RU2481872C2 - Generator of fire-extinguishing aerosol - Google Patents

Abstract

FIELD: fire-prevention facilities.

SUBSTANCE: invention relates to the field of fire extinguishing, namely, to devices that generate gas-aerosol flame retardants, using for this of pyrotechnic composition of combustible stick, which are released into the protected area. The generator of fire-extinguishing aerosol comprises a housing in which the pyrotechnic stick, gas-permeable cooling unit, and the igniter are consistently placed. The housing is covered from inside with a heat-insulating layer of curing material. The gas-permeable cooling unit is filled with the granular material. Under the convex cover which is equipped with radial outlet openings, the receiver and igniter are formed. The igniter is electrically connected by the current conductors with the device of remote control through the closed external switch. And the igniter is designed in the form of a resistor which is adjacent to the tablet of thermosensitive igniter composition. The tablet and the resistor are filled with the adhesive sealant in the central groove of the stick end. The current conductors are placed in the combustion chamber and are connected with the external switch through the fitting cavity, which is mounted on the housing by sealing bushes which are fixed by the material of heat-insulating layer. The perforated ends of the cooling unit, which cylindrical volume is filled with crushed rock, are covered by the membranes.

EFFECT: proposed technical solution provided the increase in functional reliability under the conditions of increased humidity and explosive atmosphere.

Description

 The invention relates to the field of fire extinguishing, and in particular to devices generating gas-aerosol combustion inhibitors, when using for this purpose the pyrotechnic composition of burning checkers, jet-emitted into a protected volume.

The level of this technical field characterizes the generator of a fire-extinguishing gas-aerosol mixture according to patent RU 2136338 C1, A62C 13/22, 1999, which contains a pyrotechnic checker placed axially in the body through a layer of building gypsum, a cooling unit made of granules of ablative material, in which the communicating material is mounted with a combustion chamber, an igniter electrically connected to the remote control device and a convex cover with distributed radial outlet openings.

In this case, a perforated receiver is formed between the cooling unit and the outlet openings of the lid in the housing.

The described generator having increased structural rigidity and thermal strength of the carrier layer of the housing is characterized by high fire extinguishing efficiency.

The metal casing serves as a heat accumulator for efficient evaporation of water associated with gypsum from the heat-insulating layer, which in the form of steam is actively mixed with the generated gas-aerosol products of burning drafts, thereby further reducing their temperature and increasing the inhibitory effect of the quenching mixture.

The distribution in the lid of the radial holes provides a dynamic uniform distribution of the extinguishing mixture in volume.

To ensure optimal conditions for igniting the checkers, the igniter (standard igniter capsule) is placed in focus relative to its end and is fixed in the central fire transfer tube, the channel of which forms a compact directional force of the flame, guaranteed to ignite the pyrotechnic composition over the entire combustion surface of the aerosol-forming charge.

The remote control of ignition initiation makes it possible to increase the efficiency of fire extinguishing in large volumes while simultaneously connecting generators distributed in flammable areas.

However, the disadvantage of this generator is the unsatisfactory functional reliability during operation in storage at high atmospheric humidity, mainly on ships (river, sea) due to the insensitivity to the standard heat pulse of ignition of the damp pyrotechnic composition of the pieces.

Atmospheric moisture penetrates into the generator through the outlet openings of the lid and enters the combustion chamber through the capillaries of the bulk ablation material of the cooling unit, where it is condensed and absorbed by the lyophilic pyrotechnic composition of the checker from its open surface.

More perfect is the fire extinguishing aerosol generator according to patent RU 2205671 C1, A62C 3/02, 2003, 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 a pyrotechnic checker placed axially in the body through a layer of building gypsum, a cooling unit made of granules of ablative material, in which the igniter is connected to the central fire transfer tube, connected via a remote commutator, and a convex lid with distributed output radial holes and formed in the housing above the cooling unit perforated receiver.

A feature of the known generator is that the receiver above the perforations is covered by an aluminum membrane located above the igniter, and a cover geometrically closed on the housing along the contour, the outlet openings of which are closed by an aluminum foil bandage, which ensured the tightness of the internal volume of the generator, and most importantly, the pyrotechnic checker long service life at high atmospheric humidity.

The igniter of this generator is connected to an external remote start device through a conditionally sealed (closed) switch, which prevents accidental operation of the generator igniter.

