RU223048U1 - Installation of combined fire extinguishing with air-mechanical hybrid foam of medium expansion or sprayed water - Google Patents

Abstract

The utility model relates to fire-fighting equipment, to manual and stationary devices for generating air-mechanical hybrid foam of medium expansion or sprayed water.

To increase the efficiency of extinguishing emergency transport, forest, emergency industrial and other fires in a combined fire extinguishing installation containing a medium expansion foam generator, including a housing, a grid cassette installed inside the housing and a means of supplying the fire extinguishing agent to the grid cassette, and a means of connecting to the pressure fire extinguishing agent supply pipeline,

the generator housing is made cylindrical with an annular protrusion concave into the housing on its side surface on the side where foam or sprayed water exits,

in the housing with a lateral annular gap relative to the inner surface of the housing, a cylinder-shaped element is installed, at the end of which a means for supplying the fire extinguishing agent to the grid cassette is installed,

and the grid cassette

made of coaxially installed inner, intermediate and outer annular rims with cylindrical side surfaces, one inside the other, and two meshes located with a gap relative to each other, one of which is fixed by its edges in the gap between the side surfaces of the outer and intermediate rims, and the other mesh is fixed by its edges in the gap between the side surfaces of the intermediate and inner rims,

installed in the generator housing on the side of the fire extinguishing agent supply to the grid cassette with emphasis on the annular protrusion concave into the housing

and is located so that the mesh, fixed with its edges between the side surfaces of the outer and intermediate rims, faces towards the means for supplying the fire extinguishing agent to the mesh cassette, and the mesh, fixed with its edges between the side surfaces of the intermediate and inner rims, faces towards the exit of foam or sprayed water from the generator. 9 salary f-ly, 20 ill.

Description

The utility model relates to fire-fighting equipment, to manual and stationary devices for generating air-mechanical hybrid foam of medium expansion or sprayed water and can be used when extinguishing various forest, emergency transport, emergency industrial and other large-scale fires, in particular when extinguishing fires flammable and combustible liquids, liquefied natural and hydrocarbon gases (LNG and LPG), solid combustible materials, vehicles and industrial technical equipment, as well as for creating light-heat-protective screens and cooling in areas of accidents, catastrophes, natural disasters, for degassing and decontamination, camouflage of civilian and military objects.

State of the art

It is known that the most effective modern fire extinguishing agent is a hybrid air-mechanical foam of medium expansion, consisting of polydisperse bubbles with a thickened (watered) shell - reduced (low) expansion foam, and bubbles with a thinned (dehydrated) shell - high (medium) expansion foam , forming, when mixed in the process of joint movement, a hybrid foam of medium expansion [RU 2757106, A62C 5/02, publ. 10/11/2021, BI 29; RU 2757479, A62C 5/02, publ. 10/18/2021, BI 29].

There are known generators of air-mechanical foam of medium expansion in portable and stationary design options, however, most of the well-known generators of medium expansion foam by other authors provide foam jets with a range of up to 10 m, which limits their use due to the high risk of personnel working in the fire zone fire departments.

A mobile multi-purpose foam generating unit is known for generating foam, mainly at nuclear fuel cycle facilities, including a container for water or a foaming agent solution, a pump with an electric motor, a comb for connecting air-foam generators (foam generators) with an average expansion rate of K=20-200 and fire nozzles , pipelines, hoses and fittings, is additionally equipped with low expansion foam generators (K<20) and high expansion foam (K=200-1000), working with two types of mesh (conventional - flat or metal fabric - volumetric weaving), and a valve is installed on the comb, allowing you to smoothly regulate the flow of the foaming solution supplied to the high-expansion foam generator at a flow rate of 0.5-10 l/min. In addition, the container is equipped with a lid designed to seal it when creating a pressure of up to 6 atm. These features provide increased versatility of the installation [RU 2308996 A62S 27/00, A62S 5/02 Publ. 27.10.2007].

The disadvantage of the device according to RU 230899 is its significant weight and dimensions, as well as the impossibility of its use in industrial and low-rise buildings in urban and rural settlements, forest and landscape fires.

A device previously developed by the applicant’s authors for forming a jet of medium expansion foam with increased range is known, according to which, in order to increase productivity, efficiency and increase the efficiency of fire extinguishing by creating a combined jet of foam of medium expansion and increasing the range of the jet of medium expansion foam to 20-50 m, a foaming agent solution is supplied to a mesh in the body of the foam generator to produce a jet of foam of medium expansion with the formation of a jet of foam with increasing expansion and decreasing density in the direction from the center to the periphery by means of a means or means located on the mesh or inside the mesh cassette for redistributing the amount of foaming solution on the surface of the mesh, made in the form of a ring, rings, ring nozzles or other means located inside the mesh cassette and/or on the surface of the mesh or mesh cassette on the supply side of the foaming solution jet or on the foam outlet side. The body of this foam generator is made in the form of a hollow cylinder, to which a nozzle or other means of forming a jet of foam solution is attached on the supply side of the foam agent solution, and a mesh is attached inside the body on the foam outlet side. The body of the foam generator has a length of 0.3 to 1.5 times the distance from the means for forming a jet of foam solution to the mesh. The foam generator additionally contains a diffuser in the form of a hollow cylinder, fixed in the body of the foam generator directly behind the mesh on the side of the foam outlet and made with a length of 0.1 to 0.9 times the diameter of the diffuser and a free cross-sectional area less than the cross-sectional area of the mesh [RU 2170123 A62C 5/02 Publ. 07/10/2001].

The disadvantages of the device according to RU 2170123 are the complexity of the design of the means or means for redistributing the amount of foaming solution on the surface of the mesh, as well as the lack of information about the features of fastening the mesh in the device and about the design of the mesh cassette.

