RU2096053C1 - Method of fire fighting in storage tanks and device for its embodiment - Google Patents

Abstract

FIELD: fire-fighting technique. SUBSTANCE: the offered method includes burning of solid-fuel composition and supply of gas mixture to hot surface in cold state. Cooling is carried out in two stages. At the first stage, mixture is subjected to preliminary cooling to temperature below temperature of thermal decomposition of liquid found in storage tank and supplied from below upward. The device for embodiment of the offered method has generator with chamber for burning of solid fuel composition and means for preliminary cooling of gas-aerosol mixture made in form of, for instance, vessels with heat lock located on the path of mixture flow. Generator is connected with storage tank by pipeline whose inlet is located in lower part of storage tank and provided with nozzle. EFFECT: higher efficiency. 2 cl, 2 dwg

Description

 The invention relates to fire fighting equipment and is designed to extinguish fires using a gas-aerosol mixture in open and closed tanks with flammable and combustible liquids.

 A known method of extinguishing a fire by forming a gas-aerosol mixture (GAS) during the combustion of a solid fuel composition (TTK) and supplying the mixture to a combustion site.

 The known method is very effective, but has a significant drawback, namely, that the aerosol generated during the combustion of the TTK and having a temperature of about 1500 K tends to rise and begins to cover the burning surface only as it cools and drops down. In this case, the creation of a fire extinguishing medium and the extinguishing effect is achieved only when it is possible to keep the gas extinguishing near a burning surface, i.e. only if there is a roof in the tank without large openings.

 A known method and device for extinguishing a fire using a cooled aerosol, which are the closest in technical essence and the achieved result (prototypes) to this invention.

 The known method (prototype) consists in the formation of a gas-emitting agent during the combustion of the TTK and supplying the mixture to the burning surface in a cooled state. The cooling of the gas is carried out by mixing the aerosol stream with a coolant using an ejector device.

 The known device (prototype), with which this method is carried out, contains a generator located outside the tank with a TTK combustion chamber, connected to the tank by means of a pipeline, and an ejector, through which the cooler is supplied to the GAS.

 The main disadvantage of the prototypes is that they can only be used to extinguish fires in closed tanks, i.e. in tanks equipped with a roof without large openings. In the case of open tanks, tanks with a floating roof, or when the roof of a tank is dumped at the time of a fire, fire fighting can be difficult, because A gas supply to the upper part of the tank in a space free of liquid (between the roof and the surface of the liquid) provides the quenching effect only as the free space of the tank is filled according to the scheme from top to bottom, i.e. from the roof to the combustion surface.

 In the event that the free space of the tank is significant in volume, the beginning of the fire extinguishing is delayed by the time required to fill the entire volume, and the flow rate of the TTK will be overestimated by the amount necessary for the formation of the GAS required to fill the free space.

 In addition, the cooling of the GAS stream using an ejector does not provide a sufficient degree of cooling of the aerosol and does not exclude the appearance of a flame force at the initial and final moments of the combustion of the TTS. The latter makes it impossible to use prototypes to protect tanks filled with liquids capable of forming explosive mixtures in the free space of the tank.

 The invention is aimed at providing fire extinguishing with the help of GAS in both closed and open tanks with flammable and combustible liquids.

 The problem is solved due to the fact that in the method of extinguishing a fire in tanks with flammable and combustible liquids by forming a HAS during the combustion of the fuel transformer and supplying the HAS to the burning surface in a cooled state, according to the invention and in contrast to the prototype, the HAS is cooled in two stages. At the first stage, the GAS is subjected to preliminary cooling to the temperature of thermal decomposition of the liquid. The second cooling stage is combined with the supply of gas to the burning surface, passing the gas through a layer of liquid in the tank from the bottom up.

 A device for extinguishing a fire in tanks with flammable and combustible liquids, designed to implement the proposed method and containing a generator located outside the tank with a combustion chamber TTK, connected to the tank using a pipeline, according to the invention and, unlike the prototype, is equipped with means for pre-cooling of the gas station on the path of the flow of the mixture, and the input of the pipeline into the tank is located in the lower part of the tank and is equipped with a nozzle inside the tank and sleeves made of elastic material with the ability to flattening under the influence of fluid pressure in a reservoir.

 The nozzle from the sleeve, flattened in the idle mode (in standby mode), forms a shutter that cuts off the liquid from the combustion chamber and opens in the operating mode under the influence of the pressure of the gas flow. Providing the device with means for pre-cooling the gas in combination with the said nozzle allows the claimed method to be carried out by supplying the gas to the lower layers of the liquid.

 The invention is illustrated by drawings, which depict: in Fig.1 a General view of the device; figure 2 generator.

 A device for extinguishing a fire in a tank 1 consists of a generator 2, which is a combustion chamber 3 with charges 4 TTK. The chamber 3 is equipped with a TTK charge ignition unit 5 and containers 6 with a powder or liquid cooler. The generator 2 is connected to the tank 1 by a pipeline 7. Tanks 6 can be installed outside the housing of the generator on the pipe 7, which can be advisable when placing the generator at some distance from the tank. In any case, containers 6 are placed on the path of the gas flow with such a design so as to ensure that the cooler flows into the gas flow by gravity under the influence of gravity through the outlet 8. In idle mode (in standby mode), the openings 8 are closed by thermal locks 9, for example, plastic film. Holes 8 are shaped nozzles that provide the desired flow rate of the cooler. As containers, polyethylene bags can be used, in which case the latter serve as thermal locks.

