RU2030192C1 - Method of fire extinguishing in non-tight room - Google Patents

Abstract

FIELD: fire defence. SUBSTANCE: at first maximum content of oxygen, at which burning of all combustible materials in room ceases, is calculated, and summary area of all apertures in room is measured. Fire extinguishing material is delivered into room by pneumoacoustic method. Fire fighting time is directly proportional to difference in initial and maximum content of oxygen and summary area of room apertures and reversely proportional to room volume and amount of fire extinguishing material with preset dispersity of liquid phase. EFFECT: enhanced reliability of fire fighting.

Description

 The invention relates to fire fighting equipment, more specifically, to methods for eliminating a fire in an unpressurized room, and can be used to extinguish fires of various industrial equipment, book depositories, cable highways and other objects.

A known method of fire extinguishing in an airtight compartment, which consists in supplying finely atomized water in a nitrogen stream to an airtight compartment, and for 1 m ^{3 of} protected volume the nitrogen flow rate is 20-200 l / min and the water flow rate is 0.3-0.6 l / min . In this case, nitrogen is supplied under a pressure of 1.0 MPa, and water under a pressure of 3.0 MPa.

 In the process of extinguishing a fire, a nitrogen-water finely dispersed aerosol is formed, which reduces the heat capacity of the medium to a value of 170-210 kJ per mole of oxygen, at which combustion stops.

The specified range of nitrogen and water consumption allows you to eliminate the fire in a time that does not fully meet the requirements for the time of extinguishing fires. So, in a sealed compartment with a volume of 1.0 m ^3, burning of small foci does not lead to a noticeable heating of the gas medium, i.e. its temperature remains virtually unchanged. Under these conditions, the process of vaporization from the surface of water particles plays a secondary role in the dynamics of the quenching of the flame, and nitrogen plays the main role.

 It is known that for polymethylmethacrylate, one of the flammable substances widely used in industrial facilities, the oxygen limit for combustion is 15% by volume.

If the oxygen content in the sealed compartment with a volume of 1 m ³ until the ignition of polymethylmethacryl is 20.7%, then when nitrogen is supplied with a specific flow rate of 20 l / s, the oxygen limit for combustion will be reached after 20 minutes, which is unacceptable in practice.

 In addition, significantly limits the scope of the method, the condition of the tightness of the protected object. In the process of extinguishing, excessive pressure is created, which can lead to the destruction of light thin-walled structures.

 In sealed rooms with sufficient wall strength and a large amount of combustible material, the effect of self-extinguishing inevitably occurs.

 There is also known a method of extinguishing a fire in an unpressurized room containing combustible materials, which consists in supplying an extinguishing agent in the form of a gas-liquid medium to an unpressurized room having openings and characterized by an initial oxygen content.

 In the known method, a separate supply of a gaseous, liquid or solid phase of a fire extinguishing substance is provided, which is carbon dioxide, and the supply of a solid or liquid phase is carried out directly on locally heated technological surfaces contained in an unpressurized room.

 Upon reaching the extinguishing concentration in the volume, which leads to a decrease in the oxygen content, they proceed to the second stage of extinguishing: they make up for the leaks of the extinguishing agent through the openings by means of a jet supply of a gaseous extinguishing substance to heated technological surfaces.

 The known method of extinguishing a fire in practice seems to be a rather complicated technical task, since it is assumed that the gaseous, liquid or solid phase of the extinguishing agent is supplied separately.

 The directed supply of the liquid or solid phase of the extinguishing agent and the additional supply of the gaseous extinguishing agent to the pre-selected heated technological surfaces do not always achieve the goal, since during the fire any other surfaces, for example, due to spreading of the burning liquid, may become overheated.

 In such conditions, the effectiveness of the known method is reduced, since to reduce the temperature in the leaky room and achieve the maximum oxygen content for combustible materials in the room, a large consumption of extinguishing agent is required, leading to an increase in the content of carbon dioxide in the room, which negatively affects the condition of the staff located indoors.

 In addition, in non-pressurized rooms, new oxygen flows are possible, leading to repeated foci of ignition, which in turn requires even greater consumption of extinguishing agent.

 Along with this, it should be noted that when extinguishing a fire by a known method, the penetrating ability of the extinguishing agent is not high enough, which is due to the particle size of the liquid or solid phase of the extinguishing agent.

 The basis of the invention is the task of developing a method of extinguishing a fire in an unpressurized room, in which such a supply of extinguishing agent would be carried out, in which its consumption would be reduced, and such factors would be determined that taking into account would increase the efficiency of extinguishing the fire.

 The problem is solved in that in a method of eliminating a fire in an unpressurized room containing combustible materials, namely, in an unpressurized room having openings and characterized by an initial oxygen content, an extinguishing agent in the form of a gas-liquid medium is supplied, the extinguishing agent is supplied by a pneumoacoustic method, providing gas-liquid with a given dispersion of particles of the liquid phase, while the limit oxygen content is preliminarily determined, at which the burning of all combustible materials in an unpressurized room decreases, the total area of the openings of the unpressurized room and the time of the liquidation of the fire, which is directly proportional to the difference between the initial and ultimate oxygen content and the total area of the openings of the unpressurized room and is inversely proportional to its volume and consumption of extinguishing agent with a given dispersion of liquid phases of a gas-liquid medium.

 The supply of extinguishing agent by the pneumatic-acoustic method, in contrast to its injection by the jet method in the prototype, provides a high degree of dispersion of the liquid phase of the gas-liquid medium, and as a result, volume quenching of the source of ignition.

 The smallest particles of liquid transfer a gas inert to combustion throughout the leaky room, as a result of which the maximum oxygen concentration for combustion is quickly reached and the consumption of extinguishing agent is reduced.

 A preliminary determination of the limit oxygen content at which the combustion of all combustible materials in the room ceases allows us to determine not only the time to extinguish the fire, but also the flow rate of the extinguishing agent needed to extinguish the fire.

 Accounting for the total area of the openings, which was also not performed in the prototype, allows us to evaluate heat transfer processes and take into account new possible air flows into the leaky room during fire fighting.

The proposed method for eliminating a fire in an unpressurized room is characterized by high efficiency, short fire extinguishing time that does not go beyond the accepted requirements, and the ability to eliminate both small and rapidly spreading fire sources. At the same time, the flow rate of the extinguishing agent decreases by an order of magnitude and the gas composition in the room does not deteriorate significantly, which allows the presence of people in the room without special protective equipment
The invention is further explained in the description of specific options for its implementation and examples.

The method of eliminating a fire in an unpressurized room containing combustible materials is as follows. Preliminarily determine the maximum concentration of oxygen at which the combustion of all combustible materials in the room ceases. For this, a list of combustible materials in the room is compiled, and For each of them, C _pr is determined - the maximum concentration of oxygen at which the combustion process stops (according to the well-known method). As a result, the definitions establish the material for which C _ol is minimal. The difference between the values of C _n - the initial oxygen concentration in the leaky room and C _pr determines not only the time of suppression of the source of ignition, but also the amount of extinguishing agent needed to eliminate the fire. The smaller the difference C = C _n - C _ol, the more quickly the quenching occurs.

 The second most important element of the fire extinguishing method is to determine the total area of openings in an unpressurized room, which is also determined in advance for each specific case. This indicator determines the complexity of the heat and mass transfer of the gaseous medium contained in the room into which the extinguishing agent is supplied.

 Moreover, the larger the total area of the openings, the more difficult it is to extinguish the process of extinguishing, the greater the number of extinguishing agent must be fed into the room and, accordingly, the longer the process of extinguishing.

 The dimensions of the openings should be considered relative to the volume of the protected room, since the process of convective heat exchange substantially depends on this ratio.

 If a fire occurs in a leaky room, the corresponding sensors generate a signal through which the extinguishing agent is supplied by the pneumoacoustic method, which is currently one of the most effective methods of dispersing liquids. The method is based on the energy of ultrasonic vibrations created by an inert gas medium. The process of formation of liquid particles proceeds in an inert medium, for example, in nitrogen. Each formed particle does not contain an oxidizing agent in the boundary layer. Therefore, filling the volume of the protected space, the smallest particles of liquid evenly distribute nitrogen throughout the entire free space. As a result, the maximum concentration of oxygen for combustion is quickly reached and the amount of spent fire extinguishing composition is significantly reduced. The solution of the problem associated with the processes of heat release and heat transfer arising in the process of extinguishing fires with a fog-like gas-liquid medium was carried out by a computer numerical method. The compiled program allows one to make calculations for various initial data and to obtain quantitative characteristics of the physical processes occurring under extinguishing conditions.

 A series of laboratory and polygon experiments on the extinguishing of both solid polymer materials and combustible liquids was carried out. Moreover, the data obtained within 17% correspond to theoretical data.

 It should be noted that if the dimensions of the openings in the room are so large that even at high flow rates of the extinguishing medium, quenching is not achieved, then in these cases for applying the method it is necessary to provide solutions that allow, at the time of detecting a fire, to artificially reduce the total area of the openings to the calculated ones values that ensure successful quenching. The indicated actions to limit the area of openings in the room are due to the fact that the proposed extinguishing method should be considered as volumetric, since in this case the protected room is completely filled with a misty environment, for example, with a mixture of finely sprayed water with nitrogen. In this case, first of all, there is a sharp decrease in temperature in the entire volume due to the process of evaporation of the liquid particles from the surface and, in parallel, the oxygen concentration limit for combustion is created due to the partial displacement of the initial atmosphere by an inert gas and vapor of the evaporated part of the liquid.

 As a result, the combustion process quickly ceases, the leakage of the gaseous medium due to the high temperature difference between the surrounding gaseous medium and the indoor environment is reduced.

 In addition, the high efficiency of the quenching process is associated with the penetrating ability of a misty liquid, particles of which are 10-30 μm in diameter, being carriers of an inert gas for combustion, spread throughout the entire protected volume and fill all inaccessible places.

 The peculiarity of the method also consists in the fact that when it detects ignitions at an early stage, when the room temperature has not yet changed, the extinguishing process is carried out mainly due to an inert gas, since under these conditions the vaporization mode is insignificant.

 In the case of a developing fire, when the temperature in the room has substantially increased, the process of evaporation of liquid particles comes into effect and creates additional volumes of a gas inert to combustion.

 As a result, the inert gas consumption and the fire fighting time are significantly reduced.

(1) при 7

160
0,053≅ ΔС≅ 0,092
1˙10^-3 ≅ I ≅ 9˙10^-3 где V - объем негерметичного помещения;
F - суммарная площадь проемов;
I - расход огнетушащего вещества.By supplying the extinguishing agent with the pneumatic acoustic method and taking into account the maximum oxygen content and the total area of the openings of the leaky room, the time for eliminating the fire is determined. Based on many experiments, it was found that it is directly proportional to the difference between the initial and maximum oxygen content and the total area of the openings of the leaky room and inversely proportional to its volume and the flow rate of the extinguishing agent with a given dispersion of the liquid phase. Considering the case when volume extinguishing of a small fire is carried out, the time τ for extinguishing the fires can be estimated from the relation
τ = 9.02

(1) at 7

160
0,053≅ ΔС≅ 0,092
1˙10 ^-3 ≅ I ≅ 9˙10 ^-3 where V is the volume of the leaky room;
F is the total area of the openings;
I - consumption of extinguishing agent.

 Specific examples are provided to better understand the advantages of the invention.

Example 1. In an unpressurized room, the volume of which was 160 m ³ and the area of the openings was 2.0 m ² , the initial oxygen content С _{n was} determined, which was 20% by volume. For the combustible material in the room defined C, _etc., which amounted to 15% by volume. It was believed that the fire that occurred was local and a relatively small thermal power was released for a given volume of 0.2 MW, i.e. the case when the process of evaporation of liquid particles did not make a significant contribution to the quenching process.

 Nitrogen was used as the gaseous phase of the extinguishing agent, and water was used as the liquid phase. The extinguishing agent was supplied by the pneumoacoustic method, in which the nitrogen pressure was 0.2-0.3 MPa, the water pressure was 150-300 mm water column, and the particle size of the liquid phase was 10-30 microns.

= 29,5 c.The extinguishing agent consumption was 5–10 ^-3 kg / m ³ ˙ s. From the expression (1), the time to eliminate the fire was determined
τ = 9.02

= 29.5 s.

 Thus, after 29.5 s in the example under consideration, the fire will be extinguished.

PRI me R 2. The conditions are the same as in example 1, and the flow rate of the extinguishing agent was 9˙10 ^-3 kg / m ³ ˙ s. The fire extinguishing time was τ = 16.4 s.

PRI me R 3. The conditions are the same as in example 1, and the area of the openings was 1.0 m ² .

 The fire extinguishing time was 16.9 s.

 Thus, the proposed method of fire extinguishing is characterized by high efficiency, short fire extinguishing time and low consumption of extinguishing agent.

Claims (1)

 METHOD FOR FIRE FIGHTING IN A NON-SEALING ROOM containing combustible materials, which consists in supplying an extinguishing agent in the form of a gas-liquid medium to an unpressurized room having openings and characterized by an initial oxygen content, characterized in that the extinguishing agent is supplied by a pneumatic-acoustic gas method, providing media with a given dispersion of particles of the liquid phase, in this case, the limiting oxygen content at which all hot materials in an unpressurized room, the total area of the openings of the unpressurized room and the time of fire elimination, which is directly proportional to the difference between the initial and maximum oxygen content and the total area of the openings of the unpressurized room and inversely proportional to its volume and flow rate of the extinguishing agent with a given dispersion of the liquid phase gas-liquid medium.