CN210530190U - Inorganic vitrified micro bubble external wall insulation structure - Google Patents

Abstract

The utility model belongs to the field of building materials, in particular to an inorganic vitrified microsphere external wall heat insulation structure, which is provided with a base layer wall body, an anti-crack mortar layer, an alkali-resistant glass fiber mesh cloth, an anchoring part, an anti-crack mortar layer, a rubber powder polyphenyl particle heat insulation mortar layer, a graphene modified flexible water-resistant layer and an inorganic vitrified microsphere coating layer from inside to outside in sequence; the inorganic vitrified micro bubble coating layer has the effect of heat preservation; the graphene modified flexible waterproof layer is used for mildew resistance and water resistance; the adhesive polystyrene granule heat-preservation mortar layer is formed by coating adhesive polystyrene granule heat-preservation mortar on the surface of the anti-crack mortar layer; an anti-cracking mortar layer is arranged between the anchoring piece and the adhesive polystyrene particle heat-preservation mortar layer; the anchoring piece is used for supporting and fixing the alkali-resistant glass fiber mesh cloth; the alkali-resistant glass fiber mesh cloth is pressed into the surface of the anti-crack mortar layer, so that the adhesion and anti-crack performance of the anti-crack mortar are improved; an anti-cracking mortar layer is arranged between the base wall and the alkali-resistant glass fiber mesh cloth; the anti-crack mortar layer is formed by coating anti-crack mortar on the surface of the base wall.

Description

Inorganic vitrified micro bubble external wall insulation structure

[ technical field ] A method for producing a semiconductor device

The utility model belongs to the building material field, concretely relates to inorganic glass bead external wall insulation structure.

[ background of the invention ]

With the rapid development of economy and the acceleration of energy consumption, energy conservation and emission reduction are promoted, people pay more and more attention to energy conservation and emission reduction and pay more attention to quality of life, and the requirements on the heat preservation and waterproof performance of the outer wall are gradually increased.

But the single coating can not simultaneously satisfy the heat preservation and waterproof effects at present.

[ Utility model ] content

In view of the above, there is a need for an inorganic vitrified small ball external wall insulation structure, which is not easy to age, has good thermal insulation effect and low thermal conductivity coefficient.

In order to achieve the above purpose, the utility model adopts the technical proposal that:

an inorganic vitrified microsphere external wall insulation structure is sequentially provided with a base wall, an anti-cracking mortar layer, an alkali-resistant glass fiber mesh cloth, an anchoring part, an anti-cracking mortar layer, a glue powder polyphenyl particle insulation mortar layer, a graphene modified flexible water-resistant layer and an inorganic vitrified microsphere coating layer from inside to outside;

the inorganic vitrified micro bubble coating layer is formed by spraying inorganic vitrified micro bubble coating on the surface of the graphene modified flexible waterproof layer, and has a heat preservation effect;

the graphene modified flexible water-resistant layer is formed by spraying graphene modified flexible water-resistant paint on the surface of the glue powder polyphenyl particle heat-preservation mortar layer and is used for preventing mildew and water;

the adhesive polystyrene granule heat-preservation mortar layer is formed by coating adhesive polystyrene granule heat-preservation mortar on the surface of the anti-crack mortar layer;

an anti-cracking mortar layer is arranged between the anchoring piece and the adhesive polystyrene particle heat-preservation mortar layer;

the anchoring piece is vertically nailed into the anti-crack mortar layer adjacent to the alkali-resistant glass fiber mesh cloth from one side of the alkali-resistant glass fiber mesh cloth; the device is used for supporting and fixing the alkali-resistant glass fiber mesh cloth;

the alkali-resistant glass fiber mesh cloth is pressed into the surface of the anti-cracking mortar layer, and the cut alkali-resistant mesh cloth is pressed into the mortar of the anti-cracking layer which is just smeared by using an iron trowel, so that the bonding property and the anti-cracking property of the anti-cracking mortar are improved;

an anti-cracking mortar layer is arranged between the base wall and the alkali-resistant glass fiber mesh cloth; the anti-crack mortar layer is formed by coating anti-crack mortar on the surface of the base wall.

The inorganic vitrified microbead coating is mainly composed of the following components (in wt.%): 13 percent of expanded and vitrified micro bubbles, 5 percent of high-alumina aluminum silicate cotton, 13 percent of mullite fiber, 3 percent of penetrating agent, 12 percent of binder, 2 percent of calcium silicate powder and 52 percent of water.

