CN216476011U - Artificial stone structure - Google Patents

Abstract

The utility model relates to the technical field of building boards, in particular to a novel simulation stone structure capable of realizing the functions of water resistance, crack resistance, stain resistance and the like, and particularly relates to a simulation stone structure which comprises an inorganic powder layer, an interface coating, a stone fluid material layer and a surface protection coating which are sequentially arranged from inside to outside; the inorganic powder layer, the interface coating, the stone fluid material layer and the surface protection coating are all pressed and molded in a fixed bonding mode; the thickness of the inorganic powder layer is 3-5 mm; forming a plurality of decorative texture areas with chromatic aberration on the surface of the stone fluid material layer; the inorganic powder layer is a light flexible base plate formed by heating and crosslinking. The visual similarity of the whole appearance of the simulated stone and the real stone is high, and the decorative effect is strong; meanwhile, the surface protection coating is arranged, so that the effects of water resistance, crack resistance, water resistance, alkali resistance, weather resistance, scrubbing resistance, dirt resistance and the like can be achieved.

Description

Artificial stone structure

Technical Field

The utility model relates to the technical field of building boards, in particular to a novel simulated stone structure capable of realizing the functions of water resistance, crack resistance, pollution resistance and the like, and particularly relates to a simulated stone structure.

Background

A stone dry hanging method belongs to a common construction method in the building engineering industry, also called a hollow hanging method, and is a construction process in wall decoration.

Because the real stone has the structural characteristics of unique texture and strong decoration and the processing technology thereof, the thickness of the stone is limited, the whole stone has larger volume and heavier weight, the condition that the stone falls off easily occurs when the stone is subjected to external larger wind load after being hung, and the heavier stone falls off and has larger potential safety hazard.

For this reason, this application has designed a section and has been convenient for hang the construction futilely and can reduce the novel emulation stone material structure of the risk of falling again simultaneously through research and development and design after this.

SUMMERY OF THE UTILITY MODEL

In order to solve one of the technical problems, the utility model adopts the technical scheme that: a simulated stone structure comprises an inorganic powder layer, an interface coating, a stone fluid material layer and a surface protection coating which are sequentially arranged from inside to outside; the inorganic powder layer, the interface coating, the stone fluid material layer and the surface protection coating are all pressed and molded in a fixed bonding mode; the thickness of the inorganic powder layer is 3-5 mm; forming a plurality of decorative texture areas with chromatic aberration on the surface of the stone fluid material layer; the inorganic powder layer is a light flexible base plate formed by heating and crosslinking.

The utility model also provides a simulated stone structure, which comprises an inorganic powder layer, an interface coating, a stone fluid material layer and a surface protection coating, wherein the inorganic powder layer, the interface coating, the stone fluid material layer and the surface protection coating are sequentially arranged from inside to outside; the inorganic powder layer is a light flexible base plate formed by heating and crosslinking.

In any of the above aspects, preferably, the thickness of the inorganic powder layer is 3 to 5 mm;

the thickness of the interface coating is 0.2-0.5 mm;

the thickness of the stone fluid material layer is 1-2 mm;

the thickness of the surface protection coating is 0.2-0.5 mm.

In any of the above schemes, preferably, a framework layer is further fixedly bonded to the bottom of the inorganic powder layer, and the framework layer is of a mesh fabric structure.

In any of the above embodiments, preferably, the stone fluid layer is made of a liquid stone fluid material.

In any of the above aspects, the inorganic powder layer is preferably a mixed powder layer or a mixed particle layer formed by pressing inorganic powder.

In any of the above embodiments, preferably, the inorganic powder in the inorganic powder layer is made of mixed inorganic powder with a homogeneous structure.

In any of the above embodiments, the interfacial coating is preferably roll coated on the surface of the base sheet and made compatible to ensure the compatibility of the upper and lower layers.

The utility model also provides an artificial stone component which comprises a plurality of artificial stone structures, wherein two adjacent artificial stone structures are connected through a strength connecting piece, the strength connecting piece comprises a bottom steel plate, the bottoms of the two sides are inserted and fixed with the artificial stone structures on the corresponding outer sides through a plurality of connecting short columns, the outer surface of the bottom steel plate is abutted and fixedly connected with the inner surface of the artificial stone structures, and seam beautifying gaskets are integrally formed on the bottom steel plate at the connecting seams of the two adjacent artificial stone structures.

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

1. the visual similarity of the whole appearance of the simulated stone and the real stone is high, and the decorative effect is strong; meanwhile, the surface protection coating is arranged, so that the effects of water resistance, crack resistance, water resistance, alkali resistance, weather resistance, scrubbing resistance, dirt resistance and the like can be achieved.

2. This emulation stone material's whole thickness is thinner, light in weight, the installation construction of being convenient for, in addition, installation back stable in structure can reduce the risk that the stone material drops, and the safety in utilization is high.

3. The structure adopts the roller coating interface coating, the surface protection coating and other matching basic plates, can effectively improve the upper and lower compatibility of the whole plate to ensure the compatibility and the melting firmness of the upper and lower layer materials, and has stronger integral firmness.