A continuation of these advantages are inherent disadvantages.

Combustible aluminum membrane above the receiver and the bandage at the outlet openings increase the time of supplying the extinguishing mixture to the source of ignition, which reduces the efficiency and effectiveness of fire extinguishing.

Moreover, part of the generated aerosol is lost in the form of a condensed phase deposited on aluminum foil.

The ablation material of the cooling unit effectively removes heat from the generated aerosol, but at the same time it is a consumable material, which dramatically changes the thermodynamics of the extinguishing mixture.

The bulk material of the filling of the cooling unit is a large aerodynamic drag, which leads to an increase in pressure in the generator and, as a result, requires strengthening of body parts and their connection nodes, which make the structure heavier.

The placement of the igniter inside the axial fire tube installed in the cooling unit causes an inevitable increase in the dimensions of the latter and the generator as a whole, which limits the adaptability of the fire extinguisher in the cramped interior of guarded ship premises.

The transfer of the igniter pulse from the remote igniter through the fire transfer tube and the combustion chamber to the open surface of the pyrotechnic checker reduces the functional reliability of the stable initiation of its combustion.

In this case, the igniter and the checker are not isolated from the structural moisture of the gypsum of the heat-insulating layer, which for a long time of service protection enters through the perforations of the receiver and condenses on these functional elements.

The igniter corrodes, which may cause the generator to self-start or to fail when an initiating signal is supplied to ignite the drafts, whose thermal sensitivity decreases when damp.

The generator’s performance during operation by testing actuators for their functionality is impossible, therefore, the probability of failure when it is started is high, which is unacceptable in autonomous life support on boats.

The problem to which the present invention is directed, is to increase the functional reliability of the generator while simplifying its design and expanding the technological capabilities of the application.

The required technical result is achieved by the fact that in the known fire extinguishing aerosol generator, comprising a body coated internally with a heat-insulating layer of curable material, in which a pyrotechnic checker is axially arranged in series and through the gap of the combustion chamber a gas-permeable cooling unit filled with granular material, above which under a convex lid, equipped with radial outlet openings, a receiver is formed, and an igniter electrically connected by current leads to the device station control through a closed external switch, according to the invention, the igniter is made in the form of a resistor adjacent to the tablet of a heat-sensitive igniter composition, filled with adhesive sealant in the central groove of the checker end, while the current leads are placed in the combustion chamber and communicate with the external switch through the cavity of the fitting mounted on the case by means of sealing sleeves fixed by the material of the heat-insulating layer, and the perforated ends of the cooling unit are cylindrical s volume of which is filled with gravel, covered with membranes, wherein the granular filler cylindrical cooling unit in the form of crushed stone is made of the heat capacity material magmatic rock: granite, basalt or quartz.

Distinctive features ensured an increase in the functional reliability of the sealed fire extinguishing aerosol generator of a simple and technological design while expanding its field of operation in conditions of high humidity and explosive atmosphere.

The implementation of the igniter in the form of a resistor, which is the executive end element of the electric circuit, providing a given nominal resistance to electric current, stabilizes the start of the generator in operation.

The resistor is placed inside the igniter tablet, for which it is preliminarily placed in the bulk composition before the pyrotechnic hinge is pressed in. This forms a constructive unity of functionally related elements of the means for initiating ignition and stable end burning of the functional checker.

The minimized dimensions of the resistor, which heats up when an electric current is applied and acts as an initiating thermal element, allow it to be mounted directly adjacent to a tablet made of a thermosensitive pyrotechnic composition.

Filling an igniter tablet with an adjacent resistor, which is placed in the central groove of the functional pyrotechnic checker, with adhesive sealant ensures their strong fastening directly to the checker when isolating from the external environment, while maintaining electrical connection with the launch unit through an external switch.

The affinity of the pyrotechnic materials of the igniter pellet and the aerosol-generating checkers, which are gaplessly adjacent to the assembly, creates a functional unity and provides an almost instantaneous transfer of a thermal pulse from an electrically heated resistor.

In this case, the checker ignites and stably burns over the entire open end surface.

The spatial restriction by the geometry of the groove of the functional checker, in which the resistor and the igniter tablet are rigidly connected to each other, and the fastening of the igniter by the adhesion forces of the adhesive sealant layer, ensure that this compact assembly is self-sufficient for its intended purpose.

