RU144062U1 - AUTONOMOUS FIRE EXTINGUISHING MEANS - Google Patents

Abstract

1. An autonomous fire extinguishing agent, which is a long product, characterized in that it is made in the form of a flexible fire extinguishing cord with a diameter of 3-50 mm from an elastic material consisting of fuel, a catalyst, a combustion inhibitor, an elastic polymer binder and an oxidizing agent. 2. The tool according to claim 1, characterized in that the flexible cord is reinforced with natural or synthetic, or mineral fibers. The tool according to claim 1, characterized in that the flexible cord is reinforced with basalt or carbon fibers. The tool according to claim 1, characterized in that the flexible fire extinguishing cord is reinforced with cotton or paper fiber. The tool according to claim 1, characterized in that the flexible fire extinguishing cord is reinforced with polyester fibers. The tool according to claim 1, characterized in that the fire extinguishing cord is outside coated with a polymer layer in the form of a tape or tube. The tool according to claim 1, characterized in that an initiator is applied on its surface, ignited at a temperature of from 80 to 200 ° C. The tool according to claim 1, characterized in that it contains an additional ignition initiator based on an electric heating element. The tool according to claim 1, characterized in that it contains an additional initiator of ignition, made in the form of a thermal cord. The tool according to claim 1, characterized in that the oxidizing agent is sodium nitrate or perchlorate, or potassium, or ammonium, or calcium, or a mixture thereof. The tool according to claim 1, characterized in that the fuel used is phenol-formaldehyde resin or beckons, or sorbitol, or cellulose, or cellulose nitrates. The tool according to claim 1, characterized in that as a catalyst use salts or oxides of iron or calcium, and�

Description

The utility model relates to the field of volumetric fire extinguishing, in particular to means of volumetric fire extinguishing, designed to localize and extinguish fires of enclosed electrical equipment (power, high-voltage and switching equipment, industrial and consumer electronics, etc.), as well as fires of class A fire (wood , insulating materials, plastics, etc.) flammable and combustible liquid (gasoline and other petroleum products, organic solvents, etc.).

Aerosol fire extinguishing installations have long been known and are widely used for the elimination of ignitions of liquid and solid substances, as well as electrical equipment. The vast majority of aerosol extinguishing agents have the following, “classic” design: the aerosol forming composition in the form of a solid washer is placed in a housing made, as a rule, of metal; a trigger device (a miniature electric heater, the so-called electric igniter), or the end of a fire-conduit cord for transmitting a fire pulse is connected to the aerosol-forming composition; the housing has one or more openings for the exit of the extinguishing aerosol. In most aerosol products, the design also includes an aerosol cooler block - granules consisting of magnesium and aluminum hydroxides. The well-known fire extinguishing agent (RU 107699 from 08.27.11), designed for volume extinguishing fires in enclosed and semi-enclosed volumes of a protected facility (production facilities, warehouses, vehicle compartments, etc.), mainly for inaccessible places and volumes of complex configuration, represents a fire extinguishing aerosol generator, including a cylindrical body with exhaust openings on the side surface and closed ends, a combustion chamber, a launch device, a cooling chamber with granular heat absorption element, an aerosol-forming charge installed in a metal casing with perforation, coaxial to the casing, the casing is fixed inside the casing by means of longitudinal ribs made along the entire length of the casing and dividing its internal volume into the combustion chamber and cooling chamber, and perforation is performed only on the surface of the casing in contact with the combustion chamber, and on the longitudinal ribs, and the exhaust openings are made on the surface of the cylindrical body in contact with the cooling chamber, with their distribution only along the generatrix Indra and to provide a radial segment aerosol release.

Known fire extinguishing agent when used provides:

- the optimal intensity of the aerosol supply and a decrease in the concentration of products of incomplete combustion due to an increase in the time they remain in the gas phase;

- increase the fire extinguishing ability and uniformity of the aerosol output without increasing the temperature of the aerosol jet;

- the completeness of combustion of the aerosol forming charge with increasing intensity of gas evolution.