There is a known method, previously developed by the authors of the applicant, of forming a jet of medium-expansion foam with increased range and a device for its implementation, according to which increasing the productivity, economy and efficiency of fire extinguishing with combined medium expansion foam while simultaneously simplifying the manufacture, transportation and use in fire extinguishing systems, when receiving a jet of foam, a jet of foam concentrate solution is supplied to the mesh in the foam generator body under pressure RP in front of the nozzles from 0.4 to 1.2 MPa. In a device for forming a jet of medium expansion, containing a housing and a mesh located in the housing, the body of the foam generator is made in the form of a hollow cylinder or two or more half-cylinders connected to each other by planes, while a mesh is fixed inside the body on the foam outlet side, the body of the foam generator has a length from 0.3 to 1.5 distances from the means for forming a jet of foaming agent solution to the mesh, and the means for forming a directed jet of foaming agent solution is made in the form of a nozzle or nozzles or other means for forming a directed jet or jets, located or located at a distance from the mesh, determined by formula, where A is the distance from the center of the nozzle or other means of jet formation to the mesh, m; Rs - radial mesh size; tgα/2 is the tangent of half the opening angle of the foam solution jet; α is the angle of opening of the foam solution jet at the exit from the nozzle or other means of forming a directed jet [RU 2180607, A62C 5/02, publ. 03/20/2002 Bulletin. No. 8].

The disadvantages of the device according to RU 2180607 and other known foam-generating devices are the lack of information about the features of fastening the mesh in the device, about the design and manufacturing technology of the mesh cassette as a determining factor in influencing the quality of the resulting foam.

The closest in technical essence and achieved technical result (prototype) is the medium expansion foam generator GPS-600 in accordance with GOST R 50409-92, containing a conical generator body made of cast aluminum alloy AK7 or other alloys with a nozzle on the foam outlet side and a conical collector from the supply side of the sprayed foam solution to the grids, a grid cassette in the form of a ring, covered along the end planes with a metal mesh with a cell size of 0.8 - 1 mm, a centrifugal vortex-type sprayer with a connecting head GM-70 attached to the body by means of three racks [GOST R 50409-92 Medium expansion foam generators. Technical conditions. Official publication. Gosstandart. Moscow. 8 p. (prototype)].

The GPS 600 generator (prototype) is a portable water-jet ejector apparatus.

The nozzle in the GPS-600 generator is designed to form a foam stream after a grid cassette into a compact stream and increase the flight range of medium-expansion foam.

The vortex-type sprayer in the GPS-600 generator has six windows located at an angle of 12°, which causes swirling of the flow of working fluid and ensures that a sprayed stream of foam solution is obtained at the output, covering the entire surface area of the grid cassette.

The GPS-600 generator (prototype) functions as follows: The sprayed stream of foaming agent solution emerging from the atomizer, due to ejection and the reduced pressure created inside the housing, sucks in air through a conical manifold and mixes with it in the housing. A mixture of droplets of foaming solution and air falls on the mesh cassette. On grids, deformed drops form a system of stretched films, which, enclosed in limited volumes, form first elementary (in the form of individual bubbles) and then mass foam. With the energy of newly arriving droplets and air, the mass of foam is pushed out of the foam generator and with the formation of a jet of air-mechanical foam of medium expansion with a multiplicity of 100 + 30, obtained as a result of intensive mixing in the GPS-600 generator in a certain proportion of three components: water, foaming agent and air [Moiseev Yu., N. Kharlamov R.I., Kolbashov M.A.. Fire-technical and emergency rescue equipment. Tutorial. - Ministry of the Russian Federation for Civil Defense, Emergency Situations and Disaster Relief. Federal State Budgetary Educational Institution of Higher Education Ivanovo Fire and Rescue Academy of the State Fire Service. Ivanovo, 2017, pp. 36-38].

The main technical disadvantage of the GPS-600 generator (prototype) is the insufficient (only about 8-10 m) range of medium expansion foam supply, as well as insufficient operational reliability. This significantly limits the scope and effectiveness of the GPS-600 generator and increases the risk of danger for fire personnel. In particular, the probability of failure-free operation of GPS-600 for 50 hours of operation, or failure-free operation of GPS-2000 for 25 hours of operation, specified in GOST R 50409-92 (p. 7, clause 2.19) is 0.993 at a nominal pressure of the foam concentrate solution in front of the sprayer of 0.0, 4-0.6 MPa ((4-6 kg/cm ² ) proves the relatively low reliability of the known GPS foam generators, due to the possible destruction of the mesh cassette and the tearing out of the mesh from their attachment points with the cessation of their normal operation as a result of the dynamic pressure of the flows acting on the mesh.

A common disadvantage of the known water-foam fire extinguishing devices is that the known stationary and mobile devices, with their relatively low reliability and inability to function normally at high pressure of the foam solution or water supplied to them, have a relatively low operating efficiency due to insufficient range and productivity in generating and supplying medium foam. multiplicity.

At the same time, in the known information about medium-expansion foam generators, there is practically no information about the design features and manufacturing technologies of mesh cassettes, mesh packages or fastening in the mesh body, which are the main working element of medium-expansion foam generators, loaded by the dynamic pressure of the flow of foam concentrate solution or water.

Problem solved and technical result

An inventive problem that has not been properly resolved to date, hindering the increase in productivity and efficiency of modern fire extinguishing methods and equipment, is that the known generators of medium-expansion foam or bulky foam are complex and low-tech to manufacture, or do not provide the required efficiency in extinguishing large and fast-moving fires, since it is known that when extinguishing large-scale industrial, forest, emergency transport and emergency industrial fires, controlled, rapid and uniform coverage of the entire fire-hazardous area with fire extinguishing agents is required, preferably with water-air foam of medium expansion from the most remote positions.

