CN112411863A - Plug-in type insulation block with quick-release function - Google Patents

Abstract

The invention discloses a plug-in type heat-insulation building block with a quick-release function, which belongs to the technical field of constructional engineering and comprises a first building block main body, wherein a second building block main body is arranged at the side position of the first building block main body, a first heat-insulation sandwich layer is arranged between the second building block main body and the first building block main body, and plug-in grooves are formed in the end parts of the first building block main body and the second building block main body corresponding to the first heat-insulation sandwich layer. According to the invention, through the mutual matching of the designed structures such as the third heat-preservation sandwich layer, the plug socket, the through hole, the first concave connecting groove, the plug groove, the second heat-preservation sandwich layer, the second concave connecting groove and the fourth heat-preservation sandwich layer, the use cost of manpower is reduced, the overall connecting strength is higher, the permanent integrity and the stability of the first heat-preservation sandwich layer are improved, the heat bridge effect of the first building block main body and the second building block main body is avoided, the heat-insulation efficiency is high, the weight is light, the strength is good, the construction is simple and convenient, and the comprehensive performance is better.

Description

Plug-in type insulation block with quick-release function

Technical Field

The invention belongs to the technical field of constructional engineering, and particularly relates to a plug-in type insulation block with a quick-release function.

Background

The composite self-insulation building block consists of a main building block with a hollow structure, a heat insulation layer, a protective layer and a connecting pin which connects the main building block and the protective layer and runs through the heat insulation layer, in order to ensure safety, a reinforcing steel wire is arranged in the connecting pin, the main building block is provided with three structural forms of blind holes, through holes and filling, according to the specific requirements of different buildings, through the corresponding setting of adjustable parameters such as the material, thickness, aggregate variety and proportion of the heat insulation layer, the section structure and the number of the heat insulation connecting pin, various technical indexes are adjusted, the market demand is met to the maximum extent, the requirement of energy saving is met by 50% -75%, the compressive strength is 5.0 MPa-15 MPa, the bearing and non-bearing requirements are met, and the composite self-insulation building block.

For example, Chinese patent discloses a corrugated autoclaved aerated concrete block (patent number: CN 208039604U), which solves the technical problems that the surface of the traditional autoclaved aerated concrete block is a plane, the combination with a plastering layer is easy to be disturbed, especially the plastering layer is hollow due to wall vibration caused by the fact that water and electricity are changed and a wall surface is grooved in the current home decoration process, and the technical problems are solved by the designed structures of a cuboid heat-insulating block, a positioning bulge, a groove, a first polyurethane heat-insulating layer, a foam micro-particle layer, a second polyurethane heat-insulating layer and the like, but the patent still has some defects that the adjacent two concrete block bodies are easy to be dislocated in the stacking and connecting process to cause inconvenient disassembly and assembly, and the connection part of the first polyurethane heat-insulating layer is easy to generate a gap when the first polyurethane heat-insulating layer is carried out, so that a heat bridge effect is caused, and the heat-insulating balance degree of the wall surface piled by the first polyurethane heat-insulating layer is reduced.

Disclosure of Invention

The invention aims to: in order to solve two adjacent concrete block bodies and in piling up the connection process, the phenomenon of easy emergence dislocation leads to the dismouting inconvenient, and its connection position produces the gap easily when first polyurethane heat preservation goes on, and then causes the heat bridge effect, has reduced the problem of the heat preservation equilibrium degree that first polyurethane heat preservation piled up into the wall, and the insulation block that a plug-in type has the quick detach function that proposes.

