RU192065U1 - Carriage barrel with medium and low multiplicity air-mechanical foam generator - Google Patents

Abstract

The invention relates to fire extinguishing and fire explosion prevention techniques, namely, fire extinguishing and fire and explosion prevention means with medium and low multiplicity air-mechanical foam or sprayed and dispersed water. To increase the efficiency of fire extinguishing and fire and explosion prevention due to the possibility of generating medium and low foam generation and delivery over increased distances multiplicity with the ability to control the multiplicity of the foam in the case of using water as a fire extinguishing agent with additives of a foaming agent or sprayed and dispersed water, if water is used as a fire extinguishing agent without additives of a foaming agent, an air-mechanical foam generator for a fire monitor that forms a pressurized water stream with additives of a foaming agent, contains a housing in the form of at least one hollow cylinder and a mesh coaxially installed in the housing in (in the form of an axisymmetric truncated cone with open bases on the input side of the generator the water flow coming from the gun barrel from the foaming agent and on the exit side of the air-mechanical foam generator. The housing with the mesh installed in it is equipped with coaxial attachment to the gun barrel with the formation of an annular gap between the walls of the housing with the mesh installed in it and the gun barrel with the ability to eject air through the annular gap between the walls of the housing with the mesh installed in it and the gun barrel and the mesh installed in the housing into the water stream coming from the gun barrel with the addition of a foaming agent and receiving at the exit from the generator a stream of air-mechanical foam. The gun barrel is equipped with an air-mechanical foam generator of the above construction. f-ly, 16 wp f-ly, 11 ill.

Description

Technical field

The invention relates to fire extinguishing and fire explosion prevention techniques, namely, fire extinguishing and fire explosion prevention means with medium and low multiplicity air-mechanical foam or sprayed and dispersed water, and can be used for rapid formation and even distribution of medium and low multiplicity foam or sprayed and dispersed water by area of fire of flammable liquids, solid combustible materials, as well as for cooling and / or fireproof explosion-proof protection of buildings, structures, machinery, equipment, flammable or explosive materials in manual, automatic and remote modes of operation and control.

State of the art

It is known that at different stages of fires and fire and explosion hazard situations, namely at the stages of occurrence, development, intense burning, attenuation and possible resumption of a fire or emergency, it is effective to use different (low, medium or high) multiplicity, or sprayed and dispersed water, which accordingly requires the timely use of various foam generators and fire barrels capable of generating either high multiplicity foam, or foam of medium multiplicity, or foam of low multiplicity, or to provide sprayed or dispersed water.

At the same time, the well-known foam generators and fire monitors in the vast majority of cases are specialized and are capable of generating only one fire extinguishing agent - or water-mechanical foam of a certain (high, medium or low) multiplicity or jet of water of a certain dispersion, therefore, to effectively extinguish a fire and fire and explosion prevention on different stages and in different situations requires the availability and rapid replacement of various fire extinguishing agents, which significantly complicates and reduces the effectiveness of fire extinguishing processes and fire and explosion prevention.

In fire fighting equipment, fire monitors with nozzles are known for supplying a fire extinguishing agent in the form of atomized water or low-pressure air-mechanical foam to the fire at a distance.

The advantage of the known fire monitors with nozzles is the relatively high range of dispersed and sprayed water of about 50-60 meters and the ability to control the flow rate and angle of the spray flame extinguishing agent, however, using well-known fire monitors can only produce air-mechanical foam with a low ratio of up to 7-10 with its range feed up to 40-50 meters, which in some cases does not provide the required fire extinguishing efficiency and proper protection of operators.

It is also known that the most effective fire extinguishing agent is medium-sized air-mechanical foam with a multiplicity of 30 ± 10, but the well-known medium-sized air-mechanical foam generators usually have a medium-range foam supply range of not more than 20-30 m.

To increase the range of the jets of fire extinguishing substances from the fire monitors use nozzles.

