SU1416467A1 - Composition and method for producing heat-insulating material - Google Patents

Abstract

The invention relates to the manufacture of a thermal insulation material based on mineral fiber and an organic binder. With the purpose of this coefficient of thermal conductivity and bulk density, to increase the strength and reduce the heat treatment time, the mass for the manufacture of the heat insulating material contains, in wt%: basalt fiber 22.0-35.7; polyvinyl acetate dispersion 6.0-10.7; an aqueous solution of sulfuric acid concentration of 0.2-0.8% 12.0-21.5; water 32.1-60.0. The volumetric mass of the products is 90-120 kg / m, the flexural strength is 2.0-2.6 MPa, the thermal conductivity coefficient is 0.055-0.065 W / M K. Thermal insulation material from the specified composition is prepared by mixing; initial components, including the preparation of diluted water solution of polyvinyl acetate dispersion and add the resulting solution to basalt fiber, previously moistened with an aqueous solution of sulfuric acid, followed by molding, drying to remove water at 120-150 0 for 3-4 hours and holding at 150-190 ° C for 2 5-4 h. 2 with. and gz.p. f-ly, 3 tab. i (L

Description

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ABOUT)

The invention relates to the manufacture of a thermal insulation material based on mineral fiber and an organic binder.

The purpose of the invention is to reduce the thermal conductivity and bulk density, increase strength and reduce heat treatment time.

The technology of manufacturing heat insulation materials is as follows.

The polyvinyl acetate dispersion is pre-diluted with water in a ratio of 1: (3-8), and the basalt fiber is placed in a mold and moistened with a solution. Then, a solution of a polyvinyl acetate dispersion diluted with water is added to the moistened basalt fiber. The hydromassage mold is dried at 120-150 ° C for 3 hours to remove water, then heat treated at 150-190 seconds for 2.5-4 hours. When amorphous alkali aluminosilicate or lime is added to the composition the silica-containing component is introduced into an aqueous solution of the polyvinyl acetate dispersion before mixing with the fiber.

The invention is illustrated by the specific examples given in Table 1.

Properties of the material obtained are given in table. 2,

In tab. Figure 3 shows the modes of manufacture of the heat insulating material in the case of the introduction of an amorphous alkaline aluminosilicate or lime and a finely ground silica-containing component.

Claims (3)

Invention Formula I. The mass for the manufacture of insulating material, including fibrous component, polyvinyl acetate dispersion and water, characterized in that, in order to reduce the thermal conductivity, bulk density, increase strength and shorten the heat treatment time, it additionally contains 0.2-0.8% sulfuric acid solution, and as a fibrous component - basalt fiber in the following ratio of components, wt,%: Basalt fiber22-35.7 Polyvinyl acetate dispersion 6-10,7 Water 32,1-60 0.2-0.8% sulfuric solution acids 12-21,5 2. A method of making a heat insulating material, including preparing an aqueous solution of a polyvinyl acetate dispersion and mixing it with a fiber component, followed by molding, drying at 120-150 ° C, characterized in that, in order to reduce thermal conductivity, bulk density, increase strength and reducing the heat treatment time, basalt fiber moistened with a solution of sulfuric acid is injected as a fiber component, and after drying the product is kept at 15 ° -190 ° C within 2.5-4 hours 3. A method according to claim 2, in which it is necessary to introduce an amorphous alkaline aluminosilicate or lime and a finely ground silica-containing component into the aqueous solution of the polyvinyl acetate dispersion before displacement with basalt fiber. 1T a b l and c a 1 Components, May. % Basalt fiber Polyvinyl acetate dispersion An aqueous solution of a concentration of 0.2-0.8 wt.% 29.6 25.5 30.0 22.0 8,8 9.3 10.0 6.0 5.2 15.7 20.0 12.0 Continuation of table 1 Containing aluminum lykat Containing lime and fine cream unearthly component Table3 170 190 180 170 185 .180 4.0 3.5 4.0 2.5 4.0 3.0