RU117357U1 - INORGANIC THIN-WALLED MULTILAYERED FACING MATERIAL - Google Patents

Abstract

1. Inorganic thin-walled multilayer facing material, which is at least one sandwich made of glued together outer layers, consisting of an inorganic reinforcing fabric impregnated with an inorganic binder, and an inner layer of inorganic sound-insulating and heat-insulating, and / or radioprotective, and / or radiation-resistant and / or electrically conductive material. ! 2. Material according to claim 1, characterized in that the outer layers of the sandwich are two to ten layers of reinforcing fabric impregnated with an inorganic binder. ! 3. Material according to claim 2, characterized in that basalt, or glass, or carbon, or metal fabrics are used as the reinforcing fabric of the outer layer. ! 4. Material according to claim 3, characterized in that alumina cements with alkali metal silicates, or geopolymers, or aluminophosphates are used as the inorganic binding outer layer. ! 5. Material according to claim 1, characterized in that non-woven ceramic fiber paper is used as the inorganic heat-insulating and sound-insulating material of the inner layer. ! 6. A material according to claim 1, characterized in that a metal foil or a material including chopped graphite fibers is used as the radioprotective material of the inner layer. ! 7. Material according to claim 1, characterized in that a boron-containing sheet material is used as the radiation-resistant material of the inner layer. ! 8. Material according to claim 1, characterized in that sheets are used as the electrically conductive material of the inner layer

Description

The utility model relates to non-combustible thin-walled inorganic facing materials that do not emit harmful substances and smoke when heated. Non-combustible materials can be used, in particular, for exterior and interior cladding of premises, including vehicle interiors.

Fire-resistant materials for interior decoration of passenger vehicles based on phenolic binders and fiberglass fillers, phenol-formaldehyde binders modified with polyethylene glycol and fosdiol containing hollow glass microspheres, aluminum hydroxide and fiberglass are known (RU 2276638 C1, 2006).

A disadvantage of the known fire-resistant materials is that the pyrolysis of the organic component of the binder is accompanied by the release of degradation products, smoke formation and the release of a large amount of heat.

Known non-combustible inorganic sheet material based on fiberglass with K _combustible ~ 0.002 and a density of 2.0 g / cm ³ for facing the walls of stations, subways, car salons, obtained by impregnating fiberglass with chromium-phosphate binder followed by curing at 150-180 ° C and pressing into sheets 3-5 mm thick (Pronin, B.F., Aslanova, N.I., Tsirul, N.P., Non-combustible fiberglass plastic for civilian products. Best practice, 1989, No. 12).

The disadvantages of this material are low deformation and complex manufacturing technology (high curing temperatures and pressing).

Known multilayer fire-resistant material according to RU 2360800 C2, 2009, consisting of two layers, one of which is made of metal foil, and the other of mineral or ceramic (basalt or multi-siliceous) fiber. However, this material does not provide sufficient heat resistance: the temperature of the onset of weight loss is 500 ° C.

A composite material is known (RU 2027555 C1, 1995), which includes an inner layer of low-density filler and external reinforcing-protective layers, the internal low-density filler being pressed thermally split graphite, and the outer reinforcing-protective layers are made of corrosion-resistant metals, for example, chromium, nickel, vanadium, copper, zinc, or their alloys, with a ratio of the thickness of the filler and the outer layers of not less than 5: 1. The outer layers cover all or part of the surface of the filler. The metal coating is applied by sputtering, gluing or electrolytic deposition, and different metals can be applied to different pressing surfaces. A sheet of composite material with a thickness of 2 mm allows bending by 45 ° without peeling metal and with a thickness of 0.5 mm is twisted into a pipe. There are no harmful emissions during high-temperature (up to 1200 ° С) heating. When lining the cabin of a passenger aircraft, the reduction in lining weight can reach 44-48% compared with plastic with a density of 2 g / cm ³ .

The disadvantage of this material is the complex manufacturing technology and high cost.

A facing plate is known (application for invention of the Russian Federation No. 2001112965, 10.11.2003) containing particles of crushed rock-like materials fixed to the substrate by means of a binder, the substrate being made of pressed sheet material based on asbestos-cement sheet, or fiber cement sheet, or cement-bonded particleboard, stone-like materials have a particle size of 1 to 10 mm and fixed on the substrate to form a continuous front layer by a binder applied in an amount of 0.6-1.1 kg / m ² to form the adhesive Loy.

The disadvantages of the known material is the high density and content of harmful substances.

The objective of the utility model is the creation of an inorganic non-combustible multilayer thin-walled facing material with (increased heat and heat resistance and) increased mechanical strength.

This problem is solved by performing an inorganic multilayer facing material in the form of at least one sandwich of outer layers glued to each other, consisting of an inorganic reinforcing fabric impregnated with an inorganic binder, and an inner layer of inorganic soundproofing and heat insulating, and / or radioprotective, and / / or radiation resistant and / or electrically conductive material.

The outer layers of the sandwich are from two to ten layers of reinforcing fabric impregnated with an inorganic binder.

As the reinforcing fabric of the outer layers, basalt, or glass, or carbon, or metal fabrics can be used.

Alumina cements with alkali metal silicates, or polysialates, or aluminophosphates can be used as the inorganic binder of the outer layers.

As a heat-insulating and sound-insulating material of the inner layer in a sandwich, non-woven paper made of ceramic fiber is used.

As a radioprotective material of the inner layer, a metal foil is used, or a material including chopped graphite fibers.

As a radiation-resistant material of the inner layer, a sheet material containing boron is used.

As the electrically conductive material of the inner layer, sheet metal or graphite-containing material is used.

The non-combustible facing multilayer material can be made of 2-10 sandwiches glued together with an inorganic binder.

The utility model is a thin-walled inorganic multilayer facing material in the form of at least one sandwich consisting of several outer layers glued together of inorganic reinforcing fabric impregnated with an inorganic binder and one inorganic inner layer.

Inorganic binders reinforced with fabric or fibers are used as the inorganic material of the outer layers.

As the reinforcing fabric of the outer layers, basalt, or glass, or carbon, or metal fabrics are used, depending on the required characteristics of the material, for example, strength (metal, glass fabric), chemical resistance (carbon, glass fabric), heat resistance (basalt, carbon fabric ), and cost (glass cloth).

As inorganic binders, alumina refractory cements, or aqueous solutions of oligomers (alkali metal silicates with hardeners), or aluminoborphosphates, aluminochromophosphates, or a mixture of refractory cements with aqueous solutions of inorganic oligomers can be used.

As a heat-insulating and sound-insulating material of the inner layer in a sandwich, non-woven paper made of ceramic fiber is used.

Inorganic thin-walled multilayer facing material, depending on the requirements for the outer and inner lining of the premises, including the interiors of vehicles, can be made of 2-10 sandwiches of a straight or curved shape.

The outer layers are obtained from 2-6 canvases of fibrous tissue, freshly impregnated with a solution of inorganic binder, followed by combination with the material of the inner layer and curing in atmospheric conditions or at elevated temperatures.

A multilayer facing material based on only inorganic components does not emit toxic substances during operation and in combustion conditions, and also has improved mechanical characteristics (bending strength).

Claims (9)

1. Inorganic thin-walled multilayer facing material, which is at least one sandwich made of glued outer layers consisting of an inorganic reinforcing fabric impregnated with an inorganic binder, and an inner layer of inorganic soundproofing and heat insulating, and / or radioprotective, and / or radiation resistant and / or electrically conductive material. 2. The material according to claim 1, characterized in that the outer layers of the sandwich are from two to ten layers of reinforcing fabric impregnated with an inorganic binder. 3. The material according to claim 2, characterized in that basalt, or glass, or carbon, or metal fabrics are used as the reinforcing fabric of the outer layer. 4. The material according to claim 3, characterized in that alumina cements with alkali metal silicates, or geopolymers, or aluminophosphates are used as the inorganic binder outer layer. 5. The material according to claim 1, characterized in that a non-woven paper made of ceramic fiber is used as an inorganic heat-insulating and sound-insulating material of the inner layer. 6. The material according to claim 1, characterized in that a metal foil or a material including chopped graphite fibers is used as the radioprotective material of the inner layer. 7. The material according to claim 1, characterized in that as a radiation-resistant material of the inner layer is used sheet material containing boron. 8. The material according to claim 1, characterized in that a sheet metal or graphite-containing material is used as the electrically conductive material of the inner layer. 9. The material according to any one of claims 1 to 8, characterized in that it contains 2-10 sandwiches glued together with an inorganic binder.