CN117605166A - Reinforcing device for disassembly-free composite insulation board and construction method of reinforcing device - Google Patents

Abstract

The invention discloses a reinforcing device for a disassembly-free composite heat insulation board and a construction method thereof, and relates to a beam assembly, a top support assembly and a locking assembly, wherein the beam assembly comprises a first beam assembly and a second beam assembly which is arranged in parallel with the first beam assembly, and two first beams and two second Liang Qiahao form four long sides of a cuboid; the top support assembly comprises a plurality of first top support assemblies and a plurality of second top support assemblies, the plurality of first top support assemblies are vertically movably arranged between the two first groove-shaped sliding rails, and the plurality of second top support assemblies are vertically movably arranged between the two second groove-shaped sliding rails; the locking component is used for fixedly connecting the first beam component and the second beam component; the two locking assemblies are respectively close to the two ends of the beam assembly; the method solves the problems that the existing split bolt for reinforcing the disassembly-free composite insulation board is complex in installation process and low in construction efficiency.

Description

Reinforcing device for disassembly-free composite insulation board and construction method of reinforcing device

Technical Field

The invention relates to the field of building construction, in particular to a reinforcing device for a disassembly-free composite insulation board and a construction method thereof.

Background

The disassembly-free composite heat insulation board is a novel heat insulation material, has the characteristics of simple and convenient installation, space saving, energy saving, environmental protection and good fireproof performance, and is widely applied to the fields of building external wall heat insulation and the like.

The composite insulation board exempts from to tear open in the use, exempt from to tear open the composite insulation board and pass through the heat preservation nail and install in the wall body reinforcing bar outside, the wall body reinforcing bar inboard installation inboard template, in order to guarantee to exempt from to tear open the wall body mould that composite insulation board and inboard template constitute has enough intensity, need install a large amount of split bolts between exempting from to tear open the composite insulation board and inboard template, before the split bolt installation, need be in advance drilling between exempt from to tear open composite insulation board and inboard template, and ensure to counterpoint accuracy, and follow-up still need do further treatments such as truncated cone or cutting to the part that split bolt stretches out the wall body, use of a large amount of split bolts makes the installation of exempting from to tear open the composite insulation board complicacy, the efficiency of construction low.

Disclosure of Invention

The invention provides a reinforcing device for a disassembly-free composite heat-insulating plate and a construction method thereof, which are used for solving the problems of complex installation process and low construction efficiency of the conventional split bolts for reinforcing the disassembly-free composite heat-insulating plate.

The invention relates to a reinforcing device for a disassembly-free composite insulation board and a construction method thereof, which adopts the following technical scheme: the device comprises:

the beam assembly comprises a first beam assembly and a second beam assembly which is arranged in parallel with the first beam assembly, wherein the first beam assembly comprises two first beams, a first connecting piece fixedly connected with the two first beams and a first groove-shaped sliding rail which is arranged on the first beams in parallel; the second beam assembly comprises two second beams, a second connecting piece fixedly connected with the two second beams and a second groove-shaped sliding rail arranged on the second beams in parallel; the two first beams and the two second Liang Qiahao form four long sides of a cuboid; the notches of the two first groove-shaped sliding rails are arranged in opposite directions, and the notches of the two second groove-shaped sliding rails are arranged in opposite directions;

the top support assembly comprises a plurality of first top support assemblies and a plurality of second top support assemblies, the plurality of first top support assemblies are vertically and movably arranged between the two first groove-shaped sliding rails, and the plurality of second top support assemblies are vertically and movably arranged between the two second groove-shaped sliding rails;

the locking assembly is used for fixedly connecting the first beam assembly and the second beam assembly; the two locking assemblies are respectively close to the two ends of the beam assembly.

