RU242512U1 - Fire extinguishing cloth for active fire suppression - Google Patents

Abstract

The invention relates to fire-fighting devices and is intended for extinguishing localized fires using microencapsulated fire extinguishing agents. It can be used, in particular, to extinguish fires in domestic settings, electrical installations, batteries, and small spills of flammable liquids. The active fire extinguishing blanket has a layered structure and includes a carrier layer made of a polymeric material with a flame retardant and a functional layer made discretely of a polymeric material with a flame retardant and with microcapsules containing a fire extinguishing agent distributed therein. The carrier layer additionally comprises a protective layer made of a polymeric material with a flame retardant. The technical result of the invention consists in ensuring resistance to thermal destruction of the blanket and mechanical loads, which provides additional protection against secondary flame spread while increasing strength characteristics, increasing the effectiveness of fire extinguishing at localized sources of fire. 3 ill.

Description

The utility model relates to fire-fighting devices and is intended for extinguishing local fires using microencapsulated fire extinguishing agents, and can be used in particular for extinguishing fires in domestic settings, electrical installations, batteries, and small spills of flammable liquids.

A fire-insulation blanket is a rescue blanket comprising a three-layer fire-retardant fabric. The face layer is made of basalt fabric, the middle layer is made of a cotton-polyester lining with a PVC coating, and the outer fire-heat-protective layer is made of Oxipan fire-retardant material, backed with a fire-retardant fabric made of silica (patent RU 211355 U1, June 1, 2022). This blanket exhibits a long fire-extinguishing time due to insufficient mechanical strength, leading to calcination of the fabric and loss of integrity, reducing its reliability and fire-extinguishing effectiveness. Furthermore, reignition is possible after the blanket is removed when a new supply of oxygen reaches the smoldering fragments of the fire.

A fire-resistant cloth is known, consisting of a woven or non-woven material impregnated with a fire-extinguishing gel, consisting of a thickener, a combustion phlegmatizer, antifreeze, an antiseptic and water in a mass ratio: thickener 0.05-10%, combustion phlegmatizer 1-15%, antifreeze 1-30%), antiseptic 0.1-10%, water is the rest (patent RU 126945 U1, published 20.04.2013). This fire extinguishing material eliminates Class A and B fires by blocking oxygen supply to the fire. The fire extinguishing gel's flame retardant and cooling antifreeze interact with the fire source, locally extinguishing it. Rapid combustion of the gel's aerosol-forming composition releases a large amount of aerosol (smoke) containing harmful and corrosive substances such as chlorine and its derivatives into the surrounding area. However, a disadvantage of this material is its high initial response temperature (200-300)°C, which leads to calcination of the material, resulting in a loss of fiber strength, reduced tensile strength, and an increased risk of rupture and loss of integrity, thereby reducing its effectiveness and reliability.

Autonomous fire extinguishing systems based on microencapsulated extinguishing agents are now widely used. Their high extinguishing efficiency is achieved through a low activation temperature of 90-160°C and the delivery of extinguishing agent from dehiscent microcapsules directly to the fire. Upon reaching the fire, the extinguishing agent molecules decompose, forming free radicals that interrupt the kinetic chains of combustion, quickly halting its progression.

The closest approach is a fire-resistant fabric based on microencapsulated fire extinguishing agents, comprising a carrier layer and a functional layer. The carrier layer is made of a material with high heat resistance and good mechanical properties, such as fiberglass or mineral fiber (patent RU 2751396 C1, published August 17, 2021), while the functional layer is made of a polymer material with microcapsules containing the fire extinguishing agent distributed within it. This known fabric is designed to improve extinguishing efficiency by virtually simultaneously opening the microcapsules containing the fire extinguishing agent, simultaneously destructively breaking down the polymer material and releasing a significant amount of neutral gases, further blocking the source of the fire. This results in a salvo release of the entire extinguishing agent, resulting in the suppression of the fire. The polymer matrix utilized is a flammable polymer material capable of independently supporting combustion of the microcapsule-containing composite after brief exposure to fire. This leads to thermal destruction of the supporting layer and the product as a whole. This reduces the tensile strength and increases the likelihood of rupture and burn-through with flame propagation, thereby reducing the effectiveness and reliability of fire suppression at localized sites. Furthermore, the continuous and solid functional layer leads to the surface propagation of cracks within the layer, which form under the mechanical stresses that occur during storage and operation of the product. This leads to premature failure of the functional layer, reducing the effectiveness and, therefore, the reliability of fire suppression.

The objective of this utility model is to develop a new fire-extinguishing active fabric with high strength properties, ensuring high efficiency and reliability of extinguishing the source of fire.

The technical result of the invention consists in ensuring resistance to thermal destruction of the web and mechanical loads, which provides additional protection against secondary flame propagation while increasing strength characteristics, increasing the efficiency of fire extinguishing local sources of fire and, thereby, the reliability of the device.