4. The whole base layer is made of light flexible base plates, so that the flexibility of the whole plate can be effectively improved, and the whole plate is lighter.

Drawings

In order to more clearly illustrate the detailed description of the utility model or the technical solutions in the prior art, the drawings that are needed in the detailed description of the utility model or the prior art will be briefly described below. Throughout the drawings, like elements or components are generally identified by like reference numerals. In the drawings, elements or components are not necessarily drawn to scale.

Fig. 1 is a schematic sectional structure of the present invention.

Fig. 2 is a schematic view of the mounting structure of the present invention.

Fig. 3 is a schematic structural diagram of the present invention in an exploded state.

In the figure, 1, an inorganic powder layer; 2. an interface coating; 3. a layer of stone fluid material; 4. a surface protective coating; 5. a framework layer; 6. a strength connector; 601. a bottom steel plate; 602. a short connecting column; 603. a seam beautifying gasket; A. simulating a stone structure.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings. The following examples are only for illustrating the technical solutions of the present invention more clearly, and therefore are only examples, and the protection scope of the present invention is not limited thereby. As shown in fig. 1-3:

example 1:

a simulated stone structure comprises an inorganic powder layer 1, an interface coating 2, a stone fluid material layer 3 and a surface protection coating 4 which are arranged in sequence from inside to outside; the inorganic powder layer 1, the interface coating 2, the stone fluid material layer 3 and the surface protection coating 4 are all pressed and molded in a fixed bonding mode; the thickness of the inorganic powder layer 1 is 3-5 mm; a plurality of decorative texture areas with color difference are formed on the surface of the stone fluid material layer 3; the inorganic powder layer 1 is a light flexible base plate formed by heating and crosslinking.

This structure wholly adopts the multilayer lamella to constitute, and overall structure stability, compatible fixity are stronger, and simultaneously the base plate thickness is thinner, effectively alleviates the weight of whole panel, the installation and construction of being convenient for, and 3 surfaces on the stone fluid bed of material form a plurality of have the decorative texture region of colour difference can play the effect of the real stone material surface line of emulation better simultaneously, guarantee the decorative effect of this emulation stone material effectively.

Example 2:

the utility model also provides a simulated stone structure, which comprises an inorganic powder layer 1, an interface coating 2, a stone fluid material layer 3 and a surface protection coating 4 which are sequentially arranged from inside to outside, wherein the interface coating 2 is fixedly adhered to the surface of the inorganic powder layer 1 after being rolled and brushed, the stone fluid material layer 3 is sprayed on the interface coating 2 on the surface of the inorganic powder layer 1 in a high-temperature liquid stone fluid material mode to realize fixation, and a plurality of decorative texture areas with chromatic aberration are formed on the surface of the stone fluid material layer 3; the inorganic powder layer 1 is a light flexible base plate formed by heating and crosslinking.

This structure wholly adopts the multilayer lamella to constitute, and overall structure stability, compatible fixity are stronger, and the thickness of whole panel is thinner simultaneously, effectively alleviates the weight of whole panel, and the installation and construction of being convenient for forms a plurality of and has the effect of the real stone material surface line of emulation can be played better in the decoration texture region of colour difference on 3 surfaces of the stone fluid bed of material simultaneously, guarantees the decorative effect of this emulation stone material effectively.

In any of the above solutions, it is preferable that the thickness of the inorganic powder layer 1 is 3 to 5 mm;

the thickness of the interface coating 2 is 0.2-0.5 mm;

the thickness of the stone fluid material layer 3 is 1-2 mm;

the thickness of the surface protective coating 4 is 0.2-0.5 mm.

The thickness of selecting for use here each layer has reduced the thickness between each floor effectively under the prerequisite that guarantees to satisfy service conditions, has reduced the whole thickness of whole panel effectively, has reduced the whole weight of whole panel simultaneously effectively, and the bonding installation construction of being convenient for more guarantees effectively that the installation hangs the stability after, reduces the risk that the panel high altitude drops.

In any of the above schemes, preferably, a framework layer 5 is further fixedly bonded to the bottom of the inorganic powder layer 1, and the framework layer 5 is of a mesh fabric structure.

The grid cloth is used as the main framework layer 5, so that the whole plate structure can be effectively reinforced, and the overall firmness is effectively enhanced.

In any of the above solutions, it is preferable that the stone fluid material layer 3 is made of a liquid stone fluid material.

The high-temperature liquid stone fluid material is sprayed on the inorganic plate with the coating at high pressure, and the firmness of connection can be better ensured by high-temperature fixation.

In any of the above embodiments, the inorganic powder layer 1 is preferably a mixed powder layer or a mixed particle layer formed by pressing inorganic powder.

The inorganic powder is prepared from inorganic materials such as soil, stone powder, slag, tailing powder, ceramic slag powder, fly ash and the like through pretreatment, drying, grinding, uniformly stirring according to a proportion, and modifying by using a surfactant to prepare powder or particles.

In any of the above embodiments, the inorganic powder in the inorganic powder layer 1 is preferably made of mixed inorganic powder with a homogeneous structure.

