EA021958B1 - Fire extinguisher - Google Patents

Abstract

The invention relates to fire-fighting technology, to devices for extinguishing by directed supply of compressed fire-fighting substance. A fire extinguisher is proposed comprising a vessel with a working fire-fighting substance, a gas system of liquid displacement from the vessel having a siphon pipe, a lock and release device connected to the siphon pipe outlet, a fire-fighting liquid sprayer connected to the lock and release device by an inlet branch and provided with a fire-fighting liquid flow swirler and an outlet jet, wherein the fire extinguisher has an ejector positioned in the upper part of the siphon pipe enabling for gas ejecting from the displacement system, the liquid sprayer comprises an inlet convergent tube, a linear section and a resonating chamber positioned successively along the fire-fighting liquid flow, the swirler has an outlet diffuser, the fire-fighting substance swirler is embodied as at least one rectilinear rod for generating coherent flow fluctuations and arranged in the linear section. The rods are positioned in the linear section of the swirler successively in the fire-fighting liquid flow direction in different planes relative each other, wherein the rod's end sections are fixed in the swirler wall. Each of rod is mounted so that its longitudinal axis is perpendicular to the fire-fighting liquid flow direction.

Description

The invention relates to fire fighting equipment, and more particularly to portable and mobile devices designed to extinguish by means of a directed supply of a fire extinguishing substance under pressure, and can be used for volumetric or locally volumetric fire extinguishing mainly in closed or semi-enclosed rooms.

A spray nozzle of a fire extinguisher is known from the prior art, comprising a housing with a nozzle and a connecting fitting for supplying a fire extinguishing agent, which is equipped with a generator of coherent oscillations of the flow of the fire extinguishing agent located in the housing between the nozzle and the connecting fitting, made in the form of at least two rectilinear rods, each of which is installed in the housing in such a way that the longitudinal axis of the rod is perpendicular to the direction of flow of the extinguishing agent, the transverse profile the cross-section of the rods has an axis of symmetry, the rods are arranged in the housing sequentially in the direction of flow of the extinguishing agent, in different planes relative to each other and at a distance greater than the profile size along its axis of symmetry, and the end sections of the rods are fixed in the wall of the housing, mainly the rods are located in the housing along its diameter and in mutually perpendicular planes relative to each other (see patent KI No. 2422215, class B05B 17/08, published on June 27, 2011). The nozzle provides a high degree of atomization of the flow of extinguishing agent at the exit of the nozzle. A disadvantage of the known spray nozzle of a fire extinguisher is the inability to control the flow rate at the inlet and the shape of the jet at the exit due to the cylindrical shape of the respective sections.

A known fire extinguisher comprising a container with a working fire extinguishing liquid, a system for displacing a liquid from a container with a siphon tube, a locking and starting device connected to the outlet of the siphon tube, a flow rate control of the fire extinguishing liquid and a liquid atomizer connected to the output of the locking device, which is equipped with a centrifugal swirl fluid and an output nozzle (see KI patent No. 2311673, class A62C 13/62, published June 20, 2007). The invention provides an increase in the efficiency of use of the working fluid when using a fire extinguisher by maintaining a constant flow rate and the range of supply of the fire extinguisher. This well-known technical solution was adopted as a prototype as the closest analogue in technical essence and achieved result.

The disadvantage of the prototype is the lack of dispersion of the flow of extinguishing agent at the inlet to the liquid atomizer, its low speed with the complete absence of mixing with the gas of the displacement system, in addition, the liquid atomizer is characterized by significant water losses due to the angular change in the direction of flow. The result of the manifestation of a pressure drop is a significant decrease in the range of the extinguishing agent stream. The presence in the design of the prototype of this drawback limits the effectiveness and scope of its application.

The invention is aimed at achieving a technical result, which is expressed in providing a high speed and dispersion of a jet of fire extinguishing agent at the outlet of the nozzle of the spray due to the use of compressed gas energy of the system for displacing the liquid from the capacity of the fire extinguisher, reducing the hydraulic resistance of the spray. Ultimately, the specified technical result allows to increase the efficiency of using a fire extinguisher and simplify its design. In the invention, all the positive properties of the prototype are maximally preserved, the most important of which is the range of supply of the extinguishing fluid.

