CN215977816U - Integrated external wall heat insulation system - Google Patents

Abstract

The application relates to an integrated external wall insulation system. The application integral type external wall insulation system include: the heat preservation square, the bottom layer grid cloth and the mounting bar; the bottom layer grid cloth is laid on one side surface of the heat-insulation square blocks, the heat-insulation square blocks are sequentially spliced, and the bottom surfaces of the heat-insulation square blocks are placed on the mounting strips; the heat-insulating block comprises a surface interface agent layer, a heat-insulating layer, a middle interface agent layer, a first mortar layer, a first grid cloth layer, a putty layer and a finish coat which are sequentially stacked; the bottom layer mesh cloth is fixedly adhered to the surface interface agent layer; one side of the heat preservation layer is provided with a convex strip, the other side of the heat preservation layer is provided with a groove at the corresponding position, and the convex strip of the heat preservation layer is matched with the groove of the other heat preservation layer in a splicing manner. The application integral type external wall insulation system have the advantage of saving time and saving cost.

Description

Integrated external wall heat insulation system

Technical Field

The application relates to a heat preservation system, in particular to an integrated external wall heat preservation system.

Background

The existing wall surface is insulated, a multilayer structure is respectively arranged to match with the laying of an insulation board or an insulation material, and each layer of structure needs to be constructed on site once, so that the overall construction amount is large. For example, after wall surface leveling is performed, a wall surface adhesive needs to be coated, then grids are installed, the grids are laid layer by layer, once construction is needed after one layer is laid, even leveling is needed, the workload of field construction is increased, especially in recent years, the requirement for wall body heat insulation is improved, the construction amount is large, and the total construction cost is greatly increased along with the increase of labor cost. Therefore, the wall body heat preservation of the prior art has the problems of great labor and high cost.

Disclosure of Invention

Based on this, the purpose of this application is to provide integral type external wall insulation system, and it has the advantage of saving time and saving cost.

One aspect of the application provides an integrated external wall insulation system, which comprises insulation blocks, bottom layer grid cloth and installation bars; the bottom layer grid cloth is laid on one side surface of the heat-insulation square blocks, the heat-insulation square blocks are sequentially spliced, and the bottom surfaces of the heat-insulation square blocks are placed on the mounting strips;

the section of the mounting bar is shaped like a T;

the heat-insulating block comprises a surface interface agent layer, a heat-insulating layer, a middle interface agent layer, a first mortar layer, a first grid cloth layer, a putty layer and a decorative surface layer; the surface interface agent layer, the heat insulation layer, the middle interface agent layer, the first mortar layer, the first mesh fabric layer, the putty layer and the finish coat are sequentially stacked;

the bottom layer mesh cloth is fixedly adhered to the surface interface agent layer;

one side of the heat preservation layer is provided with a convex strip, the other side of the heat preservation layer is provided with a groove at the corresponding position, and the convex strip of the heat preservation layer is matched with the groove of the other heat preservation layer in a splicing manner.

The application integral type external wall insulation system, the heat preservation square can be prefabricated in the mill, then assembly moulding, only need with the heat preservation square direct mount on the wall can at the job site, reduced site operation's operating requirement and time limit for a project. In order to ensure the connection stability of the heat-insulating blocks during site construction, on one hand, bottom layer grid cloth is arranged to facilitate the stable connection of the heat-insulating blocks and the wall body, and the stable connection of the two heat-insulating blocks is also enhanced; on the other hand has set up sand grip and recess for the concatenation of two heat preservation squares is stable. The heat preservation square block is fixed on the wall through gluing or expansion screws so as to be convenient to install and fix.

Furthermore, the mounting strip comprises a transverse plate and a vertical plate, one end of the transverse plate is fixedly mounted in the middle of the vertical plate, and the transverse plate is vertically arranged relative to the vertical plate;

the bottom end of the heat preservation square block is supported and placed on the transverse plate.

Furthermore, the convex strips are provided with mounting holes, and the heat-insulating layer is provided with alignment holes at corresponding positions of the grooves; an expansion screw is arranged in the alignment hole;

the alignment hole of one heat-insulating layer is correspondingly matched with the mounting hole of the other heat-insulating layer.

Furthermore, the height of the bottom layer grid cloth is consistent with that of the heat preservation square block, and the width of the bottom layer grid cloth is consistent with that of the heat preservation square block;

the bottom layer grid cloth and the heat preservation square blocks are installed in a staggered mode along the width direction.

Furthermore, the adhesive mortar layer is laid on the bottom layer grid cloth and is respectively positioned on two sides of the bottom layer grid cloth together with the surface interface agent layer.

Furthermore, the heat-insulating block also comprises a second mortar layer, and the second mortar layer is arranged between the first mesh fabric layer and the putty layer.

