RU90813U1 - ENERGY-SAVING HEAT-INSULATING AND DECORATIVE PANEL - Google Patents

Abstract

1. Energy-saving heat-insulating and decorative panel made of laminated, characterized in that it includes an inner plate (3) of heat-insulating material; a frame (2) placed around the perimeter of the inner plate and glued to the sides of the inner plate using an adhesive layer (5); a shield (1) located in front of the inner plate (3) and connected to the front ends of the frame (2) and the front side of the inner plate (3) with an adhesive layer (5); a mounting surface (4) attached to the rear side of the inner plate (3) and used to attach to the wall. ! 2. The panel according to claim 1, characterized in that the mounting surface (4) is made in the form of a back plate glued to the rear ends of the frame (2) and the rear side of the inner plate (3). ! 3. The panel according to claim 1, characterized in that the mounting surface (4) is made in the form of a layer of cement mortar with reinforcing mesh deposited on the rear side of the inner plate (3) and the rear ends of the frame (2). ! 4. The panel according to claim 1, characterized in that the shield (1) is made in the form of a plate of cement with fiber filler, a plate of calcium silicate, a plate of magnesia cement or a thin plate of stone, having a thickness of 3-10 mm ! 5. The panel according to claim 1, characterized in that the shield (1) is made in the form of a plate of aluminum or sheet steel having a thickness of 0.4-1.0 mm ! 6. The panel according to claim 1, characterized in that the inner plate (3) is made of extruded polystyrene foam, polyurethane foam, foamed material based on phenolaldehyde resin, foamed polyvinyl chloride, porous ceramic material or foamed material based on cement, having a thickness of 20-300 mm ; density 25-300 kg / m3; coefficient

Description

The utility model relates to building materials, in particular to energy-saving heat-insulating and decorative panels for thermal insulation and decoration of external walls.

With the development of technology, the society makes more and more stringent requirements for energy conservation and environmental protection in the construction industry, and the government will also issue relevant acts for these purposes.

Existing technical solutions for energy saving and thermal insulation of external walls are the use of thermal insulation material for walls, internal thermal insulation of external walls and external thermal insulation of external walls. In comparison, the best is the external thermal insulation of the external walls, due to which the appearance of a thermal bridge can be avoided. Compared to the internal thermal insulation of external walls, their external thermal insulation retains more heat in a real wall, maintains a stable room temperature and humidity and contributes to a more comfortable state of a person, and also allows you to save the brick-concrete structure of the wall body and increase internal areas by about 2 % Due to the above advantages, the technology of external thermal insulation of external walls is developing quite quickly.

The main technical solutions used for external thermal insulation of external walls are:

(1) attaching heat-insulating materials, followed by applying a cement mortar on top, which is reinforced with reinforcing mesh [patent RU 2139980 C1, published on 10/20/1999];

(2) casting polyphenyl plates with a reinforcing mesh of steel wire in the formwork directly in place, and then dismantling the formwork and plastering [patent RU 2224854 C2, published on September 20, 2003];

(3) the preliminary manufacture of a laminated external heat-insulating panel, its attachment and sealing of joints [patent RU 78729 U1, published 10.12.2008, prototype].

Compared to the first two technical solutions mentioned above, the third technical solution is more practical and flexible, due to fewer work on site, more choice for the external surface and the possibility of large-scale production. However, existing prefabricated external heat insulating panels have a number of disadvantages, for example, their following properties are not good enough, in particular: internal stresses in the prefabricated panel, thermal insulation ability, impact strength and tear resistance, as well as the existence of a serious drawback with respect to fire resistance. The safety margin is also low and the service life is relatively short.

The proposed utility model provides an energy-saving thermal insulation and decorative panel, which has the following advantages: high thermal insulation ability, the presence of a finishing effect, low weight, high impact strength and tear resistance, fire safety, ease of application, high margin of safety and long service life.

This utility model is, therefore, intended to achieve the above technical characteristics by providing an energy-saving heat-insulating and decorative panel, which includes: an inner plate of heat-insulating material; a frame placed around the perimeter of the inner plate and glued to the sides of the inner plate using an adhesive layer; a shield located in front of the inner plate and connected to the front ends of the frame and the front side of the inner plate using an adhesive layer; a mounting surface attached to the rear side of the inner plate and used to attach to the wall.

The mounting surface can be made in the form of a back plate glued to the rear ends of the frame and the rear side of the inner plate or as a layer of cement mortar with reinforcing mesh deposited on the back side of the inner plate and the rear ends of the frame.

The shield can be selected from the group: a plate made of cement with fiber filler, a plate made of calcium silicate, a plate made of magnesia cement or a thin plate made of stone with a thickness of 3-10 mm, or a plate made of aluminum or sheet steel with a thickness of 0.4-1, 0 mm

The inner plate can be made of a material selected from the group: extruded polystyrene foam, polyurethane foam, foamed material based on phenolic resin, foamed polyvinyl chloride, porous ceramic material or foamed material based on cement, and may have the following characteristics: thickness - 20-300 mm; density - 25-300 kg / m ³ ; the thermal conductivity is less than 0.08 W / (m · K), the compressive strength is at least 0.25 MPa, and the tensile strength is at least 0.10 MPa.

The frame can be made of a material selected from the group: foamed polyvinyl chloride, a calcium silicate sheet with fiber filler, a cement sheet with a hollow glass filler, or a magnesite sheet with a hollow glass filler, having: a thermal conductivity of less than 0.3 W / (m K), the compressive strength is not less than 1 MPa.

The adhesive layer can be made of epoxy or polyurethane adhesive with a peel strength of at least 2.0 MPa.

The proposed energy-saving thermal insulation and decorative panel performs two functions - thermal insulation and decoration. This completely enclosed structure and glued structure provide the proposed panel with higher indicators of impact strength, fire resistance, seismic resistance, and tensile strength. It is quite simple to use and has a high margin of safety and a long service life.

This utility model is further illustrated by examples using the drawings, which show:

figure 1 - schematic view of a structure according to an example implementation of the present utility model;

figure 2 is a schematic view of the design of the outer curtain wall of energy-saving heat-insulating and decorative panels suspended from the wall by means of a suspension in accordance with one preferred embodiment of the present utility model;

figure 3 is a schematic view of the structure of the outer curtain wall of energy-saving heat-insulating and decorative panels attached to the wall in accordance with another preferred embodiment of the present utility model.

Used digital notation: 1 - shield; 2 - frame; 3 - inner plate; 4 - mounting surface; 5 - adhesive layer; 6 - protruding beam; 7 - sealant; 8 - foam strip; 9 - a bolt; 10 - wall; 11 - suspension; 12 - coating layer of cement mortar.

Figure 1 shows a schematic view of a structure according to an example implementation of the panel of the present utility model, including, an inner plate 3 of heat-insulating material, made square; a frame 2 placed around the perimeter of the inner plate 3 and glued to the sides of the inner plate 3 with an adhesive layer 5; a shield 1 in front of the inner plate 3 connected to the front ends of the frame 2 and the front side of the inner plate 3 by means of an adhesive layer 5; a mounting surface 4 attached to the rear side of the inner plate 3 and respectively attached to the wall. The mounting surface 4 is a back plate glued to the rear ends of the frame 2 and the rear side of the inner plate 3, or is a cement mortar layer with a reinforcing mesh deposited on the rear side of the inner plate 3 and the rear ends of the frame 2.

In this embodiment, the shield 1 is a thin plate of stone, the frame 2 is made of PVC (polyvinyl chloride), the inner plate 3 is made of extruded polystyrene foam, the mounting surface 4 is a plate of high strength calcium silicate or a layer of cement mortar with a reinforcing mesh.

The manufacturing method is as follows:

(1) cutting the required number of internal plates 3;

(2) placing the shield 1 on the mounting table so that its back side is facing up, then applying the adhesive to its back side, smearing the adhesive with strips using a notched trowel, gluing the inner plate 3 to the obtained adhesive layer 5 on the shield 1 and placing a heavy object on it until the adhesive has cured;

(3) gluing the frame 2 on the adhesive layers from the four sides of the inner plate 3 and to the shield 1 with its subsequent fastening with clamps for 3-5 hours, after which the clamps are removed;

(4) applying adhesive to the back surface of the inner plate 3 with smearing it with strips with a notched trowel, gluing the plate onto the obtained adhesive layer 5 of the inner plate 3 and placing a heavy object on it until the adhesive hardens, or applying a layer of cement mortar reinforced with reinforcing mesh with a spatula , about 2 mm thick.

Thermal insulation and decorative panel is made in accordance with the above method.

Example 1

Shield 1: a thin stone plate having a thickness of 6 mm, a length of 900 mm and a width of 600 mm.

Frame 2: PVC, thermal conductivity coefficient - 0.14 W / (m · K), compressive strength - 1.1 MPa, thickness - 12 mm, shorter side strip - 600 mm × 50 mm, longer side strip - 900 mm × 50 mm.

Inner plate 3: extruded polystyrene foam, density - 30-35 kg / m ³ thermal conductivity coefficient - 0.03 W / (m · K), tensile strength - 0.1 MPa, thickness - 50 mm, length - 875 mm, width - 575 mm.

Glue layer 5: epoxy adhesive, peel strength - not less than 2.0 MPa.

Mounting surface 4 on the rear side of the inner plate 3: a plate made of high strength calcium silicate.

Example 2

Shield 1: a thin stone plate having a thickness of 6 mm, a length of 900 mm and a width of 600 mm.

