RU2490041C1 - Potable fire-extinguishing plant - Google Patents

Abstract

FIELD: fire-prevention facilities.

SUBSTANCE: invention relates to portable fire-extinguishing facilities and may be used in knapsack fire-extinguishing plants. The portable fire-extinguishing plant comprises a reservoir for storage of a fire-extinguishing substance, a balloon with gas, a gas pressure control facility, a barrel with a sprayer and a trigger mechanism, valves of liquid and gas supply, a facility to control spraying of the fire-extinguishing substance and pipelines. Pipelines connected the reservoir and the balloon with valves of fluid and gas supply. The barrel is equipped with a chamber for mixing of liquid and gas. The sprayer is made with a central channel and a row of peripheral channels. Peripheral channels are arranged around the central channel. The facility of fire-extinguishing substance spraying control includes two controlled valves. The first of which is installed on the pipeline, which connects the balloon with the gas supply valve. The second controlled valve is arranged between the chamber of gas and liquid mixing and output holes of the peripheral channels of the sprayer. The second controlled valve is made as capable of opening and closing of a throughput section of peripheral channels of the sprayer.

EFFECT: plant design makes it possible to change modes of fire-extinguishing substance spraying by means of alternate switching between single-phase and double-phase mode of sprayed flow generation.

17 cl, 7 dwg

Description

The invention relates to fire-fighting equipment, in particular to portable fire extinguishing means, and can be used in backpack fire extinguishing installations.

There are various types of designs of portable fire extinguishing installations equipped with a regulator of the mode of supply of liquid fire extinguishing substance to the source of ignition. Liquid sprays of such installations are usually multichannel. So, for example, in the patent US 6425537 (IPC: A62C 31/00, published July 30, 2002), the design of a mobile fire extinguishing system is described, which includes a container for storing liquid fire extinguishing agent (OTV), a cylinder with compressed gas and a barrel with a liquid spray ANSWER The compressed gas cylinder is connected through a gas reducer and shut-off valves to the gas cavity of the tank. Under the influence of gas pressure, the liquid OTV is displaced from the tank and fed into the multichannel barrel sprayer. In this case, the barrel is equipped with a controlled valve for switching the supply of OTV through various channels of the sprayer. The central channel of the spray is designed to supply a foaming solution to the source of ignition. Water is supplied through the peripheral channels of the nebulizer equipped with centrifugal flow swirlers. The peripheral channels are evenly spaced along the circumference, which is the pine axis of symmetry of the central channel of the atomizer. With the help of peripheral channels, the generation of finely dispersed flows of water is provided to create a protective water curtain. It should be noted that the generation of atomized fluid flows through both the central and peripheral channels of the liquid atomizer is carried out in a single-phase mode (without preliminary mixing of liquid and gas).

Portable fire extinguishing installations are also known, with the help of which two-phase gas-droplet flows are generated due to preliminary mixing of liquid and gas and subsequent acceleration of the formed gas-droplet flow (see, for example, patent RU 2297864, IPC: А62С 13/00, published April 27, 2007). The device of this type includes a fluid supply system connected to the barrel. The fluid and gas valves of the barrel are in communication with the fluid and gas supply lines, respectively. Between the outlet openings of the liquid and gas supply valves and the entrance to the profiled channel of the nozzle (atomizer), a chamber for mixing liquid and gas is installed. The gas-droplet flow formed in the mixing chamber is accelerated in the profiled channel of the gas-dynamic nozzle. The required velocity of the gas-droplet flow, at which the spray range of the OTV stream is provided from 8 to 12 m, is achieved by selecting the gas pressure supplied to the mixing chamber. Due to the use of a gas stream as a medium accelerating droplets of finely dispersed OTV, the velocity of the formed gas-droplet jet at the nozzle exit is ~ 80 m / s.

The closest analogue of a portable fire extinguishing installation is disclosed in patent RU 2254155 (IPC: А62С 15/00, 31/02, published on 06/20/2005). Known knapsack fire extinguishing installation contains a container for storing OTV, at least one cylinder with compressed gas and a barrel with a spray of liquid OTV and fluid supply valves. Spraying liquid OTV through the atomizer is carried out in a single-phase mode (without preliminary mixing of liquid and gas). As a regulator, a rotatable sleeve is used, connected to the guide elements of the swirler. Using the guide elements of the swirler, the fluid flow is twisted, as well as the size of the droplets and the angle of the torch opening of the generated finely dispersed flow are controlled. The intensity of the swirl of the fluid flow is determined by the angular position of the guide elements of the swirler relative to the holes in the diaphragm, which is rigidly connected with the barrel body. By rotating the sleeve relative to the barrel body and relative to the aperture openings, a smooth or stepwise change in the cone angle of the torch of the sprayed fluid stream is carried out in the range from 20 ° to 30 °.

