RU89964U1 - VOLUME AEROSOL FIRE EXTINGUISHING DEVICE - Google Patents

Abstract

1. A device for volumetric aerosol fire extinguishing, comprising a coaxial ignition unit and a pyrotechnic block mounted through a heat-insulating interlayer in a perforated housing combined with a receiver communicating with a reversible annular channel closed by a lid having exit openings and which is separated from the casing by a heat-insulating interlayer characterized in that the checker, packed in a polymeric film case, rests on a transverse rod mounted above a receiver equipped with a reflective tray, housing, wherein forming the strap fastened to a diameter of checkers and installed inside the casing bolts mounting plate carrying the power supply terminals of the ignition assembly. ! 2. The device according to claim 1, characterized in that the transverse rod is installed in diametrically located perforations of the housing under the free end of the pyrotechnic checker, blocking the reversible annular channel.

Description

The proposed utility model 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. The generator is intended for use in both autonomous and automatic fire extinguishing systems for stationary installation, and can be used to extinguish a fire manually.

The level of this technical field is characterized by the device for volumetric fire extinguishing described in patent RU 2096055, А62С 13/22, 1997, containing a unit for initiating (igniting) the pyrotechnic composition of the checker, which is installed with a gap in a metal case, equipped with communication holes for communication with a reversible annular channel casing, closed with a cover with outlet openings, slotted heat exchanger and receiver.

Changing the direction of the flow of gaseous products of combustion of the pyrotechnic checker in the reverse ring channel to the opposite ensures their additional cooling, and the main heat is removed in a spiral slit heat exchanger from a material with a melting point above the temperature of the products of combustion.

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

The disadvantages of this device include the following.

The low productivity of generating a quenching gas-aerosol mixture due to the relatively small mass of the functional checker, since the longitudinal structural layout of the structural elements determines the length of the device and, therefore, unsatisfactory mechanical strength.

At the same time, it is irrational to equip the generator with a small ratio of the mass of the pyrotechnic checker to the mass of the generator as a whole, that is, a low filling and efficiency ratio.

Insufficient cooling of the products of combustion of the pyrotechnic checker due to the fact that the accumulated heat is transferred to the casing by means of heat transfer from the spiral heat exchanger, and then it is radiated into the gas-aerosol stream of the annular reversal channel, again heating its products of the quenching mixture.

The use of the described device is limited only to stationary due to the high temperature of the outer casing, heated by direct interaction with the hot products of the current stream, and there may be cases of burns through which the quenching mixture flows radially.

More perfect is a device for volumetric fire extinguishing according to patent RU 2164808, А62С 13/22, 2001, which is selected by technical essence and the number of matching features as the closest analogue to the proposed one.

The known device contains a node for initiating (igniting) a pyrotechnic checker mounted with a gap in a metal case, equipped with communication openings for communication with a reversible annular channel of the casing, closed with a cover with outlet openings, a heat exchanger and a receiver.

The heat exchanger is made in the form of an external perforated shell relative to the housing, reinforced coaxially to the checker in the casing through a layer of building gypsum, which also fills the gap between the checker and the housing combined with the receiver.

Communication holes are made on the side of the receiver.

The device is characterized by increased productivity of generating combustion inhibitors and high cooling efficiency of the extinguishing mixture products inside the device, therefore it is intended for manual use.

However, the disadvantage of the described device is that the issue of installing the generator in a secure room is not structurally resolved, which requires additional hardware, increasing the consumer cost of technological work on fire protection of various rooms.

In addition, the scope of use of the generator in the conditions of vibration and transport shaking is limited due to insufficient adhesion of the pyrotechnic checker to the heat-insulating layer of the receiver shell to prevent shifting of the mechanically not fixed checker into the receiver.

This extinguishing aerosol generator is explosion-proof when used in rooms with technological suspensions and volatile substances that penetrate inside, where they are concentrated. When the ignition unit is triggered for this reason, an explosion and destruction of a device that does not perform fire protection functions, but, moreover, is a serious additional source of ignition with fragmentation damage, can occur.