The technical problem to be solved by the claimed utility model is the need to quickly prevent fires and explosions, reduce the intensity of combustion and extinguish fires through the rapid formation and long-range distribution of air-mechanical (water-air) foam of medium expansion or sprayed water over large areas of fire of flammable liquids , solid combustible materials, liquefied natural and hydrocarbon gases (LNG and LPG), when and where, to prevent fires and extinguish fires, prompt coverage of the entire fire-hazardous area with a fire extinguishing agent is required, as well as cooling and fire protection of buildings, structures, machinery, and equipment adjacent to the fire , flammable and explosive materials. This is possible only if there is a sufficient number of long-range generators of medium-expansion foam or sprayed water in various manual and stationary designs, which are structurally simple and technologically advanced to manufacture, but convenient and effective in operation, which is not observed at present.

The technical result achieved by implementing the claimed utility model is to increase the efficiency of extinguishing emergency transport, forest, industrial and other fires through the creation, mass production and widespread practical use of structurally simple, technologically advanced and reliable combined extinguishing installations. hybrid foam of medium expansion or sprayed water with increased range.

Disclosure of the essence of the utility model

The problem is solved and the required technical result is achieved by the fact that in a combined fire extinguishing installation containing a medium expansion foam generator, including a housing, a grid cassette installed inside the housing and a means for supplying the fire extinguishing agent to the grid cassette, and a means for connecting to the pressure pipeline for supplying the fire extinguishing agent,

according to the utility model, the generator housing is made cylindrical with an annular protrusion concave into the housing on its side surface on the side where foam or sprayed water exits,

in the housing with a lateral annular gap relative to the inner surface of the housing, a cylinder-shaped element is installed, at the end of which a means for supplying the fire extinguishing agent to the grid cassette is installed,

and the grid cassette

made of coaxially installed inner, intermediate and outer annular rims with cylindrical side surfaces, one inside the other, and two meshes located with a gap relative to each other, one of which is fixed by its edges in the gap between the side surfaces of the outer and intermediate rims, and the other mesh is fixed by its edges in the gap between the side surfaces of the intermediate and inner rims,

installed in the generator housing on the side of the fire extinguishing agent supply to the grid cassette with emphasis on the annular protrusion concave into the housing

and is located so that the mesh, fixed with its edges between the side surfaces of the outer and intermediate rims, faces towards the means for supplying the fire extinguishing agent to the mesh cassette, and the mesh, fixed with its edges between the side surfaces of the intermediate and inner rims, faces towards the exit of foam or sprayed water from the generator.

The means for supplying the fire extinguishing agent to the grid cassette installed in the generator housing is made in the form of a nozzle installed in a cylinder-shaped element by means of centering stops, located with the ability to supply a jet of fire extinguishing agent to the central zone of the grids and with the ability to supply air to the peripheral zones of the grids through the annular gap with the formation at the exit from the grid cassette and the generator housing, a combined jet of hybrid foam of medium expansion or sprayed water with increasing expansion and decreasing density in the direction from the center to the periphery.

The nozzle is equipped with a branch pipe with a means of connection to the fire extinguishing agent supply pipeline, made in the form of a quick-release/detachable connection with rotary eccentric camlock type fasteners, or a connecting head, or a flange with holes for bolting.

A shut-off valve can be installed on the connection pipe to the pressure pipeline for supplying the fire extinguishing agent.

The combined fire extinguishing installation is made with the ability to use an aqueous solution of a foaming agent or water as a fire extinguishing agent with the ability to form and supply a combined jet of air-mechanical hybrid foam of medium expansion or sprayed water to the fire zone at a distance of 25-30 m.

A combined fire extinguishing installation can be manufactured

in manual version with handles attached to the body and to the confosor,

with the possibility of permanent installation in a fire safety system,

with the possibility of permanent installation on a fire escape, foam lifter, manipulator, automobile, rail, air, watercraft or all-terrain vehicle or trailer, gas and oil production platform or fastening on a stationary platform,

with manual or remote control or oscillation,

with means of rotation in vertical and/or horizontal planes with a manual or linear drive with an electric, pneumatic or hydraulic motor with the possibility of connecting them to a remote control system for their operation via a remote control or radio signals from the remote control system.

Brief description of drawings

The utility model is illustrated in the drawings, where in FIG. 1-20 the design of the proposed combined fire extinguishing installation is disclosed in detail, then - an installation containing a medium expansion foam generator, then - a generator including a housing 1, a cylinder-shaped element, a grid cassette 8 installed inside the housing of the original design, a means of supplying the fire extinguishing agent to the cassette meshes and a means of connecting to the pressure pipeline for supplying the fire extinguishing agent.

The drawings show in detail the design features of the installation and the possibilities of its operation in manual and stationary design options, and the installation as a whole, and its individual parts and assemblies.

The installation includes those shown in the drawings: a thin-walled metal cylindrical housing of the generator 1, on the side surface of which, on the side of the exit of foam or sprayed water, there is an annular protrusion 2 concave into the housing, an element in the shape of a cylinder 3, one end of which is coaxially installed with a lateral annular gap in the housing 1 , and at the other end of which, by means of centering stops 5, a means of supplying the fire extinguishing agent to the grid cassette is installed in the form of a nozzle 4.

The position of the cylinder-shaped element 3 relative to the body 1 is fixed using screws or self-tapping screws 18.

The nozzle 4 is equipped with a pipe with a means 6 for connecting to the fire extinguishing agent supply pipeline, made in the form of a quick-release/detachable connection with rotary eccentric camlock type clamps, or a connecting head, or a flange with holes for bolting.

Handles 6 and 7 are attached to the body 1 and to the cylinder-shaped element 3 to control the generator in its manual version.

Inside the housing 1, with an emphasis on the annular protrusion 2 concave inside the housing, there is a cassette 8, fixed in the housing by means of screws or self-tapping screws 9.

The mesh cassette 8 contains an inner 10, an intermediate 11 and an outer 12, coaxially located one inside the other, annular cylindrical rims, in the spaces between the side surfaces of which meshes 13 and 14 located with a gap relative to each other are fixed and which are additionally fixed by spot welding 15.