The specified technical result is achieved in that a fire extinguisher, including a container with a working fire extinguishing liquid, a gas system for displacing a liquid from a tank with a siphon tube, a locking and starting device connected to the outlet of the siphon tube, connected to the outlet of the latter by means of a nozzle of the extinguishing liquid, equipped with a fire extinguisher spray extinguishing liquid and an outlet nozzle, differs from the prototype in that it is equipped with an ejector installed in the upper part of the siphon tube with the possibility of In order to eject gas from the displacement system, the liquid atomizer is made up of an inlet confuser, a linear section and a resonator chamber arranged sequentially along the extinguishing liquid flow, and the nozzle contains an output diffuser, the extinguishing liquid flow swirl is made in the form of at least one rectilinear rod for generating coherent flow oscillations and is located on a linear section, each of the rods is installed in such a way that its longitudinal axis is perpendicular to the direction of flow fire extinguishing fluid.

The optimal from the point of view of achieving the indicated technical result is the implementation of the ejector consisting of a confuser, a mixing chamber and a diffuser arranged sequentially along the flow of the extinguishing fluid, while a suction pipe is mounted in the wall of the ejector to communicate the gas cavity of the container with the ejector mixing chamber. In all versions of the fire extinguisher, it is advisable that the rods are located on the linear section of the swirl sequentially in the direction of flow of the fire extinguishing fluid, in different planes relative to each other, and the end sections of the rods are fixed in the wall of the swirl.

In the fire extinguisher, a liquid-gas ejector installed inside the tank is used to form a high-speed dispersed stream of extinguishing liquid. The ejected gas enters the mixing chamber of the ejector directly from the displacement cavity of the container filled with compressed gas, as a result of the difference in static pressure in the extinguishing liquid stream. The mixture of compressed gas and extinguishing fluid in the mixing chamber of the ejector contributes to the formation of a high-speed flow. The increase in the flow rate by two or more times in comparison with the conventional displacement method of fluid supply is provided due to the expansion and acceleration of the gas phase in the satellite stream in the mixing chamber and the diffuser of the ejector. The flow part of the ejector with an axial inlet of compressed gas is determined from the optimization of the ratio of the required gas and liquid flow rates. The profile and geometrical dimensions of the flow part of the ejector, the length, the opening angle, the speed and the quantitative parameters of dispersing the jet into droplets, all other things being equal, depend on the required gas saturation of the two-phase flow.

The atomizer is based on the principle of generating a fire extinguishing substance in the flow in the flow part and, in particular, in the nozzle of coherent oscillations. By coherent oscillations in the flow of a fire extinguishing substance we mean coordinated mechanical vibrations of several oscillatory processes from various sources, manifested during their addition. Coherent vibrations are able to efficiently initiate the formation of a finely divided droplet structure in the flow of extinguishing agent. In the design of the atomizer, a coherent oscillation generator is used, which consists of oriented rectilinear rods having insignificant hydraulic resistance when they flow around a continuous medium flow. Thus, at the exit from the nozzle of the atomizer, a highly dispersed high-velocity jet of extinguishing agent with a given opening angle is formed, and there is no loss of kinetic energy of the flow.

All the features that characterize a fire extinguisher that are distinct from the prototype are sufficient to achieve a technical result, namely, ensuring a high speed and dispersion of a fire extinguisher jet at the outlet of the nozzle of the spray due to the use of compressed gas energy of the system for displacing the liquid from the capacity of the fire extinguisher and reducing the hydraulic resistance of the spray.

A fire extinguisher characterized by the described set of essential features is new and industrially applicable.

The technical solution is illustrated by drawings.

In FIG. 1 shows a General view of a fire extinguisher in a section; in FIG. 2 is a cross-sectional view of an ejector mounted in the upper part of a siphon tube; in FIG. 3 is a longitudinal section of a liquid atomizer; in FIG. 4 is a cross-sectional view of the liquid atomizer AA in FIG. 3.