The problem the real utility model is aimed at eliminating the noted drawbacks to create a more functionally reliable, universal and safe generator in operation.

The required technical result is achieved by the fact that in the known device for volumetric aerosol fire extinguishing, comprising a coaxial ignition unit and a pyrotechnic composition block installed through a heat-protective layer in a perforated housing combined with a receiver communicating with a reversible annular channel closed by a lid having exit openings, and which is separated from the casing by a heat-protective layer, at the suggestion of the authors, the checker, packed in a plastic film case, rests on a transverse rod b mounted above a receiver equipped with a reflecting tray in a case where laths are mounted along the generatrix for the diameter of the checker, and inside the case there are bolts for the mounting bracket carrying the power supply terminals of the ignition unit, while the transverse rod is installed in diametrically located perforations of the case under the free end pyrotechnic checkers, blocking the reversible annular channel.

Distinctive features have ensured the versatility in using the design of safe in the operation of the extinguishing mixture generator, mobile in installation and functionally reliable, more technological in manufacture.

Packing the pieces of the pyrotechnic composition in a polymer film cover ensures its tight isolation from atmospheric moisture, without changing the design and structural relationship with the adjacent elements of the device, since the cover film is placed in technological gaps and does not affect the functional interaction.

The support of the checker on a transverse rod, rigidly mounted in the housing above the receiver, is aimed at the invariance of the spatial position of the checker in the generator, determined by the specified thermodynamic regime of the expiration of the generated gas-aerosol mixture during its combustion.

The installation of longitudinal strips of measured thickness along the generatrix of the cylindrical body constructively limits the free volume for the diameter of the pyrotechnic checker installed inside, which simplifies the assembly of the functional unit with a fixed annular gap into which the gypsum mortar is poured, forming a symmetrical heat-insulating layer.

The longitudinal bars additionally serve as reinforcing fittings, significantly increasing the structural rigidity of the functional block and the performance of the generator as a whole.

Equipping the receiver with a reflecting tray provides a reversal of the main volume of the generated extinguishing mixture, directing it into the reversible annular channel to the outlet, while additionally acting as a convective heat exchanger for evaporating water from the bottom layer of gypsum.

Fastening from the inside of the casing, in the supporting layer of building gypsum, of two power bolts allows you to freely and simply install a variety of mounting fittings on the generator, in particular, a bracket for hanging it on surfaces of different profiles in the protected room.

The supporting bracket, as a structural element of the generator, is used to place the power supply terminals of the ignition unit on it, which allows the generator to be adapted to the existing fire alarm system, for communication with temperature or smoke control sensors of the protected volume.

The transverse placement of the support rod in diametrically located perforations of the body under the free end of the pyrotechnic checker is a structurally simple, technologically convenient means for fixing the spatial position of the interconnected structural elements of the generator. The rod is made with the diameter of the distributed holes of the perforated body and a length exceeding the size of the body, which determines the freedom of choice of any diametrical pair of holes for its transverse placement under the checker, fixing the set receiver height.

The longitudinal movement of the rod is limited by the width of the reversing channel so that even when one end stops in the shell of the heat exchanger, the opposite end of the rod remains outside the housing dimension, which eliminates the use of additional clamps and limiters.

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 stated technical problem 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 utility model does not explicitly follow for a specialist in fire fighting equipment, showed that it is not known, and taking into account the possibility of industrial serial production of fire extinguishing aerosol generators, it can be concluded that the criteria are met patentability.

The essence of the utility model is illustrated by the drawing, which has a purely illustrative purpose and does not limit the scope of the claims of the formula. The drawing shows:

figure 1 - the proposed generator, a vertical section;

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

The proposed device for volumetric aerosol fire extinguishing contains a checker 1 of a pyrotechnic composition, during combustion of which a quenching gas-aerosol mixture of combustion inhibitors is formed, including gaseous compounds and highly dispersed condensed particles.