Fixation and centering of the nozzle 4 along the axis of the housing 1 is ensured by means of centering stops 5.

The edge of the housing 1 on the side where foam or sprayed water exits contains a plastic protective ring 20.

Figure 1 shows a drawing of a general view of a combined fire extinguishing installation, then - an installation, with a medium expansion foam generator, then - a generator, and a connection head of the GM-50 type. The drawing shows, with local cuts, the features of the arrangement inside the body of the grid cassette 8 with a focus on the annular protrusion 2 concave inside the body and with the position of the grid cassette fixed in the body by means of screws or self-tapping screws 17, as well as a section of the place where the nozzle 4 is fixed and centered along the axis of the cylinder-shaped element 3 and body 1 by means of centering stops 5.

In fig. 2 – photo of the installation with a GM-50 type connection head.

In fig. 3 - drawing of the generator with half a side view and half an axial section, which shows the installation location of the grid cassette 8 inside the housing 1 with an emphasis on the annular protrusion 2 concave inside the housing, fastening the grid cassette 8 with screws or self-tapping screws 17, as well as to explain the principle of operation of the installation lines and arrows show the direction of flow of the foaming agent solution to the central zone of the grid cassette, the direction of atmospheric air suction into the housing to the peripheral zones of the grid cassette through the cylinder-shaped element and through the annular gap between the outer surface of the cylinder-shaped element 3 and the inner surface of the housing1, as well as The arrows show the direction of exit of a combined jet of medium-expansion hybrid foam from the generator with increasing expansion and decreasing density in the direction from the center of the jet to the periphery.

In FIG. 4-7 schematically show the stages of manufacturing a grid cassette installed inside the generator housing.

In fig. 8 and 9 - schematically show design options for a grid cassette installed inside the generator housing, made from three coaxially installed outer 12, intermediate 11 and inner 10 ring rims installed one inside the other and two grids located with a gap relative to each other, one of which 13 is fixed by the edges in the gap between the mating side surfaces of the outer 12 and intermediate 11 rims, and the other is fixed by the edges in the gap between the mating side surfaces of the intermediate 11 and inner 10 rims.

In fig. 10 – photo of a manual installation with a GM-50 type connecting head.

In fig. 11 – photo of a manual installation with a GM-50 type connecting head and a shut-off valve on the branch pipe for supplying the fire extinguishing agent to the nozzle.

In fig. 12 – photo of a stationary installation with a connecting flange.

In fig. 13 – photo of a stationary installation with a connecting flange and a rotation unit.

In fig. 14 – map of irrigation generated by the device with a combined jet of hybrid foam of medium expansion or sprayed water.

In fig. 15 – map of the installation’s range of action;

In fig. 16 -20 - photo of the manual operation of the installation when extinguishing various fires.

Implementation of a utility model

The combined fire extinguishing installation proposed according to the utility model, hereinafter referred to as an installation containing a medium expansion generator, hereinafter referred to as a generator, a grid cassette of an original design and a means of connecting a to the pressure pipeline for supplying a fire extinguishing agent (foaming agent solution or water) is a new design modification of the type of installations produced by the applicant “Combined fire extinguishing installations PURGA 7 and PURGA 10” (UKTP PURGA 7 and UKTP PURGA 10), where numbers 7 and 10 show the performance of the installation with an aqueous solution of foaming agent or water. 7 and 10 l/sec.

The installation proposed according to the utility model is intended for use in extinguishing various forest, emergency transport, emergency industrial and other large-scale fires, in particular when extinguishing fires of flammable and combustible liquids, liquefied natural and hydrocarbon gases (LNG and LPG), solid combustible materials, vehicles and industrial technical equipment, as well as for creating light-heat-protective screens and cooling in areas of accidents, catastrophes, natural disasters, for degassing and decontamination, camouflage of civil and military objects.

The characteristic design, which is in a cause-and-effect relationship with the achieved technical result, are the distinctive features of the proposed installation, which contains a generator of original design, including a housing with a cylinder-shaped element attached to it, a grid cassette installed inside the housing of the original design and a means of supplying a fire extinguishing agent (foaming agent solution or water) onto the grid cassette, as well as the means for connecting the generator to the pressure pipeline for supplying the fire extinguishing agent, are:

The presence of a technologically advanced thin-walled metal cylindrical body with an annular protrusion concave into the body on the side where the stream of foam or sprayed water exits and a cylinder-shaped element installed in the body with an annular gap, which not only increases the rigidity and strength of the generator body, but also simply and reliably fix the grid cassette and the cylinder-shaped element in the generator body, and also simply and reliably attach the fixing and centering stops of the nozzle to the generator body with a means of quick-detachable or permanent connection of the installation to the pressure pipeline for supplying the fire extinguishing agent (foaming agent solution or water).

Possibility of manufacturing and using almost the same simple and technologically advanced, but convenient and efficient to use installation design in manual and stationary versions;

The presence of a generator located inside the housing at an optimal distance from the nozzle of an original design cassette of grids, structurally formed by three coaxial outer, intermediate and inner ring rims located with interference one inside the other and two located at an optimal distance from each other (about 20 mm) tightly and evenly tensioned meshes, tightly and securely fixed edges in the gaps between these three rims with possible additional fixation by spot welding of both the said annular rims to each other, and the specified meshes with the rims. This original design of the grid cassette provides not only a tight and uniform tension of the grids, rigid and reliable fixation of the grid cassette and the location of the grids inside the body at an optimal distance from each other and from the nozzle, but also ensures the effective formation of a long-range combined jet of hybrid foam of medium expansion or sprayed water through two meshes located with an optimal gap relative to each other;

Placing a grid cassette inside the body so that the mesh fixed between the outer and intermediate rims faces the nozzle, and the mesh fixed between the intermediate and inner rims faces the exit of the foam jet, allows not only to significantly increase the reliability of the design and long-term normal operation of the device in extreme conditions, even with a pressure at the inlet of the fire extinguishing liquid above 1.2 MPa (12 kg/cm ² ), but also the formation and supply of a combined jet of medium-expansion hybrid foam or sprayed water over a distance of more than 20-25 m;

Optimal proportions of overall dimensions (for the version without a shut-off device, the length is about 870 mm, for the version with a shut-off valve, the length is about 1030 mm and the height with a handle is about 430 mm, the body diameter is 350 mm, the diameter of the cylinder-shaped element is 310 mm, allowing for water (solution) productivity foam concentrate) 7-10 l/s, the optimal operating pressure at the inlet of the fire extinguishing liquid is 0.8 MPa and the control pressure is 1.2 MPa (12 kg/cm ² ), form a combined jet of medium expansion hybrid foam over a distance of more than 25-30 m or sprayed water with increasing frequency and decreasing density in the direction from the center to the periphery.