Preferably, the first top support assembly comprises a first primary sliding piece and a first top support screw vertically penetrating through the first primary sliding piece, two ends of the first primary sliding piece are provided with protrusions, the two protrusions are oppositely arranged, and the protrusions at the two ends of the first primary sliding piece are respectively connected with the two first groove-shaped sliding rails in a matched mode;

the second top support assembly comprises a second first-stage sliding piece and a second top support screw rod vertically penetrating through the second first-stage sliding piece, protrusions are arranged at two ends of the second first-stage sliding piece, the two protrusions are oppositely arranged, and the protrusions at two ends of the second first-stage sliding piece are respectively connected with the two second groove-type sliding rails in a matched mode.

Preferably, the length of the first top support screw rod is larger than the thickness of the first beam, and a handle is vertically arranged at the outer end of the first top support screw rod;

the length of the second top support screw rod is greater than the thickness of the second beam, and a handle is vertically arranged at the outer end of the second top support screw rod.

Preferably, the first primary sliding piece is in threaded connection with the first supporting screw rod, and the second primary sliding piece is in threaded connection with the second supporting screw rod;

the first primary sliding piece is in sliding connection with two end parts of the first U-shaped pressing plate, and when the first supporting screw rod rotates, the first U-shaped pressing plate can be pushed to move towards the direction of the second supporting screw rod;

the second-stage sliding piece is in sliding connection with two end parts of the second U-shaped pressing plate, and when the second jacking screw rotates, the second U-shaped pressing plate can be pushed to move towards the direction of the first jacking screw.

Preferably, two ends of the first U-shaped pressing plate are inserted at two sides of the first primary sliding piece;

two ends of the second U-shaped pressing plate are inserted into two sides of the second-stage sliding piece.

Preferably, a rubber pad is arranged on one side of the first U-shaped pressing plate, which is close to the second U-shaped pressing plate, and a rubber pad is arranged on one side of the second U-shaped pressing plate, which is close to the first U-shaped pressing plate;

the length of the first U-shaped pressing plate is greater than the thickness of the first beam, and the length of the second U-shaped pressing plate is greater than the thickness of the second beam.

Preferably, the locking assembly comprises a first secondary sliding piece, a second secondary sliding piece, a locking screw rod and two locking nuts;

protrusions are arranged at two ends of the first secondary sliding piece, the two protrusions are distributed in opposite directions, and the protrusions at two ends of the first secondary sliding piece are respectively connected with the two first groove-shaped sliding rails in a matched mode; protrusions are arranged at two ends of the second-stage sliding piece, the two protrusions are distributed in opposite directions, and the protrusions at two ends of the second-stage sliding piece are respectively connected with the two second groove-shaped sliding rails in a matched mode;

the locking screw rod is arranged on the first second-stage sliding piece and the second-stage sliding piece on two opposite sides in a penetrating mode, and two ends of the locking screw rod are respectively provided with a locking nut.

Preferably, the two first beams and the two second beams are all square-shaped steel beams, and the structural dimensions of the two first beams and the two second beams are the same;

the first connecting pieces are distributed between the two first beams uniformly, and the second connecting pieces are distributed between the two second beams uniformly.

Preferably, the outer sides of the first groove-shaped sliding rail and the second groove-shaped sliding rail are provided with scale bars along the length direction.

The invention discloses a construction method of a reinforcing device for a disassembly-free composite insulation board, which comprises the following steps of:

s1: selecting proper positions on the inner side templates of the inner sides of the disassembly-free composite heat insulation board and the wall steel bars, and drilling alignment holes, wherein the number of the alignment holes is at least two;

s2: a proper number of first primary sliding pieces are slid between two first groove-shaped sliding rails on the first beam assembly, and a corresponding number of second primary sliding pieces are slid between two second groove-shaped sliding rails on the second beam assembly; when the first primary sliding piece slides in, the first U-shaped pressing plate inserted on the first primary sliding piece moves to the two end parts of the first U-shaped pressing plate, and when the second primary sliding piece slides in, the second U-shaped pressing plate inserted on the second primary sliding piece moves to the two end parts of the second U-shaped pressing plate; a first secondary sliding piece is respectively slid into the space between two ends of two first groove-shaped sliding rails on the first beam assembly, a second secondary sliding piece is respectively slid into the space between two ends of two second groove-shaped sliding rails on the second beam assembly, and the first secondary sliding piece and the corresponding second secondary sliding piece are moved to a position opposite to the alignment hole;