The graphene-modified flexible water-resistant coating is mainly composed of the following components (in wt.%): the composite material is prepared by mixing 33% of epoxy resin, 5% of polysulfide rubber, 1% of petroleum resin, 5% of reactive diluent, 6% of organic silicon resin, 0.1% of auxiliary agent and 6% of hydrophobic graphene.

The rubber powder polyphenyl particle thermal mortar comprises the following components (in wt.%): 10 percent of rubber particles, 60 percent of cement, 4.5 percent of polyphenyl granules, 2.5 percent of rubber powder and 3.5 percent of auxiliary agent.

Furthermore, the inorganic vitrified micro bubble coating layer is 0.3-0.5 mm.

Further, the thickness of the graphene modified flexible waterproof layer is 0.2-0.3 mm.

Furthermore, the glue powder polyphenyl particle heat-preservation mortar layer is 4-6 mm.

Furthermore, the thickness of the anti-cracking mortar layer is 2-4 mm.

Compared with the prior art, the utility model discloses inorganic glass bead outer wall insulation structure has fabulous weatherability, and the coefficient of thermal conductivity is low, and thermal insulation performance is stable, freeze-thaw resistance, the ageing resistance, interlayer material elastic change index phase-match, and basic unit deformation strong adaptability effectively prevents the fissured production of wall, does not have the cavity in the system, and anti-wind pressure ability reinforce has fine waterproof function, and the fire-resistant grade accords with the building requirement.

[ description of the drawings ]

Fig. 1 is a schematic structural diagram of the inorganic vitrified micro bubble external wall insulation structure of the utility model.

Description of the main elements

Basic wall 1	Crack-resistant mortar layer 2	Alkali-resistant glass fiber gridding cloth 3
			Anchor 4	Adhesive polystyrene granule heat preservation mortar layer 5	Graphene modified flexible water-resistant layer 6
Inorganic vitrified micro bubble coating layer 7

The following detailed description of the invention will be further described in conjunction with the above-identified drawings.

[ detailed description ] embodiments

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.

Referring to fig. 1, in a preferred embodiment of the present invention, an inorganic vitrified microsphere exterior wall thermal insulation structure is sequentially provided with a base wall 1, an anti-crack mortar layer 2, an alkali-resistant fiberglass mesh 3, an anchoring member 4, an anti-crack mortar layer 2, a rubber powder polyphenyl particle thermal insulation mortar layer 5, a graphene modified flexible water-resistant layer 6, and an inorganic vitrified microsphere coating layer 7 from inside to outside;

the inorganic vitrified micro bubble coating layer 7 is formed by spraying inorganic vitrified micro bubble coating on the surface of the graphene modified flexible water-resistant layer 6, and has a heat preservation effect.

The graphene modified flexible water-resistant layer 6 is formed by spraying graphene modified flexible water-resistant paint on the surface of the glue powder polyphenyl particle heat-preservation mortar layer 5 and is used for mildew prevention and water prevention.

The glue powder polyphenyl granule heat preservation mortar layer 5 is formed by coating glue powder polyphenyl granule heat preservation mortar on the surface of the anti-crack mortar layer 2.

An anti-cracking mortar layer 2 is arranged between the anchoring piece 4 and the adhesive polystyrene particle heat-preservation mortar layer 5;

the anchoring piece 4 is vertically nailed into the anti-crack mortar layer 2 adjacent to the alkali-resistant glass fiber mesh cloth 3 from one side of the alkali-resistant glass fiber mesh cloth 3; used for supporting and fixing the alkali-resistant glass fiber mesh 3.

The alkali-resistant glass fiber mesh cloth 3 is pressed into the surface of the anti-crack mortar layer 2, and the cut alkali-resistant mesh cloth 3 is pressed into the mortar of the anti-crack layer which is just smeared by using an iron trowel, so that the adhesion and the anti-crack performance of the anti-crack mortar are improved. In the present embodiment, it is preferred that,

an anti-crack mortar layer 2 is arranged between the base wall 1 and the alkali-resistant glass fiber mesh 3; the anti-crack mortar layer 2 is formed by coating anti-crack mortar on the surface of the base wall 1.

The inorganic vitrified microbead coating is mainly composed of the following components (in wt.%): 13 percent of expanded and vitrified micro bubbles, 5 percent of high-alumina aluminum silicate cotton, 13 percent of mullite fiber, 3 percent of penetrating agent, 12 percent of binder, 2 percent of calcium silicate powder and 52 percent of water.