It should be noted that using the regulator of the OTV spraying mode during operation of a portable fire extinguishing installation of known design, it is only possible to adjust the angle of conicity of the sprayed stream in a limited range and adjust the size of the liquid droplets in the sprayed stream. When using a barrel with a regulator of the OTV spraying mode, it is impossible to alternately generate single-phase (liquid) and biphasic (gas-liquid) flows. In addition, the known device does not allow you to control the spatial characteristics of the sprayed stream in a wide range, to change the shape of the sprayed stream and to regulate the flow of OTV. These disadvantages are due to the lack of the ability to control the droplet speed due to a change in the gas-droplet flow generation mode.

The invention is aimed at providing the possibility of alternating generation of various forms of OTV flows: single-phase (liquid) and two-phase (gas-liquid) finely dispersed flows. These modes differ in the rate of liquid droplets in the stream and, accordingly, in the range of the sprayed OTV stream. Due to a change in the generation regime of finely dispersed streams, the OTV flow rate can also be changed. For a portable fire extinguishing installation, it is necessary to provide the possibility of supplying a finely dispersed flux of flux-protective substances at distances from 4 to 12 m by switching the spraying modes of fluorine-based substances. In addition, it is necessary to expand the range of control of the angle of cone of the torch generated gas-droplet flow and to provide the ability to control the shape of the sprayed stream.

The solution of these technical problems allows you to expand the range of OTV spraying modes, which is necessary to expand the functionality (multifunctionality) of a portable fire extinguishing installation through the use of an installation for extinguishing various types of fires, including putting out ground forest fires and extinguishing fires. Due to the expansion of the range of OTV spraying modes, the efficiency of using OTV, the supply of which is in the tank, and the efficiency of using compressed gas, the supply of which is in the cylinder, are increased. In this case, the limited reserves of liquid and gas should be taken into account, since the fire extinguishing installation is portable. These advantages are associated with the ability of the operator to select the optimal spraying method for HFA, taking into account both the efficiency of extinguishing a certain type of fire and the efficiency of using liquid HSS and compressed gas.

The achievement of the above technical results is achieved using a portable fire extinguishing installation, which includes a container for storing liquid OTV, at least one cylinder with compressed gas, a means of regulating gas pressure. The installation is equipped with a barrel that contains a spray liquid OTV, a chamber for mixing liquid and gas, valves for supplying liquid and gas and the trigger mechanism. The installation also contains means for regulating the OTV spraying mode and pipelines connecting the tank and cylinder to the liquid and gas supply valves.

The sprayer is multi-channel. Coaxial to the spray housing is a central channel, around which at least one row of peripheral channels is located. The means for regulating the OTV spraying regime includes two controlled valves. The first valve is installed on the pipeline connecting the cylinder to the gas supply valve. The second controlled valve is located between the chamber for mixing liquid and gas and the outlet openings of the peripheral channels of the atomizer. The second controlled valve is configured to open and close the flow area of the peripheral channels of the atomizer.

The use of a multi-channel sprayer and means for regulating the regime of spraying of the OTV in the form of two valves, one of which ensures the supply or termination of gas supply to the cavity of the liquid-gas mixing chamber, and the second provides the OTV only through the central channel of the atomizer or simultaneously through the central and peripheral channels of the atomizer, allows you to switch the operating modes of a portable fire extinguishing installation from single-phase to two-phase and vice versa. As a result of this, it is possible to alternately generate with the help of a single fire extinguishing installation various types of atomized fluxes of OT. In the first mode, a compact OTV jet without air with a supply range of at least 4 m is generated. In the second mode, a compact gas-droplet jet of OTV with a supply range of at least 8 m is generated. In this case, the OTV flow rate can also change in different operating modes of the fire fighting installation. These features of a portable fire extinguishing installation expand the range of types and characteristics of fires that can be extinguished when using one multifunctional installation. At the same time, the expansion of a number of functional capabilities of the portable fire extinguishing installation allows increasing the efficiency of using the stock of spent fuel and compressed gas. The specified result is achieved due to the possibility of choosing the most optimal mode of operation of the installation when extinguishing a specific fire.

The first controllable valve may be secured to the barrel body. To prevent liquid from entering the gas supply pipe, a non-return valve is installed between the outlet of the gas supply valve and the liquid-gas mixing chamber.