Furthermore, the heat preservation square also comprises a second mesh cloth layer, and the second mesh cloth layer is arranged between the second mortar layer and the putty layer.

Furthermore, the heat-insulating block also comprises a plastering mortar layer, and the plastering mortar layer is arranged between the second mesh fabric layer and the putty layer.

Further, the finish coat is a paint finish coat or a tile finish coat.

Further, the bottom layer mesh cloth is glass fiber alkali-resistant mesh cloth.

For a better understanding and practice, the present application is described in detail below with reference to the accompanying drawings.

Drawings

FIG. 1 is a perspective view of an exemplary insulating cube and bottom grid assembly of the present application;

FIG. 2 is a schematic perspective view of an alternative perspective view of an exemplary insulating cube and bottom grid arrangement of the present application;

FIG. 3 is a top view of an exemplary insulating block, bottom layer scrim, bonded mortar layer assembly of the present application;

FIG. 4 is an enlarged view of the partial structure I shown in FIG. 3;

FIG. 5 is a schematic perspective view of an exemplary integrated exterior wall insulation system of the present application;

FIG. 6 is a schematic perspective view from another perspective of an exemplary integrated exterior wall insulation system of the present application;

FIG. 7 is a front view of an exemplary insulating cube and underlying scrim assembly of the present application;

FIG. 8 is a top wall view of an exemplary integrated exterior wall insulation system of the present application.

Detailed Description

In the description of the present application, it is to be understood that the terms "center," "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientation or positional relationship indicated in the drawings for convenience in describing the present application and for simplicity in description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed in a particular orientation, and be operated in a particular manner, and are not to be considered limiting of the present application. In the description of the present application, "a plurality" means two or more unless otherwise specified.

FIG. 1 is a perspective view of an exemplary insulating cube and bottom grid assembly of the present application; FIG. 2 is a schematic perspective view of an alternative perspective view of an exemplary insulating cube and bottom grid arrangement of the present application; FIG. 3 is a front view of an exemplary insulating cube and underlying scrim assembly of the present application; FIG. 4 is a top view of an exemplary insulating block, bottom layer scrim, bonded mortar layer assembly of the present application; FIG. 5 is an enlarged view of the partial structure I shown in FIG. 4; FIG. 6 is a schematic perspective view of an exemplary integrated exterior wall insulation system of the present application; FIG. 7 is a schematic perspective view from another perspective of an exemplary integrated exterior wall insulation system of the present application; FIG. 8 is a top wall view of an exemplary integrated exterior wall insulation system of the present application.

Referring to fig. 1 to 8, an exemplary integrated external wall insulation system of the present application includes an insulation block 10, a bottom layer mesh cloth 20, and a mounting bar 30; the bottom layer grid cloth 20 is laid on one side surface of the heat-insulation square blocks 10, the heat-insulation square blocks 10 are sequentially spliced, and the bottom surfaces of the heat-insulation square blocks 10 are placed on the mounting strips 30;

the section of the mounting bar 30 is T-shaped;

the heat-insulating block 10 comprises a surface interface agent layer 11, a heat-insulating layer 12, an intermediate interface agent layer 13, a first mortar layer 14, a first mesh fabric layer 15, a putty layer 19 and a finishing layer 51; the surface interface agent layer 11, the insulating layer 12, the middle interface agent layer 13, the first mortar layer 14, the first mesh fabric layer 15, the putty layer 19 and the finishing layer 51 are sequentially stacked;

the bottom layer grid cloth 20 is fixedly adhered to the surface interface agent layer 11;

one side of the heat-insulating layer 12 is formed with a convex strip A1, the other side thereof is correspondingly formed with a groove A2, and the convex strip A1 of one heat-insulating layer 12 is matched with the groove A2 of the other heat-insulating layer 12 in a splicing manner.

The application integral type external wall insulation system, heat preservation square 10 can be prefabricated in the mill, then assembly moulding, only need with heat preservation square 10 direct mount on-wall at the job site can, reduced site operation's operating requirement and time limit for a project. In order to ensure the connection stability of the heat-insulating square blocks 10 during field construction, on one hand, the bottom layer grid cloth 20 is arranged to facilitate the stable connection of the heat-insulating square blocks 10 and the wall body, and the stable connection of the two heat-insulating square blocks 10 is also enhanced; on the other hand, the convex strips A1 and the grooves A2 are arranged, so that the splicing of the two heat preservation squares 10 is stable. The insulating block 10 is fixed to the wall by gluing or by expansion screws for easy installation and fixing.

When the surface interface agent layer 11, the heat insulation layer 12, the intermediate interface agent layer 13, the first mortar layer 14, the first mesh fabric layer 15, the putty layer 19 and the finish coat layer 51 are sequentially stacked and sequentially laid for installation.

