CN215254083U - Energy-saving diatom ooze wall cloth - Google Patents

Abstract

The utility model provides an energy-conserving diatom mud wall cloth, energy-conserving diatom mud wall cloth is formed by bottom, anti-crack layer, phase transition energy storage layer and inoxidizing coating from interior extremely compound in proper order to compound through modes such as spraying, knife coating, knurling, thereby avoid using organic glue to paste and bring harmful substance, and make the utility model provides an energy-conserving diatom mud wall cloth has multilayer structure's wall cloth, and this wall cloth is difficult to damage under the protection of protective layer to and reduce the efficiency through phase transition energy storage layer heat absorption skill, make the utility model provides a wall cloth has the ability of preventing the heat to scatter and disappear to reach energy-conserving efficiency.

Description

Energy-saving diatom ooze wall cloth

Technical Field

The utility model relates to an interior decoration field specifically is an energy-conserving diatom mud wall paper.

Background

Along with the improvement of living standard, people also attach more and more importance to the interior decoration of house that oneself lives in, can generally adopt various wall cloths to paste indoor wall and ceiling, generally divide into two kinds on the market, one kind is single layer construction wall cloth, and another kind is multilayer structure wall cloth.

However, most of the wall cloths on the market are of a single-layer structure, only can play a role in beautifying and are easy to damage, most of the wall cloths on the market of the multi-layer structure are adhered by a large amount of liquid glue, and the liquid glue can generate harmful substances such as toluene or formaldehyde, so that the health of people can be harmed.

SUMMERY OF THE UTILITY MODEL

In view of this, the embodiment of the utility model provides an energy-conserving diatom mud wall cloth to solve the individual layer diatom mud wall cloth fragile among the prior art, and multilayer diatom mud wall cloth produces the harmful substance that harms the health of people.

In order to achieve the above object, the embodiment of the present invention provides the following technical solutions:

the energy-saving diatom ooze wall cloth is formed by sequentially compounding a bottom layer, an anti-cracking layer, a phase change energy storage layer and a protective layer from inside to outside.

Preferably, the bottom layer is a nonwoven material base layer.

Preferably, the non-woven material base layer is made of natural wood fibers or diatom ooze effective essence extracts.

Preferably, the non-woven material base layer is made of an effective diatom ooze essence extract, and the effective diatom ooze essence extract is silicon dioxide.

Preferably, the anti-cracking layer is formed by compounding a propylene fiber layer, a multi-component sand layer, a film forming layer and a filler layer.

Preferably, the propylene fiber layer is compounded on the outer surface of the bottom layer by a spraying or blade coating construction mode after being stirred by adding water, the multi-component sand layer is compounded on the outer surface of the propylene fiber layer by a spraying or blade coating construction mode after being stirred by adding water, the film forming layer is compounded on the outer surface of the multi-component sand layer by a spraying or blade coating construction mode after being stirred by adding water, and the packing layer is compounded on the outer surface of the film forming layer by a spraying or blade coating construction mode after being stirred by adding water.

Preferably, the phase change energy storage layer is formed by compounding a molding layer and an adsorption layer.

Preferably, the molding layer is a natural resin extract layer, and the adsorption layer is a phase-change paraffin microcapsule particle layer.

Preferably, the natural resin extract layer is compounded on the outer surface of the anti-cracking layer in a spraying or blade coating and embossing mode after being stirred by adding water, and the phase-change paraffin microcapsule particle layer is compounded on the outer surface of the natural resin extract layer in a spraying or blade coating and embossing mode after being stirred by adding water.

Preferably, the protective layer is formed by compounding a diatomite layer and a ceramic clay layer.

Preferably, the diatomite layer is sprayed or roll-coated on the outer surface of the phase change energy storage layer after being stirred by adding water, and the ceramic clay layer is sprayed or roll-coated on the outer surface of the diatomite layer after being stirred by adding water.

The utility model discloses an energy-conserving diatom ooze wall cloth, energy-conserving diatom ooze wall cloth is formed by bottom, anti-crack layer, phase transition energy storage layer and inoxidizing coating from interior to outer complex in proper order to mode such as through spraying, knife coating, knurling is compound, thereby avoids using organic glue to paste and brings harmful substance, and makes the utility model provides an energy-conserving diatom ooze wall cloth has multilayer structure's wall cloth, and this wall cloth is difficult to damage under the protection of protective layer to and reduce the efficiency through phase transition energy storage layer heat absorption skill, make the utility model provides a wall cloth has the ability that prevents the heat and scatter and disappear, thereby reachs energy-conserving efficiency.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

Fig. 1 is a schematic structural view of an energy-saving diatom ooze wall cloth provided by an embodiment of the utility model.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The embodiment of the utility model provides an energy-conserving diatom mud wall paper, see figure 1, for the schematic structure of energy-conserving diatom mud wall paper, diatom mud wall paper is formed by bottom, anti-crack layer, phase transition energy storage layer and inoxidizing coating from interior to outer compound in proper order.