All this proves the confident achievement of the required technical result when implementing and using a utility model, namely, the implementation of a utility model provides the opportunity to increase the efficiency of extinguishing emergency transport, forest, industrial and other fires through the creation, mass production and widespread practical use of structurally simple, technologically advanced in production and reliable in operation, offered according to the utility model, with original generators of medium-expansion foam of increased range.

As shown in the drawings, almost the same design of the installation, with minor design changes, can be implemented in manual and stationary versions, with and without a shut-off valve, which allows you to quickly regulate the activation of work by starting the formation and supply of foam and the shutdown of operation by stopping the supply fire extinguishing agent on a grid cassette, with oscillating devices and with remote control in fire extinguishing systems, in a design for fresh and sea water.

The installation offered according to the utility model can be equipped with quick-release connections (type TZA, Kamlok, flange connections, etc.), allowing them to be mounted and used on all types of domestic and foreign fire fighting equipment.

The connections ensure quick and easy installation of the proposed installation or installations on stationary and mobile equipment and in fire extinguishing facility systems, as well as the possibility of using them either as trunks with connecting heads of the GM type in accordance with GOST R 53279-2009, or as attachments on stationary and auto-mechanical ladders, or as attachments for car lifts, or as stationary installations with flange connections, etc.

If there are rotation units, the proposed installation can be produced with manual control, with wired or radio remote control for turning the generator in horizontal and vertical planes; with combined switchable manual and remote control.

The proposed installation can be manufactured manually or placed on mobile hand trucks, cars and car trailers, sea vessels, industrial premises, public and residential buildings, etc. in stationary version.

Thus, all individual essential features and the totality of essential features of a utility model shown in detail in the drawings and in the description are essential and are in a cause-and-effect relationship with the technical result obtained from the use of the utility model.

The grid cassette used in the generator is original in design, including three coaxially installed with interference one inside the other: inner 10, intermediate 11 and outer 12 annular rims with cylindrical side surfaces and two tightly stretched grids located with a gap relative to each other, one of which 13 is fixed by the edges in the gap between the mating side surfaces of the outer and intermediate rims, and the other mesh 14 is fixed with its edges in the gap between the mating side surfaces of the intermediate and inner cylindrical ring rims, is made as follows (Fig. 4-9):

A mesh 14 is placed on the intermediate rim 11 (Fig. 4) and the inner rim 10 is pushed coaxially on top of it in the axial direction until the inner rim 10 is completely inserted into the intermediate rim 11, ensuring a tight tension of the mesh 14 on the bottom of the inner rim 10 and tight fixation. the edges of the mesh 14 in the gap between the mating side surfaces of the inner rim 10 and the intermediate rim 11 (Fig. 5).

Then, the ends of the mesh 14 protruding from the gap between the rims of the workpiece obtained in this way are cut off flush and the edges of the inner rim 10 and the intermediate rim 11 and the mesh 14 are additionally fixed relative to each other by spot welding 15 to the indicated rims (Fig. 6).

On the inner 10 and intermediate 11 rims fixed by spot welding to each other with the edges of the mesh 14 located in the gap between their mating side surfaces (Fig. 6), a mesh 13 (Fig. 7) is applied and the outer one is pushed on top with an interference fit in the axial coaxial direction. rim 12 until the combined intermediate 11 and inner 10 rims with the edges of the mesh 14 are completely inserted into the outer rim 12, ensuring tight and uniform tension of the mesh 13 on the top of the intermediate rim 11 and tightly fixing the edges of the mesh 13 in the gap between the mating side surfaces of the intermediate rim 11 and the outer one rim 12 (Fig. 8 and 9).

After this, the ends of the protruding edges of the mesh 13 are cut flush or turned outward and the edges of the outer 12 and intermediate 11 rims and the mesh 13 with the specified rims are fixed relative to each other by spot welding 15 to obtain design variants of the finished mesh cassette suitable for installation in the housing 1 (Fig. 8,9).

The mesh cassette can use a mesh with nominal dimensions of the sides of the cells in the clear 0.8-1.12 mm in accordance with GOST 3826, made of wire with a diameter of 03.04 mm from high-alloy steel, or a mesh in accordance with GOST 6613 from semi-pompak wire with the same cell sizes and wire diameter.

The medium expansion foam generator used in the proposed installation is manufactured as follows:

A rectangular blank is cut out of a thin-walled metal sheet of predominantly stainless steel or ordinary painted steel, from which a cylindrical body 1 of the required dimensions is made by bending and welding, on which an annular protrusion 2 concave inside the body 1 is formed on one side (from the side where foam and sprayed water exit). with a radius from 3 to 5 mm.

A mesh cassette 8 manufactured using the technology described in detail is installed inside the housing 1 from the side of subsequent installation of an element in the shape of a cylinder 3 with an emphasis on the annular protrusion 2 concave inside the housing so that the mesh 13 fixed by the edges between the outer 12 and intermediate 11 rims faces the direction of subsequent installation element in the form of a cylinder 3 and a nozzle 4, and the mesh 14 fixed by the edges between the intermediate 11 and inner 10 rims (Fig. 22) was turned towards the exit of foam or sprayed water, which ensures maximum reliability and strength of the mesh cassette as a whole and the mesh fastening in a mesh cassette.