Pre-packaged in a polymer film cover 2, the checker 1 through a layer 3 of gypsum is fixed in a perforated cylindrical body 4, which is combined with the receiver 5.

Technological longitudinal strips 6 are fixed on the inside of the housing 4, the thickness of which forms a gap under the interlayer 3 in diameter coaxially mounted inside the checker 1.

In the perforations of the housing 4 closest to the free end of the fixed checker 1, the support rod 7 is transversely mounted to fix the checker 1 and form a receiver 5 of a given volume.

The receiver 5 is mounted on a reflective perforated tray 8, which is rigidly connected with a cylindrical perforated shell 9 located coaxially to the housing 4 with a gap forming an annular reversal channel 10.

In turn, the shell 9 is fixed through a layer 11 of gypsum in the outer casing 12.

The shell 9 with the housing 4, adjacent respectively to the heat-insulating gypsum layers 11 and 3, form a heat exchanger for the flow of the generated extinguishing mixture.

From the inside of the casing 12 two bolts 13 are diametrically installed, fixed in the layer 11 when pouring a mortar of gypsum.

An arm 14 is mounted on the bolts 13 for mounting the generator on bearing surfaces in a protected volume.

Coaxially to the checker 1 in the bottom sleeve 15, an ignition unit 16 is installed, electrically connected to the terminals 17 (Fig. 2) mounted on the bracket 14.

A cover 18 is mounted on the casing 12 with the outlet openings 19 distributed over the annular channel 10.

Thus, the proposed device is autonomous and self-sufficient for automatic functioning by a signal from the sensitive elements of a standard fire alarm system.

A device for volumetric aerosol fire extinguishing as follows.

When the sensor triggers an excess of temperature or smoke in a protected room, the signal is fed to terminals 17, as a result of which the ignition unit 16 is initiated.

By the force of the flame from the triggered unit 16, the free end of the pyrotechnic block 1 is ignited, during combustion of which a gas-aerosol quenching mixture is generated, which enters the receiver 5, where it accumulates, mixes, equalizing pressure and temperature.

Through the perforations of the receiver 5, the quenching mixture enters the annular channel 10 and is reversed, that is, it is deployed towards the outlet openings 19 of the lid 18.

In this case, the metal housing 4 and the shell 9 are heated by hot gas-aerosol products, taking away their thermal energy.

Convective heat of the housing 4 and the shell 9 evaporates structurally bound water from the interlayers 3 and 11, which through their distributed perforations with transverse jets in the form of steam enters from both sides into the annular channel 10, where it is actively mixed with the quenching mixture.

This water, as an additional environmentally friendly combustion inhibitor, dilutes the working gas-aerosol mixture, lowering the temperature.

Under the lid 18, the extinguishing mixture, expanding, is inhibited and is discharged by autonomous jets into the protected volume, filling it.

At the output of the device, high-speed jets of the extinguishing mixture inject air into the room, with which there is active mixing and additional cooling.

When the specified concentration of combustion inhibitors is reached in the protected volume, the ignition site is suppressed.

The obtained test results of the prototypes of the described generators for the dynamics and efficiency of fire extinguishing allow us to recommend them for serial delivery to customers.

Claims (2)

1. A device for volumetric aerosol fire extinguishing, comprising a coaxial ignition unit and a pyrotechnic block mounted through a heat-insulating interlayer in a perforated housing combined with a receiver communicating with a reversible annular channel closed by a lid having exit openings and which is separated from the casing by a heat-insulating interlayer characterized in that the checker, packed in a polymeric film case, rests on a transverse rod mounted above a receiver equipped with a reflective tray, housing, wherein forming the strap fastened to a diameter of checkers and installed inside the casing bolts mounting plate carrying the power supply terminals of the ignition assembly. 2. The device according to claim 1, characterized in that the transverse rod is installed in diametrically located perforations of the housing under the free end of the pyrotechnic checker, blocking the reversible annular channel.