In order to achieve the purpose, the invention adopts the following technical scheme:

a plug-in type insulation block with a quick-release function comprises a first block main body, wherein a second block main body is arranged on the side of the first block main body, a first insulation sandwich layer is arranged between the second block main body and the first block main body, plug-in grooves are formed in the positions, corresponding to the first insulation sandwich layer, of the end portions of the first block main body and the second block main body, a first concave connecting groove is formed in the position, corresponding to the two plug-in grooves, of the end portion of the first insulation sandwich layer, a plug-in seat is fixedly connected to the position, corresponding to the two plug-in grooves, of the other end portion of the first block main body and the second block main body, a through hole is formed in the side surface of the plug-in seat, corresponding to the first concave connecting groove, a third insulation sandwich layer is sleeved in the through hole, and the opposite surfaces of the third insulation sandwich layer and the first insulation sandwich layer are fixedly connected through the, and the second heat preservation sandwich layer is positioned between the first building block main body and the second building block main body, a second concave connecting groove is formed in the top of the first heat preservation sandwich layer, and a fourth heat preservation sandwich layer is fixedly connected to the bottom of the first heat preservation sandwich layer at a position corresponding to the second concave connecting groove.

As a further description of the above technical solution:

the surface of the first heat-preservation sandwich layer is fixedly connected with plug-in connecting pins, and the plug-in connecting pins are respectively positioned in plug-in connecting grooves formed in opposite surfaces of the first building block main body and the second building block main body.

As a further description of the above technical solution:

the overlooking section of the plug socket is of a trapezoidal structure, and the inner diameter of a concave cavity defined by the first heat-preservation sandwich layer and the two plug sockets is matched with the outer diameter of the plug socket.

As a further description of the above technical solution:

the side view cross section sizes of the plug socket and the first concave connecting groove are the same, and the depth of the first concave connecting groove is the same as the thickness of the part, located outside the through hole, of the plug socket.

As a further description of the above technical solution:

the fourth heat preservation sandwich layer and the second concave connecting grooves are identical in cross section size in plan view, and the depth of the second concave connecting grooves is identical to the thickness of the fourth heat preservation sandwich layer.

As a further description of the above technical solution:

the cross section of the socket in a top view is in an isosceles trapezoid shape, and the smaller inner angle of the contour of the socket is controlled to be 45-48 degrees.

As a further description of the above technical solution:

first bayonets have all been seted up to the position that first building block main part and second building block main part tip correspond the grafting groove to the equal fixedly connected with first card in the position that the other tip of first building block main part and second building block main part corresponds first bayonet socket is stupefied.

As a further description of the above technical solution:

the second bayonet sockets are formed in the positions, corresponding to the inserting grooves, of the tops of the first building block body and the second building block body, and the second bayonet sockets are fixedly connected to the positions, corresponding to the second bayonet sockets, of the bottoms of the first building block body and the second building block body respectively.

As a further description of the above technical solution:

the third heat-insulating sandwich layer can be made of heat-insulating materials such as polyurethane, polystyrene compounds, polystyrene, phenolic resin or foamed cement, and the heat-insulating capacity of the third heat-insulating sandwich layer per unit area is larger than that of the first heat-insulating sandwich layer per unit area.

As a further description of the above technical solution:

the first clamping edge and the second clamping edge are made of the same material and are silica gel rods.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

1. according to the invention, through the mutual matching of the designed structures such as the third heat-preservation sandwich layer, the plug socket, the through hole, the first concave connecting groove, the plug groove, the second heat-preservation sandwich layer, the second concave connecting groove and the fourth heat-preservation sandwich layer, the butt joint positioning effect is achieved, the assembly and disassembly are convenient, the construction is convenient, the use of manpower is reduced, the cost is saved, the integral connection strength is higher, the permanent integrity and the stability of the first heat-preservation sandwich layer are improved, the heat bridge effect of the first building block main body and the second building block main body is avoided, the heat-insulation efficiency is high, the weight is light, the strength is good, the construction is simple and convenient, and the comprehensive performance is better.

2. In the invention, the designed plug-in connecting pin and the plug-in connecting groove are used as connecting media between the first heat-preservation sandwich layer and the first building block main body and between the first heat-preservation sandwich layer and the second building block main body respectively, so that the stability of the three after plug-in combination connection is ensured.

