RU2076760C1 - Method and facility for fire-fighting - Google Patents

Abstract

FIELD: fire-fighting facilities. SUBSTANCE: method consists in accumulation of water in tank and of working gas in separate high-pressure cylinder. Both media are fed into spraying chamber where they are transformed into aerosol. Working gas is accumulated in addition under pressure in accumulating chamber and is fed over pipe-line, fast-action valve, system of nozzles into water under atmospheric pressure. Water is accumulated in spraying chamber, is divided and is thrown out through head to form fire-fighting mixture composed of finest not inter-coagulating particles. Areas of cross-section of pipe-line of facility communicating accumulating chamber with system of nozzles and of flow of fast-action valve exceed summary area of minimal diameters of nozzles. Accumulating chamber is connected to high-pressure cylinder of working gas through reducer, pipe-lines and fast-action valve. EFFECT: improved fire fighting capabilities of method and facility. 12 cl, 1 dwg

Description

 The invention relates to a fire extinguishing method and devices for implementing the method, designed to extinguish fires using stationary, mobile or portable fire fighting equipment, in particular in apartments, residential and non-residential premises.

Water-based fire extinguishing devices are known and widely used since the extinguishing agent is available, inexpensive and environmentally friendly. The damping effect of the discharge of the fire fighting device is based on the cooling effect due to the evaporation of water and depends on the development of its surface area in contact with the flame, that is, the size of the particles and their velocity. Combustion ceases due to lower temperatures and in terms of quenching efficiency in terms of water flow, the optimum diameter of the droplets is 100-200 microns. Using nozzles, water is sprayed onto droplets of 30-1000 microns in size and distributed in the form of a spray cone. The droplets, due to their own weight, fall into the burning area. If the droplet size is less than 100 μm, then in this case, due to the thermal backpressure and low speed of their movement, they cannot advance forward to the burning site, therefore, their share in cooling cannot be used. Sprinkler devices can be started using compressed air or an electronic software device [1] For proper protection of the combustion area, overlapping spray cones with an area of approximately 9 m ² are required, therefore, well-known fire fighting installations require additional flow of pipes and nozzles. Based on the size of the droplets, the quenching time is 60-120 s, which entails a large flow of water with possible subsequent damage caused by it.

 The efficiency of water use during extinguishing is very low, because it was not possible to develop a spray device that was easy to use and allows to form a fire extinguishing mixture with the required parameters (opening angle, flow rate, droplet size and range), which would significantly increase the fire extinguishing efficiency of water.

 The method and device for extinguishing fires with water, in which the fire is liquidated with a small flow rate of water, as well as with a small flow rate of pipelines and nozzles [2], the fire extinguishing method involves extinguishing a fire based on water and working gas, is selected as a prototype of the proposed method based on a set of common features. Water is accumulated in a vessel intended for it, and the working gas is separate from it in a high-pressure tank. After opening the high-speed valves, water from the vessel using a working gas from a high-pressure cylinder reduced to 1 MPa, as well as a working gas under pressure of at least 3 MPa, are supplied together to a sprayer operating on the "principle of a gas generator" and there they turn into a homogeneous water aerosol, so that, after exiting the spray nozzles, in the form of a free stream of water aerosol with a droplet size of a maximum of 2 μm, get directly into the fire and eliminate it. In this case, a free stream of water aerosol leaves at a speed of 20-40 m / s, water droplets, due to high kinetic energy at a distance of more than 10 m, enter the combustion zone, evaporate there and remove thermal energy from the fire, and therefore contribute to extinguishing the fire.

 The disadvantages of the method include the low rate of expiration of the extinguishing mixture and, as a consequence, the low kinetic energy of the moving smallest particles. This is due to the fact that the aerosol (extinguishing mixture) obtained in the spray chamber operating on the principle of a gas generator passes through pipelines and nozzles whose resistances reduce its speed.

 The known device, selected as a prototype, contains one or more cylinders of working gas, which are connected via a switchable electronic or other quick-acting valves to the atomizer chamber operating directly on the principle of a gas generator and, on the other hand, by means of a short pipeline and a pressure reducing valve, connected to a reservoir with water, at the inlet of which there is also a quick-acting valve and another short pipeline connected to the spray chamber, connected to spray nozzles [2] To a tank of water may be connected an external water network.

 The disadvantages of the device include the high consumption of pipelines and nozzles, as well as water and working gas, since the system will stop when the working gas or water is used up.

 Using the proposed method and device, the problem of increasing the efficiency of fire fighting, the economical use of water and working gas by increasing the kinetic energy of the spray torch is solved.

