RU2422178C1 - Fire-extinguishing aerosol generator - Google Patents

Abstract

FIELD: fire-fighting means. ^ SUBSTANCE: invention refers to fire extinguishing, namely to systems working on the principle of using suspended fine solid particles of an aerosol generated by combustion stick of a pyrotechnic composition as fire retardants. The generator comprises a pyrotechnic stick equipped with a flame igniter electrically connected with an external starting arrangement and fastened by a layer made of a curing material with a body overlapped with a diaphragm; the body through an annular gap forms a reverse pathway to an outlet annular nozzle and is coaxially fixed in a thermally shielded case provided with a central projection and an axially clamped plate-type cover. The case is filled with liquid oil covering the body wherein the pyrotechnic stick supplied with the flame igniter is arranged; a combustible diaphragm adjoins the body diagram; and over the body, distributed transverse disks alternating with in-built bulkheads is axially clamped; the central projection of the case has radial holes and adjoins a bottom of the cover. ^ EFFECT: invention provides enhanced functional reliability of the generator. ^ 2 cl, 1 dwg

Description

The invention relates to the field of fire extinguishing, and in particular to devices whose action is based on the use of suspended fine particulate matter as an aerosol, which is formed during combustion of a piece of pyrotechnic composition and released into a protected volume, as an inhibitor of combustion.

The level of this technical field is characterized by the aerosol generator described in the invention according to patent RU 2142836 C1, A62C 35/00, 13/22, 1999, which contains a pyrotechnic checker of functional composition, an ignitor, a receiver and rigidly connected, coaxially mounted, perforated block cylinders cooling and enclosures equipped with thermoprotective shells made of cured material (gypsum).

The output reversing channel between the casing and the casing of the cooling unit is closed by a lid with nozzles that acts as a diaphragm.

An axial nozzle with ejection windows is additionally fixed on the casing for suction of atmospheric air, which creates turbulent mixing with aerosol jets for more efficient cooling.

Reliable thermal insulation of the casing allows the use of this generator for manual directional fire extinguishing.

However, the described aerosol generator has unsatisfactory functional reliability due to the external location of the igniter, which interacts with the pyrotechnic bomb through an extended receiver.

The design of the generator simplifies assembly during separate storage of components, but determines the need to use a powerful igniter to guarantee the initiation of sustainable combustion of the pyrotechnic composition of the checkerboard.

The generator has a relatively large length due to the presence of an ejection nozzle, which limits the efficiency and mobility during manual fire fighting.

More perfect is the fire extinguishing aerosol generator according to the patent RU 2346718, A62C 13/22, B01J 7/00, С01В 13/02, 2007, which is selected by technical essence and the number of matching features as the closest analogue to the proposed generator.

The known fire extinguishing aerosol generator contains controlled from an external starting device means of initiating (igniter) the functional charge of the pyrotechnic pieces, distributed in a cylindrical thermally protected housing, combined with the receiver.

The receiver is blocked by a transverse diaphragm, the communication pipelines of which connect the receiver with a reversing output channel to the annular nozzle.

The housing through the gap is fixed coaxially in the casing, the open end of which is partially blocked by a counter-mounted plate-shaped lid.

The bottom of the lid rests on a housing that is mounted on the central protrusion of the casing, which form a structural unity due to rigid fastening by means of an axial screw tie.

A feature of the known generator is the presence of a labyrinth reverse channel for moving to the exit of the generated aerosol, during braking and reorientation of the direction of movement of which thermal energy is released on the obstacles, that is, the aerosol is effectively cooled.

Additional cooling of the aerosol occurs due to the evaporation of bound water from the structure of the building gypsum of the thermal protective shells of the adjacent perforated cylinders of the housing, casing and cover.

The design is characterized by high structural rigidity.

However, the disadvantage of the known aerosol generator is the unsatisfactory functional reliability due to the fact that the pyrotechnic bomb is conditionally sealed from the external environment, which does not exclude its unauthorized operation from the detonation shock pulse in a protected volume, i.e. the structure is not explosion proof.

In addition, the specific extinguishing ability of this generator is low due to the relatively large mass of gypsum as a bearing filling of the body and accumulator of moisture evaporated during operation, necessary for dilution and cooling of the aerosol.

The problem to which the present invention is directed is to increase the functional reliability of a fire extinguishing aerosol generator by ensuring its explosion safety when exposed to an external unauthorized impulse from a protected environment and high-quality higher cooling of the generated aerosol, which expands the field of practical use for its intended purpose.

The required technical result is achieved by the fact that in the known fire extinguishing aerosol generator containing a pyrotechnic bomb equipped with an igniter electrically connected to an external starting device and fastened by means of a layer of cured material with a housing covered by a diaphragm, the housing through an annular gap, forming a reversing channel to the output annular nozzle, coaxially fixed in a heat-protected casing, equipped with a central protrusion and a disk-shaped cover mounted on the axial screed according to the invention, the casing is filled with liquid oil covering the casing, a combustible membrane adjoins the diaphragm, and transverse disks are alternately mounted over the casing on the axial screed, alternating with frames inside the casing, while the central protrusion of the casing has radial openings and is adjacent to the bottom of the cover, and the open end of the dish-shaped cover on the side of the output annular nozzle is made with a flange forming an oil pan.

Distinctive features are aimed at increasing the functional reliability of the extinguishing aerosol generator by ensuring its explosion safety with a long service life for the protection of premises for various purposes, for example, with an increased content of suspended particles and moisture in the atmosphere.

In addition, the product according to the invention, according to GOST R51046 from 01.01.98, can be certified as a type III generator (p.4, table 1), since it ensures the temperature of aerosol products at the outlet cut below 130 ° C, which is unattainable operating aerosol fire extinguishers.

Placing the case with a pyrotechnic checker in the volume of liquid oil filling the casing ensures its tight isolation, excluding operation from an unauthorized initiating impulse of the external environment, that is, the generator is explosion-proof.

The liquid oil filling the casing is chemically inert for the generated extinguishing aerosol, which does not dissolve in the oil, which eliminates unproductive losses of the extinguishing inhibitor.

The oil has a high heat capacity, therefore, it serves as an additional convective aerosol cooler when sparging with ascending jets of the generated aerosol.

The use of liquid oil as an additional cooling medium for the gaseous products of combustion of the pyrotechnic checker in combination with transportation of the aerosol through the labyrinth channel inside the generator, with repeated braking, dispersion and mixing of its jet streams, ensures equalization and reduction of the temperature of the extinguishing aerosol at the outlet of the generator nozzle to the level of 100- 120 ° C.

In addition, the placement of the means of communication of the igniter with the starting device through the layer of oil eliminates the leakage of an accidental spark, since oil is by definition an excellent insulator.

The installation of a combustible membrane on the diaphragm of the casing ensures separation of the casing and the casing in official circulation, that is, isolating the pyrotechnic checker from oil, and when the aerosol generator is functioning, the membrane burns out almost instantly when it starts up and is not a noticeable obstacle to the distribution of the fire extinguishing aerosol generated by the pyrotechnic checker. .

It should be noted that liquid oil is inert with respect to the pyrotechnic composition of the checkers, does not dissolve it and does not enter into a chemical reaction. The bomb is isolated to stabilize the ignition and the calculated thermodynamic regime of aerosol generation during end-face combustion of the charge.

The axial screed fastening of the transverse disks distributed over the height is necessary for the stepwise braking of the aerosol inside the cooling oil and reflection of flows, as a result of which the turbulence intensifies in the aerosol, bubbling is activated, heat transfer is intensified, which results in an effective decrease in the temperature of the quenching mixture at the outlet of the generator. Thus, the transverse disks serve as screens preventing the free passage of aerosol flows, which are inhibited and reflected, which is accompanied by additional heat release into the oil and increases the contact time of the aerosol with the heat-intensive filling of the casing.

Placing the frames inside the casing between the transverse disks distributed on the axial screed together forms a zigzag communication channel of the pyrotechnic checker with the output ring nozzle, which is characterized by a high gas-dynamic resistance for ascending aerosol flows, which are inhibited for a longer interaction with thermal oil absorbing thermal energy and additional cooling.