s3: the locking screw rod penetrates through the first secondary sliding piece and the corresponding second secondary sliding piece, and a locking nut is screwed in and screwed on from two ends of the locking screw rod respectively, so that the reinforcing device is fixed;

s4: a first supporting screw rod is screwed into each first primary sliding piece, so that the end part of the first supporting screw rod is abutted against the first U-shaped pressing plate, a rubber pad on the first U-shaped pressing plate is abutted against the disassembly-free composite heat insulation plate, a second supporting screw rod is screwed into each second primary sliding piece, so that the end part of the second supporting screw rod is abutted against the second U-shaped pressing plate, the rubber pad on the second U-shaped pressing plate is abutted against the inner side template, and the supporting assembly and the locking assembly are matched to fix the disassembly-free composite heat insulation plate and the inner side template on two sides of a wall steel bar;

s5: and (3) carrying out concrete pouring on the wall body reinforcing steel bar between the disassembly-free composite heat-insulating plate and the inner side template, and taking down the locking nuts on the two locking assemblies after the wall body is formed by pouring and the disassembling strength is achieved, so that the reinforcing device can be taken down.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the invention, the first beam component and the second beam component are fixedly connected by the two locking components, the plurality of first shoring components are vertically and movably arranged between the two first groove-shaped sliding rails, the plurality of second shoring components are vertically and movably arranged between the two second groove-shaped sliding rails, the plurality of first shoring components and the plurality of second shoring components replace the effect of reinforcing the disassembly-free composite heat insulation board and the inner side template by using a large number of split bolts, but a large number of alignment holes are not required to be drilled between the disassembly-free composite heat insulation board inner side templates, so that the installation process is simplified, and the construction efficiency is improved.

2. According to the invention, the number of the first shoring components and the second shoring components can be flexibly increased or decreased according to actual conditions, the relative position relation can be flexibly adjusted according to requirements, only two locking components are required to be disassembled when the reinforcing device is disassembled, the disassembly is convenient, and the disassembled reinforcing device can be reused.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

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

FIG. 2 is a side view of the present invention;

FIG. 3 is a cross-sectional view of the present invention;

FIG. 4 is an enlarged schematic view of the structure of FIG. 1 at A;

fig. 5 is an exploded view of the first jack-up assembly.

Description of the reference numerals

1. A beam assembly;

11. a first beam assembly; 111. a first beam; 112. a first connector; 113. a first slot-type slide rail;

12. a second beam assembly; 121. a second beam; 122. a second connector; 123. a second slot-type slide rail;

2. a jacking assembly;

21. a first jack-up assembly; 211. a first primary slider; 212. a first jack screw; 213. a first U-shaped pressing plate;

22. a second jack-up assembly; 221. a second stage slider; 222. a second jack screw; 223. a second U-shaped pressing plate;

3. a locking assembly;

31. a first secondary slide; 32. a second stage slider; 33. locking the screw rod; 34. and (5) locking the nut.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

An embodiment of a reinforcing apparatus for a disassembly-free composite insulation board of the present invention, as shown in fig. 1 to 5, includes:

the beam assembly 1, the beam assembly 1 comprises a first beam assembly 11 and a second beam assembly 12 which is arranged in parallel with the first beam assembly 11, the first beam assembly 11 comprises two first beams 111, a first connecting piece 112 fixedly connected with the two first beams 111, and a first groove-shaped sliding rail 113 which is arranged on the first beams 111 in parallel; the second beam assembly 12 comprises two second beams 121, a second connecting piece 122 fixedly connecting the two second beams 121, and a second groove-shaped sliding rail 123 arranged on the second beams 121 in parallel; the two first beams 111 and the two second beams 121 just constitute four long sides of a rectangular parallelepiped; the notches of the two first groove-shaped sliding rails 113 are arranged in a back-to-back mode, and the notches of the two second groove-shaped sliding rails 123 are arranged in a back-to-back mode;

the top support assembly 2, the top support assembly 2 comprises a plurality of first top support assemblies 21 and a plurality of second top support assemblies 22, the plurality of first top support assemblies 21 are vertically movably arranged between two first groove-shaped sliding rails 113, and the plurality of second top support assemblies 22 are vertically movably arranged between two second groove-shaped sliding rails 123;

the locking assembly 3, the locking assembly 3 is used for fixedly connecting the first beam assembly 11 and the second beam assembly 12; the locking assemblies 3 are two, and the two locking assemblies 3 are respectively close to the two ends of the beam assembly 1.

It should be noted that, the plurality of first top support assemblies 21 are uniformly arranged between the two first groove-shaped sliding rails 113; the plurality of second jack-up assemblies 22 are evenly disposed between the two second slot-type slide rails 123.

In this embodiment, the first top supporting component 21 includes a first primary sliding element 211 and a first top supporting screw 212 vertically penetrating through the first primary sliding element 211, wherein two ends of the first primary sliding element 211 are provided with protrusions, the two protrusions are oppositely arranged, and the protrusions at two ends of the first primary sliding element 211 are respectively connected with two first groove-shaped sliding rails 113 in a matching manner;

the second top support assembly 22 comprises a second first-stage sliding piece 221 and a second top support screw 222 vertically penetrating through the second first-stage sliding piece 221, protrusions are arranged at two ends of the second first-stage sliding piece 221 in opposite directions, and the protrusions at two ends of the second first-stage sliding piece 221 are respectively connected with two second groove-shaped sliding rails 123 in a matched mode.

In this embodiment, it should be noted that two protrusions disposed opposite to each other at two ends of the first primary slider 211 are matched with two notches disposed opposite to each other on the two first slot-shaped sliding rails 113; two protrusions arranged at two opposite ends of the second stage sliding piece 221 are matched with two notches arranged at opposite ends of the second groove type sliding rail 123.

In this embodiment, the length of the first supporting screw 212 is greater than the thickness of the first beam 111, and a handle is vertically disposed at the outer end of the first supporting screw 212;

the second jacking screw 222 has a length greater than the thickness of the second beam 121, and a handle is vertically provided at an outer end of the second jacking screw 222.

In this embodiment, the handle on the first supporting screw 212 is fixedly connected to the outer end thereof, and the handle on the second supporting screw 222 is fixedly connected to the outer end thereof.

In this embodiment, the first primary sliding member 211 is in threaded connection with the first jack screw 212, and the second primary sliding member 221 is in threaded connection with the second jack screw 222;

the first primary sliding piece 211 is slidably connected with two end parts of the first U-shaped pressing plate 213, and when the first supporting screw 212 rotates, the first U-shaped pressing plate 213 can be pushed to move towards the second supporting screw 222;

the second stage slider 221 is slidably connected to both ends of the second U-shaped pressing plate 223, and when the second supporting screw 222 rotates, the second U-shaped pressing plate 223 can be pushed to move in the direction of the first supporting screw 212.

In this embodiment, it should be noted that, a threaded cylinder is disposed on the outer side of the first primary sliding member 211, an internal thread is disposed on the threaded cylinder, and the first supporting screw 212 passes through the threaded cylinder on the first primary sliding member 211 and is in threaded connection with the threaded cylinder; the outside of second one-stage slider 221 is provided with a screw thread section of thick bamboo, is provided with the internal thread on the screw thread section of thick bamboo, and second jack screw 222 passes the screw thread section of thick bamboo on the second one-stage slider 221 and is connected with the screw thread section of thick bamboo screw thread.

