RU2498829C1 - Fire-extinguishing aerosol generator - Google Patents

Abstract

FIELD: fire prevention facilities.

SUBSTANCE: invention relates to devices for 3D aerosol fire extinguishing. The fire-extinguishing aerosol generator comprises a central candle, an igniter, a cooling unit coaxially mounted in the housing. On the lateral surface of the housing the outlet openings are distributed. The central candle from the functional pyrotechnic composition is connected to an igniter. The igniter is mounted in the lid. The mesh shell retains the cooling unit with the bulk heat-capacious material. The shell is placed with assured gap in relation to the candle, forming the combustion chamber. The outlet openings are distributed in the sector opposite the mounting bracket. The bracket is mounted on diametrical trunnions. Between the igniter and the end of candle a prechamber is formed which communicates with the annular gap.

EFFECT: technical solution provided the increase of functional reliability of the generator easily adaptable in the protected area, which is characterised by a guaranteed ignition and stable combustion of functional candle, at that the generated aerosol is structurally directed with dense flow to the focal point of the possible ignition.

3 cl, 2 dwg

Description

The invention relates to a device for volumetric aerosol fire extinguishing by means of a pyrotechnic charge generated during combustion of a gas-aerosol mixture of combustion inhibitors introduced into a protected room.

The level of this technical field is characterized by the aerosol generator of the extinguishing mixture described in the invention RU "Fire extinguishing method and device for its implementation" according to the application No. 94020391, A62C 3/00, A62C 31/00, publ. 01/10/96.

The pyrotechnic checker of the generator is coaxially mounted in a cylindrical body with distributed outlet openings on the side surface, and an igniter is installed in its lid, which communicates with the functional pyrotechnic checker.

Between the generator housing and the checker there is a cooling unit made in the form of a container filled with granules or tablets of heat-resistant material.

A disadvantage of the described generator is the incomplete combustion of the pyrotechnic composition of the functional checker due to the lack of free space above the burning equipment, where the gas phase is formed, which provides thermochemical decomposition of the components of the pyrotechnic composition to safe compounds.

The high content of harmful chemicals in the extinguishing mixture limits the practical use of these generators.

More perfect is the design of the fire extinguishing aerosol generator according to patent RU 2114657 C1, A62C 3/00, 1998, which is selected by technical essence and the number of matching features as the closest analogue to the proposed generator.

The known aerosol generator for extinguishing a fire contains a cylindrical body with outlet openings distributed on the side surface, inside of which a cooling unit and a central pyrotechnic charge (functional checker) are coaxially mounted.

The cooling unit is made in the form of a perforated cylinder filled with bulk heat-sensitive material (granules or tablets), while between the cylinder of the cooling unit and the pyrotechnic block there is a guaranteed annular gap of 10-20 mm, which ensures effective combustion of the composition in the phase phase, where the oxidation reduction reactions.

Ignition and combustion of the checker occurs along the developed lateral surface in the annular combustion chamber, without noticeable formation of harmful substances, which expands the field of use of the known aerosol generator for effective fire fighting.

However, the disadvantage of the known extinguishing aerosol generator is the unsatisfactory functional reliability due to the inertia of the ignition of the checker, which is adjacent to the central igniter.

In addition, the checker is not structurally fixed relative to the cooling unit, which in official handling, storage and transportation can lead to its radial displacement, distorting the calculated gas-dynamic combustion mode and aerosol gas intake, but also to crack formation, mechanical splitting of the functional charge, which is more detrimental to functioning, up to breaking the hull and scattering of burning fragments of equipment.

For the practical use of the known generator, it is necessary to produce special mounting equipment for its mounting in a variety of cramped volumes, which limits the free exit of the aerosol to the supporting surfaces of the protected premises, which are directly exposed to thermal energy and can serve as a source of secondary fire.

The technical problem to which the present invention is directed is to eliminate the noted drawbacks in order to increase the functional reliability of an improved generator that can be easily adapted in various interiors of secure premises for effective and safe volumetric fire extinguishing.

The required technical result is achieved by the fact that in the known fire extinguishing aerosol generator containing coaxially mounted in a cylindrical body, the outlet openings are distributed on its lateral surface, a central piece of functional pyrotechnic composition communicating with the igniter mounted in the lid, and a cooling unit with bulk heat-resistant material held by a mesh shell, which is placed with a guaranteed clearance relative to the checker, forming a combustion chamber, according to to the vent, the outlet openings are distributed in a sector opposite to the mounting bracket mounted on the diametric trunnions, and a prechamber is formed between the igniter and the end of the checker, communicating with the annular gap, while ring cuffs are placed in the annular gap between the pyrotechnic checker and the cooling unit, and the housing sector, on which the outlet openings are distributed, is limited by an angle in the range of 120-270 °.

Distinctive features of the proposed technical solution provided an increase in the functional reliability of an easily adaptable generator in a guarded room, characterized by guaranteed ignition and stable burning of a functional checker, while the generated aerosol is structurally oriented with a dense flow towards a potential fire source.

The distribution of the outlet openings on the localized part of the housing surface from the side opposite to the mounting bracket ensures the direction of the fire extinguishing flow for targeted suppression of the source of ignition. Moreover, the formed monolithic part of the housing excludes direct contact of hot gaseous products of combustion with the supporting surface of the room, which is shielded from the aerosol stream from the generator.

Installation of the mounting bracket in the diametric trunnions of the housing allows you to rotate the longitudinal axis of the generator relative to its supporting surface to orient the outlet openings to the protected object, which increases the efficiency of fire fighting.

The prechamber between the igniter and the end face of the functional checker allows, upon initiation of its combustion, to accumulate thermal energy in the local volume, where the gaseous products of the ignition force create a pulse increase in pressure to guarantee the ignition of the functional checker at the end and its stable burning.

The communication between the prechamber and the annular gap between the cooling unit and the checker ensures unhindered dynamic transfer of the combustion front to the open side surface of the pyrotechnic checker, during which a fire extinguishing mixture is intensively generated.

The installation of ring cuffs in the gap between the cooling unit and the checker structurally forms a symmetric combustion chamber, where stable uniform burning of the functional pyrotechnic composition takes place. The spatial relative position of these structural elements of the generator remains unchanged in the handling, storage and transportation of the generator.

The cuffs damp radial deformations while maintaining the integrity of the pressed pyrotechnic checker for its intended purpose.

The execution of the housing outlet openings on the sector 120-270 ° symmetrically to the mounting bracket forms a monolithic part of the housing from the supporting surface side in the protected room, preventing direct contact with hot aerosol.

The size of the sector of the housing surface on which the outlet openings are distributed was determined experimentally to solve the practical problems of fire fighting in various interiors, providing orientation of a more dense flow of combustion inhibitors in the aerosol to a likely source of ignition.

When the distribution of the outlet openings of the housing on the sector is less than 120 °, an uncontrolled increase in pressure occurs inside the generator, which does not guarantee its integrity and can lead to unacceptable ejection of burning fragments of the bursting block.

When the housing outlet openings are distributed over a sector of more than 270 °, direct contact of hot combustion products with the supporting surface in a protected room is not prevented.

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

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 the claims of the totality of the features of the formula. The drawing shows:

figure 1 - General view of the generator;

figure 2 is a view along arrow a in figure 1.

The extinguishing aerosol generator includes a functional checker 1 of a pyrotechnic composition, which during combustion forms gaseous products and condensed fine particles of combustion inhibitors.

The checker 1 through the annular gap 2, in which the damping cuffs 3 are placed, is coaxially mounted inside the mesh shell 4 of the cooling unit 5, made of heat-resistant material (tablets, granules, crumbs) or a gas-permeable curing substance (gypsum, foam concrete).

The cooling unit 5 is adjacent to the cylindrical body 6, on the side surface of which the outlet openings 7 are distributed.

The housing 1 on top (according to the drawing) is closed by a thermally insulated cover 8, in which a central igniter 10 is installed, communicating through the pre-chamber 11 with the end face of the checker 1.

The prechamber 11 is communicatively connected to the annular gap 2, which serves as the combustion chamber of the pyrotechnic composition of the checker 1.

In the housing 6, trunnions 12 are diametrically mounted, supporting a bracket 13, by means of which the generator is fixed on the supporting surfaces in a protected room.