When aerosol is braked, dispersed particles of oil are adsorbed on the surface of the transverse disks, sticking to them, that is, in the bulk they are not taken out of the casing.

When turning the transverse jet streams emerging from the radial holes of the central protrusion of the casing, the above-described processes of cooling the aerosol and adsorption of oil residues occur on the bottom walls of the dish-shaped cover, which drips dropwise on the wall and accumulates in the volume of the inner flanging of the annular nozzle. Thus, the oil is practically not taken out into the protected volume.

The execution in the central protrusion of the casing of radial holes, which in this case is a classic receiver, where the gaseous products of the quenching mixture are accumulated and mixed, provides a jet distributed outflow of aerosol at a high speed, resulting in concomitant injection of air from the protected volume, which dilute and actively Thin aerosol jets are cooled.

The installation of a central protrusion at the bottom of the dish-shaped lid, the open end of which forms an annular exit nozzle, automatically reorients once again the direction of the extinguishing aerosol flow, which expands, mixes actively, and is additionally cooled before being fed into the protected volume.

Performing on the open end of the dish-shaped lid, from the side of the output annular nozzle, flanging, where separated particles of oil are separated from the aerosol supplied to the protected volume, prevents physical contamination of the adjoining area and mottled traces of burning oil droplets. That is, the flanging at the end of the lid serves as an oil pan for dripping drops of oil along its walls.

Therefore, each essential feature is necessary, and their combination in a stable relationship is sufficient to achieve the novelty of a quality that is not inherent in the characteristics of disunity, that is, the technical task posed is not solved by the sum of the effects, but by a new super-effect of the sum of the attributes.

The essence of the proposed invention is illustrated by the drawing, which has a purely illustrative purpose and does not limit the scope of the claims of the totality of the features of the formula. The drawing schematically shows a longitudinal section of the proposed generator.

The extinguishing aerosol generator according to the invention comprises a pyrotechnic checker 2 coaxially mounted in a cylindrical casing 1, which is secured through a layer 3 of cured material (gypsum, foam concrete, etc.) in a casing 4 mounted with an annular gap 5 relative to the casing 1.

The casing 1 is equipped with a thermally insulating layer 6 of building gypsum or foam concrete, technologically formed in the form of a shell adjacent to the casing 1.

The casing 1 and the thermally insulating layer 6, which are rigidly interconnected, form in a stable aggregate a supporting composite structure that works elastically under alternating loads.

The pyrotechnic checker 2 is equipped with an igniter 7, which is electrically connected by means of communication 8 (electric cords) with an external starting device 9.

The housing 4, combined with the receiver 10, is closed by a diaphragm 11, covered with a burning membrane 12, overlapping its outlet openings 13 in service.

The casing 1 is filled with liquid oil 14 (transformer, motor, etc.), covering the housing 4, over which a number of transverse disks 15 are located, is distributed along the height of the axial screw coupler 16. The placement of electrical cords 8 in the layer of oil 14 forms an intrinsically safe electrical circuit igniter 7, which excludes unauthorized start of the generator from extraneous pulses.

The coupler 16 is suspended on the Central protrusion 17 of the casing 1, bearing a plate-shaped cover 18.

In the Central protrusion 17 of the casing 1 is made of radial holes 19 for the exit of the generated aerosol.

Between the transverse disks 15 there are frames 20 fixed inside the casing 1, together forming a zigzag communication channel of the pyrotechnic checker 2 with an annular outlet nozzle 21 (generator outlet) formed by the gap between the casing 1 and the cylindrical wall of the plate-shaped cover 18.

The bottom cover 18 is supported by a central protrusion 17 of the casing 1, with which it is rigidly connected by means of an axial screw tie 16 in a structural unity.

The open end face of the dish-shaped lid 18 is provided with an annular flange 22 from the inside, which acts as a reservoir of oil droplets flowing down the wall of the lid 18.

Liquid oil 14 is poured into the casing 1 through a through hole in the adjacent bottom of the lid 18 and the Central protrusion 17 of the casing 1, which is closed by a threaded plug 23.

The generator operates as follows.

