RU81551U1 - MULTILAYER INSULATING MINERAL FIBER PRODUCT - Google Patents

Abstract

The utility model relates to construction and can be used in the manufacture of thermal insulation materials based on mineral wool. An insulating plate, consisting of two layers located one above the other of different density and thickness, one of which is less dense and of a greater thickness, is made of mineral fiber with a binder, and the second layer is made of mineral fiber with a binder. The density of one is 10-150 kg / m ³ and the density of the other is 50-300 kg / m ³ . The utility model will improve the performance, quality and strength of the product.

Description

The utility model relates to construction and can be used in the manufacture of thermal insulation materials based on mineral wool.

An insulating board is known, consisting of two layers located one above the other of different density and thickness, one of which is the main one - less dense and of a greater thickness made of mineral fiber impregnated with a synthetic binder (SU 889812 A, 12/15/1981).

The main layer has a density of 200-350 kg / m ³ and has a thickness of 30 mm. The second is a rigid reinforced surface layer 1-3 mm thick consisting of a mineral filler (10-60 wt.%) And an inorganic binder based on magnesite (40-90 wt.%).

A disadvantage of the known design is the length of the manufacturing process of the surface layer due to the slow curing of magnesia cement, low productivity, strength and quality, as well as fragility. The product has high corrosion activity caused by the content of chlorides and sulfates.

The technical result of the proposed utility model is to increase productivity, quality, strength and durability of the product.

This technical result is achieved due to the fact that in the insulating plate, consisting of two layers located one above the other of different density and thickness, one of which is the main one - less dense and of greater thickness is made of mineral fiber with a binder, the second layer - additional - made of mineral fiber with a binder, while the density of the main is 10-150 kg / m ³ and the density of the additional 50-300 kg / m ³ .

In addition, the main and additional layers are interconnected by means of an organic binder, deposited on at least one of the joined surfaces.

In addition, the binder in the main and additional layers is organic and its content in them does not exceed 7% by weight of the corresponding layer.

In addition, formaldehyde resin is used as a binder in the primary and secondary layers.

In addition, the main and additional layers of the slab are formed by cutting the original mineral wool carpet with their subsequent prepressing and joining.

In addition, the fibers in each of the layers are wavy.

The insulation plate is prepared as follows.

Mineral wool carpet is formed on an inclined conveyor of the fiber deposition chamber. At the time of fiber deposition, a binder is sprayed onto it through nozzles. Then, the fiber treated with the binder enters the pendulum distributor, which averages the density of the layer of mineral wool treated with the binder.

A layer of cotton wool treated with an organic binder (for example, formaldehyde resin in an amount of 1.5-5% by weight of the layer) and not compacted, 10-30 cm high and a density of 9-18 kg / m ³ is conveyed to a special installation where horizontal the knife is cut in height into two layers. Most often, the layers have the same thickness after cutting, although the ratio of thicknesses can vary, depending on the required thickness of the layers of the resulting product.

Then the layers are separately fed into two crimping-prepressers. One of the layers is denser stronger - the other is weaker. Each crimping machine gives the fiber a wave-like arrangement in the slab.

(corrugation), which increases the physical and mechanical characteristics (the higher the frequency of the "wave", the greater the degree of corrugation and strength).

After sealing, one of the surfaces to be joined can be treated with an additional amount of organic binder supplied through nozzles, after which both flows are combined by combining the surfaces of the layers and together enter the heat treatment chamber, where the binder cures.

After cutting the obtained cured structure, we obtain a plate consisting of two layers, one of which has a higher density, and, as a rule, a smaller thickness. Layers can have varying degrees of corrugation.

Example 1. According to the above technology, an insulating plate was obtained, consisting of two layers - the main lower one, with a density of 110 kg / m ³ and a thickness of 60 mm and an additional upper layer, with a density of 180 kg / m ³ and a thickness of 30 mm. The plate is used for warming flat roofs. The layers are joined by a binder used in the layers, usually a urea-modified phenol-formaldehyde resin

Example 2. According to the above technology, an insulating plate was obtained, consisting of two layers - the main lower one, with a density of 45 kg / m ³ and a thickness of 50 mm and an additional upper layer, with a density of 90 kg / m ³ and a thickness of 30 mm. The slab is used for ventilated facades. The layers are interconnected by applying a melamine-urea-formaldehyde resin with a melamine content of at least 17%.

Example 3. According to the above technology, an insulating plate was obtained, consisting of two layers - the main lower one, with a density of 95 kg / m ³ and a thickness of 40 mm and an additional upper layer, with a density of 180 kg / m ³ and a thickness of 30 mm. The slab is used for plaster facades. Layers

bonded by a binder used in the layers, usually a urea-modified phenol-formaldehyde resin.

The utility model will increase the productivity of manufacturing the product by eliminating the long (due to slow curing) process of performing one of the layers - from a mineral filler and inorganic binder and replacing this layer with a layer of mineral fiber. Such a replacement leads to an increase in the strength characteristics of the product, since the layer of mineral filler and inorganic binder is rigid, and the layer of mineral fiber gives the product higher deformation characteristics, as well as increases the sound and heat insulation properties of the product and reduces its specific gravity, which allows one to speak about improving the quality of the product and its durability. The optimal parameters of the finished plate, providing high consumer properties of the product, are the density of the main heat-insulating layer in the range of 10-150 kg / m ³ and the density of the additional supporting heat-insulating layer in the range of 5-300 kg / m ³ .

In particular, productivity can be improved due to the possibility of manufacturing the product in an automated line operation mode.

In particular, the strength of the product can be improved by using a more effective binder with less corrosive activity.

Claims (6)

1. The insulating plate, consisting of two layers located one above the other of different density and thickness, one of which is the main, less dense and larger thickness, is made of mineral fiber with a binder, characterized in that the second layer - additional - is made of mineral fiber with a binder, while the density of the main is 10-150 kg / m ³ and the density of the additional 50-300 kg / m ³ . 2. The insulating board according to claim 1, characterized in that the main and additional layers are interconnected by means of an organic binder, deposited on at least one of the joined surfaces. 3. The insulation plate according to claim 1, characterized in that the binder in the primary and secondary layers is organic and its content in them does not exceed 7% by weight of the corresponding layer. 4. The insulating board according to claim 1, characterized in that a formaldehyde resin is used as a binder in the primary and secondary layers. 5. The insulation plate according to claim 1, characterized in that the main and additional layers of the plate are formed by cutting the original mineral wool carpet, followed by prepressing and joining. 6. The insulation plate according to claim 1, characterized in that the fibers in each of the layers are arranged in a wave-like fashion.