 The problem is solved by the accumulation of water and working gas in separate vessels intended for them, from where both media are supplied to the spray chamber and converted into aerosol. In this case, the working gas is additionally accumulated under pressure in the storage chamber and supplied through a pipeline, a quick-acting valve containing the working and control cavities, and a nozzle system into the water accumulated in the spray chamber under atmospheric pressure, which is crushed and discharged through nozzles, thereby forming a fire extinguishing a mixture consisting of the smallest particles that do not coagulate with each other, so that after exiting the nozzle in the form of a torch, it will spray into the fire and eliminate it. Moreover, the speed of the spray flame extinguishing mixture exceeds 60 m / s. This ensures high kinetic energy of the spray torch of the extinguishing mixture, which contributes to more effective fire fighting, the economical use of water and working gas.

 As a fire extinguishing agent, a non-toxic liquid or powder is used.

 The corresponding device consists of a working gas high pressure cylinder connected through a quick-acting valve, a reducing device into which bursting safety membranes are inserted, and pipelines with a water vessel, a spray chamber containing nozzles, and a storage chamber for working gas communicated through a quick-acting pipe valve, nozzle system with a spray chamber. The cross-sectional areas of the pipeline connecting the storage chamber to the nozzle system and the passage section of the high-speed valve exceed the total area of the minimum nozzle diameters. The accumulation chamber is connected through a reducing device, pipelines and a quick-acting valve to a high-pressure cylinder of the working gas.

 The nozzle is an elastic slotted diaphragm. The nozzles included in the system have the configuration of a truncated Laval nozzle. In the high-speed valve, an unloading cavity connected with the atmosphere is introduced. The cavity between the back side of the fast-acting valve shut-off element and the piston is connected by a channel to the control cavity. When the quick-acting valve is open, the pipeline supplying the working gas is disconnected from the control cavity and the storage chamber. The nozzle system, quick-acting valve and spray chamber are made of titanium and stainless steel.

 The implementation of the fire extinguishing method is as follows. Water is accumulated in a vessel intended for it, and the working gas is separated from it in a high-pressure cylinder, both media are supplied to the spray chamber and converted into aerosol. In addition, an accumulation chamber is introduced, where the working gas is accumulated and supplied through a pipeline, a quick-acting valve and a nozzle system into the spray chamber with atmospheric water in it, dispersed and thrown out through nozzles, forming a fire extinguishing mixture. After ejection from the nozzle, the water splits into a set of closely spaced and co-flying drops. With the further advancement of this torch, the droplets leading on its front are slowed down and partly move to the side, making way for the next portion of water at a high speed (a kind of relay mechanism). Drops that are on the side surface of the spray torch are braked and move away. Since the inner part is thus protected from interaction with the environment, it does not slow down and continues to move at an initial ejection speed a certain distance. Outgoing droplets take away only their own amount of movement and, braking, transmit it to the environment, forming a more rarefied cloud around the central part (core) of the torch. The largest drops located in the central part of the torch upon reaching the periphery, braking, are crushed and so on until the kinetic energy is completely exhausted.

 The resulting fire extinguishing mixture is ejected by a spray torch with an opening angle of 100-120 degrees and a diameter of 2-3 m with a flow velocity of more than 60 m / s. After departure, droplet crushing continues due to aerodynamic forces and allows the formation of a spray torch with a diameter of 2-3 m and provides a range of over 10 m.

 This sequence of operations makes it possible to increase the flow rate of the extinguishing mixture, which significantly affects the time of extinguishing the fire, and the diameter of the spray torch of 2-3 m makes it possible to efficiently use water, which makes it possible to produce a larger number of emissions or stop work if the fire is extinguished.

 A device that implements a fire extinguishing method consists of a high-pressure cylinder of the working gas connected through a quick-acting valve, a reducing device and pipelines to a water vessel, a spray chamber containing nozzles, and a storage chamber for working gas communicated through a pipeline, a quick-acting valve, and a system nozzles with a spray chamber. The cross-sectional areas of the pipeline connecting the storage chamber to the nozzle system and the passage section of the high-speed valve exceed the total area of the minimum nozzle diameters. The accumulation chamber is connected through a reducing device, pipelines and a quick-acting valve to a high-pressure cylinder of the working gas.

 The nozzle is an elastic slotted diaphragm. The nozzles included in the system have the configuration of a truncated Laval nozzle. In the high-speed valve, an unloading cavity connected with the atmosphere is introduced. The cavity between the back side of the fast-acting valve shut-off element and the piston is connected by a channel to the control cavity. When the quick-acting valve is open, the pipeline supplying the working gas is disconnected from the control cavity and the storage chamber. The nozzle system, quick-acting valve and spray chamber are made of titanium and stainless steel.

Explosive safety membranes are additionally introduced into the reducing device [4]
In a device that implements a fire extinguishing method, a new set of elements known in the art is proposed: chambers that allow the accumulation of working gas and water, nozzles included in the system having the configuration of a truncated Laval nozzle, an unloading cavity in a quick-acting valve, connected with the atmosphere, a cavity with a back side of the fast-acting valve shut-off element connected to the control cavity, the pipeline supplying the working gas, disconnected when the quick-acting valve is opened from the control cavity and digestive chamber. This combination allows you to achieve an unexpected result provides the expiration of the extinguishing mixture with a speed of more than 60 m / s.

