CN219365394U - Double-sided steel wire mesh reinforced building disassembly-free composite heat preservation template - Google Patents

Abstract

The utility model provides a double-sided steel wire mesh reinforced building disassembly-free composite heat preservation template, which comprises: the top layer, heat preservation and bottom surface layer, the fixed one side that sets up in the heat preservation of top layer, the fixed another side that sets up in the heat preservation of bottom surface layer, the inside a plurality of connecting wire that have run through in the heat preservation, a plurality of connecting wire still fixed inside that set up in the top layer respectively near the heat preservation one side, the inside that the bottom surface layer is close to the heat preservation one side. According to the utility model, the inside of the heat preservation layer is also penetrated with a plurality of connecting steel wires, each connecting steel wire penetrates out of the heat preservation layer and is further fixedly connected with the top surface layer and the bottom surface layer respectively, the top surface layer and the bottom surface layer are reinforced on the heat preservation layer through the plurality of connecting steel wires, the secondary reinforcement of the heat preservation layer, the top surface layer and the bottom surface layer is realized, the connection strength of the heat preservation layer, the top surface layer and the bottom surface layer is further enhanced, and the phenomenon that the top surface layer and/or the bottom surface layer fall off from the heat preservation layer is not easy to occur.

Description

Double-sided steel wire mesh reinforced building disassembly-free composite heat preservation template

Technical Field

The utility model relates to the technical field of heat preservation devices, in particular to a double-sided steel wire mesh reinforced building disassembly-free composite heat preservation template.

Background

In the building design or construction process, especially in some areas with low average air temperature in high altitude, how to realize the heat preservation of the outer wall is a non-negligible problem.

The prior art solution is to attach an insulation board on an external wall of a building, for example, chinese patent publication No. CN2433328Y discloses an external wall insulation board in related technology, and the external wall insulation board is formed by once synthesizing and shaping a surface layer, an insulation layer and adhesive ribs, and the formed insulation board can be installed on the external wall.

However, the surface layer in the above patent is only adhered to the heat insulation layer, the connection mode is single, only one-time reinforcement of the surface layer and the heat insulation layer can be realized, and the connection strength of the surface layer and the heat insulation layer needs to be improved.

Disclosure of Invention

The utility model aims to provide a double-sided steel wire mesh reinforced building disassembly-free composite heat preservation template, which aims to solve the problem of insufficient connection strength between a surface layer and a heat preservation layer in the prior art.

In order to achieve the above purpose, the utility model provides a double-sided steel wire mesh reinforced building disassembly-free composite heat preservation template, which comprises: the top layer is fixedly arranged on one surface of the heat preservation layer, the bottom layer is fixedly arranged on the other surface of the heat preservation layer, a plurality of connecting steel wires penetrate through the heat preservation layer, and the connecting steel wires are fixedly arranged in the top layer, close to the inner portion of one surface of the heat preservation layer, and the bottom layer, close to the inner portion of one surface of the heat preservation layer.

The double-sided steel wire mesh reinforced building disassembly-free composite heat preservation template is characterized in that a first steel wire mesh layer is further arranged in the top surface layer, and one ends of the connecting steel wires are fixedly connected with the first steel wire mesh layer.

The reinforced building disassembly-free composite heat preservation template with the double-sided steel wire meshes, wherein a first glass fiber net layer is further arranged in the top surface layer, and one ends of a plurality of connecting steel wires penetrate through the first glass fiber net layer and are fixedly connected with the first steel wire net layer.

The double-sided steel wire mesh reinforced building disassembly-free composite heat preservation template is characterized in that the second steel wire mesh layer is arranged in the bottom surface layer, and the other ends of the connecting steel wires are fixedly connected with the second steel wire mesh layer.

The double-sided steel wire mesh reinforced building disassembly-free composite heat preservation template is characterized in that a second glass fiber net layer is further arranged in the bottom surface layer, and the other ends of the connecting steel wires penetrate through the second glass fiber net layer and are fixedly connected with the second steel wire net layer.

The double-sided steel wire mesh reinforced building disassembly-free composite heat preservation template comprises a heat preservation layer, wherein the heat preservation layer is made of polyurethane particles, and the top surface layer and the bottom surface layer are made of cement-based mortar.

The double-sided steel wire mesh reinforced building disassembly-free composite heat preservation template comprises a heat preservation layer, a top surface layer and a bottom surface layer, wherein the thickness ratio of the heat preservation layer to the top surface layer is 2:1 to 2.5:1, and the thickness ratio of the heat preservation layer to the bottom surface layer is 11:1 to 11.5:1.