 The tank 1 can be closed type (with a roof) or open type, for example, with a floating roof (as shown in figure 1).

 The generator 2 is attached to the lower part of the tank 2 by means of a flange connection 10. At the end of the pipeline 7, which enters the inside of the tank, a nozzle 11 is put on in the form of a sleeve made of an elastic material. The elasticity of the sleeve is such that in standby mode the sleeve under the influence of fluid pressure in the tank is in a flattened state and forms a shutter that prevents the penetration of fluid into the generator. When the generator is turned on and the HAS flow is generated under pressure, the sleeve melts, tearing the HAS passage into the tank.

 The method is implemented as follows: in the event of a fire, the TTK ignition unit 5 is turned on manually or automatically in the generator 2. The GAS generated during the combustion of the TTK is sent through pipeline 7 to the tank 1.

 On the way to the reservoir, the HAS is subjected to pre-cooling by supplying a cooler from the tanks 6.

Thanks to the preliminary cooling, the aerosol temperature is reduced to a temperature below the thermal decomposition temperature of the organic liquid in the tank 1 (for example, to 200-300 ^o C). Next, the GAS is passed through the liquid layers in the tank in the direction from the bottom up, for which the GAS is introduced into the lower liquid layers through the nozzle 11. The GAS, which has a much lower density than the liquid stored in the tank, floats (sparges) through the liquid layer to its surface. In this case, the gas system is cooled to such an extent that, having reached the upper level of the liquid, most of it remains near the surface, creating a gaseous medium above the liquid surface that does not support combustion.

 Conducting the cooling of the gas station in two stages, carried out sequentially, but separately (independently) from each other, eliminates the influence of the TTC on the dynamics of the gas flow (speed, pressure), which ensures controllability of the combustion processes.

 At the first stage, the cooling of the gas system eliminates the thermal decomposition of the liquid stored in the tank and does not impair its properties during the fire extinguishing.

 Passing the HAS through the liquid layer from the bottom up provides the final cooling of the HAS to a temperature at which it, having reached the surface of the liquid, remains on it, covering the surface with a cooled fire extinguishing cloud. This makes it possible to use the method to extinguish a fire not only in tanks with a roof, but also in tanks whose roof has large openings, or it can be discharged during a fire, as a result of which the liquid causes the lower layers of the liquid to mix with the upper hot layers, which increases the efficiency of fire fighting.

A device that allows this method of extinguishing a fire works as follows:
in the event of a fire, thanks to the ignition unit of charges 5, the TTK charges 4 are ignited, which burn with the formation of a large amount of gas. The GAS rushes through the pipeline 7 to the tank 1. At the same time, due to the high temperature of the GAS, thermal locks 9 are instantly opened and from the tanks 6 a metered amount of liquid (water, aqueous solution of mineral salts) or powder cooler enters the GAS stream under the influence of gravity. The HAS, falling into the nozzle 11, opens a flexible sleeve, which becomes a continuation of the pipeline 2. Through the sleeve, the pre-cooled HAS enters the lower part of the tank 1. By sparging through the liquid, the HAS finally cools and enters the flame zone, providing suppression of flame combustion at a certain flow rate. At the same time, optimal fire fighting conditions are provided, as Gas without loss enters directly into the combustion zone. Moreover, unlike other methods, the quenching effect is achieved when the gas flow rate is much less and does not depend on the size of the free space in the tank.

 Example.

The proposed method and device were tested on an open reservoir model with a volume of 1.5 m ³ and a cross section of 1 m ² . As fuel, gasoline and acetone were tested, flooded to half of the tank. In both cases, the quenching was achieved by a TTK-2 charge weighing 0.2 kg, i.e. with a specific flow rate relative to the burning surface of 0.2 kg / m ² .

The main advantages of the proposed method and device are:
the ability to extinguish a fire both in closed and open (without roof) tanks;
Minimal, independent of the volume of free space of the tank, gas consumption required for extinguishing;
lack of damage to the product stored in the tank;
simplicity and ease of use.

Claims (2)

 1. The method of extinguishing a fire in tanks with flammable and combustible liquids by forming a gas-aerosol mixture when burning a solid fuel composition and feeding the mixture to a burning surface in a cooled state, characterized in that the gas-aerosol mixture is cooled in two stages, at the first stage the mixture is pre-cooled to temperature of thermal decomposition of the liquid, and the second stage of cooling is combined with the supply of the mixture to the burning surface, passing the mixture through a layer of liquid located in the tank from the bottom up.  2. A device for extinguishing a fire in tanks with flammable and combustible liquids, containing a generator located outside the tank with a combustion chamber of a solid fuel composition, connected to the tank by a pipeline, characterized in that the device is equipped with means for preliminary cooling of the gas-aerosol mixture placed on the path of the mixture flow and the pipeline entry into the tank is located in the lower part of the tank and is equipped with a nozzle from the sleeve made of el mastic material with the possibility of flattening under the action of pressure of the liquid in the tank.

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