CN215332294U - Mounting structure of window stone material wafts - Google Patents

Abstract

The application aims at providing an installation structure of bay window stone, which mainly comprises a windowsill base layer; the interface agent layer is laid on the windowsill base layer; a cement mortar leveling layer laid on the interface agent layer; the first bonding layer is flatly laid on the cement mortar leveling layer; stone laid on the first bonding layer, and the like. The first bonding layer is used for being laid on the cement mortar leveling layer after the cement mortar leveling layer is leveled and cured. Compared with the prior art, the application can effectively reduce the hollowing rate of the stone material of the floating windowsill.

Description

Mounting structure of window stone material wafts

Technical Field

The utility model relates to the field of building decoration, in particular to a mounting structure for bay window stone.

Background

In the field of decoration, more and more people prefer to design windows in the form of bay windows or to purchase a house type with bay window designs.

Since marble, etc., has a special texture and color which are preferred by users, and is hard in texture, it is not marked by friction in daily life or wetted by rainwater, and thus it is widely used as a finishing material for windowsills.

However, in the prior art, during the installation of the stone materials such as marble, a large area of hollowing and the like often occur, and the reasons for this are as follows: 1. because the table top of the bay windowsill is wide and long, and is very heavy, the condition of improper construction operation is easy to occur. 2. The laying process has problems, for example, the cement mortar cushion layer and the stone material of the floating windowsill are laid simultaneously, namely the cement mortar cushion layer is laid while the stone material is laid on the upper surface of the cement mortar cushion layer, and the cement mortar cushion layer is uneven due to collision, pressing, pushing and pulling and the like in the process of placing the stone material in place, so that the laid stone material of the floating windowsill is empty and bloated due to insufficient mortar. 3. Because the thickness of the bonding layer mortar embedded on the back of the stone material in batches is thin, the initial viscosity is low, and in the process of embedding in batches, because the back of the stone material faces downwards, the stone material is easy to fall off due to shaking, collision, pressing and other reasons in the construction process, so that the windowsill stone material is empty and bulged due to lack of the bonding layer mortar. 4. Because the floating windowsill is usually positioned at the position of an area with long sunlight irradiation, high temperature and good ventilation effect, in the laying process of the bonding layer mortar, the local area is very easy to be adhered and bonded with the stone of the floating windowsill, namely, the bonding layer mortar is cured, so that the stone of the windowsill cannot be well floated, and the stone of the floating windowsill is hollow.

Therefore, how to provide an installation structure capable of reducing the probability of hollowing of the stone of the bay sill is an urgent technical problem to be solved by the utility model.

SUMMERY OF THE UTILITY MODEL

In view of the above disadvantages, the present invention provides a mounting structure for bay window stone, which can reduce the probability of hollowing of the stone on the bay window.

In order to solve the above technical problems, the present invention provides an installation structure of bay window stone, comprising: a sill base layer; an interfacial agent layer laid on the windowsill base layer; a cement mortar leveling layer laid on the interface agent layer; the first bonding layer is flatly laid on the cement mortar leveling layer; the stone is laid on the first bonding layer;

the first bonding layer is used for being laid on the cement mortar leveling layer after the cement mortar leveling layer is leveled and cured.

Further preferably, the first adhesive layer includes: the lower bonding layer is laid on the cement mortar leveling layer; an upper bonding layer coated on the back of the stone; after the upper bonding layer is uniformly coated on the back surface of the stone, the stone is laid on the lower bonding layer, so that the upper bonding layer and the lower bonding layer are fused to form a first bonding layer for bonding and buffering.

Further preferably, a second bonding layer coated on the back of the stone; and the upper bonding layer is coated on the second bonding layer after the second bonding layer is coated on the back surface of the stone.

Further preferably, the first bonding layer is composed of a cement-based polymer; the second bonding layer is a bonding layer formed by polymer emulsion.

Preferably, the lower bonding layer is embedded in the upper surface of the cement mortar leveling layer in a batch manner, a structure layer with stripes is formed, and then the stone is laid, wherein the upper bonding layer is coated on the back surface of the stone in an embedded manner, and a structure in a stripe shape is formed, and then the upper bonding layer is laid on the lower bonding layer.

