RU112636U1 - FIRE EXTINGUISHING AEROSOL GENERATOR - Google Patents

Abstract

1. A fire-extinguishing aerosol generator, including a cylindrical casing and a housing with a cover and a bottom, coaxially fixed to each other with an annular gap for ejected air, a mixing chamber formed by the side walls of the casing, as well as an activator and a pyrotechnic charge installed inside the housing with the possibility of forming an ejection chamber aerosol, and a layer made inside the body of a material that cools the aerosol, the generator is made to allow the release of aerosol into the protected volume, characterized in that the cylindrical casing and the body are coaxially connected to each other, the generator is additionally equipped with a baffle installed parallel to the bottom, secured with partial overlapping the side surface of the housing and with the formation around the housing of an annular nozzle for the release of the ejecting aerosol, the layer of the aerosol cooler is placed in series with respect to the pyrotechnic charge with the formation between them, as well as between the side surfaces charge and body of additional free volume with the function of the combustion chamber, the ejection aerosol chamber is formed between the bottom of the body and the baffle, and the bottom is made perforated. ! 2. The generator according to claim 1, characterized in that the ratio between the cross-sectional area of the annular channel for the release of the ejecting aerosol and the initial area of the pyrotechnic charge is determined in the range of 0.014-0.025. ! 3. The generator according to claim 1, characterized in that the ratio of the mass of the cooler to the mass of the charge is determined in the range of 0.5-0.7. ! 4. The generator according to claim 1, characterized in that a layer on about

Description

The utility model relates to the field of fire extinguishing, namely, devices that generate gas-aerosol combustion inhibitors designed to extinguish fires in closed and semi-enclosed volumes, such as industrial and storage facilities, cable tunnels, vehicle compartments and other similar objects.

A number of devices are known from the prior art in this field — fire extinguishing aerosol generators (GOA), in which the combustion products of the aerosol forming composition are cooled as they pass through a narrow channel made of heat-absorbing material: RF patents No. 89963 (extinguishing aerosol generator class A62C 3 / 10, publ. 2009); No. 89964 (Device for volume aerosol fire extinguishing, class A62C 13/22, publ. 2009)

In these generators, due to the good thermal insulation of the case, it is possible to ensure a relatively low temperature of its outer surface. At the same time, when the aerosol mixture flows through the reverse channel due to heat exchange with a gypsum heat-protective layer, it is possible to lower the temperature of the aerosol mixture to an acceptable level.

At the same time, along with the thermal insulation of the case, the water contained in the gypsum (CaSO4 · 2H2O) evaporates during heating and, mixed with the aerosol, cools it. However, it is known that aerosol particles are in the main mass potassium carbonate and bicarbonate, the solution of which has an alkaline reaction. The ingress of such a solution onto the protected equipment causes its corrosion. It should be noted that during the formation of the gypsum heat-protective layer, part of the water is not in the form of crystalline hydrate, but in the free state and during evaporation it creates humidity close to 100% inside the generator volume, which negatively affects the operational characteristics of the aerosol-forming charge and the generator as a whole. So, in particular, to reduce the effect of moisture, the authors of these patents propose the use of polyethylene covers (RF patent No. 89964), which complicates the design, and when burning a polyethylene cover, the toxicity of combustion products increases.

The disadvantages of this design also include the fact that this generator circuit can be implemented at very low intensities of the supply of the aerosol mixture. In a known design, this is achieved by organizing the process of burning checkers not over the entire surface, but only along its end.

The low flow rate of the aerosol mixture significantly narrows the scope of GOA applications and makes it practically impossible to use them in rooms with a high degree of leakage.

The authors of RF patent No. 49455 (“Fire extinguishing aerosol generator class A62C 3/00, publ. 2005), also use a reversible scheme of the expiration of the aerosol mixture, but the combustion of the aerosol forming charge is organized over the entire surface, which allows to achieve high aerosol delivery rates mixtures. A certain decrease in the temperature of the aerosol mixture is achieved due to its interaction with cooling elements located in the chipper.

The disadvantages of this design include the high temperature of the aerosol mixture at the outlet of the generator and the relatively high temperature of the housing (cylindrical casing) in contact with the high-temperature aerosol mixture.

For example, the “Device for volumetric aerosol fire extinguishing” according to patent No. 2140310 includes a housing, inside which are coaxially arranged a pyrotechnic charge and an ejection gas chamber (receiver), which are surrounded by a heat-protective layer of gypsum made on the entire inner surface of the housing. The housing is closed by a cover with an igniter (activator). Outlets are made (distributed) in the lid. Coaxial to the casing, a cylindrical casing of a larger diameter is fixed than the casing, and partially overlapping the casing with the formation of an annular gap for the ejected air and the mixing chamber with this air (cooling chamber).

