RU2142836C1 - Aerosol generator - Google Patents

Abstract

FIELD: fire fighting, devices generating gas-aerosol inhibitors of burning formed in combustion of special fire- extinguishing pyrotechnic compositions directed to protected volume. SUBSTANCE: aerosol generator has blasting cartridges, igniter and is made in form of rigidly connected coaxial with annular gap cylinders of cooling unit, and body with ablation heat-insulating layer in shell. It has cover with outlet opening and receiver mounted between cooling unit and generator body. Novelty consists in that blasting cartridges are installed in center of cooling unit whose cylinder and shell of ablation heat- insulating layer from gypsum are metallic and perforated. Cover is connected with diaphragm having nozzles, and has ejection windows, and directly fastened to body axially. EFFECT: higher carrying strength of generator, increased fire-extinguishing ability, reduced overall dimensions, weight and expenditures for manufacture with preserved functional reliability and improved ecological cleanness of products of extinguishing mixture. 3 dwg

Description

 The invention relates to the field of fire extinguishing, to devices generating gas aerosol combustion inhibitors generated during the combustion of a pyrotechnic composition and organized in a guided manner in a protected volume. Generators are intended for use both in autonomous and automatic fire extinguishing systems.

 The prior art is characterized by generators containing a pyrotechnic block placed in a thermally protected case, in the cover of which an ignition unit is mounted and output nozzles are made, equally distributed along the periphery of the cover, and a cooling cylinder is installed above the nozzles with an injection gap (see RF patents N 2008045, 1994). and N 229202, 1998, both of class A 62 C 3/00).

 The gas-aerosol stream generated by burning the pyrotechnic composition of the checkers, diluted with the products of the endothermic decomposition of the heat-insulating layer of the body, effectively suppresses the fire in a confined space, but with the direct action of the high-temperature quenching mixture on the material object it can cause its fusion, burned, warpage and serve as a source of secondary ignition.

 The noted drawback is established in the aerosol generator according to the patent of the Russian Federation N 2108824, A 2 C 13/22, 1998, chosen by the authors as the closest analogue in terms of the number of matching features and technical nature, which contains pyrotechnic checkers, an igniter and made in the form of tightly connected concentrically mounted with a guaranteed clearance of the cylinders of the cooling unit and the housing with an ablative heat-protective layer in the shell, equipped with a cover with outlet openings between which the receiver is formed.

The igniter is mounted on a cylindrical lid, which is mounted with an annular gap on a glass, which closes with a slit the outlet of the cylinder of the cooling unit installed inside the cylindrical body, equipped with a heat-protective layer placed in the shell. The cylinders of the cooling unit and the housing are fixed coaxially with a gap in which the pieces of the pyrotechnic composition are equally distributed. The ablation heat-protective layer is made of sodium bicarbonate, which decomposes endothermally with the formation of neutral gaseous products (CO ₂ and H ₂ O - steam).

The relative position of the structural system: checker - cooling cylinder - glass - lid, mounted with guaranteed gaps, forms a labyrinth gas channel with increased hydraulic resistance to redistribute and equalize the temperature of the mixture, mix the aerosol with the gas stream and, ultimately, reduce the temperature of the working mixture to a temperature of 200 -250 ^o C at the output of the generator as a result of its multi-stage cooling.

 However, the disadvantage of the known aerosol generator is the complexity and bulkiness of the design, the high unit cost of protecting volumes from fires.

 The problem to which the present invention is directed is to increase fire extinguishing efficiency by reducing the cost of manufacturing a generator by reducing the mass of the structure while simplifying it, without reducing functional reliability.

 The required technical result is achieved by the fact that in the known aerosol generator containing pyrotechnic checkers, the igniter is made in the form of rigidly connected, coaxially mounted with an annular gap cylinders of the cooling unit and provided with a cylindrical cover with an outlet opening of the housing with an ablative heat-protective layer in the shell, between which is formed the receiver, at the suggestion of the authors, pyrotechnic checkers are installed centrally inside the cooling unit, the cylinder of which and the ablative heat shell The protective layer of gypsum is made of perforated metal, and the cylindrical cover is equipped with ejection windows, axially directly mounted on the housing and communicated with the annular gap by means of diaphragm nozzles.

 The proposed new forms and material for performing structural elements, their spatial interconnection provided an increase in the structural strength of the compact generator, an increase in the fire extinguishing ability of the generated gas-aerosol mixture.

 Distinctive features of the new interconnection of known features made it possible to reduce the dimensions of the generator by several times and increase the rigidity of the structure, since with multi-stage cooling of the generated gas-aerosol mixture, mechanical destruction of the supporting gypsum heat-protective layers does not occur when the water structure is evaporated from them.

 The proposed generator execution scheme ensured the structural combination of the receiver in the cylinder volume of the cooling block and the functional combination of the metal perforated shell cylinders and the cooling block in the perforated shell cylinders and the cooling block as an energy accumulator for the combustion of checkers and as radiators for the evaporation of accumulated and bound water from gypsum heat-shielding layers convective heat transfer. This effective heat and mass transfer inside the generator ensured the selection of most of the thermal energy from the generated gas-aerosol products of the quenching mixture.

 Fastening the cylindrical cover directly axially to the housing simplified the design by eliminating intermediate nodes and parts without compromising functionality. On the contrary, by equipping the cylindrical cover with a diaphragm with nozzles and ejection windows, more efficient portion mixing of the individual jets of the generated extinguishing mixture with cooler external air is obtained before it is fed into the fire zone.

 The communication of the cylindrical cover with an annular gap through the nozzles of the diaphragm provides gas-dynamic support in the annular channel, which, on the one hand, promotes better mixing of gas aerosol products and their cooling by distributed transverse jets of evaporated water from gypsum, and on the other hand, the use of an axial cylinder of the cover with ejection windows in as a jet pump of external air - an additional cooler, and more efficient: not the entire mass of the gas-aerosol stream, but in portions, f rmiruemymi concentrically arranged nozzles.

 Therefore, the entire set of essential features is necessary and sufficient to achieve the novelty of quality, serves to solve the problem posed in the invention.

 The patent search and comparative analysis with the identified analogues made it possible to conclude that the proposed technical solution meets the patentability criteria, because it is not known from available sources of information of the prior art, which does not explicitly follow for a firefighter, and can be industrially reproduced according to the developed technical documentation in serial.

The invention is illustrated in the drawing, which schematically shows:
in FIG. 1 is a sectional view of a generator;
in FIG. 2 is a view along arrow A in FIG. 1;
in FIG. 3 is a graph of the temperature distribution of the gas aerosol stream along the length of the stream after exiting the generator.

 The proposed aerosol generator is a supporting structure of rigidly bonded coaxial metal cylinders 1 and 2, respectively, of the housing and the cooling unit. In the center of the perforated cylinder 2 of the cooling unit, longitudinally pyrotechnic checkers 3 of a mixture of composition were installed: an oxidizing agent - potassium nitrate, a combustible binder - phenol-formaldehyde resin, and an aerosol forming agent - dicyandiamide, taken in an optimized quantitative ratio (in the described example, 70-11-19 weight percent, respectively). The checkers 3 are fastened to the cylinder 2 by means of a layer 4 of gypsum, the aqueous solution of which, being poured into the gap between the checkers 3 and the cylinder 2, hardens without shrinkage and fastens them, forming a monolith.

 At the end of the cylinder 2 of the cooling unit, a receiver 5 is made, behind which the igniter 6 is mounted rigidly on the thread axially to the checkers 3 in the housing.

 The inner surface of the cylinder 1 of the body is covered with an ablative heat-protective layer 7 of gypsum, which is internally limited by a perforated metal shell 8, fixed with an annular gap 9 relative to the metal cylinder 2 of the cooling unit, forming a channel for transporting the combustion products of the checkers 3 at the outlet of the generator.

 The annular gap 9 is closed by the diaphragm 10 with concentric nozzles orifices 11.

 Mounting brackets of the generator to the support are secured to the support in the protected room and axially, from the side of the diaphragm 10, a cylindrical cover 13 provided with ejection through holes 14. The cover 13 is structurally a cylinder with an outlet 15 and functionally serves as a mixer, where it is additionally cooled generated gas-aerosol combustion products of pyrotechnic checkers 3 by injected external air.

 The cylindrical cover 13 communicates with the annular gap 9 by means of nozzles 11 of the diaphragm 10.

 Before pouring an aqueous solution of gypsum into the gap between the body and the shell 8, the blocks 3 and the cylinder 2 of the cooling unit, the perforations of the shell 8 and the cylinder 2 are closed with a plastic film to prevent the gypsum solution from flowing out of the filled cavities before it hardens, after which the generator assembly is rigid supporting structure. In this case, the set gypsum of layers 4 and 7 has a developed porous surface, that is, a spongy material, which is a physical storage of water.

 The perforated cylinder 2, the interlayer 4 and the receiver 5 simultaneously form a combustion chamber and a cooling unit for the combustion products of pyrotechnic checkers 3.

 The generator operates as follows. Igniter 6 is started automatically from the fire alarm system, manually from the remote control or autonomously, triggering by exceeding the threshold of permissible air temperature in a protected enclosed volume.

 The heat pulse of the igniter 6 ignites the checkers 3, during combustion of the pyrotechnic composition of which a gas-aerosol mixture is formed, which includes both gaseous compounds and highly dispersed condensed particles, which, due to the large specific surface area, are effective combustion inhibitors. In the receiver 5, the actively forming gas-aerosol mixture accumulates, while the pressure fluctuations from the uneven burning of the checkers 3 are equalized.

 Then, through the perforations of the receiver 5, the gaseous products of combustion of the composition of the checkers 3 and the finely divided particles of the generated aerosol enter the annular gap 9, through which they are transported to the exit. In this case, the metal cylinder 2 and the shell 8 accumulate the heat of the gas-aerosol mixture products, heat up and radiate heat convectively into the gypsum, where the accumulated and bound water is evaporated, while the easily burned polyethylene film does not block the perforations.

 The vapor is then thrown through perforations of the shell 8 and the cylinder 2 of the cooling unit with transverse jets from both sides under pressure into the annular gap 9, actively mixed with the transported gas-aerosol products, diluting them. Thus, ablative heat and mass transfer are carried out, and water is an environmentally friendly product and serves as an additional combustion inhibitor. In the generator of the proposed design, from gypsum layers 4.7, water is evaporated to 26% and mass.

 Comparative tests of prototypes of the generators of the proposed design and analogues showed a higher cooling efficiency of the extinguishing stream (see figure 3).

 Active cooling of the generated gas-aerosol stream continues in the cylindrical lid 13, where the mixture is ejected by high-speed jets through the nozzles 11 of the diaphragm 10. By creating a discharge in the cylindrical lid 13, like cooler, the cooler air of the room to be protected is injected through the windows 14, where it cools the discrete stream of gas-aerosol mixture , which through the outlet 15 enters the fire and are distributed in volume.

 When a gas-aerosol mixture is introduced into the combustion zone, the chain mechanism of reproduction of active radicals breaks off, as a result of which the fire is suppressed.

 At the exit of the generator, there is practically no high-temperature jet. Fire extinguishing ability is higher than that of the prototype: the proposed one protects the volume of 110 cubic meters. against 60 cbm known for the same mass of extinguishing charge, and the mass ratio of the generators is 18 kg / 65 kg.

 The overall dimensions are reduced and, compared with the prototype, the volume of the proposed generator is 3 times less, and the price with equal performance is reduced by an order of magnitude.

Claims (1)

 An aerosol generator containing pyrotechnic checkers, an igniter, a receiver and made in the form of rigidly connected, coaxially mounted cylinders with an annular gap, respectively, a cooling unit and a housing provided with a cylindrical cover with an outlet, and an ablative heat-protective layer in the shell, characterized in that the pyrotechnic checkers are installed centered inside the cooling unit, the cylinder of which and the shell of the ablative heat-protective layer of gypsum are made of perforated metal, and the cylinders The lid is equipped with ejection windows, axially directly mounted on the housing and communicated with an annular gap by means of diaphragm nozzles.

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