The whole aerosol-forming composition is concentrated in one place of the protected volume, and the task of its launch is solved either by electric or fire pulse. However, for the electric start of such a tool, the remaining elements of the start-up system are required: a power source, a heat-sensitive element, for example, a heat fire detector, fire-resistant connecting wires for an autonomous system, or an entire control unit with arming / disarming, self-diagnostics, manual start and system operation indication - in case of an automatic fire extinguishing system.

The use of a fire-resistant cord to launch aerosol fire extinguishing modules is limited by their lower reliability due to the low resistance of the cord to mechanical and vibration loads, moisture, vapors and aerosols of hydrocarbons. In addition, a fire-retardant cord, as a rule, has a burning speed of 5-10 mm / s, which limits the actual maximum cord length to 20-30 cm to provide an acceptable delay time for starting the fire extinguishing device from the start of a fire. Thus, the use of a flame-retardant cord is ineffective in the case of protecting large objects, as well as for protecting extended objects such as a cable channel (collector), space under a raised floor or suspended ceiling.

Known low-temperature aerosol extinguishing compositions that do not require a unit for additional cooling of the extinguishing aerosol. For example, RF patent No. 2455043 dated 02.11.2010. The low-temperature flameless aerosol-forming extinguishing composition includes potassium nitrate and cellulose-fibrous mass, characterized in that it contains starch and starch paste as a combustible binder, and calcium nitrate as a combustion modifier, in the following ratio, wt.%: Potassium nitrate - 30 ... 70; calcium nitrate - 5 ... 35; cellulose-fibrous mass - 5 ... 35, starch paste - 5 ... 25, starch - 5 ... 25. The technical result is the creation of a composition in which the combustible binder has a low heat of combustion and a relatively high oxygen content in the molecular unit, which allows the combustion of the composition to be switched to a low-temperature flameless mode while maintaining acceptable performance for fire extinguishing efficiency and the content of carbon monoxide. Also, the technical result achieved by the method is the expansion of methods for further processing the mass of the aerosol forming composition through the use of starch paste.

However, in the described composition, starch and paste, known as “hard” binders, are used as a binder, which does not provide sufficient flexibility and elasticity of the material obtained, and thus they can only be used as fire extinguishing agents in the form of “tablet” or “washer”, which require individual means of initiation in case of fire. The use of calcium nitrate as a combustion modifier does not allow reaching combustion rates of more than 3.3 mm / s, which is insufficient to create a long-form fire extinguishing agent.

Known aerosol generating composition that allows you to form rods from it by extrusion (RF patent No. 2214848 from 07.24.2002). The composition contains potassium nitrate, carbon black, cellulose, or wood flour, or mixtures thereof and a binder is a copolymer of vinyl acetate with ethylene and iditol. The ratio of components, wt.%: Copolymer of vinyl acetate with ethylene 6-10; iditol 1-9; cellulose, or wood flour, or mixtures thereof 9-14; carbon black 2-10; potassium nitrate - the rest. The composition provides an extension of the operating temperature range, lowering the combustion temperature while maintaining the fire extinguishing ability and the amount of toxic products released.

However, the combustion temperature of this composition reaches 1415-1523 ° C, which obviously can be a source of secondary ignition and requires the use of a housing and a cooler block. Moreover, the burning rate of the specified composition is from 1.8 to 3.4 mm / s, which is enough for the product to work in the form of a “washer” or “checker” and clearly not enough to create a fire extinguishing agent in the form of a long product.

As a prototype, the utility model RU 134796 of 06/26/2013 was selected. A fire extinguishing aerosol or fire extinguishing gas generator containing a charge of an aerosol forming or gas generating fire extinguishing composition that is placed in a refractory body, with a layer of a microencapsulated fire extinguishing agent applied to at least one outer or inner surface of the body.