Known nozzles for supplying a fire extinguishing composition with firefighters stationary fire monitors included in a set of fire tankers, which contains a housing having an input end configured to connect to a fluid supply device and an output end, and a screen. The screen completely obscures the output end of the housing, while there is a gap between the screen and the output end of the housing for fluid passage. The technical result in the form of providing in the nozzle the adjustment of the gap for the passage of liquid and, therefore, the flow regardless of the impact on the screen of the fluid flow is achieved due to the fixed installation of the screen and the presence of a sleeve freely covering the output end (3) of the housing (1). The sleeve (9) can move around the housing under the action of a drive, including a screw-nut gear and a servo drive. The sleeve is kinematically connected to the output link of the screw-nut transmission, the input link of which is connected to the servo drive. When moving the sleeve, the gap for the passage of fluid changes and the fluid flow changes [RU 135926 A62C 31/02 Published: 12/27/2013 Bull. No. 36]

Known nozzle fire monitor for supplying a fire extinguishing fluid in the fire, including stream-forming nozzle, nut, streamlined insert, mounted on the longitudinal stabilizing ribs in the nozzle, and the nozzle of the fire monitor and the fairing in cross section along its longitudinal axis changes shape from a circle to oval shape with a long axis of the oval, parallel to the horizontal line of the level of the front of the fire, the nozzle, fairing and stabilizing plates are made with blade edges at the ends of the jet stream exit, the fairing and stabilizing plates at the jet inlet are made with streamlined shapes, the blade edge of the nozzle is made by a groove of the nozzle outlet end face in a semicircle, which allows to increase the range, width and feed force of the extinguishing agent stream while decreasing its flow rate over the fire fighting area. [RU 173819 А62С 31/02 Published: 09/12/2017 Bull. No. 26].

Known portable fire monitor for dispensing a fire extinguisher into the combustion zone, which to increase the efficiency of fire extinguishing contains a receiving casing with a barrel, consisting of pressure and dispensing pipes, interconnected via a check valve, connected via a rotary pressure device with ring sealing cuffs a fixing device equipped with a control handle, and mounted on a tripod adjustable base, and connects to the dispensing pipe There is a hose line with a nozzle control unit at the free end, moreover, air-foam nozzles and a water nozzle for an additional compact jet mounted as a spare on the base are used as nozzles, and a four-blade damper is installed inside the barrel body by means of a removable ring device mounted on the trunk [RU 2411971 A62C 31/00 Published: 02/20/2011 Bull. No. 5]

Known combined fire monitor barrel, comprising a housing with a pressure gauge connected at one end to a receiving armature, a valve for supplying water with a handle, a foam mixer, a handle for guiding the barrel, characterized in that a branch with a tap for mounting the outlet barrel between the water supply valve and the foam mixer is mounted coupling half, forming an additional upper trunk. In this case, the foam mixer is made in the form of an ejection device with a nipple for suction of the blowing agent, and a cross-shaped stabilizer is installed in the output shaft [RU 50251 Published: 12/27/2005 Bull. No. 36]

Known generator of low-level foam for sub-layer fire fighting in the tank, comprising a housing with an opening for supplying air, an opening for the exit of foam from the housing and a nozzle for supplying a foaming solution made with a nozzle, a cylindrical mixing chamber mounted in the housing opposite the nozzle, a diffuser associated with the outlet the hole of the mixing chamber, the nozzle nozzle is made with a diameter, the size of which is not less than the size of the inner diameter of the mixing chamber, and the mixing chamber is mounted on the nozzle with opla, and on its side surface holes are made for air supply. In a preferred embodiment of the generator, the mixing chamber is fixed to the nozzle by means of a threaded connection. [RU 171877 Published: 06/20/2017 Bull. No. 17].

The Osipov fire barrel is known, containing a universal water spray nozzle with an ejection device made in the form of a confuser-diffuser nozzle with certain geometric dimensions and angles. The barrel is mounted on a cart mounted on a fire truck. A container with a hardener is also mounted on the trolley to obtain quick-hardening foam or an additive to improve the extinguishing properties of the extinguishing substance. The barrel is equipped with an intake device for feeding these components from an external tank. The invention provides an increase in the efficiency of functioning, improved mobility and the expansion of the scope of the barrel. [RU 2111782 A62C 31/02 A62C 31/12 Published: 05/27/1998]

Known foam generator type KSS, intended for use in automatic fire extinguishing systems by generating highly multiple polydisperse foam in conditions of smoke in the room when blocking fast-burning products with high-polydisperse foam and containing a spray, foam nozzle and a two-phase flow divider. The sprayer is connected to the foam nozzle body made in the form of a cylindrical shell mounted coaxially and axisymmetrically with respect to the spray gun, and at least three windows for ejecting air are made on the foam nozzle body, in the part located closer to the spray gun, and the outlet is fixed a two-phase flow divider made in the form of a round mesh, and the atomizer body is made with a channel for supplying liquid and has a coaxial sleeve rigidly connected to the body with a nozzle fixed in its lower part made in the form of a cylindrical two-stage sleeve, the upper cylindrical step of which is connected by a threaded connection to a central core installed with an annular gap relative to the inner surface of the cylindrical sleeve, and consisting of a cylindrical part with a swirl fixed coaxially in its lower part, made in the form of a cylinder with a central throttle a hole on the outer surface of which at least a two-way screw thread is made [RU 2502538 А62С 31/02 Published: 27.12. 2013 bul. No. 36]