In some preferred embodiments, the mounting bar 30 comprises a horizontal plate 31 and a vertical plate 32, one end of the horizontal plate 31 is fixedly mounted in the middle of the vertical plate 32, and the horizontal plate 31 is vertically arranged relative to the vertical plate 32; the bottom end of the heat preservation square block 10 is supported and placed on the transverse plate 31. When the wall is installed, the vertical plates 32 are vertically placed and fixed on the wall body through screws, or expansion screws. The transverse plate 31 is transversely placed at this moment, and the bottom end of the heat preservation square 10 on the upper surface of the transverse plate 31 is placed on the transverse plate. Therefore, the heat-insulation square blocks 10 are supported and stacked one by one through the mounting bar 30, the heat-insulation square blocks 10 on the same row are placed on the mounting bar 30 one by one, and the heat-insulation square blocks 10 on the same row are also placed stably.

In some preferred embodiments, the protruding strips a1 are provided with mounting holes M, and the insulating layer 12 is provided with alignment holes N at positions corresponding to the grooves a 2; an expansion screw is arranged in the alignment hole N; the alignment hole N of one insulating layer 12 is correspondingly matched with the mounting hole M of the other insulating layer 12. Further, the corresponding position of the bottom layer grid cloth 20 is provided with a through hole, and the through hole is arranged corresponding to the alignment hole N. The mounting hole M corresponds to the alignment hole N in position, sequentially penetrates through the mounting hole M, the alignment hole N and the through hole through expansion screws, and then one heat-insulating square 10 is connected and fastened with the other heat-insulating square 10.

In some preferred embodiments, the protrusion A1 of one heat-preservation cube 10 is fixed with the groove A2 of another heat-preservation cube 10 by gluing.

In some preferred embodiments, the height of the bottom layer mesh cloth 20 is consistent with the height of the heat-preservation cube 10, and the width of the bottom layer mesh cloth 20 is consistent with the width of the heat-preservation cube 10; the bottom layer grid cloth 20 and the heat preservation square 10 are installed in a staggered mode along the width direction. The bottom layer grid cloth 20 is staggered in the width direction relative to the heat preservation square 10, so that one end of the bottom layer grid cloth 20 extends for a certain distance relative to the heat preservation square 10, and meanwhile, the connection range of the bottom layer grid cloth 20 on the heat preservation square 10 lacks for a certain distance; therefore, during splicing, the three heat-insulating squares 10 are connected in sequence, the extending section of the bottom layer grid cloth 20 of one heat-insulating square 10 is bonded on the missing section of the bottom layer grid cloth 20 of the other heat-insulating square 10, and the heat-insulating squares 10 are spliced with each other and are connected more firmly. Therefore, the connection of the plurality of heat preservation blocks 10 has double guarantees, one is the matching of the grooves A2 and the convex strips A1, and the other is the bonding of the extension section of the bottom layer grid cloth 20 and the other heat preservation block 10.

In some preferred embodiments, the adhesive mortar layer 40 is further included, and the adhesive mortar layer 40 is laid on the bottom grid cloth 20 and is located on both sides of the bottom grid cloth 20 together with the surface interface agent layer 11. The bonding mortar layer 40 is arranged, so that the heat-insulating square 10 and the bottom grid cloth 20 can be respectively fastened and bonded on the upper wall. During installation, a layer of adhesive mortar is applied to the wall, the bottom layer mesh cloth 20 is laid on the wall, and when the adhesive mortar is dried and solidified, the adhesive mortar layer 40 is formed.

In some preferred embodiments, the bonding mortar layer 40 is a polymeric bonding mortar coating.

In some preferred embodiments, the insulating block 10 further includes a second mortar layer 16, and the second mortar layer 16 is disposed between the first mesh fabric layer 15 and the putty layer 19. The second mortar layer 16 is formed by mortar which is laid when prefabricated at a factory and then dried and solidified to form the second mortar layer 16. The second mortar layer 16 is provided to reinforce the tight engagement of the first and second scrim.

In some preferred embodiments, the insulating block 10 further includes a second scrim layer 17, and the second scrim layer 17 is disposed between the second mortar layer 16 and the putty layer 19. After the second mortar layer 16 is solidified, a second scrim layer 17 is laid thereon. Further, the second scrim layer 17 is a fiberglass scrim.

In some preferred embodiments, the heat-insulating block 10 further comprises a finishing mortar layer 18, and the finishing mortar layer 18 is disposed between the second mesh fabric layer 17 and the putty layer 19. After the second scrim is laid, a layer of rendering mortar is applied and a layer of rendering mortar 18 is then formed. The surface smoothness of the heat-insulating block 10 can be improved by coating the plastering mortar layer 18.

