RU2591000C1 - Propellant fire-extinguishing device - Google Patents

Abstract

FIELD: fire safety.

SUBSTANCE: invention relates to manual portable devices for rapid fire extinguishing. Propellant fire-extinguishing device includes two pyrotechnic charges arranged through thermal protection layer in case containers of plate form connected with gap between their flanges, thus forming output disk nozzle. In slot-type combustion chamber there is safety gasket. Initiation assembly is mounted in case. Case is fixed in bracket with handle, which posts are installed on flange portions attachment bolts. Case of initiation assembly is screwed into threaded hole of bracket up to stop in pyrotechnic charges, thus being adjoined to safety gasket, through symmetrical slots in case containers flanges and channel in resistant protective interlayer. Thermo protective layer is made from magnesite, filled with expanded material, mainly, vermiculite or pyrite, wherein bracket posts are fixed on diameter of containers so that bend of handle is placed in plane of centre of mass of device, and igniter initiation assembly is made in form of spring-loaded pin, coaxial to detonating cap.

EFFECT: proposed technical solution simplified prompt device start-up into operation, guaranteed providing specified fire-fighting efficiency.

1 cl, 2 dwg

Description

The invention relates to fire fighting equipment, and more particularly to hand-held portable fire extinguishing devices that rush into a fire, where they generate aerosol combustion inhibitors in the form of gaseous combustion products of a pyrotechnic bomb and high-energy solid particles that interrupt the chain reaction, suppressing combustion.

The level of this technical field is characterized by a throwing fire extinguishing device described in patent RU 2164809 C2, A 62C 19/00, 2001, which contains a functional checker, pressed from a pyrotechnic composition, which is made of two charges installed in counter mounted dish-shaped containers fastened together by flanges with a gap forming an output disk nozzle.

Pyrotechnic charges are installed in containers below the flanging level, together forming a receiver for accumulating the generated quenching gas-aerosol mixture, equalizing its pressure and temperature during turbulent mixing of oncoming flows.

A bracket is fixed on the flanges, combined with the handle for throwing the device, under which the ignition unit (initiation) of the grater type is installed.

The charges are covered with a protective shell that protects from atmospheric moisture penetrating through an open outlet nozzle.

Pyrotechnic charges are fixed in case tanks by means of a carrier layer of gypsum, which serves as a knitting structural material and insulates the case from the thermal energy released during the burning of the blocks, as it has low thermal conductivity.

The disadvantage of the described device is the unsatisfactory effectiveness of the main action for the intended purpose due to the relatively low coefficient of functional filling, the mass of the pyrotechnic charge of which, when there is a receiver between them, is reduced by a quarter from the maximum body volume, which, as a result, reduces the protected room volume at a given concentration limit in combustion inhibitors necessary for guaranteed suppression of fire.

The heat-protective layer of structural building gypsum - a technological cured material characterized by structural strength and low heat conductivity, has an inherent disadvantage, which is expressed in low functionality due to the presence of structural moisture, which evaporates and diffuses into the adjacent pyrotechnic charge during long-term service protection of the device.

In addition, the safe location of the manual initiation unit of the grater type under the grip bracket is inconvenient to use, for mobile use in extreme conditions due to limited work space, secretive and difficult access.

More perfect is a throwing fire extinguishing device according to patent RU 2483771 C1, A62C 19/00, 2012, which is selected according to the technical nature and the number of matching features as the closest analogue to the proposed device.

The known throwing fire extinguishing device contains two pyrotechnic charges installed through cardboard interlayers in a dish-shaped housing, flanged in opposite directions, forming an output disk nozzle, coaxial to the slotted combustion chamber, where a technological (safety) burning gasket is placed, and an igniter communicating via a pyrotechnic moderator with initiation unit, placed in a quick-disconnect case mounted in a handle-bracket, which is mounted on flanges to Pusa.

The igniter located in the case adjoins directly to the pyrotechnic moderator.

The bracket with the handle is mounted on the mounting bolts of the flanges of the housing containers, above their diameter, inclined to the outlet nozzle to ensure the convenience of initiating a device held by one hand and to facilitate access to the lid of the canister with a free hand for manipulating the cord of the grate launch unit.

