RU186051U1 - THREE-LAYER WALL PANEL - Google Patents

Abstract

The utility model relates to construction, namely, multilayer wall panels used in large-panel housing construction. The technical task of the utility model is to increase the heat-shielding properties of the panel. The problem is solved in that in a three-layer wall panel including reinforced concrete layers, such as the outer layer, the inner layer and the intermediate layer of heat-insulating material located between them, connected by flexible metal bonds, with channels made in the intermediate layer of t of insulating material with hollow pipes located in them, closed at the ends, the internal cavity of the pipes is filled with carbon dioxide, the pressure of which is not higher than normal atmospheric pressure. The presence of pipes closed at the ends, filled with carbon dioxide, located in the channels available in the channels in the intermediate layer of heat-insulating material, improves the heat-insulating properties of the intermediate layer, due to the significantly lower coefficient of thermal conductivity of carbon dioxide in comparison with the coefficient Air eploprovodnosti. The use of pipes filled with carbon dioxide, the pressure of which is lower than normal atmospheric pressure, leads to an additional decrease in the coefficient of thermal conductivity and to an improvement in the heat-shielding properties of the panel.

Description

The utility model relates to construction, namely to multilayer wall panels used in large-panel housing construction.

Known three-layer wall panels used in large-panel house-building patents of the Russian Federation No. 1670061, 100790, 2191239, 107209, 2204666, 2209899, 2098377, 2033504, 2373346; USSR copyright certificate No. 1735527, 1724831, 1377349; US patent No. 4359848, 2248348, 5365716; Belarus patent No. 4953.

Known wall panel (RF Patent No. 2258788), consisting of a reinforced outer and inner concrete layers and an intermediate heat-insulating layer connected by flexible metal bonds. The heat-insulating layer is made of "capsimet" - coarse-porous concrete on a light porous aggregate encapsulated with a binder, binding the filler grains coated with a binder shell in a monolithic layer; the outer concrete layer is made of high-strength concrete of grade ≥ M500, the inner concrete layer is made of expanded clay concrete with a steel frame made of a rectangular or square pipe in the form of a closed rectangular frame with jumpers located around the perimeter of the panel and recessed into the expanded clay concrete layer to a depth of 15 to 25 mm from the plane of the inner surface of the panel, with the opposite ends of the steel pipes of the greater side of the frame extended to the side surfaces of the panel and made open as mounting openings, and the reinforcing mesh of the outer layer is connected to the frame of the inner layer along its contour with flexible bonds made in the form of a coarse mesh.

The disadvantages of the known panel are not high heat-insulating properties and high weight, which is due to the high coefficient of thermal conductivity of the capsimet, (thermal conductivity of the order of 0.12 W / m⋅ ° C) and high density of this material (from 400 kg / m3 to 600 kg / m3).

Known three-layer wall panel (RF Patent No. 174708), including reinforced concrete layers, such as the outer layer, the inner layer made of expanded clay concrete and the intermediate thermal insulation layer connected by flexible metal bonds, characterized in that the intermediate layer is made of foam glass, with air channels located in the plane of the panel, while the channels are arranged not through, and the outer layer is made of fiberglass concrete. The specified panel has a reduced thermal conductivity compared to the panel (RF Patent No. 2258788), however, this characteristic can be significantly improved.

The technical task of the utility model is to increase the heat-shielding properties of the panel.

The problem is solved in that in a three-layer wall panel, including reinforced concrete layers, such as the outer layer, the inner layer and the intermediate layer of heat-insulating material located between them, connected by flexible metal bonds, with channels made in the intermediate layer of heat-insulating material with in them hollow pipes closed at the ends, the internal cavity of the pipes is filled with carbon dioxide, the pressure of which is not higher than normal atmospheric pressure.

The presence of pipes closed at the ends, filled with carbon dioxide, located in the channels available in the intermediate layer of heat-insulating material, allows to improve the heat-insulating properties of the intermediate layer due to the significantly lower coefficient of thermal conductivity of carbon dioxide in comparison with the coefficient of thermal conductivity of air. The use of pipes filled with carbon dioxide, the pressure of which is lower than normal atmospheric pressure, leads to an additional decrease in the coefficient of thermal conductivity and to improve the heat-shielding properties of the panel.

The technical result of the utility model is to increase the heat-shielding properties of the panel.

The procedure for manufacturing a three-layer wall panel is as follows. At the bottom of the mold on the clamps, a metal mesh is laid with metal flexible ties fixed to it. After the installation of the mesh, the inner concrete layer is laid. Then, an intermediate layer of heat-insulating material is installed, in which the channels are formed by laying pipes with closed ends filled with carbon dioxide. After which the outer layer is applied. After the time required for the curing materials of the panel, the panel is removed from the mold.

Claims (1)

A three-layer wall panel, including reinforced concrete layers, such as the outer layer, the inner layer and an intermediate layer of heat-insulating material between them, connected by flexible metal bonds, characterized in that the intermediate layer made of heat-insulating material contains channels with hollow located in them the pipes closed at the ends, while the internal cavity of the pipes is filled with carbon dioxide, the pressure of which is not higher than normal atmospheric pressure.