The bottom layer 1 is coated with pure water type polyester emulsion and then is pasted, the pure water type polyester emulsion can be used for pasting the bottom layer 1 on a wall or a ceiling, and the substance takes water as a solvent, so that the pollution is avoided, and the safety and the reliability are realized.

It should be further noted that the anti-cracking layer 2 is mainly used for preventing the wall cloth from cracking and preventing moisture; the phase change energy storage layer 3 is a texture which can be shaped to be beautiful according to the requirements of users, has the characteristics of beauty, smoothness, uniformity and the like, has the effects of absorbing heat, saving energy and reducing consumption, and can effectively dissipate heat of resistance; the protective layer 4 is arranged on the outer surface of the phase change energy storage layer, and can protect the texture of the phase change energy storage layer from being damaged easily.

Through the above scheme, from interior to exterior compounds bottom, anti-crack layer, phase transition energy storage layer and inoxidizing coating in proper order to compound through modes such as spraying, knife coating, knurling, thereby avoid using organic glue to paste and bring harmful substance, and make the utility model provides an energy-conserving diatom mud wall cloth has multilayer structure's wall cloth, and this wall cloth is difficult to damage under the protection of protective layer to and reduce the efficiency through phase transition energy storage layer heat absorption technical ability, make the utility model provides a wall cloth has the ability that prevents the heat and scatter and disappear, thereby reachs energy-conserving efficiency.

Further, the bottom layer is a non-woven material base layer.

It should be noted that the bottom layer 1 is made of a nonwoven material base layer, which can achieve the effects of moisture protection and ventilation, and can enhance the adhesive force of the harmful substances, thereby achieving the effect of adsorbing the harmful substances.

Further, the non-woven material base layer is made of natural wood fibers or effective diatom ooze essence extracts.

It should be noted that the effective essence extract of natural wood fiber or diatom ooze is used as the non-woven material base layer, and no substances harmful to human body are generated.

Further, the non-woven material base layer is made of an effective diatom ooze essence extract, and the effective diatom ooze essence extract is silicon dioxide.

It should be noted that, the purity content of the silicon dioxide of the diatom ooze effective essence extract is generally lower than 85%, in the utility model, preferably, the purity content of the silicon dioxide of the diatom ooze effective essence extract is 85%.

Furthermore, the anti-cracking layer is formed by compounding a propylene fiber layer, a multi-component sand layer, a film forming layer and a packing layer.

The polypropylene fiber layer is compounded on the outer surface of the bottom layer in a spraying or blade coating construction mode after being stirred by adding water, the multi-component sand layer is compounded on the outer surface of the polypropylene fiber layer in a spraying or blade coating construction mode after being stirred by adding water, the film forming layer is compounded on the outer surface of the multi-component sand layer in a spraying or blade coating construction mode after being stirred by adding water, and the packing layer is compounded on the outer surface of the film forming layer in a spraying or blade coating construction mode after being stirred by adding water.

It should be noted that, when compounding propylene fiber layer, multi-level sand layer, film forming layer and packing layer, alkene fiber layer, multi-level sand layer, film forming layer and packing layer can not need to compound according to the order in the utility model discloses in, preferred propylene fiber layer is the innermost layer, and multi-level sand layer is compound at propylene fiber layer surface, and film forming layer is compound at multi-level sand layer surface, and the packing layer is compound at the compound surface of film forming layer, but is not limited to this.

Further, the phase change energy storage layer 3 is formed by compounding a molding layer and an adsorption layer.

The molding layer can be textured as required, and can be applied by spraying, knife coating, or embossing.

Specifically, the molding layer is a natural resin extract layer, and the adsorption layer is a phase-change paraffin microcapsule particle layer.

The phase-change paraffin microcapsule particle layer is subjected to high-temperature puffing treatment, so that a porous structure can be formed, a surface with large expansion area and adsorption capacity can be formed, and harmful substances in air can be adsorbed, wherein the harmful substances comprise formaldehyde, benzene and the like.

Specifically, the natural resin extract layer is compounded on the outer surface of the anti-cracking layer in a spraying or blade coating and embossing mode after being stirred by adding water, and the phase-change paraffin microcapsule particle layer is compounded on the outer surface of the natural resin extract layer in a spraying or blade coating and embossing mode after being stirred by adding water.

Further, the protective layer is formed by compounding a diatomite layer and a ceramic clay layer.

It should be noted that the ceramic clay is capable of forming a film on the outer surface of the diatomite layer, similar to the protective film of the outer layer of the tile, so that the protective layer can withstand more than 10000 wipes, even once a day, and can be used for 27 years.