A feature of the known device is that the combustion chamber is blocked by a fire arrester, made in the form of an elastic ring mounted in the nozzle, a retractor with an end of the flanges, between which the nozzle of the inclined case is directed.

The known device is characterized in that it completely eliminates the unauthorized initiation of the igniter from its own start-up unit or from a directed random source of thermal energy without first removing the mechanical protection stage in the form of a flame arrester that blocks the nozzle and, therefore, access to the pyrotechnic charge.

A continuation of the noted advantage is an inherent disadvantage: reduced mobility of the launch of generating fire extinguishing aerosol due to the need to remove the reinforced preload recessed in the nozzle of the elastic ring using a trench tool, which must be equipped with each fire extinguishing generator.

In this case, the human factor in extreme conditions should be taken into account, as a result of which the flame ring can not be removed from the nozzle, which will prevent the initiating fire pulse from the igniter inside the device, to functional charges, that is, the generator is thrown into the ignition center idle and the fire does not suppressed.

Therefore, multi-position and continuous initiation of ignition of functional charges in a known fire extinguishing device by means of a float mechanism packaged inside a pencil case is unreliable.

Placing the nozzle of the inclined case of the initiation unit mounted at a distance from the housing nozzle disk nozzle at an angle to the slit combustion chamber allows the force to be displaced from the gap between the flanges, which eliminates the ignition of pyrotechnic charges, i.e., ignition of the pyrotechnic checkers fails; extinguishing aerosol generator does not work.

Thermal protective interlayers made of cardboard do not ensure the monolithic connection with pyrotechnic charges and damping of shock loads when the device is thrown into the ignition area, which can lead to destruction of the checkers, which will not ensure stable end-face burning and the dimensional generation of fire extinguishing aerosol, i.e. the given fire extinguishing efficiency .

Mounting the rack on the chord of the disk-shaped body provides a shift of its handle beyond the center of mass of the device, while creating free access to the pencil case with a grater initiation mechanism and the convenience of its maintenance during operation.

But at the same time, the hand holding the device in an unstable position is additionally loaded, which, in addition to muscle tension, creates inconveniences for access to the rubbing mechanism and, most importantly, its use by repeatedly rubbing tangentially against the small-sized friction-sensitive igniter charge inside the case.

The technical problem to which the present invention is directed is to eliminate the noted drawbacks in order to increase the functional reliability of the propellant fire extinguishing device and the efficiency of the intended operation, while simplifying startup.

The required technical result is achieved by the fact that in the known throwing fire extinguishing device, which includes two pyrotechnic charges installed through thermoprotective interlayers in dish-shaped housing containers connected to the gap between their flanges, forming an output disk nozzle, coaxial to the slotted combustion chamber, where the safety pad is placed, and an initiation unit mounted in the canister, comprising a sequentially igniter, a pyrotechnic moderator, an amplification charge, and a nozzle directed to the nozzle, while the case is fixed in a bracket with a handle, the uneven racks of which are mounted on the flange bolts, according to the invention, the initiation unit case is screwed into the threaded hole of the bracket until it stops in pyrotechnic charges, adjacent to the safety strip, through symmetrical grooves in the flanges of the housing containers and the landing a channel in a thermoprotective layer made of magnesite, while the staples of the bracket are fixed along the diameter of the containers so that the bend of the handle is placed in the plane of the center of mass of the device CTBA and initiation igniter assembly is designed as a spring-mounted on the check nakolnika coaxial primer.

Distinctive features of the proposed technical solution increased the functional reliability of the propelling fire extinguishing device and simplified its quick start-up as intended, guaranteed to provide the specified fire extinguishing efficiency.

The installation of a removable pencil case with an initiation unit in the mounting threaded hole of the bracket allows it to be stored separately from the generator and screwed into the mounting hole of the bracket completely until it is used for its intended purpose, which eliminates, in principle, unauthorized ignition of pyrotechnic charges during storage and in service with a fire extinguisher .