A foam generator is known which, to increase the spraying efficiency of the extinguishing liquid solution of the foaming agent, contains a sprayer connected to the foam nozzle body made in the form of a shell mounted coaxially and axisymmetrically relative to the sprayer. The casing has in the part located closer to the atomizer at least three windows for air ejection, at the exit there is a two-phase flow divider made in the form of a round grid, a channel for supplying liquid and a coaxial sleeve rigidly connected to it with it fixed in its lower parts of a nozzle made in the form of a cylindrical two-stage sleeve. The upper cylindrical step of the sleeve is threadedly connected to a central core installed with an annular gap relative to the inner surface of the cylindrical sleeve, and consisting of a cylindrical part with a spherical segment fixed coaxially with it in the lower part, having throttle holes whose axes are located along the radii of the spherical surface, forming a spherical segment. The annular gap is connected by at least a couple of radial channels made in a two-stage sleeve, connecting it with an annular cavity formed by the inner surface of the sleeve and the outer surface of the upper cylindrical stage, the annular cavity being connected to the channel of the housing for supplying liquid. At least two rows of cylindrical throttle holes are made on the lateral surface of the cylindrical part of the central core, in its lower part connected to the spherical segment, with axes lying in planes perpendicular to the axis of the core, and at least in each row , three holes, while the axis of the throttle holes in adjacent rows are offset by an angle lying in the range of 15 ° ÷ 60 °. [RU 2450840 А62С 31/02 Published: 05/20/2012 Bull. No. 14]

A device is known for increasing the range of the jet, in which the main working stream is divided into two independent coaxial streams, one of which is working, and in the peripheral stream (stream) due to the suction of atmospheric air and an aqueous solution of a surfactant, a high-fold foam is formed that protects the main stream ( flow) from external disturbances. The device comprises a housing, a cylindrical nozzle, coaxially fixed inside the housing and directing the supply of a peripheral jet, a working agent supply pipe coaxially placed inside the nozzle, and a nozzle radially fixed in the annulus of the cylindrical nozzle and the pipe and designed to supply air and surface-active substance in the annular the gap between the main and peripheral flows, while the perforation holes are made in the working agent supply pipe, and qi indrichesky plugged nozzle washer that is inserted into the pipe and welded shut tightly [RU 2225732 A62S 31/12 Published: 20.03.2004 Bul. No. 8].

Known nozzles for a fire barrel, including a conical body, inside which a flow body is mounted, fixed by stabilizing plates in an amount of at least three, and a cylindrical nozzle-spray, characterized in that the conical body is twisted and butt-welded to scan from sheet material a thickness of 0.2 ÷ 2 mm, and in the reamer, through holes are made of at least three for fastening stabilizing plates of the body around them. In this case, the cylindrical nozzle-spray is made with an inner diameter 1.5–2 mm larger than the diameter of the smaller cone of the conical body, and is attached to it by spot welding in a circle, forming gaps between the welding points, with the possibility of air penetrating into them to form a two-phase flow near the surface in order to reduce the friction of the extinguishing fluid against the walls of the spray, leading to an increase in the flow rate and the range of the jet [RU 146274 А62С 31/02 Published: 10/10/2014 Bull. No. 28].

The closest in technical essence to the prototype analogue for the fire monitor c is a fire monitor barrel with a nozzle for spraying fire extinguishing liquid in the form of sprayed water or foam in jet and raster modes with a maximum capacity of 20 l / s and 40 l / s, including a cylindrical body , with a flow regulator installed inside, and with an output channel in the form of free space of a conical shape, a screen limited to the inside, made in the form of a bell, characterized in that the The flow path is made in the form of a stabilizer, the screen is installed at the end of the stabilizer, on the outside the output channel is limited by a guide in the form of a sleeve turning into a socket, a slider is installed on the outer surface of the casing so that it can reciprocate along the outer surface of the casing, while the tape thread is connected with a pusher fixed on the housing, and an additional helm is mounted on the slide with the possibility of moving the guide relative to the slide [RU 127640 A62C 31/02 Published: 05/10/2013 Bull. No. 13].