3. In the invention, through the designed third heat preservation sandwich layer, the inserting base, the through hole, the first concave connecting groove, the inserting groove and the second heat preservation sandwich layer, in the process of inserting the inserting base into the concave cavity defined by the first heat preservation sandwich layer and the two inserting bases, the third heat preservation sandwich layer can also be inserted into the first concave connecting groove, so that the outside connecting surfaces between two groups of adjacent first building block main bodies and the first building block main bodies and between the second building block main bodies and the second building block main bodies on the same horizontal plane and the connecting surfaces between the two adjacent first heat preservation sandwich layers and the second heat preservation sandwich layer are staggered, the first concave connecting groove and the third heat preservation sandwich layer can further increase the connecting area between the two adjacent first heat preservation sandwich layers, the stability between the first heat preservation sandwich layer and the second heat preservation sandwich layer can be improved, the heat preservation effect of the first heat preservation sandwich layer is prevented from being influenced by the poor sealing of the side position of the first building block main bodies and the second building blocks main bodies, make the bulk joint intensity higher, improved the permanent wholeness and the stability of first heat preservation intermediate layer, avoided the heat bridge effect of first building block main part and second building block main part itself.

4. According to the invention, through the designed first clamping ridge and the first bayonet, the first clamping ridge adopts a silica gel rod and is used for increasing connecting media between the external first clamping ridge and the first building block main body as well as between the external first clamping ridge and the second building block main body, so that the outer sides between two adjacent groups of external first building block main bodies and the first building block main body as well as between the external second building block main body and the second building block main body on the same horizontal plane are more stable, and the first clamping ridge has a certain buffering and damping effect.

5. According to the invention, through the designed second concave connecting grooves and the fourth heat-preservation sandwich layer, the connecting surfaces between the tops and bottoms of the first building block main body and the second building block main body and the external building block main body and the connecting surface between the first heat-preservation sandwich layer and the external first heat-preservation sandwich layer are staggered, and the building block has the advantages of high heat-insulation efficiency, light weight, good strength, simplicity and convenience in construction and better comprehensive performance.

6. According to the invention, through the designed second clamping ridge and the second bayonet, the second clamping ridge adopts a silica gel rod and is used for increasing connecting media between the external second clamping ridge and the first building block main body as well as between the external second clamping ridge and the second building block main body, so that the outer sides between two adjacent groups of external first building block main bodies and first building block main bodies as well as between the external second building block main bodies and the second building block main bodies on the same horizontal plane are more stable, and the second clamping ridge has a certain buffering and damping effect.

Drawings

FIG. 1 is a schematic perspective view of a plug-in type insulation block with a quick-release function according to the present invention;

FIG. 2 is a schematic perspective view of a first thermal insulation sandwich layer in the plug-in type thermal insulation block with a quick release function according to the present invention;

FIG. 3 is a schematic perspective view of a second block of the plug-in type insulation block with a quick release function according to the present invention;

FIG. 4 is a schematic perspective view of a socket in a plug-in type insulation block with a quick-release function according to the present invention;

fig. 5 is a schematic perspective view of an insertion type connecting pin inserted in the plug-in type insulation block with a quick-release function according to the present invention.

Illustration of the drawings:

1. a first block body; 2. a second block body; 3. a first thermal insulation sandwich layer; 4. a plug-in connecting pin; 5. inserting connecting grooves; 6. inserting grooves; 7. a first concave connecting groove; 8. a first bayonet; 9. a second thermal insulation sandwich layer; 10. a socket; 11. a through hole; 12. a third thermal insulation sandwich layer; 13. a first card edge; 14. a second bayonet; 15. a second concave connecting groove; 16. a second card edge; 17. and a fourth heat-insulating sandwich layer.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: a plug-in type insulation block with a quick-release function comprises a first block main body 1, wherein a second block main body 2 is arranged on the side of the first block main body 1, a first insulation sandwich layer 3 is arranged between the second block main body 2 and the first block main body 1, plug-in grooves 6 are formed in the end portions of the first block main body 1 and the second block main body 2 corresponding to the first insulation sandwich layer 3, a first concave connecting groove 7 is formed in the end portion of the first insulation sandwich layer 3 corresponding to the two plug-in grooves 6, a plug-in seat 10 is fixedly connected to the other end portion of the first block main body 1 and the second block main body 2 corresponding to the two plug-in grooves 6, a through hole 11 is formed in the side surface of the plug-in seat 10 corresponding to the position of the first concave connecting groove 7, a third insulation sandwich layer 12 is sleeved in the through hole 11, and the third insulation sandwich layer 12, the plug-in seat 10, the through hole 11 are designed, In the process of inserting the inserting seats 10 into the concave cavity surrounded by the first heat-preserving sandwich layer 3 and the two inserting seats 10, the first concave connecting grooves 7, the inserting grooves 6 and the second heat-preserving sandwich layer 9, the third heat-preserving sandwich layer 12 is also inserted into the first concave connecting grooves 7, so that the outer side connecting surfaces between two adjacent groups of the first building block main bodies 1 and between the second building block main bodies 2 and the second building block main bodies 2 on the same horizontal plane are staggered with the connecting surfaces between the two adjacent first heat-preserving sandwich layers 3 and the second heat-preserving sandwich layer 9, the first concave connecting grooves 7 and the third heat-preserving sandwich layer 12 can further increase the connecting area between the two adjacent first heat-preserving sandwich layers 3, the stability between the two can be improved, the heat-preserving effect of the first heat-preserving sandwich layer 3 is prevented from being influenced by the poor sealing of the side seam parts of the first building block main bodies 1 and the second building block main bodies 2, the opposite face of third heat preservation sandwich layer 12 and first heat preservation sandwich layer 3 passes through second heat preservation sandwich layer 9 fixed connection to second heat preservation sandwich layer 9 is located between first building block main part 1 and the second building block main part 2, and second spill spread groove 15 has been seted up at the top of first heat preservation sandwich layer 3, and the position fixedly connected with fourth heat preservation sandwich layer 17 of first heat preservation sandwich layer 3 bottom corresponding second spill spread groove 15.

Specifically, as shown in fig. 1, the surface of the first heat-insulating sandwich layer 3 is fixedly connected with a plug-in connecting pin 4, and a plurality of plug-in connecting pins 4 are respectively located in plug-in connecting grooves 5 formed on opposite surfaces of the first block body 1 and the second block body 2, through the designed plug-in connecting pin 4 and plug-in connecting groove 5, the plug-in connecting groove 5 and the plug-in connecting pin 4 are used as connecting media between the first heat-insulating sandwich layer 3 and the first block body 1 and the second block body 2 respectively, so as to ensure the stability after plug-in combination connection between the three.

Specifically, as shown in fig. 1, the cross-sectional shape of the socket 10 in a plan view is a trapezoidal structure, and the inner diameter of a concave cavity defined by the first thermal insulation sandwich layer 3 and the two inserting grooves 6 is matched with the outer diameter of the socket 10.

Specifically, as shown in fig. 1, the cross-sectional dimensions of the socket 10 and the first female coupling groove 7 are the same in side view, and the depth of the first female coupling groove 7 is the same as the thickness of the part of the socket 10 outside the through hole 11.

Specifically, as shown in fig. 2, the fourth heat preservation sandwich layer 17 and the second concave connecting grooves 15 have the same cross-sectional size when viewed from above, the depth of the second concave connecting grooves 15 is the same as the thickness of the fourth heat preservation sandwich layer 17, and the designed second concave connecting grooves 15 and the fourth heat preservation sandwich layer 17 cause the joint surfaces between the top and bottom of the first block body 1 and the second block body 2 and the external block body to be dislocated from the joint surface between the first heat preservation sandwich layer 3 and the external first heat preservation sandwich layer 3.

Specifically, as shown in fig. 1, the cross-sectional shape of the socket 10 in a top view is an isosceles trapezoid, and the smaller inner angle of the contour of the socket 10 is controlled to be 45 ° to 48 °.

Specifically, as shown in fig. 1, first bayonet socket 8 has all been seted up to the position that first building block main part 1 and 2 tip of second building block main part correspond inserting groove 6, and the equal first card of fixedly connected with in the position that another tip of first building block main part 1 and 2 second building block main part correspond first bayonet socket 8 stupefied 13, stupefied 13 and first bayonet socket 8 through the first card of design, stupefied 13 of first card adopts the silica gel stick, be used for increasing the connection media between external first card stupefied 13 and first building block main part 1 and the second building block main part 2, make the outside department of being in between adjacent two sets of external first building block main part 1 of same horizontal plane and first building block main part 1 and external second building block main part 2 and second building block main part 2 can be more stable, and the stupefied 13 of first card has certain buffering shock attenuation effect.