Placement of current leads in the combustion chamber open during assembly provides free access for their installation in the housing connector.

The connection of the cavity of the nozzle mounted on the generator housing with the bushings fixed by the curing building gypsum of the heat-insulating layer formed from the inside of the housing into the monolith provides the resistor with the external commutator by means of current leads located inside the gaplessly combined cases.

At the same time, the nozzle cavity, due to the installed inside the sealing bushings, almost completely isolates the housing mounting connector for connecting the external switch of the launch unit with the igniter placed in the pyrotechnic block.

The rigid connection of the sealing sleeves with the gypsum of the heat-insulating layer provides the structural strength of the connecting fitting.

The implementation of the cooling unit in the form of a free cylinder (without a central fire-transfer tube according to the prototype) allowed it to be isolated by installing burning membranes on the perforated ends of the cylinder, which excludes open access of atmospheric moisture to the igniter and functional checker, which preserve the specified performance for the entire extended time fire protection services for watercraft premises.

The use of crushed stone from a heat-resistant material (preferably granite, basalt, quartz) as a granular filling stabilizes the thermodynamic mode of the generator during the burning time of the pyrotechnic checker, effectively cooling the generated quenching mixture, while maintaining the original integrity of the solid granulate, i.e. constant gas permeability and, therefore, design gas dynamics.

Installation of combustible membranes at the ends of the receiver provides an additional isolation level of the internal volume of the generator, more reliable (anti-vandal) than the bandage on the radial outlet openings of the lid, which is available for accidental or malicious punctures.

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 not solved by the sum of the effects, but by a new super-effect of the sum of the attributes.

The 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 shows a longitudinal section of the proposed generator.

In the cylindrical housing 1 of the generator through the annular gap 2, a supporting shell 3 is installed, between which a solution of building gypsum or a mixture of foam concrete and the like is poured, which, when cured, forms a rigid structural layer 4 that performs the functions of thermal insulation of the housing 1.

The free annular volume of the gap 2 in the upper (according to the drawing) part of the interlayer 4 serves as a accumulator of moisture evaporated from its material in operation, damping the pressure increase.

At the bottom of the housing 1, a checker 5 of a functional pyrotechnic composition is installed for generating a fire extinguishing aerosol during combustion.

In the central groove 6, on the open end of the checker 5, there is placed an ignition tablet 7 of a heat-sensitive pyrotechnic composition, inside of which a resistor 8 is pressed in, by conductors 9 electrically connected to the terminals (not shown conventionally) of the external sealed switch 10, for which an adapter 11 is fixed in the mounting hole of the housing 1 .

The adapter 11 contains a hollow fitting 12, the flange 13 of which is adjacent to the housing 1 from the inside and closed by an insulating sleeve 14. A similar sleeve 14 is symmetrically mounted in the shell 2, forming a channel under the current leads 9 of the resistor 8, which are pulled through the adapter 11 after installing the checkers 5 on the bottom of the housing 1 before pouring the technological solution into the gap 2.

After the gypsum has cured, the interlayers 4 of the insulating bushings 14 are rigidly fixed, informing the fitting 12 the bearing properties of the structural element, which is used for installation on the housing 1 of the switch 10.

The housing of the switch 10 is installed on the nozzle 12 adjacent to the housing 1 of the generator and fix the position of the threaded nut 15.

After that, the cable 17 of the remote launch unit is mounted through a sealed input 16, connecting to the terminals of the switch 10, to which respectively the current leads 9 of the resistor 8 are connected.

Then, on the case of the switch 10, the cover 18 is hermetically strengthened, isolating its internal volume from the atmosphere.

A resistor 8 mounted in the igniter tablet 7 is poured into the central groove 6 of the checker 5 with a layer 19 of adhesive sealant, forming the igniter of the generator itself.

A cooling unit 21 is located above the combustion chamber 20, filled with crushed stone 22 made of granite, marble, quartz granules, gypsum, etc. heat-consuming materials, at the ends limited by perforated disks 23, on which membranes 24 are placed, insulating the combustion chamber 20.