The closest in technical essence to the prototype analogue for the air-mechanical foam generator for the fire monitor c is a high-pressure foam generator for extinguishing, used to extinguish fires in automatic fire extinguishing systems with high-foam foam of the premises of oil pumping stations and other rooms subject to automatic fire protection, which to increase the multiplicity foam contains a hollow body in the form of a straight cylinder with open ends, nozzles for guiding the aqueous solution of the foam An indicator in the casing, installed at one end of the casing and evenly distributed over the cross-section of the generator. The nozzle (s) located in the central part of the generator cross section is extended relative to the nozzles at the periphery. The generator also contains external, internal and additional grids, each of which is made so that it forms an axisymmetric truncated cone. The internal mesh is located in the external mesh, and the additional mesh is in the internal. The base of the external mesh is connected to the other end of the housing, its truncated apex is directed towards the fire extinguishing object, the base of the internal mesh is connected to the truncated apex of the external mesh, and its truncated apex is facing the housing. The base of the additional mesh is connected to the truncated vertex of the inner mesh, and its truncated vertex is directed to the fire extinguishing object. The angle at the apex of the cone of each of the grids is equal to half the angle of spray of the jet from the nozzles, and the ratio of the total living section area of the cells of all grids to the cross-sectional area of the body is 3.5 ÷ 4. 3 [RU 2246977 A62C 5/02 Published: 02/27/2005 Bull. No. 6 (prototype)].

A common drawback of the known water-based fire extinguishing devices is the lack of efficiency due to the fact that the well-known medium and high multiplicity air-mechanical foam generators provide generation and supply of air-mechanical foam jets with a multiplicity of 20-40 only for relatively short distances up to 25-30 meters, and the known fire monitors trunks with nozzles provide the ability to generate water-air foam only low multiplicity with a multiplicity of 7-10 and to supply jets of foam low multiple sti at a distance of 40-50 meters.

At the same time, the use of known foam generators and known fire monitors in different conditions and at different stages of extinguishing fires and fire and explosion prevention usually requires the presence and regular replacement of foam generators and fire monitors for various purposes with a significant loss of time for replacement and the corresponding possibility of continuing to develop and resume burning and exacerbation of fire and explosion hazard situations, which ultimately significantly reduces the overall effectiveness of the elimination of fires and fire and explosion disgust.

Task and technical result

The main technical problem (the inventive task has not been solved so far) that hinders the possibility of the effective use of known fire extinguishing means (foam generators and fire monitors) with a relatively low range is the need for operators to be present in the vicinity of the fire and fire and explosion prevention zones, and known fire extinguishing agents are usually specialized and usually provide the formation and supply of either foam of medium multiplicity, or only high multiples STI or just sprayed water or dispersed.

At the same time, it is known that when extinguishing large-scale industrial, forest and road transport fires, a controlled, quick and uniform coating of the entire fire-hazardous area with fire extinguishing agents is required (preferably with foam of average multiplicity with a multiplicity of 30 ± 10, and at different stages of fire fighting and fire and explosion prevention it is advisable to use various fire extinguishing agents (an aqueous solution of a foaming agent or water) in various consistencies (or in the form of foam of low and medium multiplicity or sprayed and dis water) with the rapid change of their supply to the fire and fire and explosion prevention zone, which, accordingly, requires regular change of fire extinguishing means and, as a result, significantly limits the efficiency and speed of extinguishing large-scale fires using known fire extinguishing means.

The technical result achieved by using the proposed device is to increase the efficiency of fire fighting and fire and explosion prevention by providing the possibility of generating and supplying medium and low multiplicity foam with increased distance with the possibility of regulating the multiplicity of the foam in case water is used as a fire extinguishing agent with the addition of a foaming agent or sprayed and dispersed water if water is used as a fire extinguishing agent without the addition of a foaming agent .

Utility Model Essence

The problem is solved and the required technical result is achieved by the fact that the fire monitor containing means for supplying and forming a water flow with additives of a foaming agent, according to a utility model, is equipped with an air-mechanical foam generator containing

generator housing in the form of at least one hollow cylinder

and a grid coaxially installed in the generator’s body in the form of an axisymmetric truncated cone with open bases on the side of the generator’s entrance to the water stream coming from the gun barrel with the addition of a foaming agent and on the exit side of the generator of air-mechanical foam.

wherein the generator housing with the mesh installed therein is provided with means of coaxial connection to the gun barrel with the formation of an annular gap between the walls of the generator housing with the mesh installed in it and the gun barrel with the ability to eject air through the ring annulus between the walls of the generator housing with the mesh installed in it and the gun barrel and the mesh installed in the generator’s body into the water stream coming from the gun barrel with the addition of a foaming agent and receiving the output from the generator pa vozdushnomehanicheskoy flux foam

Means for coaxial connection of the generator body to the gun barrel made with the formation of an annular gap between the walls of the generator body and the gun barrel with the possibility of:

- air ejection through the said annular gap between the walls of the generator housing with the mesh installed in it and the gun barrel, through the mesh installed in the generator housing and through the annular gap between the generator housing and the mesh installed in it into the water stream coming from the gun barrel with the addition of a foaming agent and receiving at the exit of the air-mechanical foam flow generator;

- moving the generator housing with the mesh installed therein along the axis of the gun barrel with the ability to control the multiplicity and range of the flow of the air-mechanical foam generated by the generator.

- moving the casing with the mesh installed therein along the axis of the gun barrel with the possibility of increasing the multiplicity of the air-mechanical foam generated by the generator when moving the generator housing with the mesh installed to the gun barrel and reducing the frequency generated by the air-mechanical foam generator when moving the generator body with the mesh installed in it from the gun trunk;

- moving the generator housing with the mesh installed therein along the axis of the gun barrel with the possibility of increasing the supply range of the air-mechanical foam generated by the generator when moving the generator housing with the mesh installed therein from the gun barrel and reducing the supply distance of the air-mechanical foam generated by the generator when moving the generator body with the generator installed in it mesh to the gun monitor.

A grid coaxially mounted in the generator housing in the form of an axisymmetric truncated cone is oriented with a smaller open base towards connecting the generator to the gun monitor or is oriented with a large open base towards the generator to the gun monitor.

The mesh coaxially installed in the generator housing can be made of thin-walled metal sheet with holes greater than 0.8 mm and fixed in the housing by means of rings and screws.

The generator housing in a design embodiment can be made up of at least two cylindrical shells coaxially placed with an annular gap one in the other with the possibility of additional air ejection through the annular gap between the cylindrical shells and through the annular gap between the cylindrical shells and the mesh into the outgoing barrel water flow with a blowing agent.

In this case, the fire monitor is made with the possibility of generating and supplying a homogeneous air-mechanical foam of medium multiplicity with a multiplicity of 30 + 10 to the fire or fire and explosion prevention zone and supplying it to the fire or fire and explosion prevention zone at a distance of up to 100 meters or more.

At the same time, the grid installed in the generator housing

made with an area of a smaller open base equal to or greater than the area of the output section of the gun barrel;

- made with a ratio of the area of the larger open base to the area of the smaller open base from 5 to 1.5;

- manufactured with an effective hole area commensurate with the cross-sectional area of the output section of the gun barrel.

The gun barrel may contain nozzles with the ability to control the amount and opening angle of the water stream with the addition of a foaming agent and with the ability to control the amount of ejection supply of the foaming solution into the water stream.

Brief Description of the Drawings

The essence of the utility model is illustrated by the drawings, which show: 1 - the housing of the air-mechanical foam generator of medium and low multiplicity for monitors foam (foam generator); 2 - nozzles of the gun monitor with the ability to eject and adjust the displacement of the foaming agent; 3 - a grid installed in the housing in the form of an axisymmetric truncated cone with open bases on the side of the generator’s entrance to the water stream coming from the gun barrel with the addition of a foaming agent and on the exit side of the air-mechanical foam generator; 4 - the mesh ring is small; 5 - the mesh ring is large; 6 - screws for attaching the mesh to the foam generator body; 7 - a helm for moving the housing with the mesh installed therein along the axis of the gun barrel with the possibility of moving the housing with the mesh installed therein to the gun barrel or moving the housing with the mesh installed therein from the gun barrel with the appropriate ability to control the multiplicity and feed range of the air-mechanical foam generated by the generator ; 8 - directions of flows of water ejected into the flow with additives of an air blowing agent; 9 - a blowing agent ejector in the gun barrel nozzle; 10 - a device for controlling the flow of foaming agent into the flow of water entering the fire monitor barrel; 11 - helm controlling the flow of water in the gun barrel; 12 - deflector gun mount; 13 - flow-forming housing nozzle gun mount; 14 - chipper water flow with a foaming agent in the nozzle of the gun barrel; 15 - dispenser; 16 - the handle of the steering wheel 7; 17 - reinforcement of means for connecting the generator housing with the mesh installed therein to the gun barrel nozzle; 18 - directions of movement of the generator housing relative to the nozzle when adjusting the frequency and distance of supply of foamed extinguishing agent (OTV) in the form of medium or low airborne foam.

In FIG. Figures 1 and 2 show a cross section of the proposed generator for the gun monitor and gun monitor with a nozzle and a foam generator in a constructive embodiment of a cone-shaped mesh with expansion in the direction of movement of the foamable water stream with additives of a foaming agent and in a constructive embodiment of the foam generator body in the form of one hollow cylindrical shell.