In this embodiment, it should be noted that, the contact area between the first supporting screw 212 and the disassembly-free composite insulation board can be increased by the arrangement of the first U-shaped pressing plate 213, so that the disassembly-free composite insulation board is prevented from being damaged by the first supporting screw 212, and meanwhile, the compression effect of the fixing device on the disassembly-free composite insulation board can be improved; the contact area between the second supporting screw 222 and the inner side template can be increased by the arrangement of the second U-shaped pressing plate 223, so that the damage of the inner side template caused by the second supporting screw 222 is avoided, and meanwhile, the pressing effect of the fixing device on the inner side template can be improved.

In this embodiment, it should be noted that, when the first jack screw 212 rotates, the first jack screw 212 may move relative to the first primary slider 211 along a direction perpendicular to the first primary slider 211; when the second jack screw 222 rotates, the second jack screw 222 may move relative to the second primary slider 221 in a direction perpendicular to the second primary slider 221.

In this embodiment, two ends of the first U-shaped pressing plate 213 are inserted at two sides of the first primary slider 211;

the second U-shaped pressing plate 223 is inserted at both ends thereof at both sides of the second stage slider 221.

In this embodiment, it should be noted that, the two sides of the first primary slider 211 are respectively provided with an insertion hole, and two ends of the first U-shaped pressing plate 213 are respectively inserted into the insertion holes at the two sides of the first primary slider 211, and the two ends of the first U-shaped pressing plate 213 can move relative to the insertion holes at the two sides of the first primary slider 211; the two sides of the second stage slider 221 are respectively provided with insertion holes, and the two ends of the second U-shaped pressing plate 223 are respectively inserted into the insertion holes at the two sides of the second stage slider 221, and the two ends of the second U-shaped pressing plate 223 can move relative to the insertion holes at the two sides of the second stage slider 221.

In this embodiment, a rubber pad is disposed on one side of the first U-shaped pressing plate 213 close to the second U-shaped pressing plate 223, and a rubber pad is disposed on one side of the second U-shaped pressing plate 223 close to the first U-shaped pressing plate 213;

the length of the first U-shaped pressing plate 213 is greater than the thickness of the first beam 111; the second U-shaped pressing plate 223 has a length greater than the thickness of the second beam 121.

In this embodiment, it should be noted that, the rubber pad disposed on the first U-shaped pressing plate 213 may further protect the disassembly-free composite insulation board, and the rubber pad disposed on the second U-shaped pressing plate 223 may further protect the inner side template.

In this embodiment, the locking assembly 3 includes a first secondary slider 31, a second secondary slider 32, a locking screw 33, and two locking nuts 34;

protrusions are arranged at two ends of the first secondary sliding piece 31, the two protrusions are distributed in opposite directions, and the protrusions at two ends of the first secondary sliding piece 31 are respectively matched and connected with two first groove-shaped sliding rails 113; protrusions are arranged at two ends of the second-stage sliding piece 32, the two protrusions are arranged in opposite directions, and the protrusions at two ends of the second-stage sliding piece 32 are respectively connected with two second groove-shaped sliding rails 123 in a matched mode;

the locking screw 33 is penetrated through the first secondary slide 31 and the second secondary slide 32 at opposite sides, and two ends of the locking screw 33 are respectively provided with a locking nut 34.

In this embodiment, the two first beams 111 and the two second beams 121 are all square-shaped steel beams, and the structural dimensions of the two first beams 111 and the two second beams 121 are the same;

the first connection members 112 are provided in plurality and uniformly arranged between the two first beams 111, and the second connection members 122 are provided in plurality and uniformly arranged between the two second beams 121.

In this embodiment, the girder steel of the shape of a Chinese character kou has high strength, and the overall weight of the fixing device can be reduced, thereby improving the usability of the device.

In this embodiment, the outer sides of the first groove-shaped sliding rail 113 and the second groove-shaped sliding rail 123 are provided with scale bars along the length direction.

