CS196104B1 - Extinguishing powder system - Google Patents

Abstract

The invention relates to a powder extinguishing system containing solid particles of synthetic resin, which can be used to extinguish fires of all fire classes, both incandescent and flame fires, e.g. textiles, paper, wood, flammable natural and synthetic resins, as well as other carbonaceous substances, especially flammable products of coal and oil processing in all states of matter, while extinguishing can also be carried out on devices under electrical voltage.

Description

The invention relates to a powder extinguishing system containing solid particles of synthetic resin, which can be used to extinguish fires of all fire classes, both incandescent and flame fires, e.g. textiles, paper, wood, flammable natural and synthetic resins, as well as other carbonaceous substances, especially flammable products of coal and oil processing in all states of matter, while extinguishing can also be carried out on devices under electrical voltage.

In recent years, as is known from the literature, considerable attention has been paid to powder fire extinguishing agents. Inorganic salts of alkali metals, mainly systems based on carbonate and bicarbonate of sodium and potassium, are widely used in the world.

The development of systems has led to various views on the mechanism of action of extinguishing powders. The current opinions, which are widely accepted, can be classified as follows. Initially, the extinguishing effect was attributed to the cooling of the reaction zone in the form of the loss of heat consumed for heating and decomposition of salts together with the influence of inertization phlegmatization by carbon dioxide, or other decomposition products of the aforementioned thermal decomposition.

Recently, most observations assume that similar powders have an inhibitory ability that is associated with the possibility of chain termination either as a result of heterogeneous recombination of active centers on the surface of powder particles or in a gaseous environment during partial evaporation of the powder. Some observations assume connections of heterogeneous inhibition with surface phenomena causing either cooling of the reaction environment on the surface of powder particles or recombination of active centers on the surface of particles, from which two principles are derived. Powders acting on the first principle, so-called thermal, have small specific inhibitory effects, such as magnesium carbonate or aluminum sulfate. Under their action, the extinguishing gas mixture is cooled to a critical temperature below which combustion ceases.

Powders acting on the second principle, the so-called chemical, have a strong inhibitory effect on the flame and practically do not affect the temperature of the reacting mixture. These powders include carbonates, potassium and sodium bicarbonates, potassium and sodium halides, sulfates, alkali metal dichromates and others.

The mechanism of heterogeneous radical recombination appears to be very interesting, and was derived based on the high inhibitory efficiency of homogenides, as a result of their high bond polarity and the possibility of providing a free electron for recombination of the active center. The inhibitory efficiency of halides was determined, which increases from Na to K and from Cl to I.

Opinions on the mechanism of flame inhibition by powders are diverse and often contradictory, and therefore studies in this area should continue to receive increased attention, because the issue of extinguishing with powder systems is still relevant.

The state of development of powder extinguishing systems is visible from the patent literature of industrially developed countries, primarily the USSR and the USA.

USSR Patent No. 245,562 describes the use of burnt clay for extinguishing oil products. USSR Patent No. 448,621 describes the use of a mixture of sodium bicarbonate mixed with disodium carbonate. US Patent No. 3,531,407 describes the use of phthalocyanines. The use of urea in extinguishing systems is the subject of several patents.

Among them, we can mention US patent 3,484,372, which discloses a system based on urea together with sodium bicarbonate, normal carbonate and sodium hydroxide, ammonium sulfate and hydrogen sulfate, optionally potassium, chloride, ammonium bromide, ammonium hydrogen phosphates and potassium oxalate. Furthermore, US patents 3,536,620, 3,607,744 and 3,776,843 disclose the preparation of a fire extinguishing agent of the empirical formula MC2N2H3O3, where M is an alkali metal and the products mentioned are obtained by the reaction of urea with compounds of an alkaline nature such as e.g. hydroxides and carbonates or hydrocarbonates of alkali metals, US patent 3,464,921 describes a composition consisting of calcium lignosulfonate, boric oxide, disodium tetraborate, dry sodium chloride, potassium chloride or barium chloride as well as tricalcium phosphate, sodium bicarbonate and powdered talc. Another US patent 3,544,459 describes a system containing potassium aluminum fluoride and a silicate, which acts as a lubricant in the system.