In FIG. Figure 1 shows the mode of operation of the foam generator with obtaining the minimum low multiplicity and maximum range of air-mechanical foam supply, provided by the maximum retraction of the generator housing with the mesh installed in it from the gun barrel and the minimum opening angle of the water flow with the foaming agent in the gun barrel and, accordingly, with the minimum ejection of air into the stream water with a foaming agent,

and in FIG. 2 - in the mode of obtaining the maximum average multiplicity and the minimum range of supply of air-mechanical foam provided by the maximum retraction of the generator housing with the mesh installed in it from the gun barrel provided by the maximum retraction of the generator housing with the mesh installed in it to the monitor and the maximum opening angle of the water flow with the foaming agent in monitors and, accordingly, with maximum ejection of air into the water stream with a foaming agent.

In FIG. Figures 3 and 4 show the corresponding operating modes of the foam generator in a constructive embodiment of a cone-shaped mesh with expansion in the direction of movement of the foamable water stream with additives of a foaming agent and in a constructive embodiment of the foam generator body in the form of two cylindrical shells coaxially placed with an annular gap one in the other with the possibility of additional ejection air through the annular gap between the cylindrical shells and through the annular gap between the cylindrical echaykami grid and to the output of the fire monitor the flow of water with a foaming agent.

In FIG. Figures 5 and 6 show the corresponding operating modes of the foam generator in a constructive embodiment of a cone-shaped mesh with expansion against the direction of movement of the foamable water flow with additives of a foaming agent and in a constructive embodiment of the foam generator housing in the form of two cylindrical shells coaxially placed with an annular gap one in the other with the possibility of additional ejection air through the annular gap between the cylindrical shells and through the annular gap between the cylindrical with shells and a net into the stream of water with a foaming agent emanating from the gun barrel.

образца предлагаемого генератора воздушномеханической пены средней и низкой кратности для лафетного ствола (пеногенератора) и лафетного ствола с насадком и пеногенератором в конструктивном варианте производительности 120 л/сек, результаты испытаний которого представлены ниже.In FIG. 7-9 are photo views of the side, front and

a sample of the proposed generator of air-mechanical foam of medium and low multiplicity for the gun barrel (foam generator) and the gun barrel with a nozzle and a foam generator in the constructive embodiment of a productivity of 120 l / s, the test results of which are presented below.

образца лафетного ствола с насадком со снятым пеногенератором в конструктивном варианте производительности 120 л/сек.In FIG. 10-11 are photo views of the side and

a sample of the fire monitor with a nozzle with a foam generator removed in a constructive embodiment of a productivity of 120 l / s.

Implementation and industrial implementation of utility model

The air-mechanical foam generator of medium and low multiplicity (hereinafter referred to as the foam generator) for the fire monitor constructively comprises (Fig. 1-6) a housing in the form of at least one hollow cylinder and a mesh coaxially mounted in the housing in the form of an axisymmetric truncated cone with open bases on the entrance side to the generator of the water stream coming from the gun barrel with the addition of a foaming agent and from the exit side of the generator of the air-mechanical foam.

The generator housing with the mesh installed in it is equipped with coaxial attachment to the gun barrel with the formation of an annular gap between the walls of the housing with the mesh installed in it and the gun barrel with the possibility of air ejection through the annular gap between the walls of the housing with the mesh installed in it and the gun barrel and installed in the housing, a grid into the stream of water emanating from the gun barrel with the addition of a foaming agent and receiving at the outlet of the generator a stream of air-mechanical foam.

As a fire monitor barrel, a fire monitor barrel with a nozzle, with ejection and adjustment of water flow rate, hereinafter referred to as NSLER, can be used.

The NSLER may have the ability to smoothly adjust the angle of the spray angle of the jet in the range from 0 ° to 90 ° by moving the deflector (12) along the axis of the nozzle, achieved by rotating the helm (7) using the handles of the helm (16).

In addition, the NSLER has the ability to smoothly control the flow of water by moving the flow-forming body of the nozzle (13) along the axis of the nozzle, achieved by rotating the helm of the water flow (11). When moving the flow-forming body (13) forward, it abuts against the dispenser (15) and closes the water flow. At the maximum distance (see Fig. 1, 2) the maximum water flow.

The foaming agent ejects into the main stream due to rarefaction in the area of the ejector nozzle (9). In this case, it is possible to control the flow rate of the foaming agent using the shut-off device (10). The foaming agent is sprayed into the main water stream due to the chipper (14) located at the outlet of the nozzle.

