RU2615971C1 - Device for bulk firefighting - Google Patents

Abstract

FIELD: fire safety.

SUBSTANCE: device for volumetric fire-fighting comprises a functional pyrotechnic bomb mechanical combustion cooperating with an igniter external initiation and which is coaxially mounted over a layer of plaster in a perforated cylindrical body, combined with the receiver adjacent to the closed lid of distributed outlets annular output channel reverse aerosol which is formed on distance from the shell casing rigidly connected through the interlayer of plaster with the outer casing. Perforated body and shell is made of a metal mesh or foil parogazopronitsaemoy, by supporting thermally insulating layer of plaster is conformal coated geotextile membrane. Pyrotechnic block is fixed to a diametrical bridge installed in the bayonet grooves of the housing, and an annular channel with the output openings of the cover is communicated via the expansion chamber.

EFFECT: proposed technical solution to prevent unauthorized operation surround extinguishing device.

3 cl, 1 dwg

Description

The invention relates to the field of fire extinguishing, and more particularly to devices generating aerosol combustion inhibitors generated during the combustion of the pyrotechnic composition of a functional checker, which is organized into a protected volume, where, having reached the required concentration, suppresses the source of ignition.

The level of this technical field is characterized by a device for volumetric fire extinguishing described in patent RU 2096055, А62С 13/22, 1997, which contains an initiation unit, a functional piece of a pyrotechnic composition, installed with a gap in a metal case, equipped with communication holes for communication with a reversible ring channel casing, closed by a cover with outlet openings, slotted heat exchanger and receiver.

Changing the direction of the flow of combustion products of the pyrotechnic checker to the opposite in the reversible annular channel provides additional cooling of the generated aerosol, and the main selection of thermal energy occurs in a spiral slit heat exchanger from a material with a melting point above the temperature of the gaseous products of combustion.

Placing a spiral heat exchanger between the checker and the receiver ensured flameless burning without sparks, smoke formation and efficient dispersion of the flow of combustion products for the unhindered passage of combustion inhibitors without slagging.

The disadvantages of the described device include the low flow rate of the extinguishing gas-aerosol mixture due to the relatively small mass of the checkers, since the longitudinal structural arrangement of the structural elements determines the large linear dimensions of the device and, therefore, unsatisfactory mechanical strength, difficulties in placing the generator in the cramped spaces of the guarded room.

The cooling of the combustion products of the pyrotechnic checker is insufficient due to the fact that the accumulated heat through heat transfer from the spiral heat exchanger to the body is then radiated into the gas-aerosol stream of the annular reversal channel, again heating the extinguishing mixture.

In addition, heating the casing limits the use of the device only for stationary installation, and direct contact of hot combustion products with the casing can lead to burnouts through which the extinguishing mixture flows unauthorized, destabilizing the calculated gas-dynamic mode of operation of the extinguishing device.

The device for volumetric aerosol fire extinguishing according to RU 2164808 C2, A62C 13/22, A62C 35/00, 2001, which contains an initiation unit, a pyrotechnic composition block, selected as the closest analogue in technical essence and the number of matching features, is more perfect. installed with a gap in a metal casing, provided on the side surface with communication openings for communication with a reversible annular channel of the casing, closed with a cover with exhaust openings, a heat exchanger and a perforator combined with the casing th e receiver.

A feature of the known device is that the heat exchanger includes a perforated shell that is external relative to the metal casing, reinforced coaxially with the pyrotechnic composition checker in the casing through a layer of gypsum, which is also poured into the gap between the checker and the casing.

The known device has a constructive unity and is a stable combination of form and function, providing increased efficiency of the main action for the intended purpose.

The cooling of the combustion products of the pyrotechnic checker is carried out better than in the analogue, since the heat exchange takes place actively with partial absorption on moisture of the bound and attached gypsum, which is mixed with distributed transverse jets of steam with the extinguishing aerosol stream in the annular reversal channel, reducing the temperature and diluting the mixture.

Water vapor is an additional environmentally friendly combustion inhibitor in the structure of the extinguishing mixture ejected from the generator.

The combination of the housing with the axial receiver simplified the design, providing uniform end-face burning of the checkerboard with an almost uniform flow rate of the quenching mixture.

The coaxial installation of the heat exchanger relative to the checker provided a compact device in which the mass ratio was optimized while increasing the payload, which increased the fire extinguishing efficiency in large protected volumes.

However, a continuation of the noted advantages are inherent disadvantages.

During long-term storage and in official use for the intended purpose, the attached and structural moisture of gypsum layers diffuses through the shell and body into the pyrotechnic composition of the checkers and settles on the terminals of the electrical contacts of the ignition unit, rendering them unusable and reducing the functionality of the generator as a whole.

An additional perforated metal shell of the casing, carrying a gypsum layer, significantly increases the mass of the device and reduces its payload, that is, fire fighting efficiency.

In addition, when the pyrotechnic checker burns, the connection with the case is disrupted due to inevitable peripheral burns, as a result of which the checker gravitationally moves to the receiver and blocks its volume (combustion chamber), which violates the calculated aerodynamic regime up to the checker decay, which is unacceptable by definition.

The dynamic combustion mode of the pyrotechnic checker and the additional introduction of water vapor into the generated aerosol noticeably increases the volume of the quenching mixture and the pressure in the annular channel and on the cover of the casing.

The pressure and steam can locally deform the body and the shell, blocking the bore of the annular channel between them, exacerbating the aforementioned drawback, while the lid is knocked out of the casing, destroying the structure.

The technical problem to which the present invention is directed is to increase the functional reliability of a device for volumetric fire extinguishing and fire extinguishing efficiency.

The required technical result is achieved by the fact that in the known device for volumetric fire extinguishing, containing a functional pyrotechnic block of end combustion, interacting with an igniter of external initiation and which is coaxially fixed through a layer of gypsum in a perforated cylindrical body combined with a receiver adjacent to a closed lid with distributed exhaust openings to the annular outlet channel for reversing the aerosol, which is spaced apart according to the invention, a perforated housing and a shell made of metal mesh or vapor-gas-permeable foil are conformally coated with a geotextile membrane on the side of the supporting thermally insulating layer of building gypsum, while the pyrotechnic block is fixed on a diametrical jumper installed in the bayonet grooves of the housing, and the annular channel with the outlet openings of the lid is communicated through the expander camera.

Distinctive features of the proposed technical solution eliminate the noted drawbacks and prevent the unauthorized mode of operation of the volumetric fire extinguishing device while increasing its service life with gypsum dried after curing in thermally insulating layers, access to which is blocked by unilateral permeability membranes for atmospheric moisture during storage and in official use.

At the same time, due to the multiple step cooling of the generated aerosol inside the generator, the fire extinguishing efficiency is increased.

The gaplessly adjacent permeable sheath made of metal mesh or foil with a one-sided geotextile membrane is a thin-walled composite having the sum of qualities - vapor and gas permeability inside the annular outlet channel for moisture removal during drying and complete isolation of the dried gypsum layer in official use and storage.

The execution of the shell of the annular outlet channel from a metal mesh or vapor-permeable foil, which significantly reduces the mass of the device, ensures the communication of the gypsum carrier layer with an open annular channel to remove evaporated structural and associated water removed through the conformally adjacent geotextile membrane during technological drying.

The geotextile membrane is impermeable in the opposite direction, preventing the penetration of moisture to the gypsum bearing thermally insulating layers of the shell of the casing and the casing, keeping the pyrotechnic composition of the functional checker dry, which is not found in the known analogues.

The last advantage of the generator extends the guaranteed life of the pyrotechnic checkers, isolated from the negative effects of atmospheric moisture, which expands the scope of the proposed device for volumetric fire extinguishing on sea and river vessels in high humidity.

Placing a pyrotechnic checker on a jumper diametrically fixed in the perforations of the case creates a geometric short circuit during storage and operation, preventing the burning checker from settling into the receiver, as a result of which the gas-dynamic mode of supply of the generated aerosol is not violated, and a pressure jump destroying the structure is eliminated.

The presence of a transverse jumper under the checker is guaranteed to preserve the given spatial relative position of the structural elements of the generator.

The quick-release bayonet connection of the jumper with the housing is the simplest mechanism, technologically advanced during assembly, commissioning, and repair.

The expansion chamber of the annular outlet channel under the cover dampens pressure surges of the unsteady aerosol supply and reduces the load on the cover, which does not break. At the same time, additional mixing and cooling of the aerosol occurs in the expansion chamber, which increases the efficiency of fire fighting.

Therefore, each essential sign is necessary, and their combination in a stable relationship is sufficient to achieve a novelty of quality that is not inherent in the signs of disunity, that is, the stated technical problem is solved not by the sum of the effects, but by a new effect of the sum of the signs.

The essence of the proposed technical solution is illustrated by the drawing, which has a purely illustrative purpose and does not limit the scope of claims of the totality of the essential features of the formula.

The drawing shows a General view of a device for volumetric fire extinguishing, a longitudinal section.

The device is made in the form of a compact generator with coaxially mounted structural elements, sequentially: a functional pyrotechnic checker 1, fixed by means of a heat-protective layer 2 of cured building gypsum in a cylindrical body 3, combined with a receiver 4, which are distanced from the metal shell 6 through the annular channel 5 in the outer casing 7 through the carrier layer 8 of gypsum.

The metal casing 3 with the receiver 4 is made perforated for communication with the annular output channel 5 for reversing the generated aerosol, which is formed between the casing 3 with the receiver 4 and the shell 6 made of a metal mesh or vapor-vapor-permeable foil.

A feature of this device is that membranes 9 and 10, respectively, of geotextile material having one-side vapor-gas permeability, conformally adjoin the perforated body 3 and the permeable sheath 6 from the side of the heat-protective gypsum layers 8 and 2, respectively, into the channel 5. In this case, the gypsum layers 2 and 8 reliably isolated from atmospheric moisture from the open outlet channel 5.

The casing 7, the shell 6 and the receiver 4 of the housing 3 are fixed on the bottom of the shell 10, which is connected with the bottom cover 11 of the generator through a heat-protective layer 12 of gypsum. In the lower cover 11, rolled on the casing 7, a central sleeve 13 is installed, where an igniter 14 is placed, aimed at the open end of the checker 1 and electrically connected to the temperature and / or smoke sensor of the fire alarm system (not shown conditionally).

The pyrotechnic checker 1 rests on a diametrical cross member 15, which is mounted in the perforations of the receiver 4 or in the bayonet groove 16 of the housing 3.

On top of the casing 3 is fixed by a cover 17 fixed to the casing 7, on the periphery of which the outlet openings 18 are distributed, the total passage section of which provides the calculated diaphragm of the generated aerosol from the combustion end face of the checker 1.

Between the cover 17 and the free end of the annular channel 5, an expansion chamber 19 is formed for damping the pulsations of the aerosol outlet pressure.

After assembly, the generator without a cover 17 with hardened gypsum in the interlayers 2 and 8 is dried in a ventilated heat chamber to remove moisture from them, which, through the perforations of the housing 3 with the membrane 9 and the permeable shell 6 with the adjacent membrane 10, is evaporated into the channel 5 and then removed from the process chamber .

The single-acting membranes 9, 10 serve as a screen from the penetration of atmospheric moisture to the adjacent interlayers 8, 2, respectively, whose gypsum remains dry throughout the entire period of operation.

After the drying operation, the generator is closed with a lid 17, which is rolled on the casing 7, forming a structural unity.

The device for volumetric fire extinguishing operates as follows.

If a fire occurs in the protected volume, the signal from the temperature rise or smoke detector of the fire alarm system triggers the igniter 14.

The fire pulse of the fired igniter 14 ignites the pyrotechnic composition along the open end of the checker 1, which burns steadily, generating gaseous and condensed combustion inhibitors - a fire extinguishing aerosol, which enters the receiver 4.

In the receiver 4, the aerosol expands, mixes and brakes on the bottom of the shell 10, turning around in the channel 5, as a result of which it is cooled.

Through the perforation of the receiver 4, the aerosol enters the annular channel 5 to reverse the flow movement to the outlet 18 of the cover 17.

At the exit of channel 5, the aerosol enters the expansion chamber 19, where pressure and temperature are equalized and additional cooling occurs during heat removal to the metal casing 7.

The aerosol from the expansion chamber 19 is distributed by thin jets through the openings 18 of the cover 17 into the protected volume, where it is mixed with the injected air, which is diluted and cooled, forming a quenching mixture filling the room.

Upon reaching the required concentration of combustion inhibitors in the volume of the enclosed space, the ignition site is suppressed by interrupting the chain reactions of the reproduction of active radicals during the burning of organic substances - volumetric fire extinguishing automatically occurs.

Comparison of the proposed technical solution with the closest prior art analogues did not reveal an identical match of the totality of the essential features of the invention.

The proposed differences of the extinguishing aerosol generator, which do not directly follow from the statement of the technical problem, are not obvious to a specialist in fire fighting equipment

The combination of the structural elements of the proposed generator in their interconnection can be carried out at the existing production of fire extinguishers, equipping customers with automatic means of volumetric suppression of fires.

From the foregoing, we can conclude that the invention meets the conditions of patentability.

Tests of the prototypes of the proposed generator in an air-conditioning system with temporary modeling confirmed an increase in the shelf life after at least 10 years of storage while maintaining increased effectiveness of the intended purpose, which allows recommending its serial production for customers.

Claims (3)

1. A device for volumetric fire extinguishing, containing a functional pyrotechnic block of end combustion, interacting with an external initiation igniter and which is coaxially fixed through a layer of gypsum in a perforated cylindrical body, combined with a receiver adjacent to a closed lid with distributed exhaust openings of the reverse aerosol output air passage , which is shaped by a shell remote from the body, rigidly connected by means of interlayers and of gypsum with an external casing, characterized in that the perforated casing and the shell on the side of the carrier insulating layer of gypsum are conformally covered with a geotextile membrane, while the pyrotechnic block is fixed on the diametrical bridge of the casing, and the annular channel with outlet openings of the lid communicates through an expansion chamber . 2. The device according to p. 1, characterized in that the shell of the annular output channel is made of metal mesh or vapor-permeable foil. 3. The device according to claim 1, characterized in that the jumper for supporting the functional checker is installed in the bayonet grooves of the housing.

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