Among the systems intended for extinguishing metals, we can mention the system described in the USSR Patent No. 544,437, containing calcined sulfur, stearic acid, iron, aluminum and magnesium stearates, graphite and polyethylene. and the US Patent No. 3,475,332, which describes the use of silicon carbide, zirconium boride and graphite. In the USSR Patent No. 485,742, we encounter a flammable gas inhibitor based on cobalt sulfide, potassium stearate and talc.

US patent 3,523,893 describes a system based on ammonium phosphate and boron trioxide. Very interesting is the Czechoslovak patent 146,521, which describes the use of formaldehyde cresol resin in a mixture with asbestos flour, and the USSR patent 258,042 and 379,272, which suggest the use of polyvinyl chloride resin for the purpose of reducing powder shrinkage. Furthermore, US patent 3,673,088 describes the use of cellulose ethers, and the USSR patent 481,290 describes the use of nepheline concentrate for the purpose of improving fluidity. This overview of patents and patent certificates shows the development of powder systems in industrially developed countries over the past ten years.

When objectively evaluating previously known powder fire extinguishers, we mainly encounter the following disadvantages. Systems with fine particles have high caking and flammability.

To reduce this, selection is necessary based on particle shape, crystal structure, etc. Improved protection against caking and improved transportability are achieved by adding hydrophobicizing agents, such as stearic acid salts. One way to overcome the above-mentioned disadvantages is to use resins.

According to the present invention, the extinguishing powder system containing solid particles of synthetic resin and/or a mixture of synthetic resins in a mixture with a carrier medium and other substances, such as inertizing phlegmatizers and/or flame inhibitors, consists of a condensate prepared by condensation of compounds from the group of amines, phenols and/or their derivatives with 1 to 8 carbon atoms, preferably urea, melamine, cresol with carbonyl compounds from the group of aldehydes, ketones

1 to 5 carbon atoms, preferably formaldehyde, acetaldehyde, acetone and lignosulfonic acid and/or lignosulfonate and/or their derivatives, preferably haloderivatives, in an amount of 0.1% by weight to 50% by weight, preferably 2 to 15% by weight.

As compounds with a mobile hydrogen atom with 1 to 8 C atoms, urea, thiourea, melamine, guanidine, dicyandiamide, aminoguanidine, as well as aromatic compounds, for example phenol, cresol and the like, in the case of carbonyl compounds with 1 to 5 carbon atoms, formaldehyde, acetaldehyde, furfural, acetone, ethyl methyl ketone and the like can be used. Lignosulfonates can be used in the form of calcium, ammonium, sodium, magnesium salts or lignosulfonic acids, which ^can be used in the form of a sulfite leachate. Good results have been achieved by using halogenated lignosulfonates, which are obtained by reacting lignosulfonates in an anhydrous environment with thionyl chloride or athionyl bromide, as well as using lignosulfonamides obtained by reacting lignosulfonates with acid halides and amines. The resins obtained after concentration are filtered off and dried according to their nature in the temperature range of 20 to 210 °C. The dry condensate is subjected to grinding and fractional separation by sieving. This is followed by homogenization of the resin with other inorganic and/or organic substances capable of inertization, phlegmatization and/or inhibition,

The measurement showed that the fire extinguishing efficiency, which was determined based on a statistical analysis of the number of successful extinguishing operations based on the amount of extinguishing agent, depended on the grain size of the system, namely on the particle size of the individual components of the system, as well as on the average diameter of the system particles. The most effective are systems with the smallest and the same diameter.

