SU773035A1 - Composition for making construction material - Google Patents

Description

The invention relates to building materials and is intended for the production of thermal insulation materials on mineral fiber, with high temperature resistance, which can be used for. thermal insulation of furnaces, turbines, various thermal units with a Hot surface temperature of 600 ° C and above.

A known composition for the manufacture of heat-insulating material, including,%: asbestos fiber 50.5-64.5, alumochromophosphate binder 32.3-40.5 and caustic magnesite 3.2-9.0 (1].

The disadvantage of this composition is the presence in its composition of scarce and toxic dust-containing particles of asbestos fiber, as well as high water absorption and bulk density of the material made from this heat-insulating composition.

Known heat-insulating composition, including basalt superthin fiber ^{1 with a} diameter of up to 1.5 microns in the amount of 88-98% and clay binder 2-12% [2].

The disadvantage of this composition is that the material made from it has low mechanical strength and high water absorption.

Known heat-insulating composition, including kaolin fiber 70-90% and alumochromophosphate binder 10-30% [3].

The disadvantage of this composition is the low mechanical strength and high bulk density of the material made from it.

Closest to the proposed one is a composition for producing building material, including mineral fiber, aluminochromophosphate '· binder and finely ground serpentinite [4].

The disadvantage of this composition is that the material obtained from it is structurally facing and has a high bulk density of 1600-1900 kg / m ³ and a thermal conductivity of 0.20.3 kcal / m <h / ° C, which does not allow its use in quality of insulating material.

The purpose of the invention is the provision of the possibility of obtaining a material with thermal insulation properties.

This goal is achieved in that the composition for obtaining a building material, including mineral fiber, alumochromophosphate binder and finely ground serpentinite, contains basalt fiber as a mineral fiber in the following ratio of components, wt.%: Yu

Basalt fiber 84 - 90

Alumochromophosphate binder 7 - 10

Fine serpentinite 3-6

Basalt fiber containing in its _; 15 composition of up to 20% alkaline and alkaline earth oxides, under the influence of an aqueous aluminochromophosphate binder having an acidic reaction, leaches, which is expressed in the conversion of most of the mentioned oxides to the liquid jo phase and in the formation of surface defects, i.e., roughness or porosity on elementary fibers. The introduction of a chemically active additive, finely ground serpentinite, into the composition results in its chemical interaction with the components of the liquid phase with the formation of a complex compound with high adhesive properties.

The porosity of the fiber surface improves adhesion thereto binder that kupnosti The aggregate ₃₀ of adhesive properties with high latter allows to increase the mechanical strength of the material and reduce the specific consumption of the binder, ie. E. Reduce the bulk density of the material. The decrease in bulk density ₃₅ also contributes to the finely porous structure of the surface of the fiber.

A decrease in the content of aluminochromophosphate binder below 7% negatively affects the strength of the material, while an increase in its content above 10% leads to an increase in bulk mass. A content of serpentinite below 3% is not enough to complete the reaction with the liquid phase, which is incomplete in this case, and an increase in its content above 6% negatively affects the bulk material and technological properties of the binder (viscosity, fluidity).

Example 1. To 10 wt.% Aluminochromophosphate binder add 6 wt.% · Finely ground serpentinite, the mixture is thoroughly mixed, shut with water to a density of 1.11 g / cm ³ and poured into a reactor equipped with a stirrer. Further into the reactor with the stirrer switched on gradually! 84 wt.% basalt fiber is added. After preparing a stable aqueous-fiber suspension, the latter is poured into a vacuum form, where at a vacuum of 500 mm RT. Art. forming raw. The molded raw is subjected to heat treatment at 200 ° C for 4 hours

Example 2. The same as in example 1, only take 8 wt.% Aluminochromophosphate binder, 4 wt.% Finely ground serpentinite, 88 wt.% Basalt fiber.

Example 3. The same as in example I, only take 7 wt.% Aluminochromophosphate binder, 3 wt.% Finely ground serpentinite, 90 wt.% Basalt fiber.

The table shows the properties characterizing the material obtained from the proposed composition.

