RU174909U1 - Fire retardant material - Google Patents

Abstract

The utility model relates to fire-retardant materials and can be used primarily for sewing overalls while providing protection against dangerous and harmful production factors of fire, elevated temperature, sparks and splashes of molten metal, high-intensity heat fluxes, etc. The essence of the utility model consists in the fact that the fire-retardant material consists of an external fire-retardant layer and a heat-insulating layer combined by flashing, and between the external fire-retardant and heat-insulating layers there is a heat-protective layer of non-woven material made of heat-resistant fibers, and the external fire-retardant layer is made of aramid fabric and wire is needle-punched heat-resistant fibers of the heat-protective layer. 7 C.p. f-ls, 1 ill.

Description

The utility model relates to fire-retardant materials and can be used primarily for sewing overalls while providing protection against dangerous and harmful production factors of fire, elevated temperature, sparks and splashes of molten metal, high-intensity heat fluxes, etc.

Known fire-retardant material in the form of fabric [RU 2309204, C1, D03D 15/12, 10.27.2007], containing staple yarn based on weft and including staple fibers based on triple aromatic copolyamide mixed with natural or artificial fibers, while the fabric is through derivatives, combined and complex weaves, and as natural fibers use cotton, linen, woolen fibers, fire-resistant viscose fibers are used as artificial fibers.

The disadvantage of this material is the relatively low fire retardant properties.

Also known fabric [RU 121256, U1, D03D 15/12, 20.10.2012], made by weaving the main threads selected from the group of para-aramid fibers, and weft threads selected from the group containing natural fibers, and the main threads additionally contain yarn from natural fibers, and the weft yarns additionally contain yarn from fibers selected from the group of paraamide fibers in the following ratio of components, wt.%: paraamide fibers 20-30, natural fibers 70-80, while the surface density of the produced fabric is 290-310 g / m ² .

The disadvantage of this fabric is also the relatively low fire retardant properties.

Closest to the proposed one is a multilayer fire retardant material for clothing [RU 10182, U1, D03D 15/00, 06/16/1999] containing a fire retardant layer of heat-resistant fibers and at least one heat-insulating layer of natural fibers, as well as a water-insulating layer, and is made in the form package, and the fire-retardant layer is made in the form of a non-woven needle-punched heat-resistant fabric of high-modulus fibers of the type CBM, Terlon, Armos, a water-insulating polymer layer is applied to the fire-retardant layer by coating and heat treatment, and heat-insulating layers formed by layers of wool batting adjacent to the fire-retardant layer and layers of cotton fabric, while the layers are combined into a firmware package.

The disadvantage of this material is the relatively low heat-insulating properties, since layers formed by layers of wool batting, which do not have high heat-insulating properties and are directly adjacent to the fire-retardant layer, are used as heat-insulating. In addition, the disadvantage of this material is its relatively low fire retardant properties, since exposure and exposure to hot media do not provide localization of exposure and they spread along the surface of the fabric. An additional drawback of the closest technical solution is the relatively low mechanical strength of the material, which can exclude the use of fabric for sewing clothes when working in an environment associated with surrounding metal structures and other rigid materials having elevated temperature and sharp protrusions.

The problem that is solved in the utility model is the creation of a flame retardant material with high mechanical strength, high flame retardant properties and low thermal conductivity.

The required technical result is to increase the flame retardant and mechanical properties of the material and reduce its thermal conductivity.

The problem is solved, and the required technical result is achieved by the fact that in the fire-retardant material, consisting of an external fire-retardant layer and a heat-insulating layer, united by firmware, according to a utility model, a heat-protective layer made of heat-resistant fibers of a nonwoven material is introduced between the external fire-retardant and heat-insulating layers, and the external the fireproof layer is made of aramid fabric and is needle-pierced by heat-resistant fibers of the heat-protective layer.

In addition, the desired technical result is achieved by the fact that the insulating layer is made of wool fibers.