The presented extinguishing system reduces the shortcomings of the used extinguishing agents, such as caking and smoldering, and the resin used ensures flame resistance, an optimal specific surface for the course of radical recombination in the reaction zone. The decomposition products in the next phase contribute both to inertization and have a high inhibitory ability. The system is characterized by increased resistance to moisture, thermal stability, reduced electrical conductivity, as well as reduced corrosive and toxic effects. It is advantageous to use a resin that is generated as waste during wastewater treatment in the production of sulfite pulp in the form of precipitation with suitable precondensates. The above-mentioned advantages as well as the possibility of using waste lead to lower costs for the production and use of the extinguishing system.

The obtained system is characterized by good dispersion and fluidity of the dense cloud of gaseous suspension formed and, in combination with other extinguishing agents, e.g. air-mechanical foam, is suitable for extinguishing fires involving petroleum products.

The examples show the use of resin in a system with 8 other substances.

Example 1

Condensation of urea, formaldehyde and calcium lignosulfonate was carried out in a mass ratio of 1:1:3, after concentration and filtration, the obtained condensate was dried at a temperature of 120 °C. The dry condensate was subjected to grinding in a ball mill and then fractional separation was carried out by sieving through 10 standardized DIN sieves. according to the table presented:

Table

Number of mesh holes

DIN 1171 to 1.10 ^-4 bore size diameter

1 14 20 30 50 70

100

130 in meters

25 64 1.2-10 ^-3 . 0.75. 10 ^-3 121 0.54.10 ^-3 196 0.43.10 ^-3 400 0.3.10 ^-3 900 0.2.10 ^-3 2 500 0.12.10 ^-3 4 900 0.088.10 ^-3 10 000 0.060.10 ^-3 16 '900 0.042.10 ^-3

0.8.10 ^-3 0.5.10-3 0.37.10 ^-3 0.28.10 ^-3 0.20.10^ ³ 0.13.10 ³ 0.08.10 ^-3 0.055.10 ^-3 0.040.10 ^-3 0.020.10 ^-3

Further, the grinding of other components KHCO3 and MgO was carried out and their functional distribution according to particle size was carried out. Mixtures were prepared from individual fractions, for which the fire extinguishing efficiency was determined based on a statistical analysis of the number of successful extinguishing operations per amount of extinguishing agent.

For a fire extinguishing system with a chemical composition in wt.% of urea condensate, formaldehyde and calcium lignosulfonate in a wt. ratio of 1:1:3 5 magnesium oxide 5 potassium bicarbonate 90, the maximum number of successful extinguishing operations was achieved when using all components with the same diameter of particles on a sieve whose opening size was 0.042.10”^ m.

Example 2

A condensate of thiourea, formaldehyde and calcium lignosulfonate was prepared in a weight ratio of 1:1:3, after operations as in Example 1, a fire extinguishing system was prepared in weight Z:

condensate of thiourea, formaldehyde and calcium lignosulfonate in mass. ratio: 1:3 15 ammonium sulfate 15 ammonium hydrogen phosphate 40 calcium oxide 10 stearic acid 10 calcium fluoride 10

Example 3 'Similar to examples 1 and 2, a fire extinguishing system was prepared with the content in wt. %:

condensate of melamine, glyoxal, and ammonium lignosulfonate in a mass ratio of 4:1:3 5 sodium bicarbonate 50 dipotassium carbonate 45

Example 4

Similar to examples 1, 2 and 3, a fire extinguishing system with a chemical composition in mass 7 was prepared:

condensate of semicarbazide, formaldehyde and sodium lignosulfonate in a mass ratio of 1:1:2 10 ammonium hydrogen phosphate 60 ammonium sulfate 20 magnesium oxide 5 glass filings 5

Example 5

Similar to examples 1, 2, 3 and 4, a fire extinguishing system with a chemical composition in mass 7 was prepared:

condensate of guanidine, furfural and bromolignosulfonic acid in a mass ratio of 4:1:3 7 magnesium oxide 3 sodium bicarbonate 90

Example 6

Similar to examples 1, 2, 3, 4 and 5, a fire extinguishing system with a chemical composition in mass 7 was prepared:

condensate of cresol, formaldehyde, sulfite leachate with a content of % dry matter 1:1:3 10 ammonium sulfate 20 ammonium dihydrophosphate 40 ammonium hydrophosphate 20 calcium oxide 5 calcium stearate 5