The second controlled valve may have a different design form. In particular, the second controllable valve may include a fixed disk connected to the barrel body. The disk has a central hole coaxial with the central channel of the atomizer and peripheral holes located around the central hole. In this embodiment, the atomizer has the ability to rotate about the axis of symmetry of the Central channel. The peripheral openings of the disk are made in such a way that when the nozzle is rotated, these openings are aligned with the inlet openings of the peripheral channels of the atomizer. For ease of regulation of the OTV spraying mode, the controlled valve is equipped with a control lever that is connected to the sprayer.

The central channel may be formed by a cylindrical surface. Other forms of execution of the cylindrical channel are possible. So, for example, the central channel may have a conical expanding shape. In a preferred embodiment, a jet-centrifugal nozzle is installed in the cavity of the central channel, which ensures effective atomization of the OTV. The peripheral channels of the atomizer can be made in the form of a conical tapering section, a cylindrical section and a conical expanding section, sequentially conjugated from the mixing chamber side.

The liquid-gas mixing chamber may be provided with a cylinder-shaped housing. Slit channels for supplying liquid are arranged in the wall of the housing, perpendicular to the axis of symmetry of the chamber. In other warrants of the execution of the chamber for mixing liquid and gas, the channels performed in the wall of the housing may have a cylindrical shape.

In order to expand the functionality of a portable fire extinguishing installation by regulating the shape of the sprayed stream and the angle of the taper of the torch of the generated gas-droplet stream, a controlled nozzle is installed behind the exit section of the spray channels.

In one design option, the controlled nozzle includes a mount and a plate configured to move relative to the outlet openings of the gun channels. At least two groups of channels are formed in the plate. In the first position of the plate opposite the outlet openings of the channels of the atomizer is the channel of the first group. In the second position of the plate opposite the outlet openings of the channels of the atomizer are the channels of the second group. The plate is made with the possibility of translational movement in a plane orthogonal to the axis of symmetry of the central channel of the atomizer.

The plate can be made with three groups of channels. In this case, the first group is formed by a cylindrical channel. The diameter of the cylindrical channel does not exceed the maximum distance between the edges of the diametrically opposite outlet openings of the peripheral channels. The second group of channels is formed in this case by at least one row of channels located along a circle. The third group is formed by channels located along a straight line segment.

Design options for a controlled nozzle with a specific orientation of the channels of the second and third groups are possible. So, for example, the axis of symmetry of the channels of the second group can intersect the axis of symmetry of the central channel of the atomizer at an acute angle from the side of the liquid-gas mixing chamber when the channels of the second group are opposite the outlet openings of the atomizer channels.

The axis of symmetry of at least part of the channels of the third group can also intersect the axis of symmetry of the central channel of the sprayer at an acute angle from the side of the liquid-gas mixing chamber when the channels of the third group are located opposite the outlet openings of the sprayer channels. In another design variant, the nozzles of the axis of symmetry of the channels of the third group are parallel to the axis of symmetry of the central channel of the atomizer.

The use of a controlled nozzle allows you to change the shape of the generated atomized flux OTV. At various positions of the nozzle plate, the generated flow has a conical or flat shape.

In a backpack version of the design of a portable fire extinguishing installation, a container for storing liquid OTV and a cylinder with compressed gas are installed on a backpack device.

The invention is further illustrated by the description of a specific example of the design of a portable backpack fire extinguishing installation. The accompanying drawings show the following:

figure 1 is a schematic diagram of a portable fire extinguishing installation;

figure 2 is a longitudinal section of the trunk;

figure 3 is a view of the movable plate of the controlled nozzle from the side of the sprayed stream of OTV;

figure 4 is a transverse section along the plane BB of the plate of the controlled nozzle shown in figure 3;

figure 5 is a transverse section along the plane GG of the plate of the controlled nozzle shown in figure 3;

figure 6 is a transverse section along the plane BB of the barrel shown in figure 2, with the open position of the second controlled valve;

Fig.7 is a transverse section along the plane BB of the barrel depicted in Fig.2, with the closed position of the second controlled valve.

The portable fire extinguishing installation depicted in figure 1, contains a container (container) 1 for storing liquid OTV, which is used as water with additives of salts and film-forming foaming agent or water without additives. The volume of the tank 1 is 15 liters. A shut-off valve 2 is installed on the tank 1. The installation includes a system for supplying an OTV of a displacing type. The system contains a high pressure cylinder 3, which is filled with compressed gas (air). The cylinder 3 is connected to the compressed gas supply pipe using a sealed detachable connection 4. A pressure gauge 5 and a shut-off valve 6 are installed on the cylinder connection 3. The gas cavity of the container 1 is connected to the cylinder 3 through a supply pipe with a gas reducer 7, which is used as a means of regulation ( decrease) gas pressure. Capacity 1, cylinder 3, gear 7 and inlet pipelines with shutoff valves are installed on the shoulder bag of the operator (user).