If a fire occurs in the protected volume, an igniter 8 is automatically triggered by a signal from the start-up unit 9, igniting the pyrotechnic composition of the checker 2, during combustion of which gaseous products of combustion inhibitors are formed in the form of an aerosol filling the receiver 10.

In the receiver 10, the generated aerosol fills the volume, mixes, while its temperature and pressure are equalized.

With increasing pressure in the receiver 10 through the holes 13 of the diaphragm 11, the membrane 11 breaks through or burns out from direct contact with hot aerosol, which flows fluidly into the oil 14, filling the casing 1.

In the volume of oil 14, under the action of distributed aerosol jets, bubbling occurs, accompanied by active heat exchange, without chemical interaction.

In the process of burning the checkers 2, the generated aerosol accumulates in the free volume of the casing 1 under the central protrusion 17, where the pressure of the combustion products of the checkers 2 increases.

From the housing 4, the aerosol moves in the cooling oil 14 along the zigzag channel between the frames 20 of the casing 1 and the transverse disks 15 of the screed 16, which serve as mechanical chippers that prevent the free passage of the aerosol, during braking and turning of which additional heat is extracted - cooling of the aerosol.

On the disks 15 in the free volume of the casing 1, the droplets of oil 14 are separated, carried away by the aerosol leaving the casing 4, which adhere to the surface of the disks 15.

From the central protrusion 17, an aerosol under pressure is distributed by radial jets into the cover 18, where they unfold when braking on its walls towards the outlet 21 (ring nozzle) of the generator.

When the aerosol flows out through the radial openings of the central protrusion 17, air is intensively injected from the protected volume through the nozzle 21 through the gap between the casing 1 and the cover cylinder 18, relatively cold injected air is actively mixed with the aerosol jets, diluting and noticeably cooling it.

When braking aerosol jets on the wall of the dish-shaped lid 18, the residual droplets of oil adhere adherently to its surface, accumulate, increase and gradually drain into the annular flange at the end of the lid 18, formed by flanging 22, where they remain for the entire duration of the generator.

Therefore, in the dynamics of the process, oil drops are separated from the extinguishing aerosol, which are not thrown into the protected volume.

The gas and hydrodynamic regime of the labyrinth flow of the generated aerosol from the burning pyrotechnic checker 2 to the output section of the generator (its nozzle 21), organized in this way, provides cooling of the inhibitory gaseous products to a temperature in the range of 110-120 ° C, which corresponds to the standard of type III generators, previously the achieved level for all operating aerosol generators.

The pyrotechnic bomb in this aerosol generator is hermetically isolated from the external environment, unauthorized electrical and shock pulses, which greatly expands the field of application, for example, in an atmosphere of high humidity, explosive suspensions, electrical networks.

Tests of prototypes of the proposed generator showed its high fire extinguishing efficiency, reliable operation with complete explosion safety in official use and during long-term operation for fire protection of special objects, for example, with an increased content of combustible gases, suspended dust and fibers in the atmosphere of the room, which form explosive vapor-gas and dust-air mixtures, as well as completely eliminate the way out of the generator together with an aerosol of sparks and solid hot particles, obnyh ignite surrounding materials or objects.

A comparative analysis of the proposed technical solution with identified analogues of the prior art, from which the invention does not explicitly follow for a fire extinguisher specialist, showed that it is not known, and given the possibility of serial production of fire extinguisher aerosol generators in an existing production, we can conclude that the criteria are met patentability.

Claims (2)

1. A fire extinguishing aerosol generator containing a pyrotechnic checker equipped with an igniter electrically connected to an external starting device, and fastened by means of a layer of cured material with a housing covered by a diaphragm, the housing through an annular gap, forming a reversing channel to the output ring nozzle, coaxially fixed in a thermally protected casing equipped with a central protrusion and a plate-shaped lid mounted on an axial screed, characterized in that the casing is filled with liquid oil ohm covering housing, which adjoins the diaphragm membrane is combusted, and above the housing on the screed centerline distributively mounted transverse discs alternating with frames within the housing, wherein the housing has a central protrusion and the radial holes adjacent to the bottom cover. 2. The generator according to claim 1, characterized in that the open end of the disk cover on the side of the output annular nozzle is made with a flange forming an oil pan.

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