Compared with the prior art, the utility model has the beneficial effects that:

according to the utility model, the inside of the heat preservation layer is also penetrated with a plurality of connecting steel wires, each connecting steel wire penetrates out of the heat preservation layer and is further fixedly connected with the top surface layer and the bottom surface layer respectively, the top surface layer and the bottom surface layer are reinforced on the heat preservation layer through the plurality of connecting steel wires, the secondary reinforcement of the heat preservation layer, the top surface layer and the bottom surface layer is realized, the connection strength of the heat preservation layer, the top surface layer and the bottom surface layer is further enhanced, and the phenomenon that the top surface layer and/or the bottom surface layer fall off from the heat preservation layer is not easy to occur.

Drawings

FIG. 1 is a perspective view of a double-sided steel wire mesh reinforced building disassembly-free composite heat preservation formwork of the present utility model;

FIG. 2 is a top view of FIG. 1;

FIG. 3 is a cross-sectional view of one possible embodiment in the direction B-B in FIG. 2;

FIG. 4 is a cross-sectional view of one possible embodiment in the direction B-B in FIG. 2;

fig. 5 is an enlarged view at a in fig. 3.

In the figure: 1. a top layer; 2. a heat preservation layer; 21. polyurethane particles; 3. a bottom layer; 4. connecting steel wires; 51. a first steel wire mesh layer; 52. a second steel wire mesh layer; 61. a first glass fiber web layer; 62. a second fiberglass web layer.

Detailed Description

The following describes in further detail the embodiments of the present utility model with reference to the drawings and examples. The following examples are illustrative of the utility model and are not intended to limit the scope of the utility model.

Referring to fig. 1, the double-sided steel wire mesh reinforced building disassembly-free composite heat insulation template comprises a surface layer and a heat insulation layer 2, wherein the surface layer comprises a top surface layer 1 and a bottom surface layer 3, the heat insulation layer 2 is positioned between the top surface layer 1 and the bottom surface layer 3, in general, the top surface layer 1 is adhered to the top surface of the heat insulation layer 2, the bottom surface layer 3 is adhered to the bottom surface of the heat insulation layer 2, and one-time reinforcement of the heat insulation layer 2, the top surface layer 1 and the bottom surface layer 3 is realized.

In addition, referring to fig. 2 to 5, the inside of the heat preservation 2 is further penetrated with a plurality of connecting wires 4, each connecting wire 4 further penetrates out of the heat preservation 2 and is further fixedly connected with the top layer 1 and the bottom layer 3 respectively, the top layer 1 and the bottom layer 3 are reinforced on the heat preservation 2 through the plurality of connecting wires 4, the secondary reinforcement of the heat preservation 2 and the top layer 1 and the bottom layer 3 is realized, the connection strength of the heat preservation 2 and the top layer 1 and the bottom layer 3 is further enhanced, and the phenomenon that the top layer 1 and/or the bottom layer 3 fall off from the heat preservation 2 is not easy to occur.

In order to be convenient for laminate with the wall, heat preservation 2, top layer 1 and bottom layer 3 all set up to platy, in the installation, need guarantee that bottom layer 3 is parallel with the wall and hug closely bottom layer 3 on the wall.

In some possible embodiments, referring to fig. 3, each connecting wire 4 in the insulation layer 2 is continuously disposed, and two ends of each connecting wire 4 respectively penetrate from the top surface and the bottom surface of the insulation layer 2 and respectively penetrate into the inside of the top surface layer 1 near one side of the insulation layer 2 and the inside of the bottom surface layer 3 near one side of the insulation layer 2.

In some possible embodiments, referring to fig. 4, each connecting wire 4 in the insulation layer 2 is provided intermittently, and one end of the connecting wire 4 near the bottom surface of the insulation layer 2 penetrates out from the top surface of the insulation layer 2 and into the inside of the top surface layer 1, and one end of the connecting wire 4 near the bottom surface of the insulation layer 2 penetrates out from the bottom surface of the insulation layer 2 and into the inside of the bottom surface layer 3.

Still further, the inside of top layer 1 has laid first glass fiber net layer 61 and first wire net layer 51 in proper order along the direction of keeping away from heat preservation 2, and the one end of every connection steel wire 4 is worn out from the top surface of heat preservation 2, still need pass first glass fiber net layer 61, and last fixed setting is on the first wire net layer 51, and first glass fiber net layer 61 and first wire net layer 51 play the effect of strengthening top layer 1 structural strength on the one hand, and on the other hand play the effect of strengthening the connection effect.

