CN219175550U - Assembled heat preservation energy-saving wall structure - Google Patents

Abstract

The utility model discloses an assembled heat-insulating energy-saving wall structure, which comprises a wall body, wherein a plurality of storage cavities are uniformly formed in the wall body and used for storing indoor dispersed gas, the indoor heat-insulating effect is improved, a plurality of reinforcing seats are uniformly and fixedly connected to the side wall of the wall body, mounting grooves are formed between the corresponding reinforcing seats, and heat-insulating components are bonded to the inner walls of the mounting grooves. According to the utility model, the wall body is provided with the plurality of clamping grooves, so that the heat preservation assembly can be integrally clamped, adhered and fixed, the processing efficiency is improved, meanwhile, the inside of the heat preservation assembly is provided with the multi-layer protective layer for protecting the rock wool board inside, preventing the temperature loss of the inside, and the inside of the wall body is provided with the intermittent hollow structure, so that the heat preservation gas can be stored, and the temperature loss is reduced.

Description

Assembled heat preservation energy-saving wall structure

Technical Field

The utility model relates to the technical field of heat preservation wall application, in particular to an assembled heat preservation energy-saving wall structure.

Background

Along with the rapid development of the building industry, people are increasingly looking at indoor walls, in order to improve the indoor heat preservation performance in cold seasons, people often improve indoor or outdoor walls, and the improved walls not only improve the heat preservation performance, but also play a role in protecting the walls to a certain extent.

For example, the patent number CN214195083U is a light airtight heat-insulating wall, the hollow Kong Haoka joint hole is formed in the middle of the middle heat-insulating layer, so that the weight of materials is reduced, the construction is convenient, the construction is quicker, the labor intensity is greatly reduced, and the clamping blocks are arranged on opposite surfaces of the two heat-insulating layers to be clamped with each other, so that the layers can be fixed more firmly during installation, the firmness of the device is improved, the falling of each layer of structure is avoided, the safety of the structure is improved, however, the heat-insulating structure needs to be added into the whole building during construction, the whole cost is increased, the whole heat-insulating structure cannot be transformed in later period, the construction is a one-time construction mode, the materials are wasted, and meanwhile, some existing heat-insulating layers are required to be additionally arranged on one layer, so that the machining efficiency is lower.

Disclosure of Invention

The utility model aims to solve the technical problem of providing an assembled heat-insulating energy-saving wall structure, which can integrally clamp, bond and fix a heat-insulating component through arranging a plurality of clamping grooves on a wall, improve the efficiency in processing, and meanwhile, a plurality of protective layers are arranged in the heat-insulating component and used for protecting an internal rock wool board, preventing the internal temperature from losing, and the wall is intermittently hollow, so that heat-insulating gas can be stored, and the temperature loss is reduced.

In order to solve the technical problems, the utility model adopts a technical scheme that: the utility model provides an assembled heat preservation energy-saving wall structure, including the wall body, the inside of wall body has evenly offered a plurality of storage chamber for to the gas that gives off in the room stores, improves the heat preservation effect to indoor, the even fixedly connected with of lateral wall of wall body a plurality of reinforcing seats, all offered the mounting groove between a plurality of reinforcing seats are corresponding, the inner wall bonding of mounting groove has the heat preservation subassembly;

the heat preservation assembly comprises a rock wool board, a first layer of grid cloth is fixedly connected to the side wall of the rock wool board, a second layer of grid cloth is adhered to the side wall of the first layer of grid cloth, a third layer of grid cloth is adhered to the side wall of the second layer of grid cloth, a fourth layer of grid cloth is adhered to the side wall of the third layer of grid cloth, and fifth-layer mortar is evenly smeared on the side wall of the fourth layer of grid cloth.

The utility model is further provided with: the side walls of the reinforcing seats are symmetrically provided with clamping grooves, and are in clamping connection with the heat preservation assembly.

Through above-mentioned technical scheme, be convenient for carry out quick installation to insulation package and fix, convenient later stage's change.

The utility model is further provided with: the lateral wall of rock wool board has seted up a plurality of spouts, and is inseparable bonding setting with the mounting groove through mortar.

Through above-mentioned technical scheme, be convenient for carry out firm bonding with the heat preservation subassembly through rock wool board on the wall body.