A receiver 25 is formed in the shell 2 above the cooling unit 21, on the end of which, through the annular cuff 26, a lid 27 is fixed with radial outlet openings 28 sealed with adhesive tape 29 from the outside, protecting against penetration of foreign objects, isolating the internal volume of the generator.

The fire extinguishing aerosol generator operates as follows.

The generators are preferably installed in the lower part of the guarded premises in order to ensure the fastest filling of the volume with a fire extinguishing aerosol.

When extinguishing a fire, it is necessary to remove people from the premises and close openings (hatches, windows, doors, ventilation holes) and turn off the fans.

When the automatic fire control system is activated from exceeding the temperature threshold or smoke, the person on duty from the central console includes an appropriate start-up unit, which supplies a pulse to the switch 10 to initiate the igniter 8-7.

The heat pulse of the resistor 8 ignites a thermosensitive tablet 7, which ignites the pyrotechnic composition of the checkers 5.

Checker 5 stably burns from the end surface, generating aerosol combustion inhibitors in the form of gaseous compounds and ultrafine condensed particles with a developed energy surface into the combustion chamber 20.

The aerosol accumulates in the combustion chamber 20, where the pressure increases, under the influence of which the gaseous products of combustion of the pyrotechnic composition of the checkers 5 burn the membrane 24 through the perforated lower disk 23 and penetrate the crushed stone layer 22 of the cooling unit 21.

In this case, the heat-intensive material of the granular filling 22, while inertia heating, takes a significant part of the heat of the aerosol, which is additionally cooled, overcoming the labyrinth gaps between the granules 22.

At the outlet of the cooling unit 20, a hot aerosol under pressure overcomes the upper perforated disk 23, burning its membrane 24, and enters the receiver 25, where it accumulates.

In the receiver 25 there is mixing of the aerosol, equalization of temperature and pressure pulsations.

Further, in the volume under the cover 27, the pressure of the generated aerosol increases, which breaks through the adhesive tape 29, freeing the outlet openings 28 for free flow into the protected volume.

Aerosol jet-jet radial high-speed flows from openings 28 flow into the room volume, dynamically filling it, while thin aerosol jets are convectively cooled by colder air, mixing with it forms an extinguishing mixture.

When a gas-aerosol mixture is introduced into the fire zone, the chain mechanism of the formation of active radicals breaks off due to their recombination, as well as due to their retention on the aerosol surface, each particle of which acts as an energy condenser, which provides suppression of the fire when the required concentration of 75-100 g / m ³ combustion inhibitors.

The material of the interlayer 4, having poor thermal conductivity, protects the housing 1 from heating, not exceeding a temperature of 45 ° C, which allows, if necessary, to directionally extinguish the source of fire manually.

The end combustion of the checker 5 eliminates the transfer of pressure to the bottom of the housing 1, thereby ensuring the safe operation of the generator.

The experimental verification of the prototypes of the generator according to the invention showed stable stable operation at ambient temperature in the range from minus 50 to 60 ° C and 98% relative humidity at 25 ° C, which is guaranteed for 10 years of service life.

The sealed design of the generator with the switch is explosion-proof, that is, it is not initiated from an external detonation pulse, which expands the scope of its use in hazardous industries.

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 technician, showed that it is unknown, and given the possibility of practical serial production of a device for volumetric aerosol fire extinguishing in an existing production facility, a conclusion on its compliance with the criteria of patentability.

Claims (2)

1. A fire extinguishing aerosol generator, comprising a body, internally coated with a heat-insulating layer of cured material, in which a pyrotechnic block is axially arranged in series and through the gap of the combustion chamber a gas-permeable cooling unit filled with granular material, over which a receiver is formed under a convex lid equipped with radial outlet openings , and an igniter electrically connected by current leads to the remote control device through a closed external switch, The fact that the igniter is made in the form of a resistor adjacent to the tablet from a thermosensitive igniter composition, filled with adhesive sealant in the central groove of the checker end, while the current leads are placed in the combustion chamber and communicate with the external commutator through the cavity of the nozzle mounted on the housing by means of sealing sleeves fixed by the material of the insulating layer, and the perforated ends of the cooling unit, the cylindrical volume of which is filled with crushed stone, are covered with membranes. 2. The generator according to claim 1, characterized in that the granular filling of the cylindrical cooling unit is made of the heat-consuming material of igneous rock: granite, basalt or quartz.