The position of the grid cassette 8 in the housing 1 is fixed from the outside with screws or self-tapping screws 17 (Fig. 1, 2, 3).

Then a rectangular blank is cut out of a thin-walled metal sheet of predominantly stainless steel or ordinary painted steel, from which a cylinder-shaped element 3 is made by bending and welding, which is installed on one side into the housing 1 with an annular gap between the outer surface of the cylinder-shaped element 3 and the inner surface housing 1 with fixing the position of the cylinder-shaped element 3 in housing 1 with screws or self-tapping screws 18.

Then, a protective plastic hoop 20 is put on the edge of the body on the side of the subsequent exit of foam or sprayed water, and handles 6 and 7 are screwed to the body and confuser.

After this, using stops 5 and screws or self-tapping screws 19 cp, the free side of the cylinder-shaped element is installed along the axis of the cylinder-shaped element and body by means of centering stops, and the nozzle 4 with a connection pipe is screwed to the pressure pipe for supplying the fire extinguishing agent with the required one installed on it in certain cases structures with a shut-off valve (Fig. 11).

The figs shown in the photo are manufactured in a similar manner. 10, 12, 13) design options of the proposed installation with various means of connecting the generator nozzle to the pressure pipeline for supplying the fire extinguishing agent in the form of a foaming agent solution or water.

Individual parts and assemblies of the inventive installation can be made from structural elements and materials commonly used in fire-fighting technology, using conventional equipment, using conventional technologies known and used in the field of modern fire-extinguishing and fire-explosion prevention technology.

The utility model installation operates as follows (Fig. 3):

A solution of foaming agent or water from the pressure pipeline is supplied to the nozzle, from where it is supplied to the central zone of the mesh cassette under a working pressure of 0.8 MPa. Due to the ejection effect and vacuum created by a conical flow of foaming agent solution or water, expanding along the path from the nozzle to the grid cassette in a cylindrical body, atmospheric air is sucked into the peripheral zones of the grid 13 and through the cylinder-shaped element 3 from the side of the nozzle 4 and through the annular the gap between the outer surface of the cylinder-shaped element 3 and the inner surface of the housing 1.

At the same time, inside the mesh cassette 8 between the meshes 13 and 14, drops of a foaming agent or water solution and peripheral air flows are mixed to obtain, at the exit from the mesh cassette and from the body, a stream of hybrid foam of medium expansion or sprayed water with increasing expansion and decreasing density in the direction from the center to periphery.

When a foaming agent solution is supplied to the grid cassette, a flow of combined air-mechanical hybrid foam of medium expansion is formed at the outlet of the housing, consisting of polydisperse bubbles with a thickened (watered) shell located in the central part of the flow - foam of reduced expansion, and bubbles with thinned (dehydrated) shell - foam of increased expansion, which, when further mixed in the process of joint movement, forms a hybrid foam of medium expansion with increased fire-extinguishing properties and an increased supply range.

The combined flows of hybrid foam of medium expansion or atomized water with increasing expansion and decreasing density in the direction from the center to the periphery, formed by the inventive installation, have a significantly increased range compared to homogeneous flows due to the presence of a central part of the flow with increased density and, accordingly, increased kinetic energy .

It is known that foam is the most effective and widely used fire extinguishing agent, which is a dispersed system consisting of cells - air (gas) bubbles, separated by films of liquid containing a foaming agent [GOST R 50588-2012. Foaming agents for extinguishing fires. General technical requirements and test methods].

The ratio of the volumes of the gas and liquid phases (per unit volume) of the foam determines the structure and its properties. If the volume of the gas phase _Vg exceeds the liquid volume _Vg by no more than 10-20 times (low expansion foam), the foam cells filled with gas have a spherical shape. In such foams, gas bubbles are surrounded by liquid shells of relatively large thickness. Spherical foams are characterized by a high liquid content and, therefore, low stability. Therefore, they are classified as metastable (conditionally stable).

In unstable foams, the so-called Plateau effect is observed: the liquid phase is removed from the partitions, flowing out under the influence of gravity, and rapid coalescence occurs (from the Latin coalesce - merging, uniting) - the merging of touching gas bubbles. In foam, a gas bubble cannot move freely in either a vertical or horizontal plane. It is as if “sandwiched” by other bubbles adjacent to it.

With an increase in the V _g /V _l ratio, the thickness of the liquid film separating the gas volumes decreases, and the gas cavity loses its spherical shape. Medium expansion foams, in which the V _g / V _l ratio is several tens or even hundreds, have a multifaceted shape. Moreover, the shape of polyhedra can be different - triangular prisms, tetrahedrons, irregularly shaped parallelepipeds. During the aging process of the foam, the spherical shape of the cells becomes multifaceted. Multifaceted foams are characterized by a low liquid phase content and are characterized by high stability. In such foams, individual bubbles are brought together and separated by thin “stretched elastic films.” These films, due to their elasticity and a number of other factors, prevent the coalescence of gas bubbles. As the separating films become thinner, the bubbles come closer together, adjacent to each other and acquire a clear polyhedral shape [Bobkov S.A., Baburin A.V., Komrakov P.V. Physico-chemical foundations of the development and extinguishing of fires: textbook. manual / M.: Academy of the State Fire Service of the Ministry of Emergency Situations of Russia, 2014. - 210 pp.].

The main physical and chemical properties of the foam are:

multiplicity - the ratio of the volume of foam to the volume of the foaming agent solution contained in the foam;

dispersion – degree of bubble refinement (bubble size);

viscosity - the ability of foam to spread over a surface;

durability – the ability of foam to resist the process of destruction [ibid.].