A cone-shaped mesh (3) is installed inside the foam generator housing (1), with a mesh size of at least 0.8 mm, rolled from perforated steel. The conical mesh (3) can be installed in the direction of the expanding conical part in the direction of the discharge of the extinguishing agent (Fig. 1-4) or installed in the direction of the expanding conical part in the direction of the gun barrel (Fig. 5, 6) and is fixed on the rings of the grid small and large (4, 5) which are attached to the body of the foam generator (1) with screws (6).

The design of the NSLER was modernized due to the installation of steering wheels on it for more efficient control of the displacement of the displacement and the angle of the spray jet, as well as by increasing the diameter of the inlet section of the nozzle (9) and the diameter of the channel of the ejected foaming agent, which increased the flow rate of the foaming agent to the water flow rate to four%. Also, a shut-off device (10) has been added, with which you can adjust the flow rate of the blowing agent.

The principle of operation of the device is as follows: from the nozzle of the gun mount (2), a fire extinguishing agent in the form of a stream of water with additives of a foaming agent is thrown into the cavity of the foam generator (1). At a minimum spray angle (see Figs. 1, 3, 5), almost the entire OTV stream passes through the foam generator without touching the cone mesh and is thrown out, providing a multiplicity of foam of about 7. When the deflector is turned, it, together with the foam generator case (1) moves back along the axis of the nozzle (18), increasing the spray angle of the jet (see Fig. 2, 4, 6).

The sprayed jet enters the cone mesh (3), where due to the ejection of air (8), foam of medium multiplicity is formed, which, together with the main stream, is ejected out of the foam generator. Thus, by smoothly adjusting the nozzle (2) with a deflector, the angle of the jet spray up to 90 °, using a foam generator, smoothly controlling the multiplicity of the resulting foam is achieved.

Once on a burning surface, the foam isolates the combustion zone from the ingress of flammable vapors and gases, as well as atmospheric oxygen, and eliminates combustion.

Field tests shown in the photo of FIG. 7-11 samples of the proposed generator of air-mechanical foam of medium and low multiplicity for the gun barrel (foam generator) and the gun barrel with a nozzle and a foam generator in the constructive embodiment of a productivity of 120 l / s, showed that

- the device is able to generate air-mechanical foam of low and medium multiplicity in the range of adjustable multiplicity from 7 40 and deliver it to a distance of 90-100 m;

- the average consumption of water with a foaming agent was 100-110 l / s;

- the average emission range of the air-mechanical foam of medium multiplicity 90-100 m, and the air-mechanical foam of low multiplicity more than 100;

- the angle of the water jet with the foaming agent in the nozzle of the gun barrel from 0 ° to 90 °.

Thus, the use of the solid-state fire extinguisher extinguisher provides a sure achievement of the technical result, namely, it significantly increases the efficiency of fire extinguishing and fire and explosion prevention by providing the possibility of generating and supplying foam of medium and low multiplicity with increased distance with the possibility of controlling the multiplicity of the foam in case of using water additives foaming agent or sprayed and dispersed water as a fire extinguishing agent in water without the addition of a foaming agent, and also proves that all the essential features of a utility model are causally related to the technical result obtained from the use of the utility model.

Specific materials, design features and manufacturing techniques of the device and / or its individual parts are selected in the usual way in relation to the specific conditions of its operation.

The manufacture of prototypes and the above examples of tests in real conditions showed confident achievement of the technical result.

As individual elements and assemblies of the proposed solid-state fire extinguisher, various fire fighting materials, materials, and structural solutions commonly used in the manufacture and use of foam generators and fire monitors with foam generators can be used.

The analysis also shows that all the general and particular features of the utility model are essential, since each of them is necessary, and all together they are not only sufficient to achieve the goal of the utility model, but also make it possible to implement the utility model in an industrial way.

Given the novelty of the essential features, the technical solution of the problem, the materiality of all general and particular features of the utility model, proven in the section "prior art" and "Disclosure of a utility model", proven in the section "Implementation of a utility model" technical feasibility and industrial applicability of the utility model, successful the solution of the inventive task and the confident achievement of the required technical result when, implementing and using the utility model, in our opinion, the claimed gender knowing the model meets all the requirements for eligibility requirements for a utility model.

