RU2372953C1 - Charging method of dry powder fire-extinguishing means - Google Patents

Abstract

FIELD: fire safety.

SUBSTANCE: invention relates to firefighting sphere, notably, to the dry powder fire extinguishing means used to extinguish fires of solid and liquid combustible materials, facilities and premises of various purposes. The proposed invention can be applied to any dry powder fire extinguishing means, for example portable fire extinguisher, modules, etc. The specified technical result is achieved by the method of powder fire extinguishing means charging, including the operation of layer-extinguishing powder filling and compaction of each layer and the subsequent sealing of the container, characterised that the layer filling of fire extinguishing powder produced by powders of different bulk density, alternating a layer of lower density powder with layer higher bulk density powder, and begin filling with higher bulk density powder.

EFFECT: application of dry powder fire extinguishing means (eg, modules), charged by the proposed method allows to raise efficiency of fire-fighting in various premises, especially of larger area and height, by increasing the distance of fire extinguishing powder, maintaining its high extinguishing ability.

6 cl, 2 tbl

Description

The invention relates to the field of fire extinguishing, and in particular to powder fire extinguishing agents used to extinguish fires of solid and liquid combustible materials, objects and premises for various purposes. The present invention can be applied to any means of powder fire extinguishing both to manual fire extinguishers and to modules of powder fire extinguishing (MPP).

Currently, various means of powder fire extinguishing (hand-held fire extinguishers, MPP) are widespread. For example, it is known: a powder fire extinguisher (US Pat. RF No. 2082472, class A62C 35 \ 10, publ. 1997), a device for powder fire extinguishing (US Pat. RF No. 2085235, class A62C 35 \ 22, publ. 1997) , automatic powder fire extinguisher (US Pat. RF No. 2147902, class A62C 35 \ 22, publ. 1999).

From the descriptions of these inventions, it follows that the charging of these devices is carried out in the traditional way, namely by simply filling the extinguishing powder into the body of the device. In this case, in each case, powders with different properties can be used, but within the same device, one type of powder is used.

The reasons that impede the use of the traditional charging method include the fact that the use of one type of powder during charging allows one problem to be solved, for example, increasing the fire extinguishing ability (when using a powder with a low bulk density) or increasing the range of the powder supply (when using a powder with a higher bulk density).

A known method of charging a self-extinguishing fire extinguisher (RF patent No. 2056878, class A62C 2 \ 00, publ. 1996), which is carried out by layer-by-layer falling asleep fire extinguishing powder and a gas-forming agent, and the gas-forming agent is placed between the layers of the fire extinguishing powder, an additional separate seal of each layer and subsequent sealing of the vessel. This device is autonomous and works directly from the fire without human intervention when a glass vessel ruptures after heating to a certain temperature.

The reasons that impede the achievement of the required technical result when using the known charging method include the inability to use the device charged in this way in the manual start-up option, and therefore, to provide directional supply of the extinguishing powder, and the limited height of the device to 2 meters.

In this regard, the urgent task is to develop a method of charging powder fire extinguishing agents, which would be universal, and applicable to various types of powder fire extinguishing agents, ensuring the supply of fire extinguishing powder to a distance of more than 2 m. The invention is directed to solving this problem.

In terms of the set of essential features and the technical result achieved, the closest to the proposed method is the method of charging a self-extinguishing fire extinguisher (RF patent No. 2056878, class A62C 2 \ 00, publ. 1996), which is selected as a prototype.

The technical result when using powder fire extinguishing agents (for example, modules) charged by the proposed method is to increase the efficiency of fire extinguishing in various rooms, especially a large area and height, by increasing the range of the supply of fire extinguishing powder while maintaining its high fire extinguishing ability. In addition, charging the proposed method, for example, a manual fire extinguisher, allows you to ensure the safety of a person who extinguishes a fire by increasing the distance between the fire and a fire extinguishing agent.

The specified technical result is achieved in that the method of charging powder fire extinguishing means, including operations for layer-by-layer filling of fire-extinguishing powder, compaction of each layer and subsequent sealing of the vessel, characterized in that the layer-by-layer filling of fire-extinguishing powder is produced by powders of different bulk density, alternating a layer of powder of lower density with a layer powder of greater bulk density, and begin to fill with powder of higher bulk density.

For best results, as the higher bulk density of the powder using a powder with a bulk density of 1000 kg / m ^3, and as a powder with a lower bulk density of a powder with a bulk density less than 1000 kg / m ^3.

In order to obtain the best set of fire extinguishing efficiency indicators at a maximum distance from the fire extinguishing medium to the fire source, the difference in density between even and odd layers of powder is at least 200 kg / m ³ , the amount of extinguishing powder with a higher bulk density is not more than 40% of the total weight of the powder powder, and the mass of the powder with a higher bulk density in the individual layers are equal.

