat-insulating layer and a fireproof layer from top to bottom, the wear-resistant layer is prepared by mixing siliceous materials, calcareous materials and plant fibers, the anti-corrosion layer is prepared by carbon fiber and resin composite materials, the heat-insulating layer is prepared by polyurethane foaming materials, the heat-insulating layer is prepared by phenolic resin materials, and the fireproof layer is prepared by epoxy resin materials.

In a second aspect, the invention provides a preparation method of a high thermal insulation board, which comprises the following specific steps:

s, firstly, respectively placing the two splicing assemblies into the corresponding first groove and the second groove, then inserting the second connecting plates and the second sliding plates at the two ends of one side of the bump into the second clamping grooves on the inner walls of the corresponding first groove and the second groove, and then moving the splicing plates to enable the second sliding plates to slide along the second sliding grooves on the inner walls of the second clamping grooves;

s: then, sequentially inserting the first connecting plates at two ends of one side of the first substrate and the first sliding plate into the first clamping grooves at two ends of one side of the second substrate, and then moving the first substrate to enable the first sliding plate to slide along the first sliding groove on the inner wall of the first clamping groove until the first substrate and one side of the second substrate are tightly attached and enable the splicing plates to be overlapped with the first grooves and the second grooves;

s: and finally, a plurality of threaded rods sequentially penetrate through the corresponding splicing plates, the corresponding bumps, the corresponding first grooves, the corresponding second sliding plates and the inner wall of the corresponding second sliding groove, so that the first substrate and the second substrate can be spliced and assembled.

In the technical scheme, the invention provides the following technical effects and advantages:

the first substrate and the second substrate can be spliced and installed in the second step by inserting the second connecting plate and the second sliding plate at the two ends of one side of the bump into the second clamping grooves on the inner walls of the corresponding first groove and the second groove, the second sliding plate can slide along the second sliding groove on the inner wall of the second clamping groove by moving the splicing plate, the first connecting plate and the first sliding plate at the two ends of one side of the first substrate are sequentially inserted into the first clamping grooves at the two ends of one side of the second substrate, the first sliding plate can slide along the first sliding groove on the inner wall of the first clamping groove by moving the first substrate until the splicing plate is tightly attached to one side of the first substrate and the second substrate and is overlapped with the first groove and the second groove, the first substrate and the second substrate can be spliced and installed in the second step, and the splicing of the first substrate and the second substrate can be completed, thereby facilitating the splicing, installation and disassembly, the splicing efficiency is high, and the requirement of rapid construction can be met.

Drawings

In order to more clearly illustrate the embodiments of the present application or technical solutions in the prior art, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings can be obtained by those skilled in the art according to the drawings.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of a first substrate structure according to the present invention;

FIG. 3 is a schematic view of a second substrate structure according to the present invention;

FIG. 4 is a cross-sectional view of the left side structure of the first substrate according to the present invention;

FIG. 5 is a schematic view of the construction of the splice assembly of the present invention;

fig. 6 is a schematic view of the internal structure of the first substrate and the second substrate according to the present invention.

Description of reference numerals:

1. a first substrate; 11. a first groove; 12. a stopper; 13. a second card slot; 14. a second chute; 15. a first connecting plate; 16. a first slide plate; 2. a second substrate; 21. a second groove; 22. a first card slot; 23. a first chute; 3. splicing the components; 31. splicing plates; 32. a bump; 33. a second connecting plate; 34. a second slide plate; 35. a threaded rod; 4. a wear layer; 5. a corrosion-resistant layer; 6. a thermal insulation layer; 7. a heat-insulating layer; 8. and a fire-proof layer.

Detailed Description

In order to make the technical solutions of the present invention better understood, those skilled in the art will now describe the present invention in further detail with reference to the accompanying drawings.

The invention provides a high-heat-insulation heat-preservation plate as shown in figures 1-6, which comprises a first substrate 1 and a second substrate 2, wherein two ends of one side of the first substrate 1 are symmetrically connected with first connecting plates 15, the opposite sides of the top ends of the two first connecting plates 15 are connected with first sliding plates 16, two ends of one side, close to the first substrate 1, of the second substrate 2 are symmetrically provided with first clamping grooves 22, the two first clamping grooves 22 are respectively connected with the corresponding first connecting plates 15, the opposite sides of the two first clamping grooves 22 are respectively provided with first sliding grooves 23, and the two first sliding grooves 23 are respectively in sliding connection with the corresponding first sliding plates 16;

a first groove 11 and a second groove 21 are respectively arranged at two ends of one opposite side of the first base plate 1 and the second base plate 2, a second clamping groove 13 is respectively arranged on the inner bottom plate of each first groove 11 and the second groove 21, a second sliding groove 14 is respectively arranged at one side of the bottom of each second clamping groove 13, and two splicing assemblies 3 are arranged in the first grooves 11 and the second grooves 21, each splicing assembly 3 comprises a splicing plate 31, one side of each splicing plate 31 is connected with a convex block 32, two ends of one side, away from the corresponding splicing plate 31, of each convex block 32 are symmetrically connected with second connecting plates 33, each second connecting plate 33 is connected with the corresponding second clamping groove 13, one side of each second connecting plate 33 is connected with a second sliding plate 34, and each second sliding plate 34 is connected with the corresponding second sliding groove 14 in a sliding manner.

Further, in the above technical solution, the overall dimension of each splice plate 31 is matched with the sum of the overall dimensions of the two corresponding first grooves 11 and second grooves 21.

Further, in the above technical solution, one side of each of the first groove 11 and the second groove 21 is connected with a stopper 12, and the sum of the length sizes of the two corresponding stoppers 12 and the bumps 32 is the same as the length size of the splice plate 31.

Further, in the above technical solution, the length dimension of the first sliding plate 16 is matched with the length dimension of the first slot 22, and the length dimension of the second sliding plate 34 is matched with the length dimension of the second slot 13.

Further, in the above technical solution, the distance between the bottom of the second sliding plate 34 and the top of the corresponding splice plate 31 is equal to the distance between the bottom of the second chute 14 and the top of the first groove 11.

Further, in the above technical solution, threaded rods 35 are symmetrically arranged at two ends of one side of the splice plate 31, which is far away from the projection 32, and one ends of the two threaded rods 35 sequentially penetrate through the splice plate 31, the projection 32, the first groove 11, and the second sliding plate 34 and then are connected with the inner wall of the second chute 14.

Further, in the above technical solution, the first substrate 1 and the second substrate 2 are sequentially composed of a wear-resistant layer 4, a corrosion-resistant layer 5, a thermal insulation layer 6, a thermal insulation layer 7 and a fire-proof layer 8 from top to bottom, the wear-resistant layer 4 is made of silicon, calcium material and plant fiber, the corrosion-resistant layer 5 is made of carbon fiber and resin composite material, the thermal insulation layer 6 is made of polyurethane foam material, the thermal insulation layer 7 is made of phenolic resin material, the fire-proof layer 8 is made of epoxy resin material, and the wear-resistant layer 4 made of silicon, calcium material and plant fiber, the corrosion-resistant layer 5 made of carbon fiber and resin composite material, the thermal insulation layer 6 made of polyurethane foam material, the thermal insulation layer 7 made of phenolic resin material and the fire-proof layer 8 made of epoxy resin material are mixed, so that the wear resistance of the first substrate 1 and the second substrate 2 can be improved, Corrosion resistance, heat insulation, heat preservation and fire resistance.

The implementation mode is specifically as follows: when the invention is used, two splicing assemblies 3 are respectively placed into the corresponding first groove 11 and second groove 21, the second connecting plate 33 and the second sliding plate 34 at two ends of one side of the bump 32 are inserted into the second clamping groove 13 on the inner wall of the corresponding first groove 11 and second groove 21, so that the first substrate 1 and the second substrate 2 can be preliminarily spliced and installed, the second sliding plate 34 slides along the second sliding groove 14 on the inner wall of the second clamping groove 13 by moving the splicing plate 31, the first connecting plate 15 and the first sliding plate 16 at two ends of one side of the first substrate 1 are sequentially inserted into the first clamping grooves 22 at two ends of one side of the second substrate 2 by moving the first substrate 1, the first sliding plate 16 slides along the first sliding groove 23 on the inner wall of the first clamping groove 22 until the first substrate 1 and one side of the second substrate 2 are tightly attached, and the splicing plate 31 is coincided with the first groove 11 and the second groove 21, thereby can carry out the installation of second step concatenation with first base plate 1 and second base plate 2, through running through the splice plate 31 that corresponds with a plurality of threaded rods 35 in proper order, lug 32, first recess 11, second slide 34 is connected with the inner wall of second spout 14, can accomplish the concatenation equipment of first base plate 1 and second base plate 2, thereby be convenient for concatenation installation and dismantlement, the concatenation efficiency is high, can satisfy the demand of quick construction, this embodiment has specifically solved and has had current thermal-insulated heated board often the structure complicacy in the use among the prior art, and then lead to the concatenation between the thermal-insulated heated board inconvenient, the consuming time power of installation and dismantlement, the concatenation efficiency is low, can not satisfy the demand of quick construction, lead to the problem of delay time limit.

The preparation method of the high heat insulation board of the embodiment comprises the following steps:

s1, firstly, the two splicing assemblies 3 are respectively placed into the corresponding first groove 11 and the second groove 21, then the second connecting plates 33 and the second sliding plates 34 at two ends of one side of the bump 32 are inserted into the second clamping grooves 13 on the inner walls of the corresponding first groove 11 and the second groove 21, and then the splicing plates 31 are moved to enable the second sliding plates 34 to slide along the second sliding grooves 14 on the inner walls of the second clamping grooves 13;

s2: then, sequentially inserting the first connecting plates 15 and the first sliding plates 16 at two ends of one side of the first substrate 1 into the first clamping grooves 22 at two ends of one side of the second substrate 2, and then moving the first substrate 1 to enable the first sliding plates 16 to slide along the first sliding grooves 23 on the inner walls of the first clamping grooves 22 until the first substrate 1 and the second substrate 2 are tightly attached to each other and simultaneously enabling the splicing plates 31 to coincide with the first grooves 11 and the second grooves 21;

s3: and finally, the threaded rods 35 sequentially penetrate through the corresponding splicing plates 31, the bumps 32, the first grooves 11, the second sliding plates 34 and the inner wall of the second sliding groove 14 to be connected, so that the splicing assembly of the first substrate 1 and the second substrate 2 can be completed.

The working principle of the invention is as follows:

referring to the attached drawings 1-6 of the specification, firstly, two splicing assemblies 3 are respectively placed into a first groove 11 and a second groove 21, a second connecting plate 33 and a second sliding plate 34 at two ends of one side of a bump 32 are inserted into a second clamping groove 13 on the inner wall of the first groove 11 and the second groove 21, then the splicing plates 31 are moved to enable the second sliding plates 34 to slide along a second sliding groove 14 on the inner wall of the second clamping groove 13, then a first connecting plate 15 and a first sliding plate 16 at two ends of one side of a first substrate 1 are sequentially inserted into first clamping grooves 22 at two ends of one side of a second substrate 2, then the first substrate 1 is moved to enable the first sliding plate 16 to slide along a first sliding groove 23 on the inner wall of the first clamping groove 22 until the first substrate 1 and the second substrate 2 are tightly attached to each other and the splicing plates 31 are coincided with the first groove 11 and the second groove 21, and finally a plurality of threaded rods 35 sequentially penetrate through the corresponding splicing plates 31, 21, The bump 32, the first groove 11, the second sliding plate 34 are connected with the inner wall of the second sliding groove 14, and the splicing assembly of the first substrate 1 and the second substrate 2 can be completed.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that the described embodiments may be modified in various different ways without departing from the spirit and scope of the invention. Accordingly, the drawings and description are illustrative in nature and should not be construed as limiting the scope of the invention.

Claims

1. A high thermal-insulated heated board, includes first base plate (1) and second base plate (2), its characterized in that: two ends of one side of the first substrate (1) are symmetrically connected with first connecting plates (15), one opposite side of the top ends of the two first connecting plates (15) is connected with first sliding plates (16), two ends of one side, close to the first substrate (1), of the second substrate (2) are symmetrically provided with first clamping grooves (22), the two first clamping grooves (22) are respectively connected with the corresponding first connecting plates (15), one opposite side of the two first clamping grooves (22) is provided with first sliding grooves (23), and the two first sliding grooves (23) are respectively in sliding connection with the corresponding first sliding plates (16);