Example 7

Similar to examples 1, 2, 3, 4, 5 and 6, a fire extinguishing system was prepared with the chemical composition of urea condensate, acetone, sulfite leachate with a content of 50 7 dry matter 1:1:5 5 potassium bicarbonate 95

Claims (7)

196104 Table No. Number of mesh openings DIN 1171 to 1.10-4 Hole diameter Diameter 5 8 1 11420305070 100 130 25 64 1,2-10-3,05. 10-3 121 0.54.10-3 196 0.43.10-3 400 0.3.10-3 900 0.2.10-3 2,500 0.12.10-3 4,900 0.088.10-3 10,000 0.060.10-3 16 '900 0.042.10-3 0,8.10-30,5.10-30,37.1Ó-30,28.10-30,20.10 ^ 30,13.10 30,08.10-30,055.10-30,040.10-30,020.10-3 The further comminution of other components of KHCOg and MgO and their functional distribution according to Particle Size. From the individual fractions the mixtures were prepared in which the fire-quenching efficiency was determined on the basis of a statistical analysis of the number of successful extinguishing on the extinguishing agent. In the case of an extinguishing system with a chemical composition in the mass of urea condensate, formaldehyde and calcium lignosulfonate in mass. 1: 1: 3 5 magnesium oxide 5 potassium bicarbonate 90 reached the maximum number of successful quenching using all the component-like particle diameters on the sieve, the opening opening being 0.042 · 10 µm. Thiourea, formaldehyde and lignosulfonate lignosulphonate were prepared by a weight ratio of 1: 1: 3 after the operation as in Example 1 to prepare a fire extinguishing composition in mass. Z: Thiourea condensate, formaldehyde and calcium lignosulfonate in mass. ratio 1: 1: 3 15-ammonium sulphate ammonium phosphate 40-calcium calcium 10 stearic acid calcium 10fluoride 10 Example 3 'Similar to Examples 1 and 2, a fire extinguishing system was prepared containing at least 7% of the melamine, glyoxal, and ammonium sulfosulfonate in weight. ratio 4: 1: 3 5 sodium bicarbonate 50 dipotassium carbonate 45 Example 4 Similar to Examples 1, 2 and 3, a chemical composition of a chemical composition in mass was prepared. %: condensate of semicarbazide, formaldehyde and sodium lithium sulphonate in weight ratio 1: 1: 2 ammonium phosphate 60 ammonium sulphate 20-magnesium magnesium 5-glass sawdust Example 5 Similar to Examples 1, 2, 3 and 4, a fire-extinguishing system was prepared for chemical composition in mass. Z: guanidine, furfural and bromo-1 -ignosulfonic acid condensate in wt. ratio4: 1: 3 7 magnesium oxide 3 sodium bicarbonate 90 Example 6 Similar to Examples 1, 2, 3, 4 and 5, a fire-extinguishing system was prepared for the chemical composition in mass. %: condensate of cresol, formaldehyde, sulphite liquor containing 50% dry matter 1: 1: 3 ammonium sulphate 20diammonium phosphate ammonium phosphate 20 calcium calcium 5 calcium calcium 5 Example 7 Similar to Examples 1, 2, 3, 4, 5 and 6, an extinguishing system was prepared for the chemical composition of urea, acetone condensate, 50% dry matter sulphite leachate 1: 1: 5 5 potassium bicarbonate 95 INVENTION Powder Extinguishing System containing solids synthetic resins and / or synthetic resins in admixture with a carrier medium and other substances such as inertizing and / or flame retardants, characterized in that it consists of a condensate prepared by condensation of compounds of a group of amines, phenols and / or derivatives thereof having 1 to 8 carbon atoms, preferably urea, melamine, cresol with carbonyl compounds from the group of aldehydes, ketones having 1 to 5 carbon atoms, with the exception of formaldehyde, acetaldehyde, acetone and 1-sulfosulfonic acid and / or or lignosulfