RU175366U1 - Heat insulating structure - Google Patents

Abstract

The heat-insulating structure belongs to the field of heat engineering, it is intended for use as thermal insulation on hot surfaces for various purposes, it allows to increase the strength characteristics, while improving the efficiency of the heat-insulating and mechanical properties of the heat-insulating structure, and increasing its elasticity. The heat-insulating structure contains a fiberglass honeycomb 1, one side of which is adjacent to the heat-insulating surface 2, and the other side to the flexible heat-insulating layer 3. The flexible heat-insulating layer is made of foam material with microspheres. On the opposite side of the fiberglass honeycomb plastic side of the flexible insulating layer 3 is a shielding layer 4 containing a metal with a high reflection coefficient, for example, foil. Fiberglass honeycomb 1 connected with a heat-insulating layer 2 by means of adhesive bonds, performs the primary heat-insulating function and increases the mechanical characteristics of the heat-insulating structure. Flexible thermal insulation layer 2, containing hollow microspheres, performs the main heat-insulating function, due to the low coefficient of thermal conductivity. The shielding layer 3 reduces the radiant component of the heat transfer process, thereby reducing the effective thermal conductivity of the heat-insulating structure, and provides mechanical protection for the flexible heat-insulating layer 2. 1 il.

Description

The utility model relates to the field of heat engineering and is intended for use as thermal insulation on hot surfaces for various purposes, including pipelines and equipment of heat supply systems, hot and cold water supply, oil pipelines, gas pipelines, steam pipelines, building envelopes.

Known heat and sound insulation panel, including interconnected outer sheets and inner layers of cellular honeycomb layers (see patent for the invention No. RU 2009117089 A, E04C 2/00, publ. 20.11.2010). The composition of the heat and sound insulation panel includes differentiated heat and sound elements located and interconnected along the inner surfaces of the cells of the honeycomb. The heat and sound elements are made in the form of horizontal elements, cell edges and inner planes of the outer sheets of the panel layers, and the last layers, cell edges and horizontal elements are rigidly interconnected by compositions of polyurethane foam groups.

The disadvantages of this solution are the difficulty in manufacturing, low application temperature and low flexibility of the panels, which makes their use on thermal and power equipment almost impossible.

The closest in technical essence to the proposed utility model is a thermal insulation coating consisting of a heat-insulating and shielding layer (see utility model patent No. RU 160985 U1, Е04В 1/76, publ. 04/10/2016). The heat-insulating coating contains a heat-insulating layer deposited on the shielding layer, which contains a metal with a high reflection coefficient and adheres to a thermally insulated surface. The material of the heat-insulating layer is made of foam material forming a cavity. The heat-insulating layer is located on a heat-insulating surface and is made of a foamed binder material forming a cavity and microspheres, bonded to a shielding layer placed on the heat-insulating layer from the side of the heat-insulating surface. To create a heat-insulating layer, binders are used on organosilicate, organosilicon, epoxy, polyurethane, silicate-enamel, acrylic bases with a blowing agent and a curing catalyst. The shielding layer is made of a material containing a metal with a high reflection coefficient. The shielding layer is directly adjacent to the insulated surface.

The disadvantage of this solution is the low tensile strength of the insulation coating and the low tensile strength in bending.

The technical task of the utility model is to increase the strength characteristics of the insulating structure.

The technical result of the invention is to increase the efficiency of the insulating and mechanical properties of the insulating structure, increasing its elasticity.

This is achieved by the fact that in the known heat-insulating structure located on a heat-insulating surface and containing a heat-insulating layer made of a binder material, a foaming agent, a curing catalyst and microspheres, the shielding layer contains a metal with a high reflection coefficient equipped with fiberglass honeycomb with a thickness of 0.1-0, 15 mm, which abuts on one side to a thermally insulated surface, and on the other side to a heat-insulating layer, in which a polysiloxane comp is chosen as a binder und microspheres made of sodium borosilicate glass, and hollow inside, the curing catalyst is vulcanizer as γ-aminopropyltriethoxysilane, and blowing agent as benzenesulfonyl hydrazide, wherein the shielding layer is located on the opposite side of the glass cloth honeycomb insulation layer.

The essence of the utility model is illustrated by the drawing, which shows the heat-insulating structure.

The heat-insulating structure contains a fiberglass honeycomb 1, one side of which is adjacent to the heat-insulating surface 2, and the other side to a flexible heat-insulating layer 3. The flexible heat-insulating layer is made of foam material with microspheres. On the side opposite the honeycomb plastic flexible insulation layer 3 is a shielding layer 4 containing a metal with a high reflection coefficient, for example, foil.

Thermal insulation design works as follows.

Fiberglass honeycomb 1 connected with a heat-insulating layer 2 by means of adhesive bonds, performs the primary heat-insulating function and increases the mechanical characteristics of the heat-insulating structure. Flexible thermal insulation layer 2, containing hollow microspheres, performs the main heat-insulating function, due to the low coefficient of thermal conductivity. The shielding layer 3 reduces the radiant component of the heat transfer process, thereby reducing the effective thermal conductivity of the heat-insulating structure, and provides mechanical protection for the flexible heat-insulating layer 2.

Thermal insulation design is as follows. For the manufacture of a heat-insulating structure, a rectangular conductor located on a solid surface with a plastic film is used, which prevents the heat-insulating layer 3 from sticking to the conductor before it is vulcanized. The polyethylene film is treated with a BC-M release agent (release agent). On the film in the conductor is a shielding layer 4, for example, foil. On the surface of the shielding layer 4 is a heat-insulating layer 3, in the form of a mixture evenly distributed with a spatula on the surface of the shielding layer 4, consisting of a polysiloxane compound used as a binder, hollow glass microspheres, sodium borosilicate glass, a vulcanizer in the form of γ-aminopropyltriethoxysilane and blowing agent - benzenesulfonyl hydrazide. 10-15 minutes after the conductor is filled, the honeycomb 1 is laid onto the incompletely cured surface of the heat-insulating layer 3 by pressing it. Fiberglass honeycomb 1 is a flexible honeycomb with a diameter of 5 ± 0.2 mm, made on the basis of fiberglass with a thickness of 0.1 ÷ 10.15 mm. The large thickness of the fiberglass reduces the flexibility of the fiberglass honeycomb 1 and, as a result, reduces the flexibility of the insulating structure. The vulcanization of the heat-insulating layer 3 takes place at room temperature for 24 hours. In the process of vulcanization between the heat-insulating layer 3, the shielding layer 4 and fiberglass honeycomb 1 are formed strong adhesive bonds. At the end of vulcanization and heat-insulating layer 3, the finished heat-insulating structure is removed from the conductor.

It was experimentally established that the heat-insulating structure has a low coefficient of thermal conductivity, not exceeding 0.08 W / m * C at a temperature of 300 ° C, as well as low moisture absorption - up to 0.15% vol. in 24 hours. The use of fiberglass honeycomb allows you to increase the elasticity of the heat-insulating structure with a thickness of 15 mm to 1 mm, and a thickness of 30 mm to 12 mm.

Using the utility model provides an increase in the insulating properties of a known heat-insulating coating, increasing elasticity and mechanical characteristics.

Claims (1)

A heat-insulating structure located on a heat-insulating surface, containing a heat-insulating layer made of a binder, a blowing agent, a curing catalyst and microspheres, a shielding layer containing a metal with a high reflection coefficient, characterized in that it is equipped with fiberglass honeycomb with a thickness of 0.1-0.15 mm, one side of which is designed to adhere to a heat-insulating surface, and the other side is adjacent to a heat-insulating layer, in which polysil is selected as a binder the oxane compound, the microspheres are made of sodium borosilicate glass and hollow inside, the curing catalyst is a γ-aminopropyltriethoxysilane vulcanizer, and the benzenesulfonyl hydrazide is a blowing agent, while the shielding layer is located on the side of the insulating layer opposite the fiberglass honeycomb.

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