The structure of the installation includes a barrel 8, in the housing of which there are fluid supply valves controlled by the trigger mechanism 9, and a chamber for mixing liquid and gas. A multi-channel sprayer 10 is installed in the output part of the barrel 10. A controlled nozzle with a movable plate 11 is fixed to the output section of the sprayer channels on the sprayer housing 10. The liquid and gas supply valves are connected through the supply pipes 12 and 13, respectively, to the drain pipe of the tank 1 and to the cylinder connection 3 through reducer 7. The installation is equipped with means for regulating the OTV spraying mode, which is made in the form of two controlled valves. The first controlled valve 14 is installed on the pipe 13 connecting the cylinder 3 with the gas supply valve, which is installed in the barrel body 8. In the considered design warrant, the first controlled valve 14 is mounted on the barrel body. The second controlled valve is installed in the barrel 8 between the chamber for mixing liquid and gas and the atomizer 10 and is configured to open and close the bore of the peripheral channels of the atomizer when the atomizer rotates about the axis of symmetry of the central channel. The angular position of the second valve is controlled using the lever 15.

A controlled nozzle with a movable plate 11 is mounted on the barrel with the help of the mount 16 (see figure 2). A central cylindrical channel 18, arranged coaxially to the cylindrical body 17, is made in the rotatable housing 17 of the spray gun. Three peripheral channels are arranged uniformly around the circumference of the central channel 18. Each peripheral channel of the spray gun is made in the form of a conical tapering section 19 of the liquid and gas mixing chamber connected in series , section 20 of a cylindrical shape and section 21 of a conical expanding shape. The plate 11 is arranged to move relative to the outlet openings of the nozzle channels in a plane orthogonal to the axis of symmetry of the cylindrical central channel 18.

In the central channel 18 of the sprayer, from the side of the outlet section of the channel, a jet-centrifugal nozzle 22 is installed. The flow channel of the nozzle 22 consists of three parts. The input chamber 23 of the nozzle 22 is made in the form of a cylindrical channel. A tangential channel 25 is formed in the wall of the centrifugal chamber 24. The exit chamber 26 has the shape of a tapering conical channel.

The second controlled valve, which is part of the means for regulating the OTV spraying mode, includes a fixed disk 27 connected to the barrel body and a rotatable atomizer body 17. In the disk 27, a central hole 28 and three peripheral holes 29 are made, which are arranged uniformly around the circumference around the central hole 28. Figures 2 and 6 of the drawings show the relative position of the peripheral holes 29 made in the disk 27 and the inlet holes 30 of the peripheral channels of the atomizer, in which the axis of symmetry of the channel openings coincide. The axes of symmetry of the central hole 28 of the disk and the central channel 18 of the atomizer also coincide. With this position of the rotatable housing 17 of the atomizer relative to the stationary disk 27, the second controlled valve is in the open position.

In the closed position of the second controllable valve, shown in Fig. 7 of the drawings, when the rotatable housing of the spray gun 17 is rotated, the passage section of the peripheral channels of the spray gun is completely blocked by the surface of the fixed disk 27 (the axis of symmetry of the holes do not coincide). In this position of the second controlled valve, the central channel 18 of the atomizer remains open, since the rotation of the housing 17 is relative to the axis of symmetry of the central channel 18 of the atomizer.

In front of the disk 27 in the barrel housing is a chamber 31 for mixing liquid and gas. The housing 32 of the chamber 31 has a cylindrical shape. Slit channels 33 for supplying liquid are formed in the wall of the housing 32. The channels 33 are oriented perpendicular to the axis of symmetry of the chamber 31. The liquid OTV is supplied to the slotted channels 33 through a flow-through annular channel 34 formed between the barrel body and the body 32 of the liquid-gas mixing chamber. The inlet of the channel 34 is in communication with the outlet of the fluid supply valve, which is controlled by the trigger mechanism 9. Gas is supplied to the chamber 31 through the channel 35, the input of which is in communication with the outlet of the gas supply valve, controlled by the trigger mechanism 9. Between the outlet of the feed valve gas and chamber 31 mixing liquid and gas mounted check valve nipple type. The non-return valve consists of a central body 36 and an elastic element in the form of a tube 37 pressed against the outer rim of the central body 36. Between the end wall of the channel 35 and the central body 36 fixed to it, flow channels 38 are formed that are uniformly circumferential around the base of the central body 36.

