RU2622829C1 - Method for fire fighting at ammunition storage objects and device for its implementation - Google Patents

Abstract

FIELD: fire safety.

SUBSTANCE: in the flame-extinguishing liquid supply manifold from the storage tank into its supply unit to the fire area, the unit of its heating is installed in order to obtain the superheated water. The flame-extinguishing liquid heating unit consists of the body, made of two coaxial profiled shells-cases, forming the inter-shell circular cavity, and the shells themselves can be attached to each other either by forges or by ribbed stiffener, made along the helix line. Passing through the inter-shell circular cavity, the flame-extinguishing liquid is heated by the heat of the jet of flame, created by burning the liquid or gaseous hydrocarbon fuel, supplied through a nozzle head, which is installed at the end face of the profiled shell-cases larger diameter. The oxidizer (air) is supplied into the combustion area by means of the through channels, made in the nozzle head, due to the ejection properties of the fuel combustion products.

EFFECT: by changing the channel flow sections area of the air supply into the combustion chamber, the fuel consumption, delivered to the nozzle head, the supply pressure of the flame-extinguishing liquid, the fire extinguishing process and the parameters of the superheated water-its temperature and flow rate, are controlled.

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Description

The invention relates to fire fighting equipment and can be used to extinguish fires at objects of storage and disposal of ammunition, at objects of storage of explosive materials.

In the monograph [1], it is noted that the specificity of the properties of ammunition and explosive materials requires special fire fighting equipment when organizing fire extinguishing. Differences in fire fighting tactics is determined (depends) on the method of organizing the storage of ammunition - in open areas or in rooms (warehouses). When extinguishing fires during open storage of ammunition, the use of fire monitors is effective [2, 3], which allow to obtain the maximum range of flight (battle) of a jet of extinguishing liquid. At the same time, it is recommended to use water to irrigate the source of fire [1]. In the patent of the Russian Federation for invention No. 2530424 [4] a method for extinguishing fires by a multi-fire automated fire installation is described.

The method and apparatus implementing it [4] allow to remove fire monitors as far as possible from the source of ignition and ensure uniform irrigation of the source of ignition. However, the use of a robotic system for extinguishing fires [4] has a significant drawback that reduces the efficiency of using the installation for extinguishing fires at objects of storage and disposal of ammunition in open areas. The reason is that the extinguishing of fires at such facilities, as noted in [1], uses water that enters burning objects, which are closures, usually wooden with ammunition. Getting on the corking of large fractions of water can actually be likened to a shock process, which under certain conditions can cause the detonation of ammunition and lead to an explosion. Explosive processes in ammunition will also be facilitated by the fact that when fractions of water get into the combustion zone at certain (certain) geometric sizes of the fractions, it is abruptly heated, which can also be accompanied by a kind of “shock-explosion”.

In [5], the prospects of using (application) for extinguishing fires of steam curtains and superheated water are shown. The use of superheated water and steam will be effective both in extinguishing a fire of ammunition in enclosed spaces, and in open areas - in warehouses for their storage. However, it is impossible to create a jet of steam that strikes at a long range, as required by safety requirements. Therefore, in order to eliminate these contradictions when extinguishing fires at ammunition storage and disposal facilities in open areas, it is necessary to increase the temperature of the flame-retardant liquid to a value close to the process of vaporization, which will make it possible to activate the vaporization processes directly in the irrigation center and, accordingly, significantly intensify heat removal from the flame. Thus, adding to the fire extinguishing method according to patent No. 2530424 [4] the operation of heating the flame-extinguishing liquid can significantly increase the efficiency of fire extinguishing. To implement this proposal, a fire extinguishing fluid heating unit must be introduced into the design (in the structural layout scheme) of the fire extinguishing installation.

The work [5] noted the particular effectiveness of extinguishing fires in rooms with steam or superheated water. In this case, individual fractions of the flame-retardant liquid are reduced, which increases the efficiency of extinguishing the fire. According to the patent for the invention of the Russian Federation No. 2532812 [6], it is proposed to use not deluge or sprinkler heads, but multi-nozzle heads for fine spraying of flame-extinguishing liquid, and to increase the heat sink, the flame-extinguishing liquid (water) is expelled from the fire tank with carbon dioxide. However, to organize a fire extinguishing throughout the entire volume of the premises, it is necessary to use a bunch of multi-nozzle heads, which makes the fire extinguishing system cumbersome enough. The use of multi-nozzle heads, for example, centrifugal nozzles, including from liquid-propellant rocket engines of utilized rockets with LRE [7], additionally complicates the design of the fire extinguishing system in ammunition storage warehouses or in pyrotechnic industries. The supply of the flame-extinguishing liquid in the form of steam or superheated water (as a result, a vapor curtain is still formed) allows to obtain fractions of water of the same order as when supplying the flame-extinguishing liquid through centrifugal nozzles [5], while the design is much simplified (structural and layout scheme) autonomous fire extinguishing module.

Thus, in order to increase the efficiency of fire extinguishing at the facilities for storing or disposing of ammunition, it is advisable to heat the flame-extinguishing liquid until superheated water is obtained, which makes it possible to obtain a vapor curtain in the fire source.

To implement the method of extinguishing fires with hot or superheated water, it is necessary to introduce a fire extinguishing fluid heating unit into the fire extinguishing installation. An example of such an installation may be the installation of automatic fire extinguishing with superheated water [8].

A device for extinguishing a fire with superheated water according to the patent of the Russian Federation No. 2030194 [9] can be taken as a prototype. The device according to patent No. 2030194 can be used to extinguish fires, in particular, in fire engines to extinguish fires in areas with low ambient temperature. The essence of the invention of the prototype is that an insert for heating water having a burner is connected to the hose line of the fire engine, which, by connecting to a fan connected to the internal combustion engine, allows water to be heated in the hose line to a temperature that provides not only elimination possible icing of the sleeve, but also the water supply to the fire with a temperature not lower than 120 degrees Celsius. The fire extinguishing device according to patent No. 2030194 [9] can be taken as a prototype of a device for extinguishing fires with superheated (heated) water.

However, the use of this device to extinguish fires at ammunition storage or storage facilities is ineffective, since the main purpose of heating according to the patent [9] is to use fire engines to extinguish fires in areas with low ambient temperature, as well as to heat water in a hose line to a temperature that ensures the elimination of possible icing of the sleeve. For this purpose, a special burner insert is introduced into the sleeve. The performance of such a burner will be insufficient to extinguish fires with high-temperature (superheated) water. Such a unit should not be built into the sleeve, but in the structural layout of the fire engine or fire module. Hose supply of flame-retardant liquid to the liquid ignition area significantly reduces the reliability of the fire extinguishing system. Such a unit must be installed after the discharge pump in the supply line of the flame-retardant liquid in front of the outlet nozzle, when extinguishing the fire with fire monitors or in front of the water spray unit when using superheated water.

A block diagram of such an installation is shown in FIG. 1, where the positions indicated: 1 - tank with flame-retardant liquid; 2 - node injection flame-retardant liquid in the line of its supply during the extinguishing of the flame; 3 - node heating flame-retardant liquid; 4 - node supply flame-retardant liquid to the source of ignition (nozzles); 5 - supply lines flame retardant liquid. Flame retardant fluid is supplied to the heating unit 3 under pressure. With a sufficient pressure in the mains and sufficient power of the heating unit 3, superheated water can be obtained at the outlet of the heating unit.

Thus, the heating unit should have a sufficiently large productivity, an example of such a solution, as noted above, can be a patent of the Russian Federation for invention No. 2030194. Obtaining superheated high-pressure water is carried out according to [10] by mixing the steam produced by the steam generator with water from a natural source in a special mixer, which is proposed to use a structural-layout scheme similar to the design of the rocket engine's combustion chamber.

The use of a special steam generator as a part of a fire engine or fire extinguishing module significantly complicates the heating system of a flame-extinguishing liquid, therefore a simpler design of this unit is required.

A structural and layout diagram of a flame-retardant heating unit is shown in FIG. 2. The heating unit consists of a body made in the form of two profiled shells-shirts 6 and 7 coaxially mounted relative to each other, connected to each other or by stampings, as is the case in LPRE gas generators, for example, in an 8K14 rocket [7]. The jacket shells 6 and 7 can be connected to each other by means of a rib 8 made along a helical line. The inter-neck space between the jacket shells forms a collector that is sealed from one end by a cap 9, and the other end is sealed by a cap 10, which is the bottom of the nozzle head, and together with the top of the nozzle 11, forms the collector A. At the bottom of the nozzles 12 are installed, for example centrifugal. On the housing of the heating unit, nozzles are installed near its ends, respectively, for supplying (pipe 13) and draining (pipe 16) of the heated fluid. The heating of the liquid occurs due to the calorific value of the combusted liquid hydrocarbons entering the combustion chamber formed by the internal cavity (the cavity is indicated by K) of the housing of the fluid heating unit. The fuel enters the combustion chamber through the nozzles 12, into which the fuel is supplied from the manifold A. The fuel is supplied to the manifold A through the nozzle 14 mounted on the cap 11 of the nozzle head. The supply of the oxidizing agent, which is used as air, is fed into the combustion chamber through channels 15 made in the form of pipes connecting the upper 10 and lower bottom 11 of the nozzle head. In this case, the channel cross-section can be adjusted, which allows you to change the stoichiometric ratio of fuel and oxidizer in the combustion chamber and change the calorific value of the combustion products. The heating of the liquid occurs when it passes through the screw collector of the housing of the water heating unit. The consumption of heated water (liquid) and its temperature are governed by the area of the orifice of the pipe 13, and the change in fuel (fuel) consumption. The heated fluid is supplied by a pump, not shown in FIG. 2. The ignition of the fuel is carried out by a special spark plug, which is not indicated by a separate position in FIG. 2, which is inserted into the combustion chamber to ignite the sprayed fuel, and after ignition of hydrocarbon vapors in the combustion chamber, the spark plug is removed from the combustion zone. The combustion products of the fuel are removed from the combustion chamber through the exhaust path, which is formed by the inner shell-shirt 7 and the profile of the path is associated with the surface of the combustion chamber.

A device for extinguishing fires with superheated water at the objects of storage and disposal of ammunition as follows.

By the signal from the ignition sensor, the ignition fluid pumping unit is simultaneously launched, position 2 in FIG. 1, (pump) flame-retardant liquid into the collector (stream III), formed by the shell-shirts 6 and 7 (Fig. 2); as well as a pump for supplying hydrocarbon fuel (stream I) to the manifold A of the nozzle head of the device. In this case, the spark plug is inserted into the working cavity K of the combustion chamber of the device and the fuel is ignited, for the oxidation of which air (stream II) enters the combustion chamber through channels 15. Fuel enters the combustion chamber of the device from the manifold A through nozzles 12. After ignition of the fuel, the ignition the candle is removed from the combustion zone, and the air supply to the cavity K of the combustion chamber is provided due to the ejection properties of the fuel combustion products as they pass through the exhaust tract of the device. Arriving (stream III) through the nozzle 13 into the collector formed by the shell-shirts 6 and 7, the flame-retardant liquid passing through the helical path of the collector formed by the rib 8 is heated. Since the flame-retardant liquid in the pipe 13 is supplied under pressure, at the outlet of the collector in the pipe 16 there will be superheated water, which then flows through the line 5 (Fig. 1) to the node 4 (Fig. 1) of supplying it to the source of ignition. At the outlet of the flame-extinguishing fluid supply unit to the ignition source (node 4 in Fig. 1), the extinguishing liquid (superheated high-pressure water) turns into steam, which displaces air above the ignition source, i.e. reduces the percentage of oxygen or combustible gases and vapors. In this case, there is practically no mechanical effect of the flame-extinguishing liquid on burning surfaces, for example, capping of ammunition. In the case of using a preparation device superheated water to extinguish a fire with a stream of flame-retardant liquid, using fire monitors, by reducing the fuel supply to the collector A (Fig. 2), the flame-retardant liquid is heated to a temperature close to 100 ° C. In this case, a jet of hot flame-retardant liquid having fallen on the ignition site is quickly converted to steam and the intensity of the mechanical effect of the flame-retardant liquid on burning surfaces is reduced, and the risk of a fire moving at the objects of storage and disposal of ammunition in the phase of their explosion is reduced.

List of works taken into account

1. Fire tactics. Part II Extinguishing fires at the facilities of the national economy / A.M. Garpinchenko, N.M. Evtyushkin, I.F. Kimstach. Edited by I.F. Kimstach. - M.: From the literature on construction, 1971. - 285 p.

2. GOST 51115. Fire fighting equipment. Fire monitors combined. General technical requirements. Test methods.

3. WWW. Cleper.ru/normative-documents/etc/primenenie-stacionarnyh-pozharnyh-lofetnyh-ostcilliruishego-tipa/

4. RF patent for the invention No. 2530424. IPC A62C 37/00. Fire extinguishing method and device for its implementation / N.P. Kuznetsov, A.N. Burawov, I.B. Akhmadullin, E.V. Bukhtulova. - Publ. 10/10/2014. Bull. No. 28.

5. Sasin G.G. A new paradigm of effective fire fighting with superheated water in the housing stock and administrative buildings of the capital with minimization of damage from the action of water / G.G. Sasin, Yu.A. Kozlov, V.V. Roenko, V.A. Gingerbread men. - http://gigabasa.ru/doc/23729.html - [Appeal 08/31/2015].

6. RF patent for the invention No. 2532812. IPC A62C 31/02; B05B 1/14. Fire extinguishing method and device for its implementation / A.N. Burawov, E.V. Bukhtulova, N.P. Kuznetsov. - Publ. 11/10/2014. Bull. No. 31.

7. Kuznetsov N.P. Utilization of rockets with liquid propellant rocket engines (using the example of the 8K14 missile) / N.P. Kuznetsov, M.G. Kurguzkin, V.A. Nikolaev. - Moscow-Izhevsk: Research Center “Regular and chaotic dynamics”, 2004. - 288 p.

8. Installation of automatic fire extinguishing with superheated water. - http://www.firestop.by/catalogue/stronbox/ - [Appeal 08/31/2015].

9. RF patent for the invention No. 2030194. Device for extinguishing a fire with superheated water / V.V. Roenko and [dr]. - IPC A62C 33/00. Patent publication 03/10/1995.

10. RF patent for the invention No. 2213293. Installation for producing high-pressure superheated water. / E.I. Praying, O.Yu. Kazantsev, N.P. Kuznetsov. IPC F22B 33/18. Publ. 09/27/2003. Bull. Number 27.

Claims (1)

A device for extinguishing a fire with superheated water, consisting of a line connected to a source of flame-retardant liquid, having a node for supplying it under pressure to the ignition center and a built-in node with a burner for heating the flame-extinguishing liquid supplied to the source of ignition, characterized in that the heating unit consists of a housing made of two coaxially located profiled shells-shirts, and the inter-cup space between them is muffled at the ends of the shells-shirts and is the collector through which heating, a flame-retardant liquid, and a burner with a multi-nozzle head is used for heating, through the nozzles of which hydrocarbon fuel is fed into the cavity formed by the inner shell-jacket, and the oxidant is the air entering the combustion zone due to the ejection properties of the fuel combustion products through the through holes made in the body of the nozzle head, and the passage area of the air supply openings is adjustable, which allows you to control the temperature of superheated water, and to start the mountain It is equipped with a spark plug, which is removed from the combustion zone after starting the burner.

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