RU190538U1 - Device for preventing and extinguishing forest, industrial and emergency transport fires and laying of barrier strips with air-mechanical foam - Google Patents

Abstract

The utility model relates to fire prevention and extinguishing of large-scale forest, peat, soil, steppe, industrial and emergency transport fires and the creation of barrier strips in front of the edges of fires in the localization of upland and lower forest, soil, peat, steppe and other fires. functioning and simplifying the design while simultaneously increasing its compactness; a device for preventing and extinguishing forest, industrial and emergency transport fires and The air-mechanical foam contains protective enclosures in a protective frame with means of suspension for a helicopter or lifting device with a sealed enclosure with components of a fire extinguishing agent in the form of component A - water and component B - an aqueous solution of a foaming agent, a means of mixing the components of the extinguishing agent and the subsequent foaming of the mixture of the components of the extinguishing agent with the ejected air in the form of at least two mutually coupled foam generators with each other th and medium multiplicity with the possibility of obtaining at least one combined jet of air-mechanical foam of medium multiplicity of increased range, means for feeding the components of the fire extinguishing substance from the body into the means of mixing the components of the fire extinguishing substance under the influence of pressure inside the body and subsequent foaming of the mixture of components of the fire extinguishing substance by the ejected atmospheric air , a means of creating pressure inside the housing in the form of at least one solid-fuel gas generator with the possibility The ability to create pressure when burned inside a sealed enclosure. 16 hp f-ly, 10 ill., 1 tab.

Description

TECHNICAL FIELD

The utility model relates to fire prevention and extinguishing of large-scale forest, peat, soil, steppe, industrial and emergency transport fires and the creation of foam barrier lines and barrier foam-filled trenches in front of the edges of fires with localization of upland and lower forest, soil, peat, steppe and other fires.

BACKGROUND

It is known that forest fires often occur over large areas, sometimes in several dozens or more hectares, and spread almost at wind speed, therefore the main task of extinguishing forest fires is to prevent its spread by cutting off its front, for which protective barriers are usually arranged barrage trenches, plowing the land and cutting down glades.

It is also known that the extinguishing of highland fires (propagating mainly on the upper part of tree crowns) and lower fires (propagating mainly on the surface of the earth) require the use of various technologies and fire extinguishing agents.

Fires at industrial sites and in transport accidents often occur in large areas, at considerable heights, and in difficult to reach for fire fighters, and when burning low density (floating to the surface of the water) oil and chemical products. This makes it difficult and often makes it impossible to supply fire extinguishing substances into the fire center using traditional, well-known methods and fire extinguishing equipment.

Known technologies and equipment for extinguishing air-mechanical foam of low and medium multiplicity.

Fire monitors and handheld barrels that form low-expansion water jets or foams with a feed range of 20-60 m are known, but they do not allow for a large coverage area, require the use of expensive film-forming fluorinated frothers and require their ground delivery to the fire boundary, which does not allow obtaining the required fire extinguishing effect, leads to the inhibition of the time of extinguishing and the high cost of blowing agents used in extinguishing a fire and the impossibility of extinguishing large fires in difficult to reach ground Ransport locations.

It is known to use in case of local fires of medium expansion foam, which has increased (compared to low expansion foam) fire extinguishing efficiency in extinguishing oil and oil products and foam generators in a portable and stationary version. However, the majority of known foam generators of medium multiplicity provide foam jets from 3 to 8 m, which complicates the process of their use due to the high risk of personnel of fire departments working in the fire zone, known methods and generators of foam of medium multiplicity (multiplicity of foam KP = 40- 100) have the required fire extinguishing efficiency and allow the use of water-soluble blowing agents, but they are able to supply medium expansion foam only from 3 to 8 m, which is clearly not enough to extinguish large Ożarów over large areas.

Known low-multiplicity foam generators, which provide a jet delivery range from 20 to 60 m, do not allow the use of affordable low-cost water-soluble foaming agents and do not provide the required fire extinguishing efficiency and low-expansion foam coverage area.