Equipping the handle-bracket with a threaded hole for the longitudinally movable installation of the canister of the initiation unit allows the latter to be mounted coaxially to the nozzle and inside it, in contact with the ends of the pyrotechnic charges, for their direct fire interaction, which increases the functional reliability of starting the device.

The adjoining of the initiation unit pencil case to pyrotechnic charges, when screwed in to the stop, increases the reliability (failure-free) of transferring the fire pulse directly to the combustion chamber, along the open end surfaces of the functional checkers, which are flammable and burn steadily.

When this case adjoins directly to the safety pad, made according to the diameter of the pyrotechnic charges, it provides almost instantaneous combustion when a fire force is fed through the nozzle, and the running front of the pad helps to ignite the end surfaces of the pyrotechnic charges generating a functional aerosol into the gap between them.

The safety gasket burning at the start of the device, made according to the diameter of the adjacent housing containers, in the service circulation and storage of the device overlaps the combustion chamber, which eliminated the elastic ring in the nozzle according to the prototype. Thus, in the proposed invention, the combustion chamber is opened automatically when the safety pad from the fire force from the igniter is burned at startup.

Symmetric grooves in the flanges of the tank containers, coaxial with the landing channel in the heat-protective layer, serve to place the initiation unit's case in the pyrotechnic charges directly adjacent to the combustion chamber from the end, which ensures the reliability of their ignition.

The implementation of the thermal barrier layer of magnesite, not containing structural moisture, is aimed at increasing the functional reliability of the pyrotechnic charge and the device as a whole.

At the same time, viscous magnesite, cured during sintering, is a honeycomb structure that damps deformations from external mechanical loads that are not transmitted to pyrotechnic checkers, thereby increasing the impact strength of the structure, i.e., a projectile fire extinguishing device remains operational under dynamic loads of up to 5g.

This prevents the destruction of pyrotechnic blocks, crack-formation in them, chips, etc., which preserves the specified mode of their end burning.

The fastening of the struts of the brackets along the diameter of the housing tanks allowed to place the bend of its handle in the center of mass of the device, than to balance the load on the arm that holds it during start-up and throwing, that is, to improve ergonomics for the convenience of maintenance and operation.

The implementation of the igniter in the form of a spring-loaded cap, coaxial to the capsule, forms the mechanism of the shock action when removing it from the safety pin, which simplifies the launch of the device and increases the reliability of ignition of its pyrotechnic charges.

As an igniter with an initiating mechanism of shock action in the proposed fire extinguisher device, a standard, industrially produced one is used, which guarantees its functionality.

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 signs of disunity, that is, the technical problem posed in the invention is solved not by the sum of the effects, but by a new super-effect of the sum of the attributes.

A comparative analysis of the proposed technical solution with the identified analogues of the prior art, from which the invention does not explicitly follow for a specialist in fire extinguishing aerosol generators, showed that it is unknown, and taking into account the practical feasibility of serial production in the existing production, we can conclude that the patentability conditions are met.

The essence of the proposed technical solution is illustrated by the drawing, which does not limit the amount of claims of the totality of the features of the formula.

The drawing shows: in FIG. 1 - the proposed device; in FIG. 2 is a view along arrow A in FIG. one.

The body of the device is made of two counter-mounted containers 1 in a dish-shaped form, which are fastened with bolts 2 with a guaranteed clearance by means of measuring washers or convexes (not shown conditionally) between their flanges 3, forming a disk outlet nozzle 4.

In the tanks 1 through the heat-protective layers 5 made of magnesite, pyrotechnic functional charges 6 are fixed, between the open ends of which a slotted combustion chamber 7 is formed, coaxial to the disk nozzle 4.

The combustion chamber 7 is filled with a burning safety pad 8 made of foam rubber with a diameter comparable with the diameter of the charges 6 of the functional block.

On the diametrically located fixing bolts 2, the posts 9 of the bracket 10 are fixed, combined with the handle 11, the bend of which is placed in the plane of the center of mass of the device.

In the threaded hole 12 of the bracket 10, the canister 13 of the initiation unit is screwed to the stop, which is located in the groove 14 of the flanges 3 and in the landing channel 15, made in the interlayers 5, adjacent to the pyrotechnic charges 6.