Further preferably, the striped structure and the striped structure have the same shape and are both provided with a groove body; the groove body on the upper bonding layer can be embedded with the groove body on the lower bonding layer; all the groove bodies are parallel to each other; the opening direction of each groove body is parallel to the length direction of the windowsill base layer.

Further preferably, the thickness of the first bonding layer is 3-7 mm.

Further preferably, the interface agent layer is an adhesive layer formed by an interface agent coated on the windowsill base layer and is used for gluing the windowsill base layer and the cement mortar leveling layer.

Further preferably, the length of the sill base layer is greater than 1400 mm; the width of the windowsill base layer is between 400 and 800 mm.

Further preferably, the stone is a base layer made of marble.

Compared with the prior art, the utility model provides a mounting structure of window stone material wafts can reduce the probability that hollowing appears in the stone material of windowsill that wafts.

Drawings

Other features, objects and advantages of the present application will become more apparent upon reading of the following detailed description of non-limiting embodiments thereof, made with reference to the accompanying drawings in which:

FIG. 1: the structure schematic diagram of the mounting structure of the bay window stone in the first embodiment of the utility model;

FIG. 2: the first adhesive layer and the second adhesive layer in the first embodiment of the utility model have a schematic structural section when being bonded;

description of reference numerals:

an interfacial agent layer 1; cement mortar leveling layer 2; a first adhesive layer 3; a second adhesive layer 4; stone 5; a windowsill base layer 8; an outer window lower frame 6; and an outer window 7.

Detailed Description

The conception, the specific structure and the technical effects of the present invention will be further described with reference to the accompanying drawings to fully understand the objects, the features and the effects of the present invention.

Example one

This embodiment one provides a mounting structure of window stone material that wafts, as shown in fig. 1, this mounting structure mainly comprises windowsill basic unit 8, lay interface agent layer 1 on windowsill basic unit 8, lay the cement mortar screed-coat 2 on interface agent layer 1, the tiling sets up first tie coat 3 on cement mortar screed-coat 2, lay stone material 5 on first tie coat 3 etc..

The first bonding layer is used for being laid on the cement mortar leveling layer 2 after the cement mortar leveling layer 2 is leveled and cured.

The above results show that: the mounting structure of window stone material that wafts in this embodiment is earlier through after coating one deck interfacial agent layer 1 on windowsill base course 8, evenly lay cement mortar screed-coat 2, and after cement mortar screed-coat 2 leveled solidification, lay first tie coat 3 and lay stone material 5 in proper order again, consequently make cement mortar screed-coat 2 can attach to windowsill base course 8 betterly, and the upper surface accessible first tie coat 3 of cement mortar screed-coat 2 levels stone material 5, solidify into solid structural layer promptly after, lay windowsill stone material 5 again, so cement mortar screed-coat 2 can not change the shape because of receiving the collision in the in-process of laying stone material 5, press, push-and-pull, so can effectively reduce the empty drum rate of the stone material 5 of windowsill that wafts.

In detail, the mounting structure of bay window stone further includes: the first adhesive layer 3 includes: the lower bonding layer 31 is laid on the cement mortar leveling layer 2; an upper bonding layer 32 coated on the back surface of the stone 5; after the upper bonding layer 32 is uniformly coated on the back surface of the stone 5, the stone is laid on the lower bonding layer 31, so that the upper bonding layer 32 and the lower bonding layer 31 are fused to form the first bonding layer 3 for bonding and buffering. First bonding layer 3 is coated on cement mortar leveling layer 2 in advance to form lower bonding layer 31, and then after one layer of first bonding layer 3 is coated on the back of stone 5 to form upper bonding layer 32, the first bonding layer is laid on lower bonding layer 31 to make upper bonding layer 32 and lower bonding layer 31 fuse to form first bonding layer 3 for bonding and buffering, so that stone 5 can not be shaken, collided or pressed to fall in the processes of overturning, carrying, taking in place and the like, so that first bonding layer 3 for bonding stone 5 is very full, and the hollowing condition is not easy to occur due to the lack of bonding layers locally.

Preferably, the first bonding layer 3 is a special cement-based polymer tile adhesive, which has super strong bonding force, water resistance, heat resistance, aging resistance, very good initial adhesion and water retention, and certain toughness, and will not dry out before final setting due to slightly high environmental temperature and good ventilation, so that the bonding performance of the first bonding layer 3 to the windowsill base layer 8 is very stable and reliable, and the hollowing rate of the stone 5 can be reduced.

Further preferably, the mounting structure of the bay window stone further includes: a second bonding layer 4 coated on the back of the stone 5; the upper bonding layer 32 is coated on the second bonding layer 4 after the second bonding layer 4 is coated on the back surface of the stone 5. The second bonding layer 4 is coated on the back surface of the windowsill stone 5 and can permeate into the stone surface layer, so that the adhesive force of the stone back surface to the bonding layer 3 is improved, namely the bonding layer 3 coated on the back surface of the windowsill stone 5 can be more firmly attached, and the windowsill stone cannot fall off due to shaking, collision and the like in the carrying, overturning and positioning processes, so that the hollowing rate of the windowsill stone 5 can be further reduced, and the laying quality of the windowsill stone is improved.

As shown in fig. 2, the lower bonding layer 31 is embedded on the upper surface of the cement mortar leveling layer 2, and the stone 5 is laid after the striped structure is formed. For example, in the construction, the lower adhesive layer 31 prepared in a paste form is applied to the upper surface of the leveling layer 2 of cement mortar by a scraper with teeth, and a very uniform thin adhesive layer with a striped structure is formed by the scraper.

Because form behind the stripe structural layer on the tie coat 31 down, make stone material 5 directly lay on first tie coat 3, can extrude the stripe structure, thereby make first tie coat 3 can fill up the gap between stone material 5 and the cement mortar screed-coat 2, it is more full, and then make stone material 5 in the in-process of upset taking one's place, can not lead to this bonding coat to appear very big unevenness because of reasons such as collision, press, push-and-pull, so make stone material 5 lay the back difficult phenomenon because of bonding coat packs inhomogeneous and hollows.

Further preferably, as shown in fig. 2, the upper bonding layer 32 is also coated on the back surface of the stone 5 in a batch embedding manner, and is laid on the first bonding layer 3 after forming a stripe-shaped structure, so that the upper bonding layer 32 and the lower bonding layer 31 are tightly pressed, air is exhausted, and bonding is more sufficient. For example, during construction, the upper bonding layer 32 prepared into paste is embedded on the back of the stone 5 in batches by using a scraper with teeth, after the stone 5 is dried, a very uniform thin bonding layer with a strip-shaped structure is formed by the scraper, the first bonding layer 3 can fill the gap between the stone 5 and the cement mortar leveling layer 2 and is full, and the bonding layer cannot generate very large uneven surfaces due to collision, pressing, pushing and pulling and the like in the process of overturning the stone 5 in place

Further preferably, as shown in fig. 2, the stripe structure and the stripe structure have the same shape and are provided with groove bodies, wherein the groove bodies on the upper bonding layer 32 can be embedded with the groove bodies on the lower bonding layer 31, so that the upper bonding layer 32 and the lower bonding layer 31 can be better integrated into the integrated first bonding layer 3 by means of the embedding between the two groove bodies, and air can be quickly removed by means of the groove bodies, thereby avoiding the occurrence of the hollowing phenomenon.

In addition, it is worth mentioning that in order to meet the construction and assembly requirements in practical application, the respective tank bodies are parallel to each other as an optimal mode. The opening direction of each groove body is parallel to the length direction of the windowsill base layer 8. Obviously, the opening direction of each groove body in this embodiment may also be perpendicular to the length direction of the windowsill base layer 8 or in an included angle direction, and this is not specifically defined and described in this embodiment.

Further preferably, the thickness of the first adhesive layer 3 is 3 to 7 mm. Can guarantee through this thickness that stone material 5 is firm to be connected with cement mortar screed-coat 2, save the cost.

Further preferably, the interface agent layer is a bonding layer formed by the interface agent coated on the windowsill base layer 8 and is used for bonding the windowsill base layer 8 and the cement mortar leveling layer 2, the interface agent is formed by high polymer emulsion with very good permeability and the like, and the upper surface of the windowsill base layer 8 is coated with the interface agent to permeate into the surface mortar of the windowsill base layer 8 and the cement mortar leveling layer 2, so that the surface mortar strength of the windowsill base layer is improved, the adhesive force of the cement mortar leveling layer 2 is increased, and the cement mortar leveling layer 2 is prevented from hollowing.