In this embodiment, it should be noted that the scale bar on the first slot-shaped sliding rail 113 can intuitively reflect the position of the first primary sliding member 211, so as to facilitate adjustment of the positions of the plurality of first top support assemblies 21, and ensure uniform force application; the scale bars on the second groove-shaped sliding rail 123 can intuitively reflect the positions of the second-stage sliding pieces 221, so that the positions of the second jacking components 22 can be conveniently adjusted, and uniform force application is ensured.

When in actual use, the surface of the reinforcing device is coated with the anti-corrosion coating, so that the anti-corrosion performance of the reinforcing device is improved, and the service life of the device is prolonged.

An embodiment of a construction method of a reinforcing apparatus for a disassembly-free composite insulation board of the present invention, as shown in fig. 1 to 5, includes the steps of:

s1: selecting proper positions on the inner side templates of the inner sides of the disassembly-free composite heat insulation board and the wall steel bars, and drilling alignment holes, wherein the number of the alignment holes is at least two;

s2: a suitable number of first primary slides 211 are slid between two first slotted tracks 113 on the first beam assembly 11 and a corresponding number of second primary slides 221 are slid between two second slotted tracks 123 on the second beam assembly 12; the first U-shaped pressing plate 213 inserted in the first primary slider 211 is moved to both end sides thereof when sliding into the first primary slider 211, and the second U-shaped pressing plate 223 inserted in the second primary slider 221 is moved to both end sides thereof when sliding into the second primary slider 221; a first secondary sliding piece 31 is respectively slid into the space between two ends of two first groove-shaped sliding rails 113 on the first beam assembly 11, a second secondary sliding piece 32 is respectively slid into the space between two ends of two second groove-shaped sliding rails 123 on the second beam assembly 12, and the first secondary sliding piece 31 and the corresponding second secondary sliding piece 32 are moved to a position opposite to the alignment hole;

s3: the locking screw 33 penetrates through the first secondary sliding piece 31 and the corresponding second secondary sliding piece 32, and a locking nut 34 is screwed in and screwed on from two ends of the locking screw 33 respectively, so that the reinforcing device is fixed;

s4: a first supporting screw rod 212 is screwed into each first primary sliding piece 211, so that the end part of the first supporting screw rod 212 is abutted against a first U-shaped pressing plate 213, a rubber pad on the first U-shaped pressing plate 213 is abutted against the disassembly-free composite heat insulation plate, a second supporting screw rod 222 is screwed into each second primary sliding piece 221, so that the end part of the second supporting screw rod 222 is abutted against a second U-shaped pressing plate 223, a rubber pad on the second U-shaped pressing plate 223 is abutted against an inner side template, and the supporting assembly 2 and the locking assembly 3 are matched and fixed with the disassembly-free composite heat insulation plate and the inner side template on two sides of a wall steel bar;

s5: and (3) carrying out concrete pouring on the wall body reinforcing steel bar between the disassembly-free composite heat-insulating plate and the inner side template, and taking down the locking nuts (34) on the two locking assemblies (3) after the wall body is formed by pouring and the disassembling strength is achieved, so that the reinforcing device can be taken down.

It should be noted that, when the first primary sliding member 211 slides into the space between the two first groove-shaped sliding rails 113, the first primary sliding member 211 is ensured to be uniformly distributed, and when the second primary sliding member 221 slides into the space between the two second groove-shaped sliding rails 123, the second primary sliding member 221 is ensured to be uniformly distributed.

In actual use, the locking component 3 can be properly arranged between the first beam component 11 and the second beam component 12 according to the length dimension of the wall body to be poured and molded.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the invention.