 Depending on the control method of high-speed valves, the fire extinguishing method can be used both in stationary automatic fire extinguishing systems and in mobile and portable fire extinguishing means.

 The invention is illustrated by the drawing, which shows a diagram of the construction of a stationary device that implements a method of extinguishing a fire.

 A device that implements a fire extinguishing method includes a quick-acting valve 1 connected in series, a high-pressure gas cylinder 2, which, through a reducing device 3, communicates with a storage chamber 4, and through a reducing device 5 with a water vessel 6 connected through a quick-acting valve 7 and short pipeline 8 with a spray chamber 9, and the accumulation chamber 4 through a short pipeline 10 and a high-speed valve 11 communicates with the nozzle system 12 and the spray chamber 9, at the outlet of which rzhitsya nozzle 13 and reducing device 3, and 5 are discontinuous protective membrane 14.

 Stationary fire extinguishing device operates as follows.

 Upon receipt of a signal from the sensor about the presence of fire, the software device gives a command to open the high-speed valve 1, and the working gas from the high-pressure cylinder 2 enters through the reducing device 3 into the storage chamber 4 and simultaneously through the reducing device 5 into the vessel with water 6.

 After receiving the next command from the software device for a certain period of time, the high-speed valve 7 opens, and a portion of the water from the vessel 6 is displaced by the working gas through a short pipe 8 into the spray chamber 9.

 At the command of the software device, the high-speed valve 11 opens for a certain time, and the working gas located in the storage chamber enters through a short pipe 10 and nozzle system 12 into the spray chamber 9, where water is at atmospheric pressure, crushes it and throws it out through nozzles 13, forming a fire extinguishing mixture.

 Upon receipt of a signal from the sensor that the fire has been eliminated, the software device gives a command to close the high-speed valve 1, and for a certain time opens the high-speed valve 11 to relieve pressure from the accumulation chamber 4.

 If the signal from the sensor is not received, then the operations are repeated in the same sequence.

 The reducing device 3 is equipped with explosive safety membranes 14, which burst when the specified pressure in the cylinder 2 is exceeded and at the outlet of the reducing device 3, which ensures safety when working with the fire extinguishing device.

 When using the device as a mobile or portable fire extinguishing means, the operator assumes the function of a software device for opening high-speed valves.

Claims (11)

 1. The method of extinguishing a fire, which consists in the fact that water is accumulated in a vessel designed for it, and the working gas is separately from it in a high-pressure tank, both media are fed into a spray chamber and converted into an aerosol, characterized in that the working gas is additionally accumulated under pressure in the storage chamber and feed it through a pipeline, a quick-acting valve, a system of nozzles into water under atmospheric pressure, which is accumulated in the spray chamber, crushed and thrown out through nozzles, while forming a fire extinguishing a mixture consisting of the smallest particles not coagulating with each other.  2. The method according to claim 1, characterized in that the speed of the spray torch of the extinguishing mixture exceeds 60 m / s.  3. The method according to claims 1 and 2, characterized in that a non-toxic liquid or powder is used as the extinguishing agent.  4. Fire extinguishing device, consisting of a working gas high-pressure cylinder connected through a quick-acting valve, a reducing device and pipelines to a water vessel, and a spray chamber, characterized in that it further includes a working-gas storage chamber communicated through the pipeline, a quick-acting valve , a nozzle system with a spray chamber containing nozzles, and the cross-sectional area of the pipeline connecting the storage chamber with the nozzle system, and the passage section high-speed valves exceed the total area of the minimum diameters of the nozzles, in addition, the accumulation chamber through a reducing device, pipelines and high-speed valve is connected to a high-pressure cylinder of the working gas.  5. The device according to claim 4, characterized in that the nozzle is an elastic slotted diaphragm.  6. The device according to PP.4 and 5, characterized in that the reducing device is equipped with explosive safety membranes.  7. The device according to PP.4 to 6, characterized in that the high-speed valve contains a working, control and discharge cavity.  8. The device according to PP.4 to 7, characterized in that the nozzles have the configuration of a truncated Laval nozzle.  9. The device according to paragraphs. 4 to 8, characterized in that the cavity between the rear side of the locking element of the high-speed valve and the piston is connected by a channel to the control cavity.  10. The device according to claims 4 to 9, characterized in that when the quick-acting valve is open, the pipeline supplying the working gas is disconnected from the control cavity and the storage chamber.  11. The device according to PP.4 to 10, characterized in that the nozzle system, high-speed valve and spray chamber are made of titanium and stainless steel.