In addition, the second bonding layer 4 is a bonding layer formed by polymer emulsion, for example, the tile back glue 4 is coated on the back surface of the stone 5, and can permeate into the surface layer of the stone, so that the adhesion force of the back surface of the stone to the first bonding layer 3 is improved, that is, the first bonding layer 3 embedded on the back surface of the stone 5 can be more firmly adhered, and the stone 5 cannot fall off due to the reasons of shaking, collision and the like in the processes of carrying, overturning and positioning, so that the hollowing rate of the stone 5 can be further reduced, and the laying quality of the stone is improved.

In addition, it should be noted that in this embodiment, the upper surface of the stone 5 is 5-10 mm lower than the upper edge of the lower frame 6 of the external window, and the windowsill base layer 8 in this embodiment is preferably a floating windowsill stone table with a length of more than 1400mm and a width of 400-800 mm.

A bay window stone installation structure as claimed in claim 2, wherein the stone 5 is a base layer made of marble. Obviously, the stone material 5 in this embodiment may also be other types of stone materials, such as granite, etc.

The above embodiments are merely to illustrate the technical solution of the present invention, not to limit the same, and the present invention has been described in detail with reference to the preferred embodiments. It will be understood by those skilled in the art that various modifications and equivalent arrangements may be made without departing from the spirit and scope of the present invention and it is intended to cover the appended claims.

Claims (10)

1. A mounting structure of bay window stone, comprising: windowsill base layer (8), characterized by, still include: an interfacial agent layer (1) laid on the windowsill base layer (8); a cement mortar leveling layer (2) laid on the interface agent layer (1); the first bonding layer (3) is flatly laid on the cement mortar leveling layer (2); a stone (5) laid on the first bonding layer (3);

the first bonding layer is used for being laid on the cement mortar leveling layer (2) after the cement mortar leveling layer (2) is leveled and cured.

2. A bay window stone mounting structure as claimed in claim 1, wherein said first adhesive layer (3) comprises: a lower bonding layer (31) laid on the cement mortar leveling layer (2); an upper bonding layer (32) coated on the back surface of the stone (5); after the upper bonding layer (32) is uniformly coated on the back surface of the stone (5), the back surface of the stone is laid on the lower bonding layer (31) so that the upper bonding layer (32) and the lower bonding layer (31) are fused to form a first bonding layer (3) for bonding and buffering.

3. A bay window stone mounting structure as claimed in claim 2, further comprising: a second bonding layer (4) coated on the back of the stone (5); the upper bonding layer (32) is coated on the second bonding layer (4) after the second bonding layer (4) is coated on the back surface of the stone (5).

4. A bay window stone mounting structure as claimed in claim 2, wherein said first adhesive layer (3) is of a cement-based polymer; the second bonding layer (4) is a bonding layer formed by polymer emulsion.

5. A bay window stone installation structure as claimed in claim 2, wherein said lower bonding layer (31) is embedded on the upper surface of said cement mortar leveling layer (2) in batch, and said stone (5) is laid after a thin film layer with stripe structure is formed; the upper bonding layer (32) is coated on the back surface of the stone (5) in a batch embedding mode, forms a stripe-shaped structure and is then laid on the lower bonding layer (31).

6. A bay window stone installation structure as claimed in claim 1, wherein the striped structure and the striped structure are the same shape and are provided with grooves; the groove body on the upper bonding layer (32) can be embedded with the groove body on the lower bonding layer (31); all the groove bodies are parallel to each other; the opening direction of each groove body is parallel to the length direction of the windowsill base layer (8).

7. A bay window stone mounting structure as claimed in claim 1, wherein the thickness of said first adhesive layer (3) is 3-7 mm.

8. A bay window stone installation structure as claimed in claim 4, wherein said interfacial agent layer is an adhesive layer consisting of an interfacial agent coated on said sill base (8) for bonding said sill base (8) and said cement mortar screed (2).

9. A bay window stone installation structure as claimed in claim 1, wherein the length of the sill base layer (8) is greater than 1400 mm; the width of the windowsill base layer (8) is between 400 and 800 mm.

10. A bay window stone installation structure as claimed in claim 2, characterised in that said stone (5) is a base layer of marble.

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