The utility model is further provided with: a first layer of mortar is arranged between the rock wool board and the first layer of grid cloth.

Through above-mentioned technical scheme for protect rock wool board, improve the wholeness simultaneously.

The utility model is further provided with: and a second layer of mortar is arranged between the first layer of grid cloth and the second layer of grid cloth.

Through above-mentioned technical scheme for first layer net cloth and second floor net cloth carry out inseparable connection fixedly, play protection and heat retaining effect to whole heat preservation subassembly.

The utility model is further provided with: and a third layer of mortar is arranged between the second layer of grid cloth and the third layer of grid cloth.

Through the technical scheme, the method is used for reinforcing the firmness between the second layer of gridding cloth and the third layer of gridding cloth.

The utility model is further provided with: and a fourth layer of mortar is arranged between the third layer of grid cloth and the fourth layer of grid cloth.

Through above-mentioned technical scheme, be convenient for consolidate third layer net cloth and fourth layer net cloth, prevent to drop.

The utility model is further provided with: the grid densities of the first layer of grid cloth, the second layer of grid cloth, the third layer of grid cloth and the fourth layer of grid cloth are in decreasing arrangement.

Through above-mentioned technical scheme, be convenient for make inside net cloth more firm, prevent holistic dropping.

The beneficial effects of the utility model are as follows:

1. according to the assembled heat-insulating energy-saving wall structure, the plurality of clamping grooves are formed in the wall, so that the heat-insulating assembly can be integrally clamped, adhered and fixed, and the efficiency in processing is improved;

2. the assembled heat-insulating energy-saving wall body structure is characterized in that a plurality of protective layers are arranged in the heat-insulating assembly and used for protecting the rock wool boards in the heat-insulating assembly to prevent the temperature loss in the heat-insulating assembly;

3. according to the assembled heat-insulating energy-saving wall structure, the inside of the wall is intermittently hollow, so that heat-insulating gas can be stored, and the temperature loss is reduced.

Drawings

FIG. 1 is a schematic diagram of an assembled thermal insulation energy-saving wall structure according to the present utility model;

FIG. 2 is a cross-sectional view of a thermal insulation assembly in an assembled thermal insulation energy saving wall construction of the present utility model;

FIG. 3 is a block diagram of a multi-layer scrim in an assembled thermal insulation wall construction of the present utility model.

In the figure: 1. a wall body; 11. a storage chamber; 2. a reinforcing seat; 21. a clamping groove; 3. a mounting groove; 4. rock wool boards; 41. a first layer of mortar; 5. a first layer of mesh cloth; 51. a second layer of mortar; 6. a second layer of mesh cloth; 61. a third layer of mortar; 7. a third layer of mesh cloth; 71. a fourth layer of mortar; 8. a fourth layer of mesh cloth; 81. fifth layer mortar.

Detailed Description

The preferred embodiments of the present utility model will be described in detail below with reference to the accompanying drawings so that the advantages and features of the present utility model can be more easily understood by those skilled in the art, thereby making clear and defining the scope of the present utility model.

As shown in fig. 1, an assembled heat-insulating energy-saving wall structure comprises a wall body 1, wherein a plurality of storage cavities 11 are uniformly formed in the wall body 1 and used for storing gas emitted indoors, the indoor heat-insulating effect is improved, a plurality of reinforcing seats 2 are uniformly and fixedly connected to the side wall of the wall body 1, clamping grooves 21 are symmetrically formed in the side wall of each reinforcing seat 2 and are in clamping connection with a heat-insulating component, the heat-insulating component is convenient to install and fix rapidly, later replacement is convenient, mounting grooves 3 are formed between the corresponding positions of the reinforcing seats 2, and the inner wall of each mounting groove 3 is bonded with the heat-insulating component;

as shown in fig. 2 and 3, the heat insulation component comprises a rock wool board 4, a plurality of sliding grooves are formed in the side wall of the rock wool board 4, and the side wall of the rock wool board 4 is tightly adhered to the mounting groove 3 through mortar, so that the heat insulation component is firmly adhered to the wall 1 through the rock wool board 4, a first layer of grid cloth 5 is fixedly connected to the side wall of the rock wool board 4, a first layer of mortar 41 is arranged between the rock wool board 4 and the first layer of grid cloth 5 and used for protecting the rock wool board 4, the integrity is improved, a second layer of grid cloth 6 is adhered to the side wall of the first layer of grid cloth 5, a second layer of mortar 51 is arranged between the first layer of grid cloth 5 and the second layer of grid cloth 6, the first layer of grid cloth 5 and the second layer of grid cloth 6 are tightly connected and fixed, the whole heat insulation component is protected and insulated, the lateral wall bonding of second floor's net cloth 6 is provided with third layer net cloth 7, be provided with third layer mortar 61 between second floor's net cloth 6 and the third layer net cloth 7, be used for strengthening the fastness between second floor's net cloth 6 and the third layer net cloth 7, the lateral wall bonding of third layer net cloth 7 is provided with fourth layer net cloth 8, be provided with fourth layer mortar 71 between third layer net cloth 7 and the fourth layer net cloth 8, be convenient for consolidate third layer net cloth 7 and fourth layer net cloth 8, prevent to drop, fifth layer mortar 81 has evenly been paintd to the lateral wall of fourth layer net cloth 8, first layer net cloth 5, second layer net cloth 6, third layer net cloth 7 and fourth layer net cloth 8's net density is the setting of diminishing, be convenient for make inside net cloth more firm, prevent holistic dropping.

When the heat insulation device is used, the multi-layer protection layer is arranged in the heat insulation component and used for protecting the rock wool board 4 in the heat insulation component, so that the temperature loss in the heat insulation component is prevented, meanwhile, the multi-layer grid cloth is stacked, the temperature on the rock wool board 4 is difficult to lose, the heat insulation effect is improved, meanwhile, the inside of the wall body 1 is intermittently and hollowly arranged, so that heat insulation gas can be stored, the temperature loss is reduced, the integral heat insulation performance is further improved, the heat insulation component is pre-processed, and the heat insulation component is conveniently inserted into the clamping groove 21 in the integral mode, and therefore the installation efficiency is improved.

The foregoing description is only illustrative of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structures or equivalent processes or direct or indirect application in other related technical fields are included in the scope of the present utility model.

Claims (8)

1. The utility model provides an assembled heat preservation energy-saving wall structure, includes wall body (1), its characterized in that: a plurality of storage cavities (11) are uniformly formed in the wall body (1), a plurality of reinforcing seats (2) are uniformly and fixedly connected to the side wall of the wall body (1), mounting grooves (3) are formed between the corresponding reinforcing seats (2), and heat-insulating components are adhered to the inner wall of the mounting grooves (3);

the heat preservation subassembly includes rock wool board (4), the lateral wall fixedly connected with first layer net cloth (5) of rock wool board (4), the lateral wall bonding of first layer net cloth (5) is provided with second floor net cloth (6), the lateral wall bonding of second floor net cloth (6) is provided with third layer net cloth (7), the lateral wall bonding of third layer net cloth (7) is provided with fourth layer net cloth (8), the even fifth layer mortar (81) of scribbling of lateral wall of fourth layer net cloth (8).

2. The fabricated thermal insulation wall construction of claim 1, wherein: the side walls of the reinforcing seats (2) are symmetrically provided with clamping grooves (21) which are in clamping connection with the heat preservation component.

3. The fabricated thermal insulation wall construction of claim 1, wherein: the side wall of the rock wool board (4) is provided with a plurality of sliding grooves, and the side wall is tightly adhered to the mounting groove (3) through mortar.

4. The fabricated thermal insulation wall construction of claim 1, wherein: a first layer of mortar (41) is arranged between the rock wool board (4) and the first layer of grid cloth (5).

5. The fabricated thermal insulation wall construction of claim 1, wherein: a second layer of mortar (51) is arranged between the first layer of gridding cloth (5) and the second layer of gridding cloth (6).

6. The fabricated thermal insulation wall construction of claim 1, wherein: a third layer of mortar (61) is arranged between the second layer of gridding cloth (6) and the third layer of gridding cloth (7).

7. The fabricated thermal insulation wall construction of claim 1, wherein: a fourth layer of mortar (71) is arranged between the third layer of gridding cloth (7) and the fourth layer of gridding cloth (8).

8. The fabricated thermal insulation wall construction of claim 1, wherein: the grid densities of the first layer of grid cloth (5), the second layer of grid cloth (6), the third layer of grid cloth (7) and the fourth layer of grid cloth (8) are in decreasing arrangement.

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