the two ends of one side of the first substrate (1) and the two ends of one side of the second substrate (2) which are opposite to each other are respectively provided with a first groove (11) and a second groove (21), each inner bottom plate of the first groove (11) and the second groove (21) is provided with a second clamping groove (13), one side of the bottom of each second clamping groove (13) is provided with a second sliding groove (14), splicing assemblies (3) are arranged in the two first grooves (11) and the two second grooves (21), each splicing assembly (3) comprises a splicing plate (31), one side of each splicing plate (31) is connected with a lug (32), two ends of one side of each lug (32) far away from the corresponding splicing plate (31) are symmetrically connected with second connecting plates (33), each second connecting plate (33) is connected with the corresponding second clamping groove (13), and one side of each second connecting plate (33) is connected with a second sliding plate (34), each second sliding plate (34) is connected with the corresponding second sliding chute (14) in a sliding mode.

2. The high thermal insulation board according to claim 1, characterized in that: the overall dimension of each splicing plate (31) is matched with the sum of the overall dimensions of the two corresponding first grooves (11) and the second grooves (21).

3. The high thermal insulation board according to claim 1, characterized in that: one side in each first groove (11) and one side in each second groove (21) are connected with a stop block (12), and the sum of the length sizes of the two corresponding stop blocks (12) and the two corresponding convex blocks (32) is the same as the length size of the splicing plate (31).

4. The high thermal insulation board according to claim 1, characterized in that: the length dimension of the first sliding plate (16) is matched with the length dimension of the first clamping groove (22), and the length dimension of the second sliding plate (34) is matched with the length dimension of the second clamping groove (13).

5. The high thermal insulation board according to claim 1, characterized in that: the distance between the bottom of the second sliding plate (34) and the top of the corresponding splicing plate (31) is equal to the distance between the bottom of the second sliding chute (14) and the top of the first groove (11).

6. The high thermal insulation board according to claim 1, characterized in that: threaded rods (35) are symmetrically arranged at two ends of one side, away from the convex block (32), of the splicing plate (31), and one ends of the two threaded rods (35) sequentially penetrate through the splicing plate (31), the convex block (32), the first groove (11) and the second sliding plate (34) and then are connected with the inner wall of the second sliding groove (14).

7. The high thermal insulation board according to claim 1, characterized in that: the first substrate (1) and the second substrate (2) are sequentially composed of a wear-resistant layer (4), an anti-corrosion layer (5), a heat-insulating layer (6), a heat-insulating layer (7) and a fireproof layer (8) from top to bottom, wherein the wear-resistant layer (4) is prepared by mixing siliceous materials, calcareous materials and plant fibers, the anti-corrosion layer (5) is prepared by carbon fiber and resin composite materials, the heat-insulating layer (6) is prepared by polyurethane foaming materials, the heat-insulating layer (7) is prepared by phenolic resin materials, and the fireproof layer (8) is prepared by epoxy resin materials.

8. The method for preparing the high heat insulation board according to any one of claims 1 to 7, characterized in that: the method comprises the following specific steps:

s1, firstly, the two splicing assemblies (3) are respectively placed into the corresponding first groove (11) and the second groove (21), then the second connecting plates (33) and the second sliding plates (34) at two ends of one side of the bump (32) are inserted into the second clamping grooves (13) on the inner walls of the corresponding first groove (11) and the second groove (21), and then the splicing plates (31) are moved to enable the second sliding plates (34) to slide along the second sliding grooves (14) on the inner walls of the second clamping grooves (13);

s2: then, sequentially inserting the first connecting plates (15) at two ends of one side of the first substrate (1) and the first sliding plates (16) into the first clamping grooves (22) at two ends of one side of the second substrate (2), and then moving the first substrate (1) to enable the first sliding plates (16) to slide along the first sliding grooves (23) on the inner walls of the first clamping grooves (22) until the first substrate (1) and one side of the second substrate (2) are tightly attached, and enabling the splicing plates (31) to coincide with the first grooves (11) and the second grooves (21);

s3: and finally, a plurality of threaded rods (35) sequentially penetrate through the corresponding splicing plates (31), the corresponding bumps (32), the corresponding first grooves (11), the corresponding second sliding plates (34) and the inner wall of the second sliding groove (14) to be connected, so that the first substrate (1) and the second substrate (2) can be spliced and assembled.