The movable plate 11 of the controlled nozzle shown in FIGS. 3-5 of the drawings is made with three groups of channels. The first group is formed by one cylindrical channel 39. The diameter of the channel 39 exceeds the distance between the edges of the diametrically opposite outlet openings of the peripheral channels of the atomizer (see FIG. 2 of the drawings). The second group is made in the form of eight cylindrical channels 40, evenly spaced around the circumference. The axis of symmetry of the channels 40 intersect the axis of symmetry of the central channel 18 of the atomizer at an angle of 30 ° from the side of the liquid and gas mixing chamber 31 when the channels of the third group are located opposite the outlet openings of the atomizer channels (see FIG. 4 of the drawings).

The third group is formed by five channels 41 located along a straight line segment. The axis of symmetry of the two channels 41, the farthest from the central channel of the third group, intersect the axis of symmetry of the central channel 18 of the sprayer at an angle of 8 ° from the side of the liquid and gas mixing chamber 31 when the channels of the third group are located opposite the outlet openings of the sprayer channels (see FIG. 5 of the drawings ) The axis of symmetry of the two channels 41 located near the central channel of the third group intersect the axis of symmetry of the central channel 18 of the sprayer at an angle of 4 ° when the channels of the third group are located opposite the outlet openings of the sprayer channels (see FIG. 5 of the drawings).

The work of a portable firefighting equipment backpack-type is as follows.

Before using the unit, the tank 1 is refilled with liquid OTV containing additives that increase the efficiency of fire fighting. Refueling the tank 1 is carried out through the valve 2, which is in the open position. In other embodiments of the installation for refueling, a removable top cover of the container 1 can be used. The volume of the liquid to be filled is ~ 12 l for the fire extinguishing backpack. After refueling the tank 1 to a predetermined level of liquid OTV, the valve 2 is closed.

To charge the cylinder 3 with compressed gas, the cylinder is disconnected together with the manometer 5 and the valve 6 using a sealed detachable connection 4. The cylinder 3 is charged with compressed air to a pressure of (150 ÷ 300) · 10 ⁵ Pa from the compressor. Compressed gas is supplied through the union of the detachable connection 4 and the valve 6. located in the open position. The pressure in the cylinder 3 is controlled using a manometer 5. After reaching the required level of air pressure, the valve 6 is closed and the cylinder 3 is connected to the gas supply pipe using a detachable connection 4. Then, the gas cavity of the container 1 is pre-charged through the compressed gas supply line. To do this, open the valve 6, and compressed air enters the inlet of the gas reducer 7. The air pressure at the outlet of the reducer 7 in the supply pipe 13 and in the gas cavity of the tank 1 is maintained in the range from 8 · 10 ⁵ to 12 · 10 ⁵ Pa.

In the initial state, the first controlled valve 14 is in the closed position, and the compressed gas does not enter the inlet of the gas supply valve located in the barrel 8. The pressure in the liquid cavity of the tank 1 and in the supply pipe 12 (before entering the liquid supply valve) is set in the range from 8 · 10 ⁵ to 12 · 10 ⁵ Pa. The pressure level in the fluid supply system is selected on the basis of the required OTV flow rate in the range from 0.2 to 0.4 l / s.

The generation of the sprayed OTV stream is performed using the trigger mechanism 9, the control element of the first controlled valve 14 and the lever 15 of the second controlled valve. When operating in the single-phase OTV flow generation mode, the controlled valves are in the closed position. In this position of the valves, when the trigger mechanism 9 is triggered, only liquid OTV enters the chamber 31 for mixing the liquid and gas.

The fluid enters through an open fluid supply valve connected through a pusher to the trigger mechanism 9, an annular channel 34, slotted channels 33 and a liquid-gas mixing chamber 31 to the inlet of the second controlled valve. Due to the fact that the second valve is initially in the closed position, the liquid OTV flows only through the central channel 18 of the atomizer, the passage section of which is open when the second controlled valve is closed. Then the liquid enters the inlet cylinder chamber 23 of the jet-centrifugal nozzle 22, which is installed in the central channel 18. A part of the flow, flowing through the annular channel formed between the inner wall of the cylindrical channel 18 and the outer surface of the nozzle housing 22, enters the tangential channel 25. tangential channel 25, the liquid stream is directed into the centrifugal chamber 24, into which the main fluid flow is supplied axially from the inlet chamber 23. As a result of the interaction of the axial fluid flow minute with tangentially directed flow vortex formation occurs. The swirling flow of liquid OTV flows through the narrowing conical channel of the outlet chamber 26 of the nozzle and is directed into the surrounding space. Beyond a slice of the central channel 18, a swirling fluid flow, interacting with the air of the surrounding space, is sprayed and a directional fine-sprayed flux of flux is generated with a torch opening angle of ~ 10 °. In the single-phase mode of spraying the OTV, the delivery range of the OTV is from 4 to 8 m with a liquid flow rate of 200 to 300 g / s.