Claims (21)

1. A gun barrel containing means for supplying and forming a flow of water with additives of a foaming agent, characterized in that equipped with an air-mechanical foam generator containing generator housing in the form of at least one hollow cylinder and a grid coaxially installed in the generator’s body in the form of an axisymmetric truncated cone with open bases on the side of the generator’s entrance to the water flow coming from the gun barrel with the addition of a foaming agent and on the exit side of the generator of air-mechanical foam, wherein the generator housing with the mesh installed therein is provided with means of coaxial connection to the gun barrel with the formation of an annular gap between the walls of the generator housing with the mesh installed in it and the gun barrel with the ability to eject air through the ring annulus between the walls of the generator housing with the mesh installed in it and the gun barrel and the mesh installed in the generator’s body into the water stream coming from the gun barrel with the addition of a foaming agent and receiving the output from the generator pa vozdushnomehanicheskoy flux foam 2. The gun barrel according to claim 1, characterized in that the means of coaxial connection of the generator housing to the gun barrel is made with the formation of an annular gap between the walls of the generator housing and the gun barrel with the possibility of ejecting air through said annular gap between the walls of the generator housing with a mesh installed therein and the gun barrel, through the mesh installed in the generator housing and through the annular gap between the generator housing and the mesh installed in it, into the water flow coming from the gun barrel s with the addition of a foaming agent and receiving at the exit of the generator flow of air-mechanical foam. 3. The gun barrel according to claim 1, characterized in that the means of coaxial connection of the generator body with the mesh installed therein to the gun barrel is made with the possibility of moving the generator body with the mesh installed therein along the axis of the gun barrel with the ability to control the multiplicity and range of the flow generated by the generator air-mechanical foam. 4. The gun barrel according to claim 1, characterized in that the means of coaxial connection of the generator body with the mesh installed therein to the gun barrel is made with the possibility of moving the body with the mesh installed therein along the axis of the gun barrel with the possibility of increasing the multiplicity of the generated aeromechanical foam when pushing the generator body with the mesh installed in it to the gun barrel and reducing the multiplicity of the air-mechanical foam generated by the generator when moving the generator body with lennoy it from the monitor grid. 5. The gun barrel according to claim 1, characterized in that the means of coaxial connection of the generator body with the mesh installed in it to the gun barrel is made with the possibility of moving the generator body with the mesh installed therein along the axis of the gun barrel with the possibility of increasing the feed range of the air-mechanical foam generated by the generator when moving the generator housing with the mesh installed in it from the gun barrel and reducing the feed range of the air-mechanical foam generated by the generator when moving generator housing with a mesh installed in it to the gun mount. 6. The gun barrel according to claim 1, characterized in that the grid coaxially mounted in the generator body in the form of an axisymmetric truncated cone is oriented with a smaller open base towards the generator connecting to the gun barrel. 7. The gun barrel according to claim 1, characterized in that the grid coaxially mounted in the generator body in the form of an axisymmetric truncated cone is oriented with a large open base towards the gun barrel towards the generator. 8. The gun barrel according to claim 1, characterized in that the mesh coaxially installed in the generator housing is made of a thin-walled metal sheet with openings of more than 0.8 mm. 9. The gun barrel according to claim 1, characterized in that the grid coaxially installed in the generator body is fixed in the body by means of rings and screws. 10. The gun barrel according to claim 1, characterized in that the generator housing is made up of at least two cylindrical shells, coaxially placed with an annular gap one in the other with the possibility of additional air ejection through the annular gap between the cylindrical shells and through the annular gap between the cylindrical shells and a net in the stream of water with a foaming agent emanating from the gun barrel. 11. The gun barrel according to claim 1, characterized in that it is configured to generate and supply a homogeneous air-mechanical foam of medium multiplicity with a multiplicity of 30 + 10 to the fire or fire and explosion prevention zone. 12. The gun barrel according to claim 1, characterized in that it is configured to generate air-mechanical foam and supply it to the fire or fire and explosion prevention zone at a distance of up to 100 meters or more. 13. The gun barrel according to claim 1, characterized in that the mesh installed in the generator body is made with an area of a smaller open base equal to or greater than the output section of the gun barrel. 14. The gun barrel according to claim 1, characterized in that the mesh installed in the generator body is made with a ratio of the area of the larger open base to the area of the smaller open base from 5 to 1.5. 15. The gun barrel according to claim 1, characterized in that the mesh installed in the generator body is made with an effective hole area commensurate with the cross-sectional area of the output section of the gun barrel. 16. The gun barrel according to claim 1, characterized in that it contains nozzles with the ability to control the amount and opening angle of the water flow with the addition of a foaming agent. 17. The gun barrel according to claim 1, characterized in that it contains nozzles with the ability to control the amount of ejection supply of the foaming solution into the water stream.

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