A known method of supplying foam of increased multiplicity and device for its implementation, according to which to increase the range of supply of a jet of foam of increased multiplicity provide intersection of foam jets within the generator case and use special rotating jet accelerators [RU 1614813, A62C 5/02, publ. 12/23/90].

Air-mechanical foams of high multiplicity are characterized by increased fire extinguishing efficiency, but insignificant, up to only 8-10 m range of jets of foam of high multiplicity

A device for extinguishing fires and for throwing foam of medium and low multiplicity over a long distance and creating a sprayed and compact water jet is located next to a medium multiplicity foam generator and a watering barrel of a low multiplicity generator [RU 2129895, A62C 31/12, publ. 10.05.99 g].

Known previously developed by the authors of the proposed utility model and previously patented by the applicant CJSC "NPO SOPOT" method of forming a jet of medium multiplicity of foam of increased range, including the supply of a jet of foam solution to the grid in the foam generator body and obtaining a jet of medium multiplicity foam from one or more nozzles or other means of forming directional jet or jets under pressure of the foaming agent solution in front of the nozzles from 0.4 to 1.2 MPa, located from the grid at a distance in the direction from Tra jet of foam to the periphery, while the network simultaneously serves two or more jets of foam solution from two or more nozzles or other means of forming directed jets with the possibility of education in the body of the foam generator and / or for its redistribution two or more in contact and / or mutually overlapping jets of medium expansion foam with the formation of a single jet of medium expansion ratio foam of increased range [RU 2180607, А62С 5/02, publ. 2002.03.20].

Known methods and equipment are not sufficiently ineffective in extinguishing large fires in large areas and in places difficult to access for land road transport. Therefore, technologies and equipment for extinguishing fires with the use of aviation, mainly airplanes and helicopters, are developing intensively, which is primarily due to the speedy delivery of fire extinguishing equipment to places difficult to reach for ordinary vehicles.

The most common means of extinguishing fire using airplanes to date is water, which is usually poured from flying airplanes to forest fires, but it is known that it is impossible to extinguish fires of petroleum products and fires in urban environments and at industrial facilities, as well as by means of this method. places.

The preemptive use of helicopter equipment in fire extinguishing is connected, first of all, with the possibility of prompt delivery of firefighters, rescuers, technical fire extinguishing equipment, as well as evacuation of injured people to the site of an emergency. The cost of such work is much higher than the cost of work with road transport, but in the presence of rough terrain, blockages or traffic jams on the roads and the presence of high-rise residential and industrial buildings, a helicopter is often the only possible means of fighting forest fires and eliminating the consequences of accidents and disasters on industrial objects.

The essential advantages of helicopters are their ability to hover in place and perform vertical ascent and descent. This allows them to take off and land in a limited space and, in essence, translates helicopters into a class of non-aerodrome aircraft, thanks to which helicopters are able to perform tasks inaccessible to aircraft. Therefore, at present, aviation fire extinguishing technologies are being intensively developed with the primary use of helicopters.

The currently most common method of fire extinguishing with helicopters is the delivery of water to a fire site and its discharge into a fire using devices transported on the external suspension of a helicopter and made with the possibility of diverting water from reservoirs in the hang mode of helicopters [US Pat. USA 4,474,245, NCI 169/53, Pat. USA 4576237, NCI 169/53, RU 2143295, A62C 31/00, publ. 1999.12.27].

Known helicopter for fighting fires, including the fuselage, the power plant, consisting of an engine and propeller system, a fire extinguishing device, consisting of a rotary fire barrel, consisting of a barrel and a sleeve, installed behind an area of the projectile area, associated with the working fluid supply line, and supply systems for working fluids, including those from an external source of the working fluid [US Patent 4090567, А62С 27/30, 1976].

Known helicopter fire extinguishing installation containing a container with a shut-off valve for the liquid, a system of sleeves and pipelines with fittings, which contains pumps placed in an airtight chamber connected to the ejector, while the pumps are connected via pipes to a suction hose, tank, sleeve to the fire shaft and a manifold with nozzles, the tank is made of rubberized fabric, is enclosed in belt bandages and is suspended from the fuselage assemblies, it has a suction hose-tightening system containing a winch, a system blocks, through which the winch cable is connected with the end of the suction hose [RU 2097276, B64D 1/18, publ. 1997.11.27].

After the fire of the Ostankino television tower for extinguishing fires in high-rise buildings, the specialized Igol-V horizontal fire extinguishing helicopter was developed, containing a water cannon, which, as it turned out later, can only be used on coaxial helicopters, because in the case of using a tail rotor on a helicopter the jet of water is broken by turbulent air currents formed around the helicopter and turns into a shapeless cloud of sprayed water.

Known helicopter for fighting fires, including the fuselage with external attachment points, the power plant from the engine and screw system, which contains a fire extinguishing device, consisting of a mounting frame, an external rod, a rotary fire barrel on it, a supply line of the working fluid to the trunk and a delivery system working bodies, including those from an external source of the working body, and the mounting frame and the outrigger bar are fixed on the helicopter's fuselage, and the fire extinguishing device is equipped with an additional nozzle mounted on the end of the outrigger bar and having an additional air supply source, while inside the additional nozzle there is a rotary barrel, and at least one vertical fire barrel, pointing downwards and installed inside the estimated area of the screws [RU 2248916 B64D 1/18, A62C 27/00 , publ. 2005.03.27].

Known used for extinguishing fires in industrial and other enterprises, in public and other buildings fire extinguishing system containing a container made of composite material based on fiberglass, organofibre or carbon fiber with a cap, coaxially upper and lower pole holes, mounted in the tank trigger mechanism, the gas generator gas pipe and pipe with spray nozzles, characterized in that to increase the efficiency of extinguishing, it has a bottom cover, above which the screen is located an, in the form of a glass, with holes in the top of the neck with safety membranes, and a gas generator attached to the neck cover with a groove in the lower part of its body, the gas outlet pipe is installed with a gap relative to the screen facing the bottom of the pipe and connected with the bottom to the bottom cover, and between the racks coaxially with the inlet of the pipeline float valve is located. A screen preventing ingested oxidized gases of combustion of the charge with the fluid flow and their release into the combustion zone is turned downside to the gas flue pipe and is connected to the bottom lid by racks, and a float valve is placed between the racks coaxially to the outlet pipe. In the final stage of liquid displacement, the float closes the gas-vapor mixture inside the tank. Gas pipe, fixed to the bottom of the gas generator is installed with a gap relative to the screen. [EN 2022582 A62C 3/08 Publ. 11/15/1994]

The main requirement for extinguishing forest and industrial large-scale fires is high efficiency. This leads to the widespread use of aviation, despite the high cost of its use. Airplanes or helicopters are used as delivery vehicles, and helicopters have a number of advantages, which include:

- the ability to reach fire sources inaccessible to ground-based fire fighting equipment and fire river and sea vessels due to the lack of roads, traffic jams, debris, etc .;

- independence from equipped airfields, runways and other aerodrome infrastructure in comparison with aircraft;

- various applications for extinguishing fires - targeted fire extinguishing, fire extinguishing in the area when the length and width of the fire extinguishing zone varies according to the horizontal speed and height of the spillway.

Firefighting has its own specifics. The quenching efficiency decreases sharply with an increase in the height of the discharge of the extinguishing agent, which usually uses dispersed or sprayed water, since a significant part of the normally discharged water evaporates before reaching the ground, and a substantial part of the dispersed or sprayed water with its free fall is delayed by the upper trees.

At the same time, a low flight altitude can lead to engine surge, as hot air is depleted of oxygen, and an increase in the height of the suspension between the helicopter and the drain tank can lead to a hook on the trees, while reducing accuracy and performance.

The closest in technical essence and achieved with the use of the result (prototype) is a method developed earlier by ZAO NPO SOPOT to deliver a fire extinguishing agent to the fire zone and / or to a barrier strip, in which a combined jet of water-air foam of low multiplicity is used as a fire extinguishing agent from 7 to 20 and medium multiplicity with multiplicity from 20 to 70, as well as the helicopter device according to the first embodiment contains a combined fire extinguishing installation with the possibility of generating Water supply and supply of the combined foam jet of low and medium multiplicity and installed on the frame obliquely, horizontally or vertically water tanks. Water tanks contain suction nozzles communicating with the motor-pumping unit at the bottom and are connected to tanks for the foaming agent and motor-pumping unit with pipelines. The helicopter device according to the second embodiment comprises the installation of a combined fire extinguishing with the possibility of generating and feeding into the fire zone and / or into the barrier strip of two or more contiguous or mutually intersecting combined jets of low and medium multiplicity foam. EFFECT: increasing the efficiency of simultaneous extinguishing of both high and low forest, peat and soil fires, industrial and emergency transport fires [RU 2394724 B64D 1/16, А62С 3/02 А62С 5/02, publ. 07/20/2010 (prototype)].

The technical drawbacks of the prototype device are insufficient fire extinguishing efficiency, complexity and cumbersome design, insufficiently high speed and insufficient efficiency of the device.

OBJECTIVES AND TECHNICAL RESULTS

The main technical problem (the inventive problem that has not been resolved to date), which hinders the increase in the efficiency of modern methods and equipment for the prevention and extinguishing of large fires in forests and industrial facilities using helicopters, is that the known weir and watering devices are not sufficiently effective in extinguishing fires large areas of large-scale forest, peat, soil, steppe, industrial and emergency transport fires and the creation of foam barriers and barrier foam-filled trenches in front of the edges of the fires with the localization of upland and lower forest, soil, peat, steppe and other fires.

The technical result achieved when using the utility model is to increase the efficiency of preventing and extinguishing forest, industrial and emergency transport fires over large areas and heights in remote locations that are difficult to access for ordinary ground transportation, as well as simplifying the design of the device while increasing its compactness and speed. and performance.

DISCLOSURE OF USEFUL MODEL

The goal, required and obtained when using the utility model, the technical result is achieved by the fact that the proposed device for preventing and extinguishing forest, industrial and emergency transport fires and laying of barrier strips with air-mechanical foam according to the utility model contains

a sealed enclosure located in a protective frame with suspension means for a helicopter or lifting device with components of a fire extinguishing substance in it in the form of component A - water and component B - an aqueous solution of a foaming agent,

means of mixing the components of the extinguishing agent and the subsequent foaming of the mixture of components of the extinguishing agent with ejected atmospheric air in the form of at least two low and medium-sized foam mixer mixers / generators mated with each other with the possibility of obtaining at least one medium-range multiplicity jet of increased range ,

means for supplying the components of the fire extinguishing substance from the housing to the means for mixing the components of the fire extinguishing substance under the influence of pressure inside the housing and the subsequent foaming of the mixture of components of the fire extinguishing substance with ejected atmospheric air,

a means of creating pressure inside the housing in the form of at least one solid fuel gas generator with the ability to create pressure during combustion inside a sealed housing.

At the same time, mixers-generators of low and medium expansion foam are made

with the possibility of obtaining low expansion foam with a frequency of from 7 to 20 and medium foam with a frequency of from 20 to 70;

with the possibility of obtaining at least one combined jet of air-mechanical foam of medium multiplicity with a multiplicity of 30 ± 10;

with the possibility of obtaining streams of dispersed and sprayed water with an average dispersion of 100-150 μm when a small amount of component B is fed into the mixer-generators - an aqueous solution of the foaming agent;

attached to the protective frame with the possibility of rotation and fixation in an inclined position.

Sealed housing made of composite material based on fiberglass, organic fiber or carbon fiber, is located in a protective frame with means of suspension to the helicopter or to a lifting device and in variants of the design can be

made with a top lid with the possibility of installing at least one solid-fuel gas generator and an overpressure relief valve in the housing and or

made with the bottom cover with the possibility of installing valves in it for the intake and discharge of the components of the extinguishing agent.

The device may contain means for quickly draining the components of the extinguishing agent.

The means for delivering the components of the extinguishing agent from the casing to the means for mixing the components of the extinguishing agent can be made in the form of pipelines for supplying the components of the extinguishing agent to the means for mixing the components of the extinguishing agent under the pressure inside the casing with shut-off and regulating valves.

The means of creating pressure inside the body is made in the form of at least one solid fuel gas generator with remote actuation, which, during ignition and combustion, creates pressure inside the body and supplies the components of the fire extinguishing agent from the body to the means of mixing the components of the fire extinguishing agent and foaming the mixture of components of the extinguishing agent.

At the same time, one of the components of the extinguishing agent (component A is water) is located directly in the hermetic enclosure, and the other component of the extinguishing agent (component B is an aqueous solution of the foaming agent) is located inside a container of elastic material located in the hermetic case with the ability to supply the extinguishing agent components pipelines in the means of mixing the components of the extinguishing agent under the influence of pressure inside the sealed enclosure.

The device in variants of the design

configured to generate and feed two or more jets of contiguous or intersecting combined jets of air-mechanical foam of medium expansion ratio to the fire prevention or extinguishing zone or into the barrier zone,

contains a remote control system with the ability to remotely initiate the inclusion of solid fuel gas generators,

contains a system of remote on / off of low and medium expansion mixers-foam generators,

contains a system of remote flow control flow control flow supplied to the mixer-generator low and medium multiplicity foam components of a fire extinguishing agent components of a fire extinguishing agent.

BRIEF DESCRIPTION OF THE DRAWINGS

The essence of the proposed device for preventing and extinguishing forest, industrial and emergency transport fires and creating barrier strips with air-mechanical foam is illustrated by the drawings, which show: 1 - a hermetic body made of composite material for placing component A of a fire extinguishing substance (water) in it, 2 - adapter; 3 - bottom case cover; 4 - gas generators designed to create inside the pressurized enclosure of the working pressure of the propellant gas resulting from the combustion of the gas-generating substance of the solid fuel cartridge of the gas generator; 5 - exhaust pipe for supplying component A (water) from the housing through appropriate piping to the mixer-generators of foam 12 attached to the protective frame 7; 6 - located inside the sealed enclosure of the capacity of an elastic material to accommodate the component B of the extinguishing agent (aqueous solution of the foaming agent); 7 is a protective frame with fastening loops to the suspension of a helicopter or a lifting device, made in the form of hollow pipelines with the ability to supply component A of a fire extinguishing agent (water) to the foam generator mixers 12 located at the corners of the protective frame; 8 - splitter for the distribution of the flows of component A through the pipelines of its supply to the mixers-generators of foam 12; 9 - splitter adapter 8; 10 - internal pipelines for the supply of component B of the extinguishing agent (aqueous solution of the foaming agent) from the tank 6; 11 - external pipelines for supplying component B of the extinguishing agent from the tank 6 to the foam generator mixers 12.

FIG. 1 and 4 show general views, and FIG. 2 shows a top view of the proposed device.

FIG. 3 - the section of the proposed device on the plane aa.

FIG. 5 - a photo of a sample of the proposed device in a suspended position.

FIG. 6 and 7 - the photo at the stages of the beginning and end of extinguishing the fire site with the proposed device.

FIG. 8-10 photos of the types of the fire after extinguishing the device.

IMPLEMENTATION AND INDUSTRIAL IMPLEMENTATION OF A USEFUL MODEL

The principle of operation of the proposed device is based on the principle of displacing the components of a fire extinguishing substance under the action of gas pressure in a sealed enclosure 1 created when at least one solid-fuel gas generator 4 is triggered, in which compositions are used that do not have explosive properties and are stably burning at different pressures to release gaseous products combustion.

The device works as follows:

As a result of the gas generators triggering within 0.5-3 seconds inside the case, the pressure rises to 0.5-1.2, mainly 0.8 MPa, which displaces the component A of the extinguishing agent (water) inside the housing 1 through the exhaust pipe 5, which through the corresponding pipelines enters the main line of the foam-mixer mixers-12.

The pressure generated by the gas generators in the hermetic case 1 simultaneously displaces component B of the extinguishing agent (water solution of the foaming agent) from the elastic container 6 located inside the case 1, which corresponding pipelines 10 falls into additional lines of the foam generator mixers 12, where components A and B are mixed and foamed ejected by atmospheric air and emitted to the outside in the form of a stream of foamed extinguishing agent.

The photographs of the industrial testing of the device are shown in FIG. 5-10.

Capacities of UPAT-2000 glass fiber with a capacity of 2000 liters [http://www.fcdt.ru] were used as the hull; gas generators GG-10 (B) -02) [https: //www.b2b-center were used as gas generators. ru / catalog / tovari / generator-gaza-gg-10-b-02-m18kh1-5-2803670 /], and as the foam generators-mixers produced by the applicant UGTP Purga type foam generators [http://sopot.ru]

The device was raised to a height of 10-12 m and was made burning the stack of lumber.

After local or remote initiation of solid fuel ignition, at least one gas generator was activated and provided pressure build-up in case 1, which squeezed components A and B from the case into foam mixer generators, where components A and B mixed and the mixture of components foamed to form streams of foamed fire extinguishing agent that extinguished the source of fire in 3-5 seconds.

The total ejection time was 30-40 seconds, which corresponds to a device performance of 55-60 l / s.

At the end of the tests, it was established that a layer of air-mechanical foam with good adhesion was formed on all surfaces, in some places of the site a layer of foam reached 10-15 cm (Fig. 8-10).

A stack of lumber was also covered with a layer of air-mechanical foam with a thickness of 2-3 mm (Fig. 8-9)

Industrial tests of the device showed that

- all equipment devices worked in normal mode;

- fire extinguishing time 3-5 seconds;

- actuation of the gas generator of the first chamber of the installation showed a pressure of 0.4 MPa, which provided a weak filling of the jets;

- the gas generating device of the second chamber worked after 12 seconds, which led to an increase in pressure to 0.8 MPa, the jets became filled, the flow rate of the extinguished foam extinguishing agent increased;

- the total time of release of the extinguishing agent was 30-40 seconds;

- total consumption was 55-60 l / s;

- a layer of air-mechanical foam was formed over the entire area of the landfill;

- the area of ejection of the extinguishing agent, taking into account the filled baths, was about 150 m ² .

Taking into account the multiplicity of the foam, equal to 3-3.5, as well as a layer of air-mechanical foam on the surface of 1.5-2 mm, the expected surface treatment area will be more than 3000 m ² when the air-mechanical foam is formed as a fire extinguishing agent.

With the width of the barrier strip 6-8 meters, the length of the barrier strip in this case will be about 500 m.

In the case of using frame bundles of several similar devices (2000x2; 2000x3; 2000x4), the processing area will be up to 12,000 m ² , respectively, and the length of the barrier strip up to 2000 m. up to 2 km.

Thus, it has been experimentally proved that air-mechanical foam can be produced when a source is fed by a pulse expelling a fire extinguishing substance by means of pressure generated by gas generators from UPAT-2000 tanks.

The protective frame 7 can be made by welding from pipes and outlets so that through their internal cavities it is possible to feed the component A displaced from the housing into the mixer-foam generators.

The protective frame 7 may be provided with lugs for fastening it to the suspension device of a fire helicopter or a lifting device.