An additional change in the shape of the sprayed OTV stream is carried out using a controlled nozzle installed behind the nozzle channel cut-off. When the plate 11 is translationally moving in a plane orthogonal to the axis of symmetry of the central channel 18, a selected channel group of the plate 11 is located opposite the nozzle channel openings.

To generate a flat stream of sprayed OTV with a low liquid flow rate (up to 200 g / s), a third group of channels of the plate 11 is used. In this case, the liquid is sprayed through five channels 41 located along a straight line segment (see FIGS. 3 and 5 of the drawings). Due to the angular displacement of the axes of symmetry of the peripheral channels relative to the axis of symmetry of the central channel 41, the sprayed stream expands in one plane, and in the orthogonal plane, the sprayed stream has minimal dimensions. It is advisable to use the sprayed OTV stream having a flat shape for extinguishing lower forest fires and extinguishing fires.

If it is necessary to generate a sprayed stream of OTW with a conical torch and a taper angle of 30 ° to 80 °, a second group of channels of the plate 11 is used (see Figs. 3 and 4 of the drawings). When moving the plate 11, the holes 40, oriented at an acute angle to the axis of symmetry of the central channel 18 and evenly spaced around the circumference, are located opposite the outlet openings of the peripheral channels of the atomizer. As a result of the angular displacement of the channels 40 relative to the axis of symmetry 18 of the central channel and, accordingly, relative to the axis of symmetry of the peripheral channels of the atomizer, the sprayed OTW stream has a conical shape with an angle at the apex of the conical surface up to 80 °. The formed conical sprayed stream can be effectively used, for example, to create a gas-droplet cooling curtain for extinguishing intense foci of ignition and extinguishing foci of ignition of flammable liquids.

To work in the mode of generating a single-phase OTF stream in the form of a compact jet with an opening angle of ~ 10 °, the first group of channels of the plate 11 is used. In this case, a cylindrical channel 39 is placed coaxially with the central channel 18 (see FIGS. 2 and 3) drawings). Due to the fact that the diameter of the channel 39 exceeds the distance between the edges of the diametrically opposite outlet openings of the peripheral channels of the atomizer, the plate 11 does not affect the shape and other characteristics of the generated OTV stream in this mode of operation.

The arithmetic mean droplet size in the generated single-phase flow was from 70 to 90 μm with a liquid OTV flow rate of 200 to 300 g / s and an air flow rate of 5 g / s. It should be noted that in this mode of operation, compressed gas is used only to pressurize the gas cavity of tank 1. The resulting droplet size of the HFA in a single-phase fine-sprayed HSS stream corresponds to the optimal size of the droplets of the fine spray, which are highly effective in extinguishing foci of ignition of solid and liquid combustible substances.

If it becomes necessary to increase the speed of liquid droplets in the generated flow and, accordingly, increase the range of supply of the finely dispersed flux of OTV by distances of more than 8 m, the operator switches the mode of atomization of the OTV from single-phase to two-phase using two controlled valves. To do this, open the first controlled valve 14 and moves the lever 15 of the second controlled valve to the stop. In the open position of the controlled valve 14, compressed gas flows from the pipe 13 to the inlet of the gas supply valve installed in the barrel 8. As a result of rotation with the lever 15 of the barrel 17, the inlet openings 30 of the peripheral channels of the atomizer occupy a fixed position in which the inlet openings 30 are aligned peripheral holes 29 of the disk 27. At this position of the disk 27 and the housing 17 fully open passage sections of the peripheral channels of the atomizer. In this case, the bore of the central channel 18 remains open, since the rotation of the housing 17 is relative to the common axis of symmetry of the central channel 18 of the atomizer and the central hole 28 of the fixed disk 27.

When the trigger mechanism 9 opens, the valves for supplying liquid and gas. located in the barrel. The liquid, similar to the single-phase OTV spraying mode, enters through an open liquid supply valve, an annular channel 34, slotted channels 33 into the cylindrical cavity of the liquid-gas mixing chamber 31. Simultaneously with the supply of fluid to the chamber 31 through the axial channel 35, air is supplied under excessive pressure. Air is supplied to the chamber 31 through the inlet pipe 13, the open first controlled valve 14, the open gas supply valve connected through the pusher to the trigger mechanism 9, and the non-return valve that prevents the flow of liquid OTV into the channels and pipelines of the gas supply. The check valve opens when the air pressure in the supply channel 35 exceeds the total pressure, including the static pressure in the cavity of the chamber 31 and the pressure of the elastic tube 37 against the outer rim of the central body 36. Compressed air enters from the channel 35 into the chamber 31 through the flow channels 38 and an annular gap formed between the tube 37 and the central body 36.

In chamber 31, a stream of compressed gas is mixed with dispersed liquid flowing into the cavity of chamber 31 through narrow slotted channels 33. As a result of preliminary mixing of liquid droplets with gas in front of the inlet channels of the atomizer, a gas-droplet stream is formed, which is then directed to profiled peripheral channels and to a cylindrical central sprayer channel equipped with a centrifugal jet nozzle. In the peripheral channels of the nebulizer, an acceleration of the gas-droplet flow and additional dispersion of liquid droplets occur during the flow through the successively connected sections 19, 20 and 21 of each channel. Using a jet-centrifugal nozzle, a gas-droplet flow swirls in the central channel. In the process of vortex formation in an accelerated gas-droplet flow, additional dispersion of liquid droplets occurs.

Additional control over the shape of the sprayed OTV stream is performed using a controlled nozzle mounted on the nozzle section of the spray gun. The shape of the sprayed stream and the angle of the cone of the torch flow are controlled in the same way as the above example of the operation of the fire extinguishing installation in the mode of generating a single-phase atomized flux OTV. The shape and size of the sprayed stream, as well as the size of the liquid droplets for the two-phase stream can be selected in the optimal range of values due to the corresponding profiling of the peripheral channels of the atomizer, the choice of their number and location of the channels relative to the central channel 18.

The arithmetic average droplet size in the generated two-phase flow is from 20 to 50 μm at a flow rate of liquid OTV from 200 to 400 g / s. In this case, the total air flow rate used to pressurize the gas cavity of the tank 1 and to form a two-phase flow in the liquid and gas mixing chamber 31 varies from 5 to 12 g / s. The resulting droplet size of the HFA in the generated stream corresponds to the optimal droplet size of the finely dispersed liquid used to effectively extinguish foci of ignition of solid and liquid combustible substances.

The use of a portable fire extinguishing installation with dual-mode control allows you to expand the range of control of the spraying of the OTP and use one multifunctional installation for alternating flow generation in single-phase and two-phase modes. This feature provides the adjustment of the range of OTV flow in the range from 4 to 12 m. At the same time, the switching of the OTV spraying modes depending on the fire extinguishing conditions allows the most efficient use of both the stock of liquid OTP and the stock of compressed gas. So, for example, when extinguishing fires and extinguishing dead forest fires, when there is no need to supply HFA over distances of more than 8 m, the single-phase HSS spraying mode is switched on and, using a controlled nozzle, the optimal shape of the sprayed flow and HSS flow rate are selected. With this mode of operation, the consumption of compressed gas and liquid OTV is significantly reduced.

If it is necessary to extinguish intense foci of ignition, it is necessary to increase the feed range of the sprayed HFA stream to at least 10 m. For this, the operator, using two controlled valves, switches on the two-phase mode of spraying the HSS. At the same time, the shape of the sprayed stream and the flow of OTV are regulated through the use of a controlled nozzle mounted on a section of the channels of the sprayer. The optimal shape of the sprayed stream and the flow of HSS can be preselected by profiling the peripheral channels of the sprayer, selecting their number and location of the relative central channel of the sprayer.

The listed possibilities associated with the dual-mode control of OTV spraying provide the versatility and multifunctionality of a portable fire extinguishing installation. On the other hand, due to the expansion of the control range of the parameters of the sprayed OTV stream, the possibility arises of the most rational use of the stock of liquid OTV and compressed gas. Improving the efficiency of using liquid HSS and compressed gas is important when using a portable fire extinguishing system from gas station means, for example, in the conditions of extinguishing forest fires.

The above-described exemplary embodiment of the invention is based on a specific embodiment of the structural elements of a portable fire extinguishing installation, but this does not exclude the possibility of achieving a technical result in other special cases of the invention. So, for example, both controlled valves can be placed in the barrel. Controlled valves of various designs can be used to control the OTV spraying mode. A portable fire extinguishing installation can be used without an auxiliary control nozzle. In the latter case, the required shape of the sprayed OTW stream is achieved by profiling the peripheral channels of the atomizer, choosing their number and location.