Depending on the expansion ratio (K), foams are divided into four groups:

foam emulsions, K < 3;

low expansion foams, 3 < K < 20;

medium expansion foam, 20 < K < 200;

high expansion foam, K > 200 [ Sharovarnikov A.F., Sharovarnikov S.A. Foaming agents and fire extinguishing foams. Composition, properties, application. M.: Pozhnauka, 2005. - 335 p.].

The dispersion of the foam is inversely proportional to the average diameter of the bubbles.

It is known that the higher the dispersion, the higher the foam resistance and fire extinguishing efficiency. The degree of foam dispersion largely depends on the conditions for its production, including the characteristics of the equipment. The expansion ratio and dispersion of the foam determine the insulating ability of the foam and its fluidity. [Bobkov S.A., Baburin A.V., Komrakov P.V. Physico-chemical foundations of the development and extinguishing of fires: textbook. manual / M.: Academy of the State Fire Service of the Ministry of Emergency Situations of Russia, 2014. - 210 pp.].

The fire extinguishing properties of foam are:

insulating effect - preventing the entry of flammable vapors, gases or air into the combustion zone, causing the cessation of combustion;

cooling effect - due to the presence of a significant amount of liquid in predominantly low expansion foam.

The cooling effect of foam is due to the water released from the foam.

The insulating effect is due to the formation of a foam layer that prevents oxygen from reaching the fire zone, including:

separation effect, which consists in isolating the liquid from the vapor phase;

the displacement effect causing the isolation of the flammable substance from the air;

blocking effect in which foam prevents the evaporation of a flammable liquid.

Low expansion foams (3 < K < 20) Due to the significant amount of water in the interbubble partitions (in the Plateau-Gibbs channels), they predominantly exhibit a cooling fire extinguishing effect, which is caused by the cooling effect of the foam itself and the water released from the foam.

Medium expansion foam (20 < K < 200) Due to the smaller amount of water in the interbubble partitions (in the Plateau-Gibbs channels), they predominantly exhibit an insulating fire extinguishing effect, caused by the creation of an atmosphere depleted in oxygen and saturated with water vapor above the combustion zone, which helps slow down and completely stop the combustion.

At the same time, due to the larger amount of water present in low-expansion foam and, accordingly, the greater density (weight per unit volume), low-expansion foam compared to medium-expansion foams can be supplied from longer distances, which significantly affects the safety of fire personnel during large-scale and explosive accidents with liquefied gases.

A characteristic distinctive feature of the proposed technical solutions is the production and use of hybrid water-air foam with an expansion ratio of 30 to 70 based on synthetic hydrocarbon foaming agents.

The authors in the applicant’s laboratory have experimentally established and theoretically substantiated that hybrid water-air foam with an expansion ratio of 30 to 70 is significantly different in its structure, viscosity, dispersity, rheological, thixotropic and other properties significant for explosion prevention and fire extinguishing from the known properties of low and medium expansion foams by based on hydrocarbon and fluorine-containing foaming agents.

It was revealed that as a result of turbulent shockless mixing of low-expansion foam bubbles and medium-expansion foam bubbles in the hybrid foam, average-sized foam bubbles are formed, larger in comparison with low-expansion foam bubbles, but with thicker water-containing Plato channels compared to medium-expansion foams -Gibbs.

As experimentally established by the authors, the structure of a hybrid foam with a multiplicity of 30 to 70 with water-air bubbles unique in its structure and fire-extinguishing properties allows not only to better contain the high temperature of the flame without significant destruction of the volume of the hybrid foam itself, that is, to more effectively isolate the surface of the fire, but also Deliver hybrid foam jets over significantly longer distances compared to medium expansion foam jets or combined low expansion and medium expansion foam jets.

The authors also experimentally established that when a hybrid foam with a multiplicity of 30 to 70 is exposed to the surface of a liquefied natural or hydrocarbon gas spill, a synergistic effect appears due to the simultaneous influence of several factors - cooling, dilution of atmospheric water vapor in the zone of evaporation and combustion of gas, thermal insulation and sharp reducing the concentration of gas and vapor of flammable liquids above the foam layer in the combustion zone until the rate of the chemical reaction decreases and the subsequent decrease in the flame temperature to the extinction temperature.

This is due to the average dispersion and thickening of the water-containing Gibbs-Plateau channels of the hybrid foam compared to low- and medium-expansion foams or compared to foam in combined low- and medium-expansion foam jets.

Full-scale tests of the proposed installation under conditions of practical extinguishing of various real fires (see photos in Fig. 16-20) show a confident solution to the formulated problem (posed inventive problem) and the real achievement of the required technical result - increasing the efficiency of extinguishing emergency transport, forest, emergency industrial and other large-scale fires as a result of the creation, manufacture and practical use of the proposed installation, which is structurally simple, technologically advanced and reliable in operation, and also proves:

simplicity and manufacturability of manufacturing, preparation for use, use, assembly/disassembly and repair of the proposed installation;

simplicity and efficiency of operation;

high reliability of operation for a long time (up to 7 years);

the ability to generate with high productivity and a range sufficient for safe work for fire personnel (25-30 m) to supply a jet of medium-expansion air-mechanical foam or sprayed water, which are most effective for extinguishing and preventing the spread of most fires;

the possibility of manual and stationary use with the possibility of manual and automatic control, the ability to create automatic oscillatory movements in various angular ranges, ensuring prompt, fast and uniform coverage of the entire fire surface with medium expansion foam (photo 16-20).

Comparative tests of the medium-expansion foam generator GPS-600 (prototype) and the proposed installation in the basic version of the design type UKTP PURGA 7 and UKTP PURGA 10 with a mesh cassette of original design showed the following, listed in Table 1, the main technical and operational parameters and indicators:

Table 1.