Specifically, as shown in fig. 1, a second bayonet 14 has been all seted up at the position that first building block main body 1 and second building block main body 2 top correspond inserting groove 6, and the equal fixedly connected with second bayonet 16 in the position that first building block main body 1 and second building block main body 2 bottom correspond second bayonet 14, stupefied 16 of second card and second bayonet 14 through the design, stupefied 16 of second card adopts the silica gel stick, be used for increasing the connection media between external second card stupefied 16 and first building block main body 1 and second building block main body 2, make the outside department of being in between adjacent two sets of external first building block main body 1 of same horizontal plane and first building block main body 1 and external second building block main body 2 and second building block main body 2 can be more stable, and the stupefied 16 of second card has certain buffering shock attenuation effect.

Specifically, as shown in fig. 1, the third thermal insulation sandwich layer 12 may be made of thermal insulation materials such as polyurethane, polystyrene, phenolic resin, or foamed cement, and the thermal insulation capacity of the third thermal insulation sandwich layer 12 per unit area is greater than that of the first thermal insulation sandwich layer 3 per unit area.

Specifically, as shown in fig. 1, the first clamping edge 13 and the second clamping edge 16 are made of the same material and are both silica gel rods.

The working principle is as follows: when in use, the plug-in connecting grooves 5 and the plug-in connecting pins 4 are used as connecting media between the first heat-preservation sandwich layer 3 and the first block main body 1 and the second block main body 2 respectively, and are used for ensuring the stability after plug-in combination connection between the first heat-preservation sandwich layer 3 and the second block main body 2, in the process of inserting the plug-in socket 10 into the concave cavity surrounded by the first heat-preservation sandwich layer 3 and the two plug-in sockets 10, the third heat-preservation sandwich layer 12 can also be inserted into the first concave connecting grooves 7, so that the outer connecting surfaces between two groups of adjacent first block main bodies 1 and the first block main body 1 on the same horizontal plane and between the second block main body 2 and the second block main body 2 are staggered with the connecting surfaces between the two adjacent first heat-preservation sandwich layers 3 and the second heat-preservation sandwich layer 9, and the connecting areas between the two adjacent first heat-preservation sandwich layers 3 can be further increased by the first concave connecting grooves 7 and the third heat-, the stability between the first and second building block main bodies 1 and 2 can be improved, the adverse effect of sealing of the side seam position of the first building block main body 1 and the second building block main body 2 on the heat insulation effect of the first heat insulation sandwich layer 3 is avoided, the first clamping ridge 13 adopts a silica gel rod and is used for increasing the connecting media between the external first clamping ridge 13 and the first building block main body 1 and the second building block main body 2, so that the outer sides between the two groups of external first building block main bodies 1 and between the external second building block main body 2 and the second building block main body 2 which are adjacent in the same horizontal plane can be more stable, the first clamping ridge 13 has certain buffering and damping effects, the second concave connecting groove 15 and the fourth heat insulation sandwich layer 17 enable the connecting surface between the top and the bottom of the first building block main body 1 and the second building block main body 2 and the connecting surface between the external building block main body and the first heat insulation sandwich layer 3 to be staggered, the second clamping edge 16 is a silica gel rod and is used for increasing a connecting medium between the external second clamping edge 16 and the first building block main body 1 and the second building block main body 2, so that the outer sides of the two adjacent external first building block main bodies 1 and the first building block main body 1 and the external second building block main body 2 and the second building block main body 2 in the same horizontal plane are more stable, and the second clamping edge 16 has a certain buffering and damping effect.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical scope of the present invention and the equivalent alternatives or modifications according to the technical solution and the inventive concept of the present invention within the technical scope of the present invention.