The stated problem is solved by the fact that in a fire extinguishing active fire extinguishing fabric, made with a layered structure and including a carrier layer made of a fire-resistant material, and a functional layer made of a polymeric material with microcapsules with a fire extinguishing agent distributed in it, the new thing is that the carrier layer additionally contains a protective layer made of a polymeric material containing a fire retardant, and the functional layer is made discrete from a polymeric material additionally containing a fire retardant.

It is preferable to install the protective layer on the inside of the supporting layer, and the functional layer on top of the protective layer. It is also advisable to install an additional protective layer on the outside of the supporting layer.

It is advisable to make the protective layer on the outer side of the bearing layer, and the functional layer on the inner side of the bearing layer.

It is preferable to make a functional layer with a thickness of 0.5-2 mm and a quantity of microcapsules with a fire extinguishing agent of 30-100 grams per 1 ^m2 of fire extinguishing material.

In this application, the inner side of the supporting layer is understood to be the side that faces the source of fire during operation of the claimed fabric.

The essence of the utility model is explained by drawings, where:

Fig. 1 shows a schematic representation of an active fire extinguishing fabric, in which the protective layer is made on the inside of the supporting layer, and the functional layer is made on the protective layer;

Fig. 2 shows a schematic representation of a fire extinguishing sheet with an additional protective layer;

Fig. 3 schematically shows a fire extinguishing fabric for active fire extinguishing, in which the protective layer is made on the outer side of the supporting layer, and the functional layer is made on the inner side of the supporting layer.

The claimed utility model is implemented with a layered structure and consists of sequentially arranged layers, forming a single structure, which includes a supporting layer 1 with a protective layer 2 and a functional layer 3. Supporting layer 1 is made of a fire-resistant material, in particular fiberglass. Supporting layer 1 contains, in particular, on the inner side a protective layer 2 made of a polymeric material containing a fire retardant, and functional layer 3 is discretely applied to protective layer 2 and is made of a polymeric material with a fire retardant with microcapsules containing a fire extinguishing agent distributed therein (Fig. 1). Functional layer 3 is preferably made with a thickness of 0.5-2 mm and a quantity of microcapsules with a fire extinguishing agent of 30-100 grams per 1 ^m2 of the sheet, which is a necessary and sufficient condition for maintaining resistance to mechanical loads and thermal destruction of the functional layer with optimal use of expensive microcapsules and achieving high efficiency in extinguishing fires.

When the thickness of functional layer 3 is less than 0.5 mm, the amount of fire extinguishing agent is reduced, which requires an increase in the distribution density of microcapsules, which in turn leads to a decrease in the amount of binding components of the material, reducing the mechanical strength of the composite material of functional layer 3; when the thickness is greater than 2 mm, the ability of localized areas of the layer to resist plastic deformation and destruction decreases, which also reduces the mechanical strength. At the same time, when the number of microcapsules with fire extinguishing agent is less than 30 grams per 1 ^m2 of the sheet, the amount of fire extinguishing agent and the extinguishing efficiency decrease; when the number of microcapsules with fire extinguishing agent is greater than 100 grams per 1 ^m2 of the sheet, the consumption of expensive components increases and at the same time the amount of binding components of the material decreases, reducing the mechanical strength of the composite material of functional layer 3.

To manufacture an active fire extinguishing blanket, a fire-resistant material, such as fiberglass, is used as the carrier layer 1. On the inner side of the carrier layer is a protective layer 2, formed by spraying or impregnation using surface or immersion treatment, respectively. Carrier layer 1 can be made of fiberglass, tarpaulin, aramid or its derivatives, or another fire-resistant material. Silicone or any heat-resistant polymer with the addition of a flame retardant, the amount of which is determined according to the instructions, can be used as the material for protective layer 2. Functional layer 3 is formed on protective layer 2 by discretely applying a pre-prepared composite mixture of a polymer material with a flame retardant and microcapsules containing the fire extinguishing agent using a stencil.

Depending on the field of application of the utility model, in order to increase its fire resistance and improve protection against secondary flame spread, a material containing an additional protective layer 4 on the outside, made in a manner similar to protective layer 2, can be used as the supporting layer 1. (Fig. 2)

Depending on the field of application of the utility model, the protective layer 2 can be made on the outer side of the carrier layer 1, and the functional layer 3 can be discretely applied on the inner side of the carrier layer 1 (Fig. 3).

Any heat-resistant polymer can be used as a polymer material for functional layer 3.

Zinc borate powder can be used as a flame retardant for protective layer 2 and functional layer 3. The amount of zinc borate powder is specified during the polymer mixture manufacturing process and determined according to the instructions. Depending on the properties of the polymer used, both organic and inorganic flame retardants, including their compositions, can be used as a flame retardant. These include: organic halogen-containing flame retardants (e.g., organochlorines, organobromines), organophosphorus flame retardants, inorganic halogen-containing flame retardants (e.g., chlorides, bromides), and inorganic halogen-free flame retardants (e.g., aluminum hydroxide, magnesium hydroxide, borate compounds, antimony dioxide). The flame retardant and its concentration are selected based on a combination of factors: inhibition efficiency, compatibility with the polymer, stability during the manufacturing process, and the preservation of the mechanical, technological, adhesive, and cohesive properties of the polymer used as a polymer matrix.

Microcapsules with a liquid fire extinguishing agent, such as perfluoroketone, freon, or another heat-sensitive gas-forming agent that inhibits combustion, can be used as microcapsules with a fire extinguishing agent.

In particular, for the functional layer 3, a composite material was used having the following composition in wt.%:

silicone - 50 wt.%;

microcapsules with fire extinguishing agent - 50 wt.%;

Fire retardant - according to the instructions for silicone.

To produce the material for functional layer 3, a composite mixture is first prepared by sequentially introducing the following components with stirring until a homogeneous mass is obtained: a polymeric material in a viscous-flowing state, in particular silicone; a fire retardant, in particular zinc borate powder, in the amount according to the instructions; microcapsules with a fire extinguishing agent, in particular perfluoroketone.

Functional layer 3 is applied using a stencil with a thickness of 0.5-2 mm and a quantity of fire extinguishing agent microcapsules of 30-100 grams per 1 ^m² of sheet. Based on the specified values for the number of ^m² of sheet to be produced, the thickness of the functional layer, and the number of microcapsules, the stencil is pre-fabricated with specific parameters for the dimensions, shape of localized areas, etc.

After the functional layer 3 has hardened, the sheet is cut to the required dimensions depending on the intended use and packaged.

The device works as follows.

During extinguishing, the fire is completely covered with an active fire extinguishing blanket, with the functional layer 3 facing the fire. Due to the increased airtightness of the blanket due to the presence of a protective layer 2 on the supporting layer 1, oxygen access to the fire is blocked (Fig. 1-Fig. 3). When the activation temperature of the microcapsules containing the fire extinguishing agent is reached, which is typically 90-160°C, their thin shell is destroyed and the extinguishing agent evaporates, filling the enclosed space. With prolonged exposure to temperature, thermal destruction of the layers of the fabric begins, however, due to the presence of a fire retardant in the composite layer 3 and the protective layer 2 (Fig. 1, Fig. 3), the processes of thermal decomposition and destruction are slowed down, preventing the formation of through burns, preventing spontaneous combustion of the fabric and the spread of fire, and thereby increasing the effectiveness of fire extinguishing.

The fire retardant performs its protective function through the following mechanisms:

- formation of a non-combustible protective barrier (carbon or mineral layer) on the surface of layers with a fire retardant;

- absorption of thermal energy and slowing down the heating of the material of the layer with fire retardant to the decomposition temperature;

- the release of inert gases (for example, carbon dioxide or water vapor), blocking the access of oxygen;

- inhibition of radical reactions in flame.

The canvas is removed after the fire has been visually observed to have ceased.

The discrete design of the functional layer allows for the reduction of stress in local areas, facilitating the conditions for their relaxation, prevents the surface propagation of cracks in the layer that form under the influence of thermomechanical stresses, and increases resistance to destruction, which helps maintain the integrity of the functional layer, increasing the effectiveness of fire extinguishing.

The utility model has been tested for extinguishing model Class B fires. Test results for 0.8 x 0.8 ^m² samples of the claimed fabric are shown in Table 1. After the fabric was removed from the extinguished fire, no re-ignition was observed. Furthermore, the fire extinguishing time, even with a minimal number of microcapsules containing the extinguishing agent, does not exceed 90 seconds. No burn-throughs were detected. The entire fabric maintained its integrity and was resistant to thermal degradation, without spontaneous combustion, confirming its high extinguishing effectiveness.

Thus, the content of fire retardant in the layered structure of the utility model ensures resistance to its thermal decomposition and spontaneous combustion, and the implementation of the functional layer as discrete increases the ability of the material to resist destruction and deformation under the influence of external loads arising during the storage and operation of the utility model, ensuring resistance to mechanical loads, which in general provides additional protection against secondary flame propagation while increasing strength characteristics, increasing the efficiency of fire extinguishing of local fire sources and thereby the reliability of the device.

Claims (5)

1. A fire extinguishing sheet for active fire extinguishing, made with a layered structure and including a carrier layer made of a fire-resistant material, and a functional layer made of a polymeric material with microcapsules containing a fire extinguishing agent distributed therein, characterized in that the carrier layer additionally contains a protective layer made of a polymeric material containing a fire retardant, and the functional layer is made discrete from a polymeric material additionally containing a fire retardant. 2. A fire extinguishing sheet according to paragraph 1, characterized in that the protective layer is made on the inner side of the supporting layer, and the functional layer is made on the protective layer. 3. A fire extinguishing sheet according to paragraph 2, characterized in that the supporting layer contains an additional protective layer made on the outside. 4. A fire extinguishing sheet according to paragraph 1, characterized in that the protective layer is made on the outer side of the supporting layer, and the functional layer is made on the inner side of the supporting layer. 5. A fire extinguishing sheet according to paragraph 1, characterized in that the functional layer is made with a thickness of 0.5-2 mm and the number of microcapsules with a fire extinguishing agent is 30-100 grams per 1 ^m2 of fire extinguishing sheet.