Claims (10)

1. A reinforcing apparatus for a disassembly-free composite insulation board, comprising:

the beam assembly (1), the beam assembly (1) comprises a first beam assembly (11) and a second beam assembly (12) which is arranged in parallel with the first beam assembly (11), the first beam assembly (11) comprises two first beams (111), a first connecting piece (112) fixedly connected with the two first beams (111), and a first groove-shaped sliding rail (113) which is arranged on the first beams (111) in parallel; the second beam assembly (12) comprises two second beams (121), a second connecting piece (122) fixedly connected with the two second beams (121), and second groove-shaped sliding rails (123) arranged on the second beams (121) in parallel; the two first beams (111) and the two second beams (121) just form four long sides of a cuboid; the notches of the two first groove-shaped sliding rails (113) are arranged in opposite directions, and the notches of the two second groove-shaped sliding rails (123) are arranged in opposite directions;

the top support assembly (2), the top support assembly (2) comprises a plurality of first top support assemblies (21) and a plurality of second top support assemblies (22), the plurality of first top support assemblies (21) are vertically movably arranged between two first groove-shaped sliding rails (113), and the plurality of second top support assemblies (22) are vertically movably arranged between two second groove-shaped sliding rails (123);

the locking assembly (3) is used for fixedly connecting the first beam assembly (11) and the second beam assembly (12); the number of the locking assemblies (3) is two, and the two locking assemblies (3) are respectively close to two end parts of the beam assembly (1).

2. The reinforcing device for the disassembly-free composite insulation board according to claim 1, wherein the first top support assembly (21) comprises a first primary sliding piece (211) and a first top support screw rod (212) vertically penetrating through the first primary sliding piece (211), two ends of the first primary sliding piece (211) are provided with protrusions, the two protrusions are oppositely arranged, and the protrusions at the two ends of the first primary sliding piece (211) are respectively connected with the two first groove-type sliding rails (113) in a matched mode;

the second top support assembly (22) comprises a second-stage sliding piece (221) and a second top support screw rod (222) vertically penetrating through the second-stage sliding piece (221), protrusions are arranged at two ends of the second-stage sliding piece (221), the two protrusions are distributed in opposite directions, and the protrusions at two ends of the second-stage sliding piece (221) are respectively connected with the two second groove-shaped sliding rails (123) in a matched mode.

3. The reinforcing device for a disassembly-free composite insulation board according to claim 2, wherein the length of the first supporting screw (212) is greater than the thickness of the first beam (111), and the outer end of the first supporting screw (212) is vertically provided with a handle;

the length of the second supporting screw rod (222) is larger than the thickness of the second beam (121), and a handle is vertically arranged at the outer end of the second supporting screw rod (222).

4. A reinforcing apparatus for a disassembly-free composite insulation board according to claim 2, wherein the first primary slider (211) is screwed with a first jack screw (212), and the second primary slider (221) is screwed with a second jack screw (222);

the first primary sliding piece (211) is in sliding connection with two end parts of the first U-shaped pressing plate (213), and when the first supporting screw (212) rotates, the first U-shaped pressing plate (213) can be pushed to move towards the direction of the second supporting screw (222);

the second-stage sliding piece (221) is connected with two end parts of the second U-shaped pressing plate (223) in a sliding mode, and when the second supporting screw (222) rotates, the second U-shaped pressing plate (223) can be pushed to move towards the direction of the first supporting screw (212).

5. The reinforcing device for a disassembly-free composite insulation board according to claim 4, wherein both ends of the first U-shaped pressing plate (213) are inserted at both sides of the first primary slider (211);

two end parts of the second U-shaped pressing plate (223) are inserted at two sides of the second-stage sliding piece (221).

6. The reinforcing device for the disassembly-free composite insulation board according to claim 4, wherein a rubber pad is arranged on one side of the first U-shaped pressing plate (213) close to the second U-shaped pressing plate (223), and a rubber pad is arranged on one side of the second U-shaped pressing plate (223) close to the first U-shaped pressing plate (213);

the length of the first U-shaped pressing plate (213) is larger than the thickness of the first beam (111), and the length of the second U-shaped pressing plate (223) is larger than the thickness of the second beam (121).