The graphene-modified flexible water-resistant coating is mainly composed of the following components (in wt.%): the composite material is prepared by mixing 33% of epoxy resin, 5% of polysulfide rubber, 1% of petroleum resin, 5% of reactive diluent, 6% of organic silicon resin, 0.1% of auxiliary agent and 6% of hydrophobic graphene.

The rubber powder polyphenyl particle thermal mortar comprises the following components (in wt.%): 10 percent of rubber particles, 60 percent of cement, 4.5 percent of polyphenyl granules, 2.5 percent of rubber powder and 3.5 percent of auxiliary agent.

Further, the inorganic vitrified micro bubble coating layer 7 is 0.3-0.5 mm.

Further, the thickness of the graphene modified flexible water-resistant layer 6 is 0.2-0.3 mm.

Furthermore, the glue powder polyphenyl particle heat-preservation mortar layer 5 is 4-6 mm.

Further, the thickness of the anti-crack mortar layer 2 is 2-4 mm.

TABLE 1 comparison of structural Properties of different thermal insulation coatings

As can be seen from Table 1, the inorganic vitrified microsphere external wall insulation structure has obvious advantages in the aspects of heat insulation, heat preservation, difficult aging of the structure, good stability, good heat resistance, chemical corrosion resistance and fire safety, and has excellent comprehensive performance and good durability.

Compared with the prior art, the utility model discloses inorganic glass bead outer wall insulation structure production simple process environmental protection, the raw materials is easily obtained, and the coefficient of thermal conductivity is low, and thermal insulation performance is stable, freeze-thaw resistance, the ageing resistance, interlayer material elastic change index phase-match, basic unit deformation strong adaptability prevents effectively that the cracked production of wall, no cavity in the system, and anti-wind pressure ability is strong, has fine waterproof function, and the fire-resistant rating accords with the building requirement.

The above description is for the detailed description of the preferred possible embodiments of the present invention, but the embodiments are not intended to limit the scope of the present invention, and all equivalent changes or modifications accomplished under the technical spirit suggested by the present invention should fall within the scope of the present invention.

Claims (1)

1. An inorganic vitrified microsphere external wall insulation structure is characterized in that a base layer wall body, an anti-cracking mortar layer, an alkali-resistant glass fiber mesh cloth, an anchoring piece, an anti-cracking mortar layer, a glue powder polyphenyl particle insulation mortar layer, a graphene modified flexible water-resistant layer and an inorganic vitrified microsphere coating layer are sequentially arranged from inside to outside;

the inorganic vitrified micro bubble coating layer is formed by spraying inorganic vitrified micro bubble coating on the surface of the graphene modified flexible waterproof layer, and has a heat preservation effect;

the graphene modified flexible water-resistant layer is formed by spraying graphene modified flexible water-resistant paint on the surface of the glue powder polyphenyl particle heat-preservation mortar layer and is used for preventing mildew and water;

the adhesive polystyrene granule heat-preservation mortar layer is formed by coating adhesive polystyrene granule heat-preservation mortar on the surface of the anti-crack mortar layer;

an anti-cracking mortar layer is arranged between the anchoring piece and the adhesive polystyrene particle heat-preservation mortar layer;

the anchoring piece is vertically nailed into the anti-crack mortar layer adjacent to the alkali-resistant glass fiber mesh cloth from one side of the alkali-resistant glass fiber mesh cloth; the device is used for supporting and fixing the alkali-resistant glass fiber mesh cloth;

the alkali-resistant glass fiber mesh cloth is pressed into the surface of the anti-cracking mortar layer, and the cut alkali-resistant mesh cloth is pressed into the mortar of the anti-cracking layer which is just smeared by using an iron trowel, so that the bonding property and the anti-cracking property of the anti-cracking mortar are improved;

an anti-cracking mortar layer is arranged between the base wall and the alkali-resistant glass fiber mesh cloth; the anti-crack mortar layer is formed by coating anti-crack mortar on the surface of the base wall; the inorganic vitrified micro bubble coating layer is 0.3-0.5 mm; the thickness of the graphene modified flexible waterproof layer is 0.2-0.3 mm; the adhesive powder polyphenyl particle heat-insulation mortar layer is 4-6 mm; the thickness of the anti-cracking mortar layer is 2-4 mm.

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