Preliminary calculations showed that to bring the device into action it is necessary:

- volume of component A (water) in the UPAT-2000 tank 1550-1600 liters;

- the volume of component B (aqueous solution of the foaming agent) in a separate container of at least 150-160 liters;

- gas-generating charges of type OI-617-06 p. 89-15-l, OI-617-07 p. 93-14-l, OI-617-08 p. 55-15-l with total weight up to 10 kg.

Thus for this version of the device design:

- the total charge of components A and B is about 1700-1750 l,

- the volume of airspace above the surface of the component A 300 l;

- four barrels with UKTP of Purga-TP with a total maximum productivity of 80 l / s.

- the created pressure as a result of the actuation of the gas-generating devices inside the tank with an interval of 10-12 seconds, of the order of 0.8-0.9 MPa;

- The expected time of release of the extinguishing agent is 40-50 seconds.

To confirm the feasibility of implementing a utility model by industrial means and to experimentally confirm the possibility of achieving the required technical result, prototypes of the claimed device were manufactured and tested, which showed high efficiency of their application.

Fire extinguishing and localization is carried out by feeding under the pressure of combined jets of air-mechanical foam.

Used in the device of the combined fire extinguishing unit, the Purga UKTP dashboard manufactured by SOPOT CJSC provides various modes of operation with the ability to generate separate or combined fire extinguishing agent jets, which allows you to quickly adjust the fire extinguishing capabilities of the device depending on the characteristics of a particular fire.

A distinctive feature of this device from the well-known domestic spillway devices VSU-5, VSU-15A and foreign type HL7600 (Canadian production) is the ability to effectively extinguish large industrial and emergency fires from the air, simultaneously extinguishing both upper and lower forest fires by using empirically identified effect of air-mechanical foam.

Table 1 shows the proven effectiveness of the use of the device on the utility model as compared with devices of the type VSU-5, VSU-15A and HL7600 (Canadian production).

Preliminary tests of the device in the composition of the helicopter device, conducted on the territory of the Russian Federation (Gelendzhik), proved the possibility of a significant increase in the effectiveness of eliminating fires and creating protective fire-prevention strips on vegetation and protecting trees from fire.

The main factor influencing the effectiveness of the firefighting process is a new method of transporting and delivering fire extinguishing foams using the PURGA CGTP, produced by ZAO NPO SOPOT, ensuring the creation of pressure streams of fire extinguishing substance of high and low multiplicity combined air jets long range

Thus, the possibility of operational liquidation with the help of the proposed device of large fires at industrial facilities and transport, large forest fires (high, grassroots and soil) from the air, the rapid creation of an effective insulating foam layer on burning objects, foam fences before the edge of a forest fire and barrage of foam-filled trenches for localization of soil fires, efficient industrial and emergency transport fires over large areas and heights, including Heat oil and petroleum products.

The utility model can be used in the elimination of forest agricultural fires, fires in residential and industrial facilities of high number of floors, industrial facilities of the fuel, chemical and petrochemical industries, fires in areas of oil and gas production and processing, fires in forestry, woodworking and pulp and paper enterprises. industry, large-scale emergency fires of aircraft on land, accidents and disasters in rail, sea and river transport, in buildings high-rise floors, in warehouses and bases of fuel and rocket fuel and chemical products, as well as in places remote from object and city fire services.

As materials in the manufacture of individual components and parts of the device as a whole, various materials and components used and usually used in fire fighting equipment can be used.

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

Considering the novelty of the essential features, the technical solution of the task, the materiality of all the general and particular features of the utility model, proved in the section “Technique” and “Disclosure of the utility model”, proved in the section “Implementation of the utility model” the technical feasibility and industrial applicability of the utility model, successful the solution of the inventive problem, the causal relationship of the essential features of the utility model and the technical result, the confident achievement of the required technical result of the implementation and use of utility model, in our opinion, the claimed utility model meets all the requirements for eligibility requirements for utility models.

Claims (21)

1. Device for preventing and extinguishing forest, industrial and emergency transport fires and laying of barrier strips with air-mechanical foam, characterized in that it contains a sealed enclosure located in a protective frame with means of suspension for a helicopter or lifting device with components of a fire extinguishing substance placed in it in the form of component A - water and component B - an aqueous solution of a frother, means of mixing the components of the extinguishing agent and the subsequent foaming of the mixture of components of the extinguishing agent with ejected atmospheric air in the form of at least two low and medium-sized foam mixer mixers / generators mated with each other with the possibility of obtaining at least one medium-range multiplicity jet of increased range , means for supplying the components of the fire extinguishing substance from the housing to the means for mixing the components of the fire extinguishing substance under the influence of pressure inside the housing and the subsequent foaming of the mixture of components of the fire extinguishing substance with ejected atmospheric air, a means of creating pressure inside the housing in the form of at least one solid fuel gas generator with the ability to create pressure during combustion inside a sealed housing. 2. The device according to claim 1, characterized in that the mixer generators of low and medium expansion foam are made with the possibility of producing low expansion foam with a multiplicity from 7 to 20 and medium expansion foam with a multiplicity from 20 to 70. 3. The device according to p. 1, characterized in that the mixer generators of low and medium multiplicity foam are made with the possibility of obtaining at least one combined jet of air-mechanical foam of medium multiplicity with a multiplicity of 30 ± 10. 4. The device according to p. 1, characterized in that the mixers-foam generators of low and medium multiplicity are made with the possibility of producing streams of dispersed and sprayed water with an average dispersion of 100-150 μm when a small amount of component B is fed to the mixer-generators - an aqueous frother solution . 5. The device according to p. 1, characterized in that the sealed enclosure is made of composite material based on fiberglass, organofibre or carbon fiber. 6. The device according to p. 1, characterized in that the sealed case is made with the top cover with the possibility of installing at least one solid fuel gas generator and a safety valve for relieving excessive pressure in the case. 7. The device according to p. 1, characterized in that the sealed enclosure is made with a bottom cover with the ability to install valves in it to collect and drain the components of the extinguishing agent. 8. The device according to p. 1, characterized in that it contains means for the rapid discharge of the components of the extinguishing agent. 9. The device according to claim 1, characterized in that the means for delivering the components of the extinguishing agent from the housing to the means for mixing the components of the extinguishing agent are made in the form of pipelines supplying the components of the extinguishing agent to the means for mixing the components of the extinguishing agent under pressure from the inside of the housing. 10. The device according to claim 1, characterized in that the mixer generators of low and medium expansion foam are attached to the protective frame with the possibility of their rotation and fixation in an inclined position 11. The device according to claim 1, characterized in that the means for creating pressure inside the body is made in the form of at least one solid fuel gas generator with remote actuation, which, during ignition and combustion, creates pressure inside the body and feeds the components of the extinguishing agent from the body to the means mixing the components of the extinguishing agent and foaming the mixture of components of the extinguishing agent. 12 The device according to claim 1, characterized in that one of the components of the extinguishing agent is located directly in a sealed enclosure, and the other component of the extinguishing agent is located inside a container made of an elastic material with the ability to supply components of the extinguishing agent through appropriate piping to the component mixing means extinguishing agent due to pressure inside the sealed enclosure. 13. The device according to claim 1, characterized in that it is configured to generate and supply two or more jets in contact with or intersecting combined jets of air-mechanical foam of medium multiplicity and increased range to the fire prevention and extinguishing zone or fire barrier. 14. The device according to p. 1, characterized in that the protective frame of the device is equipped with means of suspension to the helicopter or to the lifting device. 15. The device according to p. 1, characterized in that it contains a remote control system with the ability to remotely initiate the inclusion of solid fuel gas generators. 16. The device according to p. 1, characterized in that it contains a system of remote on / off of the mixer-generator of low and medium foam generators. 17. The device according to claim 1, characterized in that it contains a system for remote control of the flow rate of low and medium expansion components supplied to the mixer-generators of the foam.

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