Also known GOA containing coaxially and sequentially located body pyrotechnic charge and the mixing chamber of the ejector: RF patents No. 2140310 (CL A62C 13/22, publ. 1999), No. 2205673 (CL A62C 13/22, publ. 2010 .). These generators include a housing, inside of which a pyrotechnic charge and an ejection gas chamber (receiver) are coaxially located, which are surrounded by a heat-protective layer of gypsum made on the entire inner surface of the housing. The housing is closed by a cover with an igniter (activator). Outlets are distributed on the lid. A cylindrical body of a larger diameter is fixed coaxially to the body than the body, and partially overlapping the body to form an annular gap for the ejected air and a mixing chamber with this air (cooling chamber).

The disadvantages of this design include a rather long mixing zone of the ejected and ejected flows, which, on the one hand, is associated with the sequential location of the ejection nozzle and generator with an aerosol-forming composition, and on the other, with a sufficiently large mixing scale, due to the size of the high-temperature ejection jet. In the generator under consideration, the combustion of the aerosol-forming charge is organized along the end surface, which ensures an aerosol supply rate of no higher than 0.5 g / s · m ³ , building gypsum is used for thermal insulation of the body, which contains a significant amount of water, which, as the authors themselves note, contributes to cooling combustion products. But at the same time, as noted above, the warranty periods of storage are noticeably reduced. To avoid this, special measures are required to seal the aerosol forming charge.

The closest technical solution for the combination of essential features and the technical result achieved by the claimed device is the "Device for volume aerosol fire extinguishing" according to the patent of the Russian Federation No. 2140310, which is selected as a prototype.

The task to which the proposed device is aimed is to develop a fire extinguishing aerosol generator, with an optimal combination of indicators of fire extinguishing efficiency, temperature of the gas-aerosol jet and the intensity of the flow of extinguishing aerosol into the protected volume with a low degree of tightness.

The proposed generator of extinguishing aerosol when used ensures the achievement of the following technical result:

- a decrease in the proportion of chemical cooler in relation to the mass of the aerosol-forming charge;

- lowering the temperature of the aerosol mixture at the output of the generator due to a constructive reduction in the mixing scale of the ejection jet (coaxial construction and the presence of a chipper) with a simultaneous increase in the ejection coefficient;

- increasing the intensity of the supply of the aerosol from a position as "above" and "below" due to the organization of combustion over the entire surface of aerosol forming charges.

The achievement of the specified technical result is ensured by the fact that the fire extinguishing aerosol generator, including a cylindrical casing and a housing provided with a lid and a bottom coaxially fixed to each other with an annular gap for ejected air, a mixing chamber formed by the side walls of the casing, as well as an activator and a pyrotechnic charge installed inside the housing with the possibility of forming the chamber of the ejection aerosol, and a layer made of the material cooling the aerosol made inside the housing, the generator it is made possible to release the aerosol into the protected volume, characterized in that the cylindrical casing and the casing are connected coaxially, the generator is additionally equipped with a chipper fixed to partially overlap the side surface of the casing and with the formation of an annular nozzle for the release of aerosol, the aerosol cooler layer is placed in series in relation to the pyrotechnic charge with the formation between them, as well as between the side surfaces of the charge and the housing of an additional free volume With the function of a combustion chamber, the chamber of the ejection aerosol is formed by a perforated bottom of the body and a chipper, and the bottom is perforated.

It is preferable to carry out the generator with the ratio between the cross-sectional area of the annular channel for aerosol release and the initial area of the pyrotechnic charge in the range of 0.014-0.025, this allows to achieve the maximum increase in the aerosol supply intensity from the position not only from above, but also from below.

The generator, made with the ratio of the mass of the cooler to the mass of the charge is determined in the range of 0.5-0.7, which makes it possible to significantly reduce the proportion of chemical cooler in relation to the mass of the charge and at the same time reduce the temperature of the walls of the housing.

In the generator, a layer based on alkali and alkaline earth metal carbonates can be used as a cooler layer.

To further reduce the temperature of the walls of the generator, the inner surfaces of the housing, the lid and the chipper can be provided with thermal insulation, and it is preferable to use materials with organosilicon impregnation as thermal insulation.

The reliability of the generator can be additionally ensured by the fact that the pyrotechnic charge and the cooler layer are fixed in the housing using compensation springs and spacers.

Convenience and efficiency of operation can be ensured by the fact that the generator is equipped with a bracket made in the form of a U-shaped bracket, and the chipper is rigidly connected to the casing at least at three points located uniformly around the circumference of the side surface of the casing.

A predetermined direction for the release of the aerosol jet from the generator can be ensured by the fact that the housing is rigidly connected to the casing by means of fasteners at two points located diametrically relative to each other, and is additionally fixed to the bracket so that the generator can rotate relative to the bracket.

In this case, the casing and the bracket is preferable to perform with the possibility of fixing the position of the generator at various angles relative to the bracket.

One design option may be an integral connection of the housing cover, for example rolling.

The essence of the proposed utility model is illustrated by drawings.

Figure 1 schematically shows a General view of the generator in section. In Fig.2 schematically shows the attachment points of the housing, the casing and the bracket, and Fig.3 - mounting the casing, chipper and casing.

The design of the generator is a housing (1) with a cover (2) and a perforated bottom (3). The housing (1) is coaxially attached to the casing (4) with the formation of an annular gap (5) for suction of the ejected air from the protected volume. A mixing chamber (6) is formed between the housing (1) and the casing (4).

The activator (7) is mounted in the cover (2) of the housing (1). A pyrotechnic charge (8) is installed inside the housing (1) and a cooler layer (9) sequentially behind it, and a combustion chamber (10) is formed in the form of free volumes between the side surfaces of the charge (8) and the housing (1), as well as between the end surfaces charge surfaces (8) and a cooler layer (9).

Beyond the bottom (3) of the housing (1), a bump stop (11) is installed with the formation of a chamber of an ejecting aerosol between them (12). The chipper (11), for example, can be made in a plate shape to partially overlap the side surface of the housing (1) and with the possibility of the formation of an annular nozzle (13) to release the ejection aerosol into the mixing chamber (6). On the inner surface of the housing (1), cover (1) and chipper (11), a heat-insulating layer (14) can be made.

The immobility of the charge (8) and the cooler layer (9) installed between the perforated bottom (3) and the same perforated surface (3) is ensured by compression springs (15) and spacers (16).

The generator can be mounted on the bracket (17) (figure 2).

The chipper (11) with the housing (1) and the casing (4) is fastened with bolts (18), for example, at 3 points distributed evenly around the circumference (Fig. 3). The housing (1) and the casing (4) are bolted (19) to the bracket (17) with the possibility of rotation of the generator relative to the bracket (17). The fixture (20) provides a fixation of the position of the generator at the required angle relative to the bracket (17) and, therefore, relative to a possible source of ignition.

The generator (figure 1) contains a housing (1), a cover (2) and a perforated bottom (3). The housing (1) is coaxially attached to the casing (4) with the formation of an annular gap (5). A mixing chamber (6) is formed between the housing (1) and the casing (4).

When an electrical impulse is applied to the electroactivator (7), the aerosol-forming charge ignites (8), the combustion chamber (10) ensures that the combustion products are close to the equilibrium composition. After passing through the cooler layer (9), the combustion products after interacting with the chipper (11) fall into the chamber of the ejection aerosol (12), the specified pressure level in which is ensured by a certain value of the passage area of the annular nozzle (13). Through the annular gap (5), external air is ejected and mixed with an aerosol in the mixing chamber (6), the length of which is selected on the basis of ensuring the optimal ratio between the dimensions of the generator and the temperature in the outlet section of the mixing chamber, i.e. at the exit of the generator.

During the tests, the pressure in the combustion chamber and the temperature along the length of the aerosol jet were measured with the installation of 3 chromel-kopel type thermocouples in each section. The test results are presented in the Table.

Based on the strength characteristics of the generator, the permissible pressure level (P) in the generator is adopted up to 1.5 atm.

The temperature (T ° C) of the jet at the outlet, according to safety standards, should not exceed 280-290 ° C.

Accepted designations in the table:

P is the pressure in the combustion chamber;

F ₁ is the cross-sectional area of the annular nozzle (13) of the ejection aerosol;

F ₂ is the cross-sectional area of the ejected gas;

M zar. - mass of aerosol-forming charge;

M cool - mass of the cooler;

I is the flow rate of the aerosol jet;

T is the temperature of the gas-aerosol jet in the output section of the generator.

Extinction of the source up / down means the exposure of the source of the aerosol jet from the upper position or from the lower position.

Analysis of the test results confirms that when using all the essential features of the formula (examples No. 1-5), the claimed technical result is achieved for all indicators.

Deviation from the declared parameters of the essential features (examples No. 6-10) does not allow to achieve the necessary technical result:

- extinguishing from the “bottom” position is not provided (examples No. 6, 8, 10);

- quenching is provided, but at dangerously high pressure in the housing (example No. 7) or at an unacceptably high temperature of the jet in the output section of the generator (example No. 9).

Testing of the device according to the prototype was carried out in the same conditions as the proposed generator. The test results indicate that the prototype device does not provide fire extinguishing when the aerosol jet is fed from a low position (from the floor) with a leak rate of 0.012.

The above materials confirm that the claimed device meets all the signs of protection under current law and is aimed at solving the problem.

Table Test results Options The results of examples No. prototype one 2 3 four 5 6 7 8 9 10 eleven 12 P, kg / cm ² 0.95 1.15 1.35 0.75 1.05 0.56 1,50 0.65 1.35 0.95 0.2 0.2 F ₁ cm2 fifteen 12 36 25 25 17 36 twenty fifteen 10 10 F ₂ cm2 780 780 1400 1400 1400 780 1400 1400 1400 780 132 132 F ₁ / F ₂ 0.019 0.015 0.014 0,025 0.018 0,032 0.012 0,028 0.014 0.019 0,07 0,07 M zar., Kg 1,5 1,5 3.0 3.0 3.0 1,5 3.0 3.0 3.0 1,5 3.0 3.0 M cooling., Kg 0.9 0.6 1,5 1,5 2.1 0.9 2.1 1,5 1,2 1,2 1.8 1.8 M ohl / Mzar 0.6 0.7 0.5 0.5 0.7 0.6 0.7 0.5 0.4 0.8 0.6 0.6 I, kg / s · m ³ × 10 ³ 2.7 2.9 3.2 2.1 2,8 2.0 3.4 2.2 3.2 2.7 0.5 0.5 T °, C 250 240 270 240 240 230 290 240 320 200 400 400 Leak rate 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.001 Top / bottom quenching + / + + / + + / + + / + + / + +/- + / + +/- + / + +/- +/- + / +

Claims (12)

1. A fire extinguishing aerosol generator, including a cylindrical casing and a housing with a lid and a bottom coaxially fixed to each other with an annular gap for ejected air, a mixing chamber formed by the side walls of the casing, as well as an activator and a pyrotechnic charge installed inside the housing to allow the formation of an ejection chamber aerosol, and the layer made of the material cooling the aerosol made inside the housing, the generator is made with the possibility of releasing the aerosol into the protected volume, distinguishing Due to the fact that the cylindrical casing and the casing are connected coaxially, the generator is additionally equipped with a chipper installed parallel to the bottom, secured to partially overlap the side surface of the casing and to form an annular nozzle around the casing to release the ejecting aerosol, the aerosol cooler layer is placed in series with pyrotechnic charge with the formation between them, as well as between the side surfaces of the charge and the housing of an additional free volume with the function of EASURES combustion, aerosol propellant chamber formed between the bottom of the housing and the baffle and the perforated bottom. 2. The generator according to claim 1, characterized in that the ratio between the cross-sectional area of the annular channel for the release of the ejecting aerosol and the initial area of the pyrotechnic charge is determined by the range of 0.014-0.025. 3. The generator according to claim 1, characterized in that the ratio of the mass of the cooler to the mass of the charge is determined by the range of 0.5-0.7. 4. The generator according to claim 1, characterized in that the layer based on alkali and alkaline earth metal carbonates is used as a cooler layer. 5. The generator according to claim 1, characterized in that the inner surfaces of the housing and the chipper are provided with thermal insulation. 6. The generator according to claim 5, characterized in that as a thermal insulation use materials with organosilicon impregnation. 7. The generator according to claim 1, characterized in that the pyrotechnic charge and the cooler layer are fixed in the housing using compensation springs and spacers. 8. The generator according to claim 1, characterized in that it is equipped with a bracket made in the form of a U-shaped bracket. 9. The generator according to claim 1, characterized in that the chipper is rigidly connected by a casing at least three points evenly spaced around the circumference of the side surface of the casing. 10. The generator according to claim 1, characterized in that the housing is rigidly connected to the casing by means of fasteners at two points diametrically relative to each other, and with additional fastening at the same points with a bracket, with the possibility of rotation of the generator relative to the bracket. 11. The generator according to claim 1 and 10, characterized in that the casing and the bracket are made with the possibility of fixing the position of the generator at various angles relative to the bracket. 12. The generator according to claim 1, characterized in that the cover is connected to the housing inextricably.