The technical solution of the prototype is aimed at increasing the efficiency of extinguishing and, thereby, expanding the scope of application of the extinguishing aerosol generator or extinguishing gas in fire fighting.

In fact, the prototype describes a fire extinguishing aerosol generator in a hull design using microencapsulated fire extinguishing agents deposited on a casing for combined gas-aerosol extinguishing. However, such a "point" design of GOA does not allow uniformly covering a large and especially extended object, for example, a cable channel; its effectiveness directly depends on the location and distance to the source of ignition.

The technical result of the utility model is to provide effective protection of large volumes and extended objects such as a cable channel (collector), spaces under a raised floor or suspended ceiling from fire.

The technical result is achieved in that the volumetric fire extinguishing agent is a lengthy product, characterized in that it is made in the form of a flexible fire extinguishing cord with a diameter of 3-50 mm from an elastic material consisting of fuel, a catalyst, a combustion inhibitor, an elastic polymer binder and an oxidizing agent

This type of performance of the volumetric fire extinguishing means - in the form of a long elastic cord with a diameter of 3 to 50 mm - is fundamentally different from the known means, and in particular from the prototype, and gives the following advantages when implementing:

- the ability to distribute funds throughout the protected volume, regardless of its geometry, configuration, and fullness of electrical components;

- the ability to install the tool in the protected object directly near the most fire hazardous places, and the number of such places, in fact, is limited only by a long tool;

- the minimum time interval from the start of the fire to the start of the extinguishing agent and the supply of the extinguishing mixture;

- the supply of the fire extinguishing mixture occurs at the starting point of the product, i.e. directly to the burning area;

- virtually unlimited length of protected cable channels;

- high reliability due to the minimum of structural and connecting parts;

- the possibility of using in standalone mode, which does not require power supply;

- complete inertness to electromagnetic interference and interference in an autonomous embodiment;

- general simplicity and manufacturability of the manufacture of the tool;

- the implementation of the tool does not require the use of cooler blocks, batteries, and individual start modules.

The listed advantages of the proposed utility model ensure the achievement of the specified technical result - effective protection of large volumes and extended objects from fire.

A cord diameter of 3-50 mm plays a key role and is a balance between the mechanical properties of the product (primarily flexibility), the burning rate, the developed temperature and the volume of the space to be protected. When reducing the diameter of the cord to less than 3 mm, it becomes not strong enough, the burning rate drops below 2 mm / s, which is not enough to effectively extinguish the fire. When the diameter of the cord is increased to more than 50 mm, it becomes not flexible enough, the combustion temperature rises above 1000 ° C, and flame burning appears.

Thus, the form of execution and the external dimensions of the tool are critical to ensure its effective operation, which characterizes the tool as a device. At the same time, the material of the agent, being used in a different form, for example, when placed in the case, when activated, has a flaming character of combustion, develops a high temperature (more than 1000 ° C), releases hot slag and, therefore, is not an effective means extinguishing. Thus, the material of the product is not an independent type of product.

The combination of the components of the material of the agent makes it possible to obtain a self-contained enclosure in the form of an elastic cord that does not require coolers, batteries and individual start-up models, as well as the flexibility necessary to place the cord in accordance with the configuration of the protected volume.

The proposed means of volumetric fire extinguishing can be implemented with a different ratio of fuel, catalyst, combustion inhibitor, elastic polymer binder and oxidizing agent, which is determined by the specific use of the agent, the selected thickness, dimensions of the volume to be protected, etc. However, the following ratio was found to be the best ratio as a result of the experiments, wt.%: Fuel - 0.5-20, catalyst 0.1-20, combustion inhibitor 0.1-30, polymer binder 5-50, oxidizing agent - the rest.

To give additional mechanical strength, the proposed tool can be reinforced or coated (braided) with natural or synthetic or mineral fibers. For reinforcing, basalt, carbon, cotton, paper, polyester and other mineral or synthetic fibers can be used. The fibers are introduced into the composition before forming from it or applied to the formed cord in the form of a braid

Also, to give additional strength and resistance to water, a protective polymer layer can be applied to the surface of the proposed agent, the polymer can be either in the form of a tube or in the form of a tape. As the polymer, any low-melting polymer, for example, polyethylene, can be used.