Frame 2: calcium silicate strip, thermal conductivity coefficient - 0.25 W / (m · K), compressive strength - 1.1 MPa, thickness - 5 mm, shorter side strip - 600 mm × 50 mm, more than long side - 900 mm × 50 mm.

Internal plate 3: extruded polystyrene foam, density - 30-35 kg / m ³ thermal conductivity coefficient - 0.03 W / (m · K), tensile strength - 0.1 MPa, thickness - 50 mm, length - 894 mm, width - 594 mm.

Glue layer 5: polyurethane adhesive, peel strength - not less than 2.0 MPa.

Mounting surface 4 on the back side of the inner plate 3: a layer of cement mortar with a reinforcing mesh, consisting of alkali-resistant reinforcing mesh and polymer-cement mortar.

All materials used in the utility model are available on the materials market.

The installation method of the above thermal insulation and decorative panels is as follows.

As shown in FIG. 2, a heat-insulating curtain wall, which consists of several separate square heat-insulating and decorative panels A ₁ , A ₂ , is provided on the outside of the wall 10 made of reinforced concrete or brick. The back plate of the thermal insulation and decorative panel is a plate of high strength calcium silicate. The protruding beam 6 is mounted on the wall 10 with a bolt 9. A suspension 11 is provided between the sides of the individual heat-insulating and decorative panels adjacent to each other from above and below, the upper and lower walls of the suspension being inserted into the corresponding gap between the frames of the individual heat-insulating and decorative panels, a grip at the rear side of suspension suspended in the projecting tool bar 6. The clearance between the adjacent sides of individual insulating and decorative panels a ₁ and a ₂ is filled with a foam strip 8, and ne ednyaya opening portion of this gap is sealed with sealant 7 from waterproof gypsum or mastics weatherable and water resistant adhesive.

As shown in FIG. 3, here the method of connecting the heat-insulating and decorative panel to the wall is different from the method shown in FIG. 2. The mounting surface 4 of this heat-insulating and decorative panel is a cement mortar coating layer consisting of alkali-resistant reinforcing mesh and a polymer-cement mortar, and the mounting surface is directly attached to the wall 10 due to such a cement mortar coating layer 12. Without a protruding beam, suspension 11, capturing the sides of the panel, directly mounted on the wall 10 using a bolt 9.

A curtain wall assembled from these heat-insulating and decorative panels can meet the requirements of thermal insulation and energy saving for an external wall, and also has the following advantages: relatively low production and installation costs, high fire safety, high strength and long service life, excellent appearance . It can be used for the external walls of high-rise buildings for the purposes of their decoration and thermal insulation.

Claims (8)

1. Energy-saving heat-insulating and decorative panel made of laminated, characterized in that it includes an inner plate (3) of heat-insulating material; a frame (2) placed around the perimeter of the inner plate and glued to the sides of the inner plate using an adhesive layer (5); a shield (1) located in front of the inner plate (3) and connected to the front ends of the frame (2) and the front side of the inner plate (3) with an adhesive layer (5); a mounting surface (4) attached to the rear side of the inner plate (3) and used to attach to the wall. 2. The panel according to claim 1, characterized in that the mounting surface (4) is made in the form of a back plate glued to the rear ends of the frame (2) and the rear side of the inner plate (3). 3. The panel according to claim 1, characterized in that the mounting surface (4) is made in the form of a layer of cement mortar with reinforcing mesh deposited on the rear side of the inner plate (3) and the rear ends of the frame (2). 4. The panel according to claim 1, characterized in that the shield (1) is made in the form of a plate of cement with fiber filler, a plate of calcium silicate, a plate of magnesia cement or a thin plate of stone, having a thickness of 3-10 mm 5. The panel according to claim 1, characterized in that the shield (1) is made in the form of a plate of aluminum or sheet steel having a thickness of 0.4-1.0 mm 6. The panel according to claim 1, characterized in that the inner plate (3) is made of extruded polystyrene foam, polyurethane foam, foamed material based on phenolic resin, foamed polyvinyl chloride, porous ceramic material or foamed material based on cement, having a thickness of 20-300 mm ; density 25-300 kg / m ³ ; the thermal conductivity is less than 0.08 W / (m · K), the compressive strength is not less than 0.25 MPa, and the tensile strength is not less than 0.10 MPa. 7. The panel according to claim 1, characterized in that the frame (2) is made of foamed polyvinyl chloride, a sheet of calcium silicate with a fiber filler, a sheet of cement with a hollow glass filler or a sheet of magnesite with a hollow glass filler having a thermal conductivity of less than 0.3 W / (m · K), compressive strength of at least 1 MPa. 8. The panel according to claim 1, characterized in that the adhesive layer (5) is an epoxy or polyurethane adhesive with a peel strength of at least 2.0 MPa.