The name of indicators GPS-600
according to GOST 50409-92
(prototype) Installation according to utility model Water capacity (foaming agent aqueous solution) [l/s] 4.8-6 7-10 Medium expansion foam capacity [l/s] 600 500-700 Distance of mid-expansion foam jet [m] 10 25-30 Height of medium expansion foam jet [m] 5 15 Inlet pressure [MPa (kg/ ^cm2 )] 0.6 (6) 0.6-0.8 (6-8) Foam ratio 100 + 30 50 + 70 dimensions Length 610 830 Width 350 365 Height 310 350 Weight [kg] 4.45 6

As shown by full-scale tests, the installation proposed based on the utility model, in comparison with known fire extinguishing means with medium expansion foam, is most promising in the process of eliminating large-scale fires:

at enterprises of the fuel, chemical, oil refining industries;

at enterprises of the forestry, woodworking and pulp and paper industries, in forests and on agricultural land;

when extinguishing post-accident fires of air transport on the ground, accidents, disasters in non-railway, sea and river transport;

when neutralizing and disposing of potent toxic substances.

The installation proposed according to the utility model makes it possible to implement new modern technologies for producing and supplying hybrid foam of medium expansion or atomized water with increased range and spreading speed over the combustion surface, which allows:

reduce fire extinguishing time compared to traditional means in warehouses of ammunition and highly toxic substances;

significantly reduce the number of firemen directly involved in fire extinguishing;

reduce the risk to human health and life, since fire extinguishing can be carried out at a considerable distance from the burning object;

increase mobility and mechanization of the process of delivering water and foam to the combustion zone.

Taking into account the novelty of individual and aggregate essential features, the technical solution to the problem, the significance of all general and particular features of the utility model, disclosed in detail in the description and shown in the drawings, the technical feasibility and industrial applicability of the utility model proven in the section “Implementation of the utility model”, a confident solution to the current problem , prove the confident achievement of the required technical result when implementing and using a utility model - increasing the efficiency of extinguishing emergency transport, forest, industrial and other fires through the creation, mass production and widespread practical use of structurally simple, technologically advanced and reliable installations combined extinguishing with medium expansion foam or sprayed water with increased range.

This proves that the proposed technical solutions comply with all established patentability requirements for utility models, and also proves that the essence of the declared utility model is disclosed in the application documents with completeness sufficient for the implementation of the utility model.

The analysis also shows that all the general and specific features of a utility model are essential, since each of them is necessary, and all together they are not only sufficient to achieve the purpose of the utility model, but also allow the utility model to be implemented industrially.

Claims (19)

1. A combined fire extinguishing installation containing a medium expansion foam generator, including a housing, a grid cassette installed inside the housing and a means for supplying a fire extinguishing agent to the grid cassette, and a means for connecting to a pressure pipeline for supplying a fire extinguishing agent, characterized in that the generator housing is made cylindrical with an annular protrusion concave into the housing on its side surface on the side where foam or sprayed water exits, in the housing with a lateral annular gap relative to the inner surface of the housing, a cylinder-shaped element is installed, at the end of which a means for supplying the fire extinguishing agent to the grid cassette is installed, and the grid cassette made of coaxially installed inner, intermediate and outer annular rims with cylindrical side surfaces, one inside the other, and two meshes located with a gap relative to each other, one of which is fixed by its edges in the gap between the side surfaces of the outer and intermediate rims, and the other mesh is fixed by its edges in the gap between the side surfaces of the intermediate and inner rims, installed in the generator housing on the side of the fire extinguishing agent supply to the grid cassette with emphasis on the annular protrusion concave into the housing and is located so that the mesh, fixed with its edges between the side surfaces of the outer and intermediate rims, faces towards the means for supplying the fire extinguishing agent to the mesh cassette, and the mesh, fixed with its edges between the side surfaces of the intermediate and inner rims, faces towards the exit of foam or sprayed water from the generator. 2. The combined fire extinguishing installation according to claim 1, characterized in that the means for supplying the fire extinguishing agent to the grid cassette installed in the generator housing is made in the form of a nozzle installed in a cylindrical element by means of centering stops, located with the possibility of supplying a jet of fire extinguishing agent to the central zone of the grids and with the possibility of supplying air to the peripheral zones of the grids through the annular gap with the formation at the outlet of the grid cassette and the generator housing of a jet of air-mechanical hybrid foam of medium expansion or sprayed water with increasing expansion and decreasing density in the direction from the center to the periphery, and equipped with a branch pipe with a means of connecting to the fire extinguishing agent supply pipeline, made in the form of a quick-detachable/detachable connection with rotary eccentric clamps of the camlock type, or a connecting head, or a flange with holes for bolting. 3. The combined fire extinguishing installation according to claim 1, characterized in that a shut-off valve is installed on the connection pipe to the pressure pipeline for supplying the fire extinguishing agent. 4. The combined fire extinguishing installation according to claim 1, characterized in that it is made with the possibility of using an aqueous solution of a foaming agent or water as a fire extinguishing agent. 5. The combined fire extinguishing installation according to claim 1, characterized in that it is made with the ability to form and supply a jet of air-mechanical hybrid foam of medium expansion or sprayed water to the fire zone at a distance of 25-30 m. 6. The combined fire extinguishing installation according to claim 1, characterized in that it is made manually and contains handles attached to the body. 7. The combined fire extinguishing installation according to claim 1, characterized in that it is manufactured with the possibility of permanent installation in the fire safety system. 8. The combined fire extinguishing installation according to claim 1, characterized in that it is made with the possibility of stationary installation on a fire escape, foam lifter, manipulator, automobile, rail, air, watercraft or all-terrain vehicle or trailer, gas and oil production platform or fastening on a stationary platform. 9. The combined fire extinguishing installation according to claim 1, characterized in that it is manufactured with manual or remote control or oscillation. 10. The combined fire extinguishing installation according to claim 1, characterized in that it contains means of rotation in vertical and/or horizontal planes with a manual or linear drive with an electric, pneumatic or hydraulic motor with the possibility of connecting them to a remote control system for their operation via a remote remote control or radio signals from a remote control system.