Specifically, the diatomite layer is sprayed or roll-coated on the outer surface of the phase change energy storage layer 3 after being stirred by adding water, and the ceramic clay layer is sprayed or roll-coated on the outer surface of the diatomite layer after being stirred by adding water.

The ceramic clay layer is a protective film similar to the outer layer of the tile, and the protective film has high hardness, wear resistance and is not easy to damage.

Preferably, in the utility model discloses in, every layer in energy-conserving diatom ooze wall paper's anti-crack layer, phase transition energy storage layer and inoxidizing coating is in concrete construction, and every layer's compound accessible another kind of form is compound.

The anti-cracking layer 2 can be formed by mixing the propylene fiber, the multi-grade sand, the film forming material and the filler with water, and then spraying or blade-coating the mixed mixture on the outer surface of the bottom layer 1.

The phase-change energy storage layer 3 can be formed by mixing a natural resin extract and phase-change paraffin microcapsule particles with water, puffing at high temperature, and spraying, blade coating or embossing on the outer surface of the anti-cracking layer 2.

The protective layer 4 can be formed by adding ceramic clay into diatomite, adding water, stirring, and spraying or rolling on the outer surface of the phase change energy storage layer.

To facilitate understanding of the above solution, the following describes the present solution with reference to a specific embodiment, with reference to fig. 1:

an energy-saving diatom ooze wall cloth is formed by sequentially compounding a bottom layer 1, an anti-cracking layer 2, a phase change energy storage layer 3 and a protective layer 4 from inside to outside.

The protective layer 4 is formed by adding high-tech ceramic clay into original diatomite and forming a protective film similar to the outer layer of a ceramic tile after a surface protective layer is formed. The protective layer 4 can withstand 10000+ times of water wiping, namely can be wiped for 27 years even if the water wiping is carried out once a day, and is directly sprayed or roll-coated on the phase change energy storage layer 3 after being stirred by adding water.

The phase-change energy storage layer 3 is made of a German natural resin extract and phase-change paraffin microcapsule particles, and is puffed at high temperature to form an adsorption layer with multiple pores and large expansion area, so that harmful substances and formaldehyde in the air are effectively adsorbed. Meanwhile, the modeling layer has various decorative and beautiful textures. Compared with the traditional diatom ooze, the texture has beautiful, smooth and uniform decorative texture, has the effects of absorbing heat, saving energy and reducing consumption, effectively prevents heat loss, and is sprayed or blade-coated and embossed on the anti-cracking layer 2 after being stirred by adding water.

The anti-cracking layer 2 is composed of propylene fiber, multi-grade sand, a film forming material and a filler, is added with water and stirred, and is constructed on the bottom layer 1 by adopting a spraying or blade coating construction mode, so that the anti-cracking and damp-proof effects can be achieved.

The bottom layer 1 is constructed by coating pure water polyester emulsion and then pasting, the material of the bottom layer is natural wood fiber or effective extract of diatom ooze (silicon dioxide SiO2 with the purity of 85 percent), and the bottom layer is processed into a non-woven material base layer which has the functions of moisture resistance, ventilation, adhesion enhancement and the like.

The utility model discloses a key point is the multilayer structure who adopts bottom 1, anti-crack layer 2, molding layer 3 and inoxidizing coating 4, can prolong the life of wall paper.

The utility model has the advantages that the purification, adsorption and aldehyde removal functions of the diatom ooze are kept, the energy-saving function is added, and the construction is simple and convenient.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (2)

1. The energy-saving diatom ooze wall cloth is characterized by being formed by sequentially compounding a bottom layer (1), an anti-cracking layer (2), a phase-change energy storage layer (3) and a protective layer (4) from inside to outside; the anti-cracking layer (2) is sprayed or blade-coated on the bottom layer (1), the phase-change energy storage layer (3) is sprayed or blade-coated on the anti-cracking layer (2) or embossed, and the protective layer (4) is sprayed or roll-coated on the phase-change energy storage layer (3);

the phase-change energy storage layer (3) is formed by compounding a molding layer and an adsorption layer, the molding layer is a natural resin extract layer, the adsorption layer is a phase-change paraffin microcapsule particle layer, and the adsorption layer is sprayed or blade-coated or embossed on the molding layer;

the protective layer (4) is formed by compounding a diatomite layer and a ceramic clay layer, and the diatomite layer is sprayed or roll-coated on the ceramic clay layer;

the bottom layer (1) is a non-woven material base layer;

the non-woven material base layer is made of natural wood fibers or diatom ooze effective essence extracts.

2. The energy-saving diatom ooze wall cloth of claim 1, wherein the anti-cracking layer (2) is compounded by a propylene fiber layer, a multi-grade sand layer, a film forming layer and a filler layer.

Images