A fire extinguisher consists of a container 1 filled with an almost completely working extinguishing liquid 2. As an extinguishing liquid 2, it is possible to use, for example, aqueous solutions of foaming agents with various modifying additives, powders of inhibitory components. The gas system for displacing a liquid from a tank consists of a siphon tube 3 and compressed gas under pressure in the gas cavity of the tank 1. As a source of compressed gas for displacing a fire extinguishing liquid 2, a pneumatic or, for example, solid fuel pressure accumulator, a compressed cylinder or liquefied gas, a powder charge placed in a special combustion chamber. In FIG. 1 shows a fire extinguisher filled during its charging with compressed gas (nitrogen, compressed air, liquefied bicarbon dioxide). With the output of the siphon tube 3, a locking-starting device 4 is connected, the output of which, in turn, is connected by means of a supply nozzle to the spray gun 5 of the extinguishing fluid.

In the upper part of the siphon tube 3, at the mirror level of the extinguishing liquid 2, a liquid-gas ejector 6 is placed with the possibility of ejecting gas from the gas cavity of the container 1. The ejector 6 is made up of extinguishing liquid arranged in series along the flow (in the drawings, the extinguishing liquid flow is conventionally shown parallel arrows) of the confuser 7, the mixing chamber 8 and the diffuser 9. An i-shaped suction pipe 10 is mounted in the wall of the ejector 6 to communicate the gas cavity of the tank 1 with the mixing chamber 8.

The extinguishing liquid spray 5 is made in the form of a nozzle with a threaded section for connecting via the inlet fitting to the outlet of the locking and starting device 4 directly or through a flexible hose 11. The flowing part of the spray 5 consists of an inlet confuser 12 arranged in series along the flow of the fire extinguishing liquid, a linear section 13 , the resonator chamber 14 and the nozzle 15. In the drawings, the length of the linear portion 13 is conventionally indicated by the letter b, and the resonator chamber 14 is conventionally indicated by the letter N. In the linear portion sprayed 5 of Tell has swirl flow of extinguishing fluid, made in the form of at least one rectilinear rod 16 for generating a stream of coherent oscillations (in the drawings swirler conventionally depicted as two straight rods 16, the diameter of which is labeled 6). The nozzle 15 consists of an inlet tapering section, a critical section and an outlet diffuser 17. The inlet confuser 12 is made tapering with a taper angle of 10-40 °, and its length (not indicated in the drawings) is no more than 2 diameters of the outlet section of the locking-starting device 4. The length b of the linear portion 13 is 1-106 diameters of the rods 16. The length H of the resonator chamber 14 is chosen equal to at least the diameter of the flow part of the atomizer 5. The output diffuser 17 of the atomizer 5 has an opening angle of 10-45 ° and a length of 0.1-0, 6 dia. Critical th section of the nozzle.

- 2 021958

On a cylindrical linear section 13 of the atomizer 5 between the inlet confuser 12 and the resonator chamber 14 is installed a swirl flow extinguishing fluid. In the drawings, the swirler is represented by two rectilinear rods 16, the end sections of which are fixed in the wall of the atomizer 5 from its inner side. According to the invention, the rods 16 may be any number. The longitudinal axis of each of the rods 16 is oriented perpendicular to the direction of flow of the extinguishing fluid. The rods 16 can be located in the flow part of the spray gun 5 sequentially in the direction of flow of the extinguishing fluid at a certain distance from each other. In the drawings, the rods 16 are depicted arranged on a linear portion 13 of the atomizer 5 by its diameter. In addition, the rods 16 are located in different (in the drawings - in mutually perpendicular) planes relative to each other. Such a design scheme of the swirler corresponds to the simplest orthogonal implementation of a coherent oscillation generator. In principle, the rods 16 can be located relative to each other at any angle of intersection, but not in parallel. The cross section of the rods 16 has a streamlined profile, the shape of which can be varied. The diameter of the cross section of the rods 16 has a certain size, the value of which is indicated in the figures by the letter b.

A fire extinguisher operates as follows.

The equipped fire extinguisher is a container 1 filled with extinguishing liquid 2, which is under excess pressure of the gas liquid displacement system. When the locking and starting device 4 is activated, the process of displacing the extinguishing liquid 2 from the tank 1 begins. Under the influence of excessive gas pressure, the extinguishing liquid 2 through the siphon tube 3 is forced out from the tank 1 under pressure.