Indicators Composition 1 Proposed 2 3 Famous 4 5 Bulk weight, kg / m ³ 220 205 195 315 1800 The coefficient of thermal conductivity, kcal / m> h "° C 0.05 0.05 0,045 0.25 Tensile Strength, kgf / cm ² 2,4 2,3 2.0 0.12 Bending strength, kgf / cm ² 2.1 1.9 1,6 0.11

Claims (4)

The invention relates to building materials and is intended for the production of heat insulating materials on mineral fiber with high temperature resistance, which can be used for thermal insulation of furnaces, turbines, various thermal units with a hot surface temperature of 600 ° C and above. A known composition for the manufacture of a heat insulating material, comprising: asbestos fiber 50.5-64.5, an aluminum-chromophosphate binder 32.3-40.5, and caustic magnesite 3.2-9.0 (C. The disadvantage of this composition is: the presence in its composition of asbestos fiber deficient and containing toxic dust-like particles, as well as high water absorption and bulk density of the material made from this thermal insulating coldshoid. 88-98% and clay binder 2-12% 2. The disadvantage of this composition is that the material produced from it has low mechanical strength and high water absorption. The thermal insulation composition is known, including kaolin fiber 70-90% and aluminum chromophosphate This is a drawback of 10-30%. 3. The disadvantage of this composition is the low mechanical strength and high bulk density of the material produced from it. The closest to the one proposed is a composition for the production of building material, including mineral fiber, aluminum-chromophosphate binder and finely ground serpentinite 4. The disadvantage of this composition is that the material obtained from it is structural facing and has a high bulk density of 1600-1900 kg / m and a thermal conductivity of 0.20,3 kcal / m W ° C, which prevents its use as a heat insulating material. 37 The purpose of the invention is to provide the possibility of obtaining a material with thermal insulation properties. The goal is achieved by the fact that the composition for the production of building material, including mineral fiber, aluminum-chromophosphate binder and fine ground serpentinite, contains basalt fiber as a mineral fiber in the following ratio of components, wt.%: Basalt fiber 84 - 90. Alumochromophosphate binder 7 - 10 Fine ground serpentinite. 3 - b Basalt fiber, containing up to 20% alkaline and alkaline earth oxides, is leached under the influence of an aqueous aluminum-chromophosphate binder having an acid reaction, which results in the transfer of a large part of the mentioned oxides to the liquid phase and the formation of surface defects, that is, roughness or porosity on elemental, tare fibers. The introduction of a chemically active Additive — finely ground serpentinite — into the composition results in its chemical interaction with the components of the liquid phase to form a complex compound with high adhesive properties. The porosity on the surface of the fiber improves the adhesion of the binder to it, which, together with the high adhesive properties of the latter, allows the material to increase its mechanical strength and reduce the specific consumption of the binder, i.e. reduce the bulk density of the material. The structure of the fiber surface also contributes to a decrease in the bulk density. A decrease in the content of the aluminochromophosphate binder below 7% adversely affects the strength of the material, while an increase in its content above 10% leads to an increase in the bulk mass. Serpentinite content below 3% is not enough to complete the reaction with the squeeze phase, which in this case is incomplete, and an increase in its content above 6% adversely affects the bulk weight of the material and the technological properties of the binder (viscosity, fluidity). Example 1. By 10% by weight of an aluminum-chromophosphate binder, 6% by weight of fine-grained serpentinite is added, the mixture is thoroughly mixed, sealed with water to a density of 1.11 g / cm, poured into a reactor equipped with a stirrer. Then 84% by weight of basalt fiber is gradually introduced into the reactor with the included blender. After preparing a stable water-fiber suspension, the latter is drained into a vacuum form, where at a vacuum of 500 mm Hg. Art. raw molding takes place. The molded raw is heat treated at 200 ° C for 4 hours. Example 2. Same as in example 1, only take 8 wt.% Apyumochromophosphate gazuyuschik, 4 wt.% Finely ground serpentinite, 88 wt.% Basalt the fibers. Example 3. Same as in Example I, only take 7% by weight of an aluminum-chromophosphate binder, 3% by weight of fine ground serpentinite, 90% by weight of basalt fiber. The table shows the properties characterizing the material obtained from the proposed KONmo3HUHH. 5 77 Claim of the invention Composition for the production of building material, including mineral fiber, aluminum-chromophosphate binder and finely ground serpentinite, characterized in that, in order to obtain a material with thermal insulation properties, it contains basalt fiber as a mineral fiber in the following ratio of components , wt.%: Basalt fiber 84 - 90 Alumochromophosphate binder 7-10 Fine-grained serpentinite 3-6 56 Sources of information taken into account during the examination I. Authors st certificate of the USSR I 471,349, cl. From 04 To 43/04, 1973. 2. USSR author's certificate N 544642, cl. From 04 To 43/02, 1973. 3. USSR author's certificate number 477149. class. From 04 To 43/02, 1972. 4. No. Management of three-layer wall panels with steel, aluminum, asbestos-cement phosphos-hectoplastic linings with perlite-plast-concrete insulation For industrial buildings. 2 - editors, VNII Industrial Buildings and TsNIISK them. V.A. Kucherenko, J976.