In some preferred embodiments, the finish 51 is a paint finish 51 or a tile finish 51. After the plastering mortar layer 18 is laid, the finishing layer 51 is laid on the surface of the plastering mortar layer, so that heat preservation and decoration are integrated, and the field construction amount is reduced.

In some preferred embodiments, the bottom layer scrim 20 is a fiberglass alkali resistant scrim.

In some preferred embodiments, the insulation layer 12 is a polyurethane insulation board.

In some preferred embodiments, the putty layer 19 is a water resistant putty coating.

The working principle of the exemplary integrated external wall insulation system of the application is as follows:

when the floor mat is installed, the bonding mortar layer 40, the bottom layer grid cloth 20, the surface interface agent layer 11, the heat insulation layer 12, the middle interface agent layer 13, the first mortar layer 14, the first grid cloth layer 15, the second mortar layer 16, the second grid cloth layer 17, the plastering mortar layer 18, the putty layer 19 and the finishing layer 51 are sequentially stacked and installed.

On one hand, the heat preservation square 10 is fully paved through the bonding mortar layer 40, and then is fixed on the wall; on the other hand, the upper wall is also fixed through expansion screws on the alignment hole N and the mounting hole M.

The exemplary integral type external wall insulation system of this application, at the direct prefabricated shaping heat preservation square 10 of mill, only need lay one deck bonding mortar layer 40 and fixed mounting strip 30 during site operation can, simple to operate is swift, and the connection fastening of heat preservation square 10 is reliable. In addition, the integral type external wall insulation system of this application, still effectual problem of avoiding and having reduced the heat bridge has improved heat preservation and protecting effect.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the claims. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application.

Claims (10)

1. The utility model provides an integral type external wall insulation system which characterized in that: comprises a heat preservation square block, bottom layer gridding cloth and a mounting bar; the bottom layer grid cloth is laid on one side surface of the heat-insulation square blocks, the heat-insulation square blocks are sequentially spliced, and the bottom surfaces of the heat-insulation square blocks are placed on the mounting strips;

the section of the mounting bar is shaped like a T;

the heat-insulating block comprises a surface interface agent layer, a heat-insulating layer, a middle interface agent layer, a first mortar layer, a first grid cloth layer, a putty layer and a decorative surface layer; the surface interface agent layer, the heat insulation layer, the middle interface agent layer, the first mortar layer, the first mesh fabric layer, the putty layer and the finish coat are sequentially stacked;

the bottom layer mesh cloth is fixedly adhered to the surface interface agent layer;

one side of the heat preservation layer is provided with a convex strip, the other side of the heat preservation layer is provided with a groove at the corresponding position, and the convex strip of the heat preservation layer is matched with the groove of the other heat preservation layer in a splicing manner.

2. The integrated exterior wall insulation system according to claim 1, wherein: the mounting strip comprises a transverse plate and a vertical plate, one end of the transverse plate is fixedly mounted in the middle of the vertical plate, and the transverse plate is vertically arranged relative to the vertical plate;

the bottom end of the heat preservation square block is supported and placed on the transverse plate.

3. The integrated exterior wall insulation system according to claim 2, wherein: the convex strips are provided with mounting holes, and the heat-insulating layer is provided with alignment holes at corresponding positions of the grooves; an expansion screw is arranged in the alignment hole;

the alignment hole of one heat-insulating layer is correspondingly matched with the mounting hole of the other heat-insulating layer.

4. The integrated exterior wall insulation system according to claim 3, wherein: the height of the bottom layer grid cloth is consistent with that of the heat preservation square block, and the width of the bottom layer grid cloth is consistent with that of the heat preservation square block;

the bottom layer grid cloth and the heat preservation square blocks are installed in a staggered mode along the width direction.

5. The integrated exterior wall insulation system according to claim 4, wherein: the adhesive mortar layer is laid on the bottom layer gridding cloth and is respectively positioned on two sides of the bottom layer gridding cloth together with the surface interface agent layer.

6. The integrated exterior wall insulation system according to any one of claims 1 to 5, wherein: the heat-insulating block also comprises a second mortar layer, and the second mortar layer is arranged between the first mesh fabric layer and the putty layer.

7. The integrated exterior wall insulation system according to claim 6, wherein: the heat-preservation square also comprises a second mesh cloth layer, and the second mesh cloth layer is arranged between the second mortar layer and the putty layer.

8. The integrated exterior wall insulation system according to claim 7, wherein: the heat-insulating square block also comprises a plastering mortar layer, and the plastering mortar layer is arranged between the second mesh fabric layer and the putty layer.

9. The integrated exterior wall insulation system according to claim 6, wherein: the finish coat is a paint finish coat or a tile finish coat.

10. The integrated exterior wall insulation system according to claim 6, wherein: the bottom layer mesh cloth is glass fiber alkali-resistant mesh cloth.

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