Claims (10)

1. A plug-in type insulation block with a quick-release function comprises a first block main body (1) and is characterized in that a second block main body (2) is arranged at the side position of the first block main body (1), a first insulation sandwich layer (3) is arranged between the second block main body (2) and the first block main body (1), plug-in grooves (6) are respectively formed in the positions, corresponding to the first insulation sandwich layer (3), of the end portions of the first block main body (1) and the second block main body (2), a first concave connecting groove (7) is formed in the position, corresponding to the two plug-in grooves (6), of the end portion of the first insulation sandwich layer (3), a plug-in base (10) is fixedly connected to the positions, corresponding to the two plug-in grooves (6), of the other end portion of the first block main body (1) and the second block main body (2), and a through hole (11) is formed in the position, corresponding to the first concave connecting groove (7), of the side surface of the plug, the building block is characterized in that a third heat-insulation sandwich layer (12) is sleeved in the through hole (11), the opposite surface of the third heat-insulation sandwich layer (12) and the opposite surface of the first heat-insulation sandwich layer (3) are fixedly connected through a second heat-insulation sandwich layer (9), the second heat-insulation sandwich layer (9) is located between the first block main body (1) and the second block main body (2), a second concave connecting groove (15) is formed in the top of the first heat-insulation sandwich layer (3), and the bottom of the first heat-insulation sandwich layer (3) corresponds to a fourth heat-insulation sandwich layer (17) fixedly connected with the position of the second concave connecting groove (15).

2. The plug-in type insulation block with the function of quick release as claimed in claim 1, wherein the surface of the first insulation sandwich layer (3) is fixedly connected with plug-in connecting pins (4), and a plurality of plug-in connecting pins (4) are respectively positioned in plug-in connecting grooves (5) formed in the opposite surfaces of the first block main body (1) and the second block main body (2).

3. The plug-in type insulation block with the function of quick release as claimed in claim 1, wherein the cross-sectional shape of the plug socket (10) in plan view is a trapezoid structure, and the inner diameter of the concave cavity defined by the first insulation sandwich layer (3) and the two plug grooves (6) is matched with the outer diameter of the plug socket (10).

4. A plug-in type insulation block with quick release function according to claim 1, characterized in that the cross-sectional dimensions of the plug socket (10) and the first concave connecting groove (7) are the same from the side, and the depth of the first concave connecting groove (7) is the same as the thickness of the portion of the plug socket (10) located outside the through hole (11).

5. The plug-in type insulation block with the function of quick release as claimed in claim 1, wherein the cross-sectional dimension of the fourth insulation sandwich layer (17) and the second concave connecting groove (15) is the same as the cross-sectional dimension of the fourth insulation sandwich layer (17) from top view, and the depth of the second concave connecting groove (15) is the same as the thickness of the fourth insulation sandwich layer (17).

6. The splicing type insulation block with the quick-release function according to claim 1, wherein the cross section of the splicing seat (10) in a top view is isosceles trapezoid, and the smaller inner angle of the profile of the splicing seat (10) is controlled to be 45-48 degrees.

7. The plug-in type insulation block with the quick-release function according to claim 1, characterized in that the end parts of the first block main body (1) and the second block main body (2) corresponding to the plug-in groove (6) are respectively provided with a first bayonet (8), and the other end parts of the first block main body (1) and the second block main body (2) corresponding to the first bayonet (8) are respectively fixedly connected with a first bayonet ridge (13).

8. The plug-in type insulation block with the quick-release function according to claim 1, characterized in that the top of the first block body (1) and the top of the second block body (2) are provided with second bayonets (14) at positions corresponding to the plug-in grooves (6), and the bottom of the first block body (1) and the bottom of the second block body (2) are fixedly connected with second bayonets (16) at positions corresponding to the second bayonets (14).

9. The plug-in type insulation block with the quick-release function according to claim 1, wherein the third insulation sandwich layer (12) can be made of polyurethane, polystyrene, phenolic resin or foamed cement, and the insulation capacity of the third insulation sandwich layer (12) per unit area is larger than that of the first insulation sandwich layer (3).

10. The plug-in type insulation block with the quick-release function according to claim 1, wherein the first clamping edge (13) and the second clamping edge (16) are made of the same material and are silica gel rods.

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