In order to achieve the required technical result, fire extinguishing powders should be used, having different indicators of bulk density, observing a certain filling sequence, and adhere to the percentage ratio between the masses of powders of different densities both in the total mass and in the mass ratios between the powder layers.

When conducting experimental studies, it was noted that when the fire extinguishing powder is ejected, particles of different sizes and correspondingly different masses (densities) acquire different kinetic energy values. Accordingly, these indicators will determine the range of supply of the extinguishing powder. On the other hand, a finer powder due to a larger specific surface area, compared with a large one, has the best fire extinguishing performance. When using a powder with a higher bulk density in an amount exceeding 40% of the total mass of the powder being poured, the fire extinguishing ability of fire extinguishing agents is reduced by reducing the proportion of powder with a lower bulk density. The combination of these two factors in a certain way allows you to get the optimal values for the feed range and fire extinguishing efficiency, which was proved when using pulsed powder fire extinguishing modules, for example, the Buran type.

When the difference in density between the even and odd powder layers is less than 200 kg / m ³ , the powder layers are mixed during storage, transportation, etc., which negatively affects the technical result.

The proposed method of charging fire extinguishing means is illustrated by specific examples.

The implementation of the proposed method in relation to a manual fire extinguisher is shown in the following example.

A fire extinguisher powder of the Vekson AVS 25 brand, the specific bulk density of which is 1400 kg / m ³ , in the amount of 0.6 kg, was poured into a 3-liter injection-type hand-held fire extinguisher. Then the fire extinguishing powder of the ISTO 1 brand was poured, the specific bulk density of which is 990 kg / m ³ . The amount of powder was 1.8 kg. The last to fall asleep powder brand Vexon ABC 25, the specific bulk density of which is 1400 kg / m ³ in the amount of 0.6 kg. After backfilling, each powder layer was compacted for 60-90 seconds. The total number of layers 3. The total amount of powder was 3 kg.

Examples of the proposed method, similar to that described above, in relation to manual fire extinguishers and the results of their tests are presented in table 1.

The implementation of the proposed method in relation to the module of powder fire extinguishing is given in the following example.

An extinguishing powder of the Vekson AVS 25 brand, the specific bulk density of which is 1400 kg / m ³ , in the amount of 0.6 kg, was poured into the 8-liter Buran-8SV powder fire extinguishing module. Then the fire extinguishing powder of the ISTO 1 brand was poured, the specific bulk density of which is 990 kg / m ³ . The amount of powder was 1.8 kg. The last to fall asleep powder brand Vexon ABC 25, the bulk density of which is 1400 kg / m ³ in the amount of 0.6 kg. After backfilling, each powder layer was compacted for 60-90 seconds. The total number of layers 3. The total amount of powder was 7 kg. Examples of the proposed method, similar to that described above, in relation to the modules of powder fire extinguishing, and the results of their tests are presented in table 2.

Tests of fire extinguishing agents charged by the proposed method were carried out in accordance with the requirements of NPB 170-98 “General-purpose fire extinguishing powders. General technical requirements. Test Methods. " According to the requirements of the NPB, foci of gasoline of a certain rank were extinguished. When testing fire extinguishers, the rank of the fire extinguisher was designated from 34 V to 70 V. The larger the digital designation, the larger the burning area, while the distance from which the fire was extinguished varied from 2.0 to 4.0 meters.

Tests of powder fire extinguishing modules were carried out according to the method of fire tests when extinguishing foci of maximum area, described in NPB 67-98 “Modules of powder fire extinguishing. General technical requirements. Test Methods. "

In the tests, fire extinguishing powders commercially available from industry were used. For example: Vekson AVS 25 brands, manufacturer of Ecohimmash CJSC in Bui, Kostroma Region, ISTO-1 brand, manufacturer of Source Plus CJSC in Biysk, Altai Territory.

It is also possible to obtain extinguishing powders of a certain bulk density by manually dispersing a commercially available powder. For example, a fire extinguishing powder of the Vexon ABC 25 brand was dispersed, and then fractions with the necessary density were selected according to the claimed parameters.

The results of the fire tests were identical to the results when working with commercially available powders. During the tests, the influence of the number of powder layers on the operating parameters was additionally determined. The number of layers was 2, 3, 4, 5. A further increase in the number of layers is impractical, since it does not increase the technical result. In addition, an increase in the number of layers is associated with a general increase in the time for refueling, which reduces the overall productivity of manufacturing products.

As can be seen from table 1, the indicators for fire extinguishing ability and delivery distance, according to the proposed application, are the best (delivery range of 4 meters, center of rank 70 V, examples 1, 2, 3, 4), compared with each powder separately. For example, when extinguishing with Vexon ABC 25 brand powder (Example 11), the powder delivery range is 4 meters and fire extinguishing ability is 55 V. When working with Isto 1 brand powder (Example 12), the range is 2.5 meters with a fire extinguishing efficiency of 70 V.