To start the fire extinguishing means, a separate start-up unit is not required: the means can work due to self-ignition of the aerosol forming composition at an ambient temperature above 200 ° C.

However, to increase the functionality of the product, a thin layer of a substance initiating the ignition of the composition, which ignites at ambient temperature from 80 to 200 ° C, can be additionally applied to its surface. The initiator can be applied to the entire area of the product, or to part of it, for example, rings or a strip. The ignition temperature of the initiator depends on its chemical composition and can vary within the necessary limits.

It is also possible to use traditional initiators: a cord or an initiator based on an electric heating element, in which case the tool can be used as an automatic fire extinguishing system.

Sodium nitrate or perchlorate, or potassium, or ammonium, or calcium, or a mixture thereof can be used as an oxidizing agent.

As fuel, cellulose nitrates or phenol-formaldehyde resin, or beckons, or sorbitol, or cellulose can be used.

As a catalyst, salts or oxides of iron, or calcium, or copper, or lead, or chromium, or mixtures thereof can be used.

The use of a combustion catalyst allowed to increase the burning rate of the agent up to 10-20 mm / s, as well as to achieve its uniformity and stability, which is important for guaranteed extinguishing of the fire source.

Urea or dicyandiamine, or guanidine, or ammonium phosphates, or ammonium chloride can be used as a combustion inhibitor. Thanks to the use of a combustion inhibitor in the composition, it was possible to lower the combustion temperature to 450-500 ° C in the absence of flame and maintaining the burning rate of 10-20 mm / sec.

Polyhalogenated hydrocarbons may also be used as combustion inhibitors. When the agent is triggered, evaporation (sublimation) of the combustion phlegmatizers occurs, as a result of which the phlegmatizers in the gas phase additionally enhance the fire extinguishing effectiveness of the agent. A wide range of substances can be used as phlegmatizers: polyhalogenated hydrocarbons, polyhalogenated amines, polyhalogenated ketones, metal compounds of variable valency.

The use of low boiling liquid combustion inhibitors in microencapsulated form in the proposed tool is effective. In this case, microcapsules with an inhibitor ranging in size from 1 to 200 μm can be distributed both on the surface of the product in the form of a coating and throughout the volume of the product. Due to the rather high temperature of the product, the material of the shells of the microcapsules does not matter, it can be any known polymer: polyurea, polyurethane, gelatin, etc.

As the elastic polymer binder, any known elastomer can be used, preferably acrylic or vinyl resins, or an ethylene vinyl acetate copolymer, or nitrile butadiene, or silicone, or isoprene rubber, or polyvinyl acetate, or polyurethane.

Implementation of the proposed fire extinguishing agent is possible as follows.

A polymer binder, finely ground combustion phlegmatizer, oxidizing agent, fuel and catalyst are sequentially loaded into a standard mixer, the mixture is mixed until uniform. Cords with a diameter of 3-30 mm are molded from the resulting mixture by extrusion at a temperature of +20 to + 150 ° C, which are then aged at a temperature of +20 to + 80 ° C from 1 to 24 hours for the final polymerization. An initiator layer is applied to the product; finished products are coated with a protective polymer layer by winding or spraying.

The tool can be used to ensure fire safety in almost any cabinet electrical equipment by laying it near the most energy-loaded and fire hazardous elements. To protect cable channels, the tool is laid along power cables. To protect raised floors and false ceilings, the product is laid evenly over their area, mainly near the wiring. The tool can be fixed in any known manner, both to the body of the protected object, and directly to electrical components, wires and cables.

The optimal amount of the proposed product depends on the volume and tightness coefficient of the space to be protected and is calculated according to the well-known formula for aerosol fire extinguishers:

M = K × E × V, where:

M is the mass of the extinguishing agent, in kg,

K is the tightness coefficient (K of the closed volume is 1),

E - extinguishing efficiency, kg / m ^3,

V is the volume of the protected space, in m ³ .

The proposed tool works as follows. If a fire occurs in the protected object in the place of the highest temperature, the proposed product is initiated (launched). As a result of the low-temperature combustion of the extinguishing cord, the protected object is filled with extinguishing gases and aerosols, and filling begins directly from the ignition site, which is especially effective for extinguishing long cable channels, collectors and raised floors. As a result of the release of extinguishing gases and aerosols, the fire is extinguished.

The proposed fire extinguishing agent can be successfully used to protect objects located in airtight or conditionally airtight spaces from fire.

Due to its solidity and virtually complete absence of compounds in the proposed tool, as well as its flexibility, high mechanical strength and resistance to moisture, it can be effectively used to protect electrical equipment in automobile, rail and sea transport.

The application of the system does not require changes in the design documentation of protected objects, special qualifications of personnel, maintenance and does not harm the environment.

The shelf life of the proposed product is ten years or more.

The tool has been successfully tested on electrical switchboards with a volume of 50 to 1000 l, in cable channels up to 100 m long, in a space under a raised floor with an area of up to 200 m ² .

Claims (18)

1. Self-contained fire extinguishing agent, which is a long product, characterized in that it is made in the form of a flexible fire extinguishing cord with a diameter of 3-50 mm from an elastic material consisting of fuel, a catalyst, a combustion inhibitor, an elastic polymer binder and an oxidizing agent. 2. The tool according to claim 1, characterized in that the flexible cord is reinforced with natural or synthetic, or mineral fibers. 3. The tool according to claim 1, characterized in that the flexible cord is reinforced with basalt or carbon fibers. 4. The tool according to claim 1, characterized in that the flexible fire extinguishing cord is reinforced with cotton or paper fiber. 5. The tool according to claim 1, characterized in that the flexible fire extinguishing cord is reinforced with polyester fibers. 6. The tool according to claim 1, characterized in that the fire extinguishing cord is externally coated with a polymer layer in the form of a tape or tube. 7. The tool according to claim 1, characterized in that the initiator is applied on its surface, ignited at a temperature of from 80 to 200 ° C. 8. The tool according to claim 1, characterized in that it contains an additional ignition initiator based on an electric heating element. 9. The tool according to claim 1, characterized in that it contains an additional initiator of ignition, made in the form of a thermal cord. 10. The tool according to claim 1, characterized in that the oxidizing agent is sodium nitrate or perchlorate, or potassium, or ammonium, or calcium, or a mixture thereof. 11. The tool according to claim 1, characterized in that the fuel used is phenol-formaldehyde resin or beckons, or sorbitol, or cellulose, or cellulose nitrates. 12. The tool according to claim 1, characterized in that the catalyst is used salts or oxides of iron, or calcium, or copper, or lead, or chromium, or a mixture thereof. 13. The tool according to claim 1, characterized in that the elastic polymer binder uses acrylic or vinyl resins, or an ethylene-vinyl acetate copolymer, or nitrile butadiene, or isoprene, or silicone rubber, or polyvinyl acetate, or polyurethane. 14. The tool according to claim 1, characterized in that urea or dicyandiamine or guanidine or ammonium phosphate or ammonium chloride or mixtures thereof are used as combustion inhibitors. 15. The tool according to claim 1, characterized in that polyhalogenated hydrocarbons are used as combustion inhibitors. 16. The tool according to claim 1, characterized in that the combustion inhibitors are made in the form of microcapsules with a polymer shell. 17. The tool according to clause 16, wherein the microencapsulated combustion inhibitors are distributed throughout the volume of the extinguishing agent. 18. The tool according to clause 16, wherein the microencapsulated combustion inhibitors are distributed over the surface of the fire extinguishing agent in the form of a coating.