A portable fire extinguishing installation, made according to the invention, can be used as a multifunctional fire extinguishing means for extinguishing various types of fires, including fires of flammable liquids, dead forest fires and fires of solid and liquid substances in residential premises.

Claims (17)

1. A portable fire extinguishing installation containing a container for storing a liquid fire extinguishing agent, at least one compressed gas cylinder, a means for regulating gas pressure, a barrel with a fire extinguisher atomizer, liquid and gas supply valves and a trigger mechanism, means for regulating the spraying of a fire extinguishing agent, and pipelines connecting the container and the cylinder with liquid and gas supply valves, characterized in that the barrel is equipped with a liquid and gas mixing chamber, the sprayer is made with a central channel and, according to with at least one row of peripheral channels located around the Central channel, while the means for regulating the spraying of the extinguishing agent includes two controlled valves, the first of which is installed on the pipeline connecting the cylinder to the gas supply valve, the second controlled valve is located between the mixing chamber liquid and gas and the outlet openings of the peripheral channels of the atomizer, and the second controlled valve is configured to open and close the bore of the peripheral sprayer channels. 2. Installation according to claim 1, characterized in that the first controlled valve is mounted on the barrel. 3. Installation according to claim 1, characterized in that a check valve is installed between the outlet of the gas supply valve and the mixing chamber for liquid and gas. 4. Installation according to claim 1, characterized in that the second controlled valve includes a disk connected to the barrel body, in which a central hole is made, coaxial with the central channel of the atomizer, and peripheral holes located around the central hole, wherein the disk is installed between the mixing chamber and the atomizer, the atomizer is rotatable relative to the axis of symmetry of the central channel, and the peripheral holes of the disk are arranged so that when the atomizer is rotated, the periphery The disk aperture holes are aligned with the inlet ports of the gun’s peripheral channels. 5. Installation according to claim 4, characterized in that the second controlled valve is equipped with a control lever connected to the sprayer. 6. Installation according to claim 1, characterized in that the central channel of the atomizer is formed by a cylindrical surface. 7. Installation according to claim 1, characterized in that a jet-centrifugal nozzle is installed in the central channel of the sprayer. 8. Installation according to claim 1, characterized in that the peripheral channels of the atomizer are made in the form of a conical tapering section, a cylindrical section and an expanding conical section, sequentially conjugated from the side of the liquid and gas mixing chamber. 9. Installation according to claim 1, characterized in that the chamber for mixing liquid and gas is provided with a body in the form of a cylinder, while in the wall of the body there are slotted liquid supply channels located perpendicular to the axis of symmetry of the chamber. 10. Installation according to claim 1, characterized in that a controlled nozzle is installed behind the output section of the spray channels. 11. Installation according to claim 10, characterized in that the controlled nozzle comprises a fastener and a plate configured to move relative to the outlet openings of the atomizer channels, at least two groups of channels formed in the plate so arranged that the first position of the plate opposite the outlet openings of the spray channels of the channel is the first group, with the second position of the plate opposite the outlet openings of the spray channels are the channels of the second group. 12. Installation according to claim 11, characterized in that the plate is made with the possibility of translational movement in a plane orthogonal to the axis of symmetry of the central channel of the atomizer. 13. Installation according to claim 11, characterized in that the plate is made with three groups of channels, wherein the first group is formed by a cylindrical channel, the diameter of which is not less than the maximum distance between the edges of the diametrically opposite outlet openings of the peripheral channels, the second group is formed of at least one row of channels located along a circle, the third group is formed by channels located along a straight line segment. 14. The apparatus of claim 13, wherein the axis of symmetry of the channels of the second group intersect the axis of symmetry of the central channel of the atomizer at an acute angle from the side of the liquid-gas mixing chamber when the channels of the second group are opposite the outlet openings of the atomizer channels. 15. The apparatus of claim 13, wherein the axis of symmetry of at least a portion of the channels of the third group intersects the axis of symmetry of the central channel of the sprayer at an acute angle from the side of the liquid and gas mixing chamber when the channels of the third group are located opposite the outlet openings of the sprayer channels. 16. Installation according to item 13, wherein the axis of symmetry of the channels of the third group are parallel to the axis of symmetry of the central channel of the atomizer. 17. Installation according to claim 1, characterized in that the storage tank for the liquid extinguishing agent and the compressed gas cylinder are mounted on the backpack device.

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