In a removable pencil case 13 of the initiation unit (Fig. 1), a spring-loaded tip 17, coaxial to the igniter capsule 18, placed on the slow powder charge 19, which through the amplification charge 20 communicates with the nozzle 21 at the end of the canister 13, is sequentially installed.

The cap 17 by means of a check 22, equipped with a pull-out ring 23, is geometrically closed in the pencil case 13, forming a stage of protection.

The burning time of the retarding charge 19 is selected from the condition of guaranteed sufficiency for aiming, swinging and throwing the device into the ignition zone.

Duza 21 is located coaxially with the slotted combustion chamber 7.

Functioning throwing fire extinguishing device as follows.

For the intended use, the brackets 10 are screwed into the threaded hole 12 completely until the stop case 13 initiation node.

Holding the device with one hand on the handle 11 of the bracket 10, with the second free hand, unscrewing the pin 22, for the ring 23, the pin 22 is removed from the pencil case 13, freeing the napolnik 17 from geometric engagement - the initiation unit is ready for operation.

Before throwing a sharp blow with the palm of your free hand, squeezing the spring 16, move the headpiece 17 until it interacts with the igniter capsule 18. The force of the flame, which is formed when the ignition capsule 18 is triggered, ignites the burning charge 19 slowly (4-5 s).

At the same time, the operator, with a swing, accurately throws the device into the ignition zone.

The heat energy from the charge 19 ignites the amplification charge 20, which during combustion forms a force of fire, which is transmitted through the nozzle 21 to the gap between the pyrotechnic charges 6, where it burns the safety pad 8 and ignites the charges 6 from the open ends.

When burning pyrotechnic charges 6, a gas-aerosol formation is generated, including combustion inhibitors, both in the form of gaseous products and in the form of a high-energy condensed phase.

The gas-aerosol extinguishing mixture almost instantly fills the combustion chamber 7, where the pressure increases, while the extinguishing mixture with an expanding high-speed stream through the disk nozzle 4 is distributed in all directions of the volume of the protected room, affecting the combustion process.

The combustion inhibitors contained in the extinguishing mixture interrupt the chain reaction of oxidation, as a result of which combustion ceases.

In closed volumes of instrument compartments, control cabinets, control cabins, etc. the fire is suppressed, and in relatively large rooms (railroad cars, workshops, transport cabins, salons, etc.), after suppressing the source of ignition, an additional hydrant is subsequently spilled.

Full-scale tests of prototypes of the proposed design of a throwing fire extinguishing device have confirmed the bearing strength of a layer of magnesite, which prevents the destruction of functional charges from impacts when an obstacle is thrown into the ignition site.

The initiating mechanism of the shock action of the igniter provides efficiency and ease of use in extreme conditions, forming a fire pulse at the output in a given narrow time range.

The assembly of the device with a removable canister of the initiation unit, which can be installed immediately before use for its intended purpose, ensures complete safety of the extinguishing mixture generator itself during separate storage.

The proposed design is suitable for serial production in existing production for delivery to customers.

Claims (1)

A throwing fire extinguishing device that includes two pyrotechnic charges installed through thermoprotective interlayers in dish-shaped housing containers connected to the gap between their flanges, forming an output disk nozzle coaxial to the slotted combustion chamber where the safety pad is placed, and an initiation unit mounted in the canister containing igniter, pyrotechnic moderator, amplification charge and nozzle directed into the nozzle, while the case is fixed in a bracket with a handle, of different height the racks of which are mounted on the bolts of the flanges, characterized in that the initiation unit's case is screwed into the threaded hole of the bracket until it stops in pyrotechnic charges, adjacent to the safety strip, through symmetrical grooves in the flanges of the housing containers and the landing channel in the heat-protective layer made of magnesite, this rack brackets are fixed by the diameter of the containers in such a way that the bend of the handle is placed in the plane of the center of mass of the device, and the igniter of the initiation unit is made in the form of lennogo on a spring-loaded check nakolnika coaxial primer.

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