In addition, the desired technical result is achieved by the fact that the insulating layer is made of cotton fibers.

In addition, the desired technical result is achieved by the fact that the insulating layer is made of linen fibers.

In addition, the required technical result is achieved by the fact that oxidized polyacrylonitrile fibers are used as heat-resistant fibers.

In addition, the required technical result is achieved by the fact that aramid fibers are used as heat-resistant fibers.

In addition, the required technical result is achieved by the fact that basalt fibers are used as heat-resistant fibers.

In addition, the required technical result is achieved by the fact that silica fibers are used as heat-resistant fibers.

The drawing shows the structure of the flame retardant material.

The fire-retardant material consists of the outer fire-retardant layer 1 and the heat-insulating layer 2 combined by the firmware, as well as the heat-protective layer 3 of non-woven material made of heat-resistant fibers placed between the external fire-retardant 1 and the heat-insulating 2 layers.

A feature of the proposed material is that the external flame retardant layer 1 is made of aramid fabric and is needle-punched with heat-resistant fibers of the heat-protective layer 3.

The heat-insulating layer 2 can be made of natural fibers, in particular from woolen, cotton and linen fibers.

Oxidized polyacrylonitrile, aramid, basalt or silica fibers can be used as heat-resistant fibers.

Fire retardant material is used as follows.

The fire-retardant material consists of the outer fire-retardant layer 1 and the heat-insulating layer 2 combined by the firmware, as well as the heat-protective layer 3 of non-woven material made of heat-resistant fibers placed between the external fire-retardant 1 and the heat-insulating 2 layers.

With strong thermal or fire exposure, the external fire-retardant layer protects under short-term temperatures up to 750 ° C and long-term up to 350 ° C, which is caused by the use of external fireproof layer 1 of aramid fabric. In this case, the external fire-retardant layer 1 of aramid fabric is needle-pierced by heat-resistant fibers of the heat-protective layer 3. This provides additional anti-fire protection during radiation and contact with hot media due to the fact that it provides localization of exposure and reduces its spread over the surface of the material. In addition, since the external fire-retardant layer 1 is made of aramid fabric, a high mechanical strength of the material is ensured, which allows it to be used for sewing clothes for workers working in environmental conditions associated with surrounding metal structures and other rigid materials having high temperature and sharp protrusions. The heat-insulating layer 2 can be made of natural fibers, in particular from wool, cotton, linen fibers, which allows for additional thermal protection and comfortable conditions for the material to come into contact with the human body.

The material can be quilted (stitched) with heat-resistant threads (aramid, silica, glass, etc.).

Thus, thanks to the introduced improvements, the required technical result is achieved, which consists in increasing the flame retardant and mechanical properties of the material and reducing its thermal conductivity.

Claims (8)

1. Fire-retardant material, consisting of an external fire-retardant layer and a heat insulating layer, combined by firmware, characterized in that a heat-protective layer made of heat-resistant fibers of a nonwoven material is introduced between the external fire-retardant and heat-insulating layers, and the external fire-retardant layer is made of aramid fabric and wire is needle-punched heat-resistant fibers of the heat-protective layer. 2. Fire-retardant material according to claim 1, characterized in that the heat-insulating layer is made of wool fibers. 3. Fire-retardant material according to claim 1, characterized in that the heat-insulating layer is made of cotton fibers. 4. Fire retardant material according to claim 1, characterized in that the heat insulating layer is made of linen fibers. 5. Fire-retardant material according to claim 1, characterized in that oxidized polyacrylonitrile fibers are used as heat-resistant fibers. 6. Fire retardant material according to claim 1, characterized in that aramid fibers are used as heat-resistant fibers. 7. Fire-retardant material according to claim 1, characterized in that basalt fibers are used as heat-resistant fibers. 8. Fire retardant material according to claim 1, characterized in that silica fibers are used as heat-resistant fibers.

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