Igniter 10 via terminals 14 is electrically connected to an initiation unit 15 controlled by an automatic fire alarm system - an external starting device

A feature of the generator according to the invention is that the outlet openings 7 are distributed on a part of the side surface bounded by an angle of 120-270 °, on the opposite side of the bracket 13. Thus, the housing 6 from the supporting surface of the generator mount does not have outlet openings 7, and a continuous shell shields the direct action of a hot aerosol.

After mounting the generator on the supporting surface, its longitudinal axis is rotated, orienting the outlet openings 7 to a likely source of ignition.

The generator operates as follows.

An automatic fire alarm system is activated from smoke sensors and / or excesses of the temperature threshold in the protected volume, including an initiation unit 15, the electric pulse of which triggers the igniter 10.

The force of the flame of the fired igniter 10 acts directly on the end face of the pyrotechnic checker 1, which ignites and burns.

The gaseous combustion products of the checkers 1 fill the pre-chamber 11, increasing the pressure, which stabilizes the combustion, and enter the annular gap 2, where the side surface of the checkers 1 is ignited, the stable combustion of which occurs in the gas phase of the volume of the combustion chamber 2 with a concomitant increase in pressure.

The generated aerosol through a gas-permeable layer of the heat-intensive material of the cooling unit 5 under pressure enters the outlet openings 7 of the housing 6, through which it is discharged into the source of ignition.

The hot aerosol stream in the layer of the heat-intensive material of block 5 excites the endothermic reaction of thermochemical decomposition, evaporates the structural water, causing the release of various non-combustible gaseous products, diluting and cooling the aerosol and preventing the deposition of its solid phase layer in the pores.

In this case, the gas-aerosol stream is cooled due to the absorption of thermal energy by the thermochemical decomposition of the material of the cooling side 5.

In the combustion chamber 2, the pyrotechnic composition of the checker 1 is burned up almost completely and forms the maximum possible amount of gaseous extinguishing agent, and a condensed phase is additionally formed in the layer of block 5, when a fire-fighting aerosol is formed by dispersing it with a gas carrier.

In the combustion chamber 2, the redox reactions are completely completed, which guarantees the content of harmful chemicals in the cooled gas-aerosol mixture in quantities not exceeding the limits of emergency exposure to humans.

Combustion inhibitors in the form of a mixture of carrier gases and highly dispersed inhibitory particles are released under pressure through the outlet openings 7 in a uniform directed flow into the volume of the protected room with a temperature of 100-120 ° C at a minimum distance from the generator (20 cm), where the technical conditions allow a temperature of 250 ° C, which classifies the proposed aerosol generator as “cold”.

The operating time of the generator, at which a fire extinguishing concentration of combustion inhibitors is guaranteed in the protected volume, is not more than 40 seconds.

The gas-aerosol stream from the outlet openings 7 of the housing 6 directionally enters the source of ignition, where combustion is suppressed.

From the side where the generator adjoins the supporting surface, the housing 6 does not have outlet openings 7, and therefore, direct exposure to hot gas-aerosol products from the combustion chamber 2 is excluded, which could cause thermal deformation, warping, etc. defects of the supporting surface.

Positive test results of the proposed design of a fire extinguishing aerosol generator allow us to recommend it for serial production for delivery to customers.

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 specialist in aerosol fire extinguishing, showed that it is unknown, and taking into account the possibility of serial production of fire extinguishing generators in an existing production, we can conclude that the patentability criteria are met.

Claims (3)

1. A fire extinguishing aerosol generator containing coaxially mounted in a cylindrical body, on the lateral surface of which there are outlet openings, a central piece of functional pyrotechnic composition that communicates with the igniter mounted in the lid, and a cooling unit with bulk heat-resistant material held by a mesh shell that is placed with a guaranteed clearance relative to the checker, forming a combustion chamber, characterized in that the outlet openings are distributed in the sector, opposite SG mounting bracket mounted on the diametral trunnions, and between the igniter and the end of checkers formed prechamber, which communicates with the annular gap. 2. The generator according to claim 1, characterized in that in the annular gap between the pyrotechnic checker and the cooling unit placed ring cuffs. 3. The generator according to claim 1, characterized in that the sector of the housing on which the outlet openings are distributed is bounded by an angle in the range of 120-270 °.

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