RU172004U1 - SHEET COMPOSITE HEAT-INSULATING MATERIAL - Google Patents

Abstract

Sheet composite heat-insulating material contains two layers of heat-insulating material, between which the middle layer is placed, while polystyrene foam is used as heat-insulating materials, the middle layer is made as a layer of cylindrical polyethylene foam gaskets in contact with non-woven fibrous material on the outer cylindrical surfaces, while cylindrical polyethylene foam gaskets and non-woven fibrous material are enclosed in fiberglass mesh and connected to the surfaces of the foam olystyrene. The utility model allows you to create thermal protection of the walls of residential and administrative buildings with variable geometry of the outer surface, such as large curvature and local differences in thickness. 2 ill.

Description

The utility model relates to sheet composite heat-insulating materials designed to create thermal protection of walls of residential and administrative buildings with variable geometry of the outer surface, such as large curvature and local differences in thickness, followed by applying a plaster layer to the heat-insulating materials.

Known sheet heat-insulating material intended for thermal insulation of pipelines and consisting of interconnected alternating insulating elements that are made elongated from non-deformable and elastically deformable materials at mounting loads, while the shell covers the side surfaces of the elements and consists of two fiberglass sheets, one of which is fixed on the side surfaces of the elements facing each other, and the second is fixed on the surfaces of the elements facing the isol Rui surface [Pat. 2233400 Russian Federation, IPC F16L 59/00. Sheet heat-insulating material / Barannikov A.A., Bulanovich V.F., Godunov V.F., Illarionov V.N .; Applicant and patent holder A. A. Barannikov, V. F. Bulanovich, V. F. Godunov, V. N. Illarionov, - No. 2003127084/06; declared 09/08/2003; publ. 07.27.2004 - 4 p.: Ill.].

A disadvantage of the known material is the inability to use it to create thermal protection of the walls of residential and administrative buildings with variable geometry of the outer surface (large curvature, with local differences in thickness).

The prototype of the claimed utility model is a composite heat-insulating material, which is formed from heat-insulating materials based on a fibrous composition in the form of two sheets and a vacuum heat-insulating material, which is included between the fibrous heat-insulating materials. The layers of fibrous heat-insulating material are combined into a single whole, and the interface between the heat-insulating materials is filled with a thinly cut layer of fibrous heat-insulating material [Pat. 2441119 Russian Federation, IPC Е04В 1/80. Composite Insulation Material / Cubonite Seitii (JP); Applicant and patent holder Mag Co. Ltd. (JP), Saint-Gobain Isover (FR); - No. 2008106771/03; declared 07/24/2006; publ. 01/27/2012, Bull. No. 3-9 p.: Ill.].

A disadvantage of the known composite (composite) thermal insulation material is that, firstly, it cannot be subjected to bending and compression due to the fact that the vacuum thermal insulation material is quite fragile due to the peculiarities of its manufacturing technology. Secondly, a plaster layer cannot be applied to the surface of the fibrous material in which the vacuum thermal insulation material is enclosed.

The technical result of the claimed utility model is the creation of thermal protection of the walls of residential and administrative buildings with variable geometry of the outer surface, such as large curvature and local differences in thickness.

The specified technical result is achieved by the fact that in a sheet of composite heat-insulating material containing two layers of heat-insulating material, between which the middle layer is placed, according to the utility model, polystyrene foam is used as heat-insulating materials, the middle layer is made in the form of a layer of cylindrical polyethylene foam gaskets contacting on the outer cylindrical surfaces with non-woven fibrous material, with cylindrical foam pads and non-woven fibrous material The material is enclosed in fiberglass nets and connected to polystyrene foam surfaces.

In FIG. 1 presents the claimed material in a perspective view (frontal isometric projection). In FIG. 2 shows the installation options of the inventive sheet composite insulation material on various surfaces of the walls of buildings, where: a - on the surface of buildings with curvature; b, c - on the surface of buildings with local differences in thickness.

The technical result, which consists in the possibility of using sheet composite thermal insulation material to create thermal protection of the walls of residential and administrative buildings with variable external surface geometry of both large curvature and local differences in thickness, is achieved by imparting new properties to the claimed design, which allow, with the required strength of the composite material to increase the values of indicators when it is deformed by bending and compression.

The achievement of the technical result is confirmed by tests in the laboratory in determining thermal conductivity, rigidity and compression deformation. For this purpose, samples were prepared (see table) with dimensions of 40 × 300 mm. The thermal properties of the sheet composite insulation material were evaluated by the thermal resistance ρ in accordance with the expression:

,

,

where Q - const is the power of the heat flux passing through the product, W;

t ₁ , t ₂ - const - surface temperature of the product, ° C;

F - const - product area, m ² ;

R - 2,8 - const - thermal resistance, m ² ⋅ deg / W.

B - 20 ... 100 - thickness of the product, mm.

For the rest of the tested materials, the values of specific thermal resistance are presented in the table.

To determine the bending stiffness, one of the ends of the formed samples (see table) was fixed motionless, and the other was loaded with a force of 1 kg for 10 min. An informative indicator is the arrow of deflection of the loose end of the sample in mm.

To determine the compression strain, the prepared samples (see table) were subjected to loading over the entire area with a load of 1 kg for 10 min. An informative parameter is an indicator reflecting the thickness of the sample in a compressed state.

The table shows that the claimed technical solution has less rigidity in bending strain and greater flexibility in compressive deformation at similar values of thermal resistance.

The inventive sheet composite thermal insulation material contains located between two surfaces of polystyrene foam 1 [GOST 15588-2014 Polystyrene foam insulation boards. Specifications], a layer of polyethylene foam cylindrical gaskets 2 (polyethylene foam gaskets are produced by the industry in a wide range, with an outer diameter of 30 to 120 mm [TP 116-01 Technical recommendations on the technology for using an integrated system of materials providing high-quality sealing and sealing of joints of external wall panels. Technical guidelines for sealing joints of prefabricated buildings with polymers (ed. GOU DPO GASIS, Moscow, 2007]). Foam cylindrical gaskets 2 are in contact on the outer cylindrical surfaces with non-woven fibrous material 3 [GOST R 53225-2008 Geotextile materials. Terms and definitions], while polyethylene foam cylindrical gaskets 2 and non-woven fibrous material 3 are enclosed in fiberglass mesh 4 [GOST R 55225-2012 Fiberglass mesh facade reinforcing alkali resistant. Specifications] and are connected to the surfaces of polystyrene foam 1.

Assembly of composite thermal insulation material is as follows. Initially, a sheet of polystyrene foam 1 is laid on the surface of the desktop, spreading it with glue (dry or polyurethane foam), then a fiberglass mesh 4 is laid, a layer of non-woven fibrous material 3 is spread, then parallel-to-side polyethylene foam gaskets 2 are laid (Fig. 1). Polyethylene foam cylindrical gaskets 2 are coated with a second layer of nonwoven fibrous material 3, after which both layers of nonwoven fibrous material 3 are joined with a construction stapler, thus covering the cylindrical surfaces of polyethylene gaskets 2 with non-woven fibrous material 3. A second layer of fiberglass mesh 4 is applied, smearing with glue, and impose a second sheet of expanded polystyrene 1.

Next, impose a load on the entire surface of the package of the claimed material, if necessary, create an additional load and withstand for a certain time (depending on the brand of glue). After that, the cargo is dismantled and the composite thermal insulation material is ready for use.

When installing a sheet of composite thermal insulation material on the wall surface of residential and office buildings, which has a large curvature or local differences in thickness, use, as with the installation of expanded polystyrene 5 (Fig. 2), special dowels with large washers in diameter. When installing the inventive composite heat-insulating material on the surface of buildings 6 having a large curvature, polyethylene foam cylindrical gaskets 2 contacting on both sides with non-woven fibrous material 3 are deformed along the corresponding curvature, while the glued fiberglass mesh 4 and polystyrene foam sheets 1 create mechanical strength design (Fig. 2, a). With local differences in the thickness of the building surface, the inventive composite heat-insulating material by setting the appropriate depth of dowels regulate the surface of the composite heat-insulating material, leveling it to the level required by the technology (Fig. 2, b, c). The sheets of polystyrene foam 1 and glued fiberglass mesh 4 take the position of the surface with a local difference in thickness due to the deformation of the foam cylindrical gaskets 2 in contact with both nonwoven fibrous material 3. The plaster layer is applied to the surface of the composite material by known methods.

Claims (1)

A composite sheet of heat-insulating material containing two layers of heat-insulating material, between which a middle layer is placed, characterized in that polystyrene foam is used as heat-insulating materials, the middle layer is made in the form of a layer of cylindrical polyethylene foam gaskets in contact with non-woven fibrous material on the outer cylindrical surfaces, while cylindrical foam pads and non-woven fibrous material are enclosed in fiberglass mesh and connected to a polystyrene foam.

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