Inorganic powder is used as raw material, and the deep-processed high molecular polymer is made into a flexible and light base plate through die forming, cross-linking and heating compounding, and the thickness of the base plate is preferably 3-5 mm.

In any of the above embodiments, it is preferable that the interface coating 2 is roll-coated on the surface of the base plate and has a compatibility to ensure the compatibility between the upper and lower layer materials.

The interface material is coated on the base plate in a rolling way, so that the base plate has the upper and lower compatibility, and the firmness of the upper and lower materials is ensured.

The surface protective coating 4 is coated with a polishing agent on the shaped decorative plate to achieve the effects of water resistance, crack resistance, water resistance, alkali resistance, weather resistance, scrubbing resistance, dirt resistance and the like.

Example 3:

the utility model also provides a simulated stone component which comprises a plurality of simulated stone structures, wherein two adjacent simulated stone structures are connected through a strength connecting piece 6, the strength connecting piece 6 comprises a bottom steel plate 601, the bottoms of the two sides are inserted and fixed with the simulated stone structures A on the corresponding outer sides through a plurality of connecting short columns 602, the outer surface of the bottom steel plate 601 is fixedly connected with the inner surface of the simulated stone structures A in a propping manner, and a beauty-joint gasket 603 is integrally formed on the bottom steel plate 601 at the connecting joint of the two adjacent simulated stone structures A.

The strength connecting piece 6 can effectively fix each simulation stone structure, meanwhile, the whole strength connecting piece 6 is fixed on the building main body through the bottom steel plate 601 to realize stable fixation, the corresponding simulation stone structure is fixed in an auxiliary mode through each connecting short column 602, the whole simulation stone structure is fixed by means of bonding, and the gap part can be filled into the seam between the adjacent simulation stone structures through the seam beautifying gasket 603.

The above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the utility model has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; the modifications or the substitutions do not cause the essence of the corresponding technical solutions to depart from the scope of the technical solutions of the embodiments of the present invention, and the technical solutions are all covered in the scope of the claims and the specification of the present invention; it will be apparent to those skilled in the art that any alternative modifications or variations to the embodiments of the present invention may be made within the scope of the present invention.

The present invention is not described in detail, but is known to those skilled in the art.

Claims (9)

1. The utility model provides a simulation stone material structure which characterized in that: comprises an inorganic powder layer, an interface coating, a stone fluid material layer and a surface protection coating which are arranged in sequence from inside to outside; the inorganic powder layer, the interface coating, the stone fluid material layer and the surface protection coating are all pressed and molded in a fixed bonding mode; the thickness of the inorganic powder layer is 3-5 mm; forming a plurality of decorative texture areas with chromatic aberration on the surface of the stone fluid material layer; the inorganic powder layer is a light flexible base plate formed by heating and crosslinking.

2. The utility model provides a simulation stone material structure which characterized in that: the coating comprises an inorganic powder layer, an interface coating, a stone fluid material layer and a surface protection coating which are sequentially arranged from inside to outside, wherein the interface coating is fixedly adhered to the surface of the inorganic powder layer after being brushed by a roller, the stone fluid material layer is sprayed on the interface coating on the surface of the inorganic powder layer in a high-pressure manner in a high-temperature liquid stone fluid material mode to realize fixation, and a plurality of decorative texture areas with chromatic aberration are formed on the surface of the stone fluid material layer; the inorganic powder layer is a light flexible base plate formed by heating and crosslinking.

3. The structure of simulated stone of claim 1 or 2, wherein:

the thickness of the inorganic powder layer is 3-5 mm;

the thickness of the interface coating is 0.2-0.5 mm;

the thickness of the stone fluid material layer is 1-2 mm;

the thickness of the surface protection coating is 0.2-0.5 mm.

4. The structure of simulated stone of claim 1 or 2, wherein: and a framework layer is fixedly bonded at the bottom of the inorganic powder layer, and the framework layer adopts a grid cloth structure.

5. The simulated stone structure of claim 4, wherein: the stone fluid material layer is made of liquid stone fluid materials.

6. The simulated stone structure of claim 4 or 5, wherein: the inorganic powder layer is a mixed powder layer or a mixed particle layer formed by pressing inorganic powder.

7. The simulated stone structure of claim 5 or 6, wherein: the inorganic powder in the inorganic powder layer is prepared from mixed inorganic powder with a homogeneous structure.

8. The simulated stone structure of claim 7, wherein: the interfacial coating is roll coated on the surface of the base plate and has up-down compatibility to ensure the compatibility and the melting firmness of the upper and lower layer materials.

9. An emulation stone material subassembly which characterized in that: the stone simulation structure comprises a plurality of simulation stone structures as claimed in any one of claims 1 to 8, two adjacent simulation stone structures are connected through a strength connecting piece, the strength connecting piece comprises a bottom steel plate, the bottoms of the two sides are fixedly inserted into the simulation stone structures on the corresponding outer sides through a plurality of connecting short columns, the outer surface of the bottom steel plate is fixedly connected with the inner surface of the simulation stone structures in a propping manner, and a seam beautifying gasket is integrally formed on the bottom steel plate at the connecting seam of the two adjacent simulation stone structures.

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