Similar to the inner structure setting of top layer 1, the inside of bottom surface layer 3 has laid second glass fiber net layer 62 and second wire net layer 52 in proper order along the direction of keeping away from heat preservation 2, and the one end of every connection steel wire 4 is worn out from the bottom surface of heat preservation 2 after, still need pass second glass fiber net layer 62, and finally fixed the setting on second wire net layer 52, second glass fiber net layer 62 and second wire net layer 52 have played the effect of strengthening bottom surface layer 3 structural strength on the one hand, have played the effect of strengthening the connection effect on the other hand.

Further, the thickness ratio of the heat preservation layer 2 to the top surface layer 1 is 2:1 to 2.5:1, the thickness ratio of the heat preservation layer 2 to the bottom surface layer 1 is 11:1 to 11.5:1, preferably, the thickness of the heat preservation layer 2 is 20cm, the thickness of the top surface layer 1 is 10cm, and the thickness of the bottom surface layer 3 is 1.9cm.

Preferably, the heat preservation layer 2 is made of a heat preservation plate with polyurethane particles 21, so that the heat preservation and heat insulation effects are achieved, the top surface layer 1 and the bottom surface layer 3 are made of cement-based mortar materials, the heat preservation layer 2 is protected, and the first glass fiber net layer 61 and the second glass fiber net layer 62 are in a grid cloth shape.

The installation process comprises the following steps: firstly, punching through holes in the heat preservation layer 2, ensuring that the heat preservation plate 2 has 6 through holes per square meter, ensuring that the heat preservation plate 2 has at least six connecting steel wires 4 per square meter, and further ensuring the connection strength of the heat preservation plate 2, the top surface layer 1 and the bottom surface layer 3;

the first glass fiber net layer 61 and the first steel wire net layer 51 form a framework of the top layer 1, and after the connecting steel wires 4 penetrate through the heat insulation layer 2, one end penetrates through the first glass fiber net layer 61 of the top layer 1 and is bound on the first steel wire net layer 51;

the second glass fiber net layer 62 and the second steel wire net layer 52 form a framework of the bottom layer 3, and after the connecting steel wires 4 penetrate through the heat insulation layer 2, the other ends penetrate through the second glass fiber net layer 62 and are bound on the second steel wire net layer 52.

The foregoing is merely a preferred embodiment of the present utility model, and it should be noted that modifications and substitutions can be made by those skilled in the art without departing from the technical principles of the present utility model, and these modifications and substitutions should also be considered as being within the scope of the present utility model.

Claims (7)

1. The utility model provides a two-sided steel wire mesh reinforcement type building exempts from to tear open compound heat preservation template which characterized in that includes: the top layer is fixedly arranged on one surface of the heat preservation layer, the bottom layer is fixedly arranged on the other surface of the heat preservation layer, a plurality of connecting steel wires penetrate through the heat preservation layer, and the connecting steel wires are fixedly arranged in the top layer, close to the inner portion of one surface of the heat preservation layer, and the bottom layer, close to the inner portion of one surface of the heat preservation layer.

2. The double-sided steel wire mesh reinforced building disassembly-free composite heat preservation formwork of claim 1, wherein a first steel wire mesh layer is further arranged in the top surface layer, and one ends of the plurality of connecting steel wires are fixedly connected with the first steel wire mesh layer.

3. The double-sided steel wire mesh reinforced building disassembly-free composite heat preservation formwork of claim 2, wherein a first glass fiber net layer is further arranged in the top surface layer, and one ends of the plurality of connecting steel wires penetrate through the first glass fiber net layer and are fixedly connected with the first steel wire net layer.

4. The double-sided steel wire mesh reinforced building disassembly-free composite heat preservation formwork of claim 1, wherein a second steel wire mesh layer is arranged in the bottom surface layer, and the other ends of the connecting steel wires are fixedly connected with the second steel wire mesh layer.

5. The double-sided steel wire mesh reinforced building disassembly-free composite heat preservation formwork of claim 4, wherein a second glass fiber net layer is further arranged in the bottom surface layer, and the other ends of the connecting steel wires penetrate through the second glass fiber net layer and are fixedly connected with the second steel wire net layer.

6. The double-sided steel wire mesh reinforced composite heat preservation formwork for construction of no-dismantling construction of any one of claims 1 to 5, wherein the heat preservation layer is a polyurethane particle heat preservation plate, and the top surface layer and the bottom surface layer are made of cement-based mortar.

7. The double-sided wire mesh reinforced building disassembly-free composite heat preservation formwork of claim 6, wherein the thickness ratio of the heat preservation layer to the top surface layer is 2:1 to 2.5:1, and the thickness ratio of the heat preservation layer to the bottom surface layer is 11:1 to 11.5:1.