7. A reinforcing device for a composite insulation board without dismantling according to claim 1, characterized in that the locking assembly (3) comprises a first secondary slide (31), a second secondary slide (32), a locking screw (33) and two locking nuts (34);

protrusions are arranged at two ends of the first secondary sliding piece (31), the two protrusions are distributed in opposite directions, and the protrusions at two ends of the first secondary sliding piece (31) are respectively connected with the two first groove-shaped sliding rails (113) in a matched mode; protrusions are arranged at two ends of the second-stage sliding piece (32), the two protrusions are distributed in opposite directions, and the protrusions at two ends of the second-stage sliding piece (32) are respectively connected with the two second groove-shaped sliding rails (123) in a matched mode;

the locking screw (33) is arranged on the first secondary sliding piece (31) and the second secondary sliding piece (32) on two opposite sides in a penetrating way, and two ends of the locking screw (33) are respectively provided with a locking nut (34).

8. The reinforcing device for a disassembly-free composite insulation board according to claim 1, wherein the two first beams (111) and the two second beams (121) are square-shaped steel beams, and the two first beams (111) and the two second beams (121) have the same structural dimensions;

the first connecting pieces (112) are distributed between the two first beams (111) uniformly, and the second connecting pieces (122) are distributed between the two second beams (121) uniformly.

9. The reinforcing device for the disassembly-free composite insulation board according to claim 1, wherein the outer sides of the first groove-shaped sliding rail (113) and the second groove-shaped sliding rail (123) are provided with scale bars along the length direction.

10. The construction method of the reinforcing device for the disassembly-free composite insulation board is characterized by comprising the following steps of:

s1: selecting proper positions on the inner side templates of the inner sides of the disassembly-free composite heat insulation board and the wall steel bars, and drilling alignment holes, wherein the number of the alignment holes is at least two;

s2: a proper number of first primary sliding pieces (211) are slid between two first groove-shaped sliding rails (113) on the first beam assembly (11), and a corresponding number of second primary sliding pieces (221) are slid between two second groove-shaped sliding rails (123) on the second beam assembly (12); when sliding into the first primary sliding piece (211), the first U-shaped pressing plate (213) inserted on the first primary sliding piece (211) moves towards the two end parts of the first U-shaped pressing plate, and when sliding into the second primary sliding piece (221), the second U-shaped pressing plate (223) inserted on the second primary sliding piece (221) moves towards the two end parts of the second U-shaped pressing plate; a first secondary sliding piece (31) is respectively slid into the space between two ends of two first groove-shaped sliding rails (113) on the first beam assembly (11), a second secondary sliding piece (32) is respectively slid into the space between two ends of two second groove-shaped sliding rails (123) on the second beam assembly (12), and the first secondary sliding piece (31) and the corresponding second secondary sliding piece (32) are moved to a position opposite to the alignment hole;

s3: the locking screw rod (33) penetrates through the first secondary sliding piece (31) and the corresponding second secondary sliding piece (32), and a locking nut (34) is screwed in and screwed on from two ends of the locking screw rod (33) respectively, so that the reinforcing device is fixed;

s4: a first jacking screw rod (212) is screwed into each first primary sliding piece (211), the end part of the first jacking screw rod (212) is abutted against a first U-shaped pressing plate (213), a rubber pad on the first U-shaped pressing plate (213) is abutted against a disassembly-free composite heat insulation plate, a second jacking screw rod (222) is screwed into each second primary sliding piece (221), the end part of the second jacking screw rod (222) is abutted against a second U-shaped pressing plate (223), the rubber pad on the second U-shaped pressing plate (223) is abutted against an inner side template, and the jacking assembly (2) and the locking assembly (3) are matched and fixed to the disassembly-free composite heat insulation plate and the inner side template on two sides of a wall steel bar;

s5: and (3) carrying out concrete pouring on the wall body reinforcing steel bar between the disassembly-free composite heat-insulating plate and the inner side template, and taking down the locking nuts (34) on the two locking assemblies (3) after the wall body is formed by pouring and the disassembling strength is achieved, so that the reinforcing device can be taken down.