The results of comparative tests of powder fire extinguishing modules charged by the proposed method and charged in the traditional way are presented in table 2. The tests showed that the best results in terms of such parameters as the extinguishing area and the height of the powder supply were obtained using modules charged in accordance with the claims.

So are the modules, the charging method of which included the distribution of the layers in such a way that at first the powder layer with a bulk density of 1200 kg / m ³ fell asleep, followed by a powder layer with a bulk density of 900 kg / m ³ , and the amount of powder with a bulk density of 1200 kg / m ³ amounted to no more than 40% of the total mass of the powder to be poured, showed the best test results (quenching of a source of rank 233 V from a height of 4.0 meters, examples 1, 2, 3, 4). While tests of the modules charged according to the prototype (examples 11, 12) showed that the best indicators of fire extinguishing ability when extinguishing a hearth of rank 233 V were achieved only from a height of 2.0 meters, and from a height of 4.0 meters a fire was extinguished only rank 89 V, which confirms the accuracy of the claims.

Thus, the present invention is aimed at solving the problem and meets all the criteria of patentability under current law.

Table number 1 The results of comparative tests of hand-held fire extinguishers charged by the proposed and traditional method No examples one 2 3 four 5 6 7 8 9 10 eleven* 12* The density of the powder in the odd layer, kg / m ³ 1400 1100 1200 1200 900 1300 1200 1400 1100 1200 1400 990 The density of the powder in an even layer, kg / m ³ 990 800 900 900 700 1100 900 900 990 900 Difference of indicators 410 300 300 300 200 200 300 500 110 300 - - powder densities Amount of powder with 40 thirty 35 35 40 40 fifty 40 40 35 - - density of more than 1000 kg / m ³ ,% Weight ratio 1: 1 - 1: 1 1: 1: 1 1: 1 1: 1 1: 1 1: 1,5 1: 1 1.5: 1 - - powders with a density of more than 1000 kg / m ³ in layers Total number of layers 3 2 four 5 3 four 3 four 3 four one one Extinguishing area, m ² 70 V 70 V 70 V 70 V 70 V 55 V 34 V 55 V 55 V 55 V 21 V 34 V Powder delivery range, m 4.0 4.0 4.0 4.0 2.5 3.0 4.0 3.0 4.0 3.0 2.0 2.0 * - fire extinguishers charged in the traditional way

Table number 2 The results of comparative tests of powder fire extinguishing modules of the type "Buran-8 SV", charged by the proposed method and the method of the prototype. No examples one 2 3 four 5 6 7 8 9 10 eleven* 12* The density of the compacted powder in the odd layer, kg / m ³ 1400 1400 1100 1300 900 1300 1200 1100 1200 1200 1400 990 Density of compacted 990 800 900 950 700 1100 900 990 900 900 ----- ----- powder in an even layer, kg / m ³ Powder Density Difference 410 500 200 350 200 200 300 110 300 300 Amount of powder with 40 thirty 35 40 40 40 fifty 40 40 35 one hundred one hundred density of more than 1000 kg / m ³ ,% Weight ratio 1: 1 - 1: 1 1: 1: 1 1: 1 1: 1 1: 1 1: 1 1: 1.5 1.5: 1 ----- ----- powders with a density of more than 1000 kg / m ³ in layers Total number of layers 3 2 four 5 3 four 3 four four four one one Extinguishing area, m ² 233 V 233 V 233 V 233 V 233 V 233 V 89 V 144 V 144 V 144 V 89 V 233 V Powder feed height, m 4.0 4.0 4.0 4.0 2.5 2.5 4.0 4.0 3.0 2.5 4.0 2.0 * - modules charged by the prototype method

Claims (6)

1. The method of charging powder fire extinguishing means, including the operations of layer-by-layer filling of fire-extinguishing powder, compaction of each layer and subsequent sealing of the vessel, characterized in that the layer-by-layer filling of fire-extinguishing powder is produced by powders of different bulk density, alternating a layer of powder of lower density with a layer of powder of higher bulk density, and begin to backfill with a powder of higher bulk density. 2. The method according to claim 1, characterized in that the powder with a bulk density of more than 1000 kg / m ^{3 is} used as a powder of higher bulk density. 3. The method according to claim 1, characterized in that a powder with a bulk density of less than 1000 kg / m ^{3 is} used as a powder with a lower bulk density. 4. The method according to claim 1, characterized in that the difference in density between the even and odd layers of powders is at least 200 kg / m ³ . 5. The method according to claim 1, characterized in that the amount of extinguishing powder with a higher bulk density is not more than 40% of the total weight of the powder to be poured. 6. The method according to claim 1, characterized in that the mass of the powder with a higher bulk density in the individual layers are equal.