In addition to a gas displacement system, a liquid-gas ejector 6 installed inside the tank 1 is used in the fire extinguisher to form a high-speed dispersed flow of extinguishing liquid 2; it is installed inside the tank 1. The ejected gas enters the mixing chamber 8 of the ejector 6 through an I-shaped suction the pipe 10 directly from the displacing cavity of the tank 1 filled with compressed gas. Thus, the supply rate of the extinguishing liquid is increased due to its acceleration by the compressed gas expanding in the mixing chamber 8 of the ejector 6, and the utilization of the energy of the compressed gas of the displacement system is also increased.

To create a dispersed jet of fire extinguishing fluid at the outlet of the fire extinguisher, a spray gun 5 is intended. The spray gun 5 is connected to the output of the locking and starting device 4 of the tank 1 with a fire extinguishing fluid under pressure through the inlet fitting. The flow of fire extinguishing fluid under the influence of pressure moves from the inlet confuser 12 to the nozzle 15, interacting on a cylindrical linear section 13 with the rectilinear rods 16 of the swirl of coherent oscillations. During the flow around the rods 16 in the flow of the extinguishing fluid, turbulent wave disturbances arise and develop in the form of a system of interacting vortices. The frequency and intensity of the oscillations generated in the flow is determined by the properties and velocity of the fluid in the flow part, the relative position, the characteristic dimensions of the rods 16. The estimates of the Reynolds number (Ke) in the extinguishing agent flow for the orthogonal generator of coherent oscillations showed that the necessary degree of turbulence of the flow for all types of extinguishing fluids are guaranteed to be achieved in the resonator chamber 14 already at a distance of more than one characteristic size b from the rod 16. Each rod 16 generates oscillations in its plane, as a result, at the outlet of the diffuser 17 of the atomizer 5, a volumetric homogeneous amplitude-frequency spectrum of coordinated (coherent) oscillations is formed in the stream. The magnitude of the amplitude and frequency of the generated oscillations depends on the average diameter of the droplet ensemble and the degree of dispersion of the extinguishing liquid flow, as well as the angle of the jet at the outlet of the diffuser 17. The rods 16 and the entire atomizer 5 have insignificant hydraulic resistance during the flow of a continuous medium, which eliminates losses kinetic energy of the flow and velocity head for the formation of a finely divided droplet structure, and ultimately increases the range of the jet during the elimination of the fire .

The advantage of the fire extinguisher according to the invention is its high efficiency in combination with a simple design. Operation of a fire extinguisher is not economically and technically fraught with significant costs.

The exemplary extinguisher embodiments described above are not exhaustive and are provided only for the purpose of explaining the invention and confirming its industrial applicability. Specialists in this field can improve it and / or implement alternative options within the essence of the present invention, reflected in the description and drawings.

Claims (3)

CLAIM 1. A fire extinguisher, including a container with a working fire extinguishing liquid, a gas system for displacing a liquid from a container with a siphon tube, connected to the outlet of the siphon tube with a shut-off device, connected to the outlet of the latter by means of a supply nozzle, a fire extinguishing liquid sprayer equipped with a swirling extinguishing liquid flow and an output nozzle, characterized in that it is equipped with an ejector installed in the upper part of the siphon tube with the possibility of ejecting gas from the displacement system, a spray the liquid is made up of an inlet confuser, a linear section and a resonator chamber arranged sequentially along the flow of the extinguishing liquid, and the nozzle contains an output diffuser, the extinguishing liquid flow swirl is made in the form of at least one rectilinear rod for generating coherent flow oscillations and is located in a linear section, each of the rods is installed in such a way that its longitudinal axis is perpendicular to the direction of flow of the extinguishing fluid. 2. The fire extinguisher according to claim 1, characterized in that the ejector is made up of a confuser, a mixing chamber and a diffuser arranged sequentially along the flow of the fire extinguishing liquid, while a suction pipe is mounted in the wall of the ejector to communicate the gas cavity of the tank with the ejector mixing chamber. 3. The fire extinguisher according to claim 1 or 2, characterized in that the rods are located on the linear section of the swirl sequentially in the direction of flow of the fire extinguishing fluid, in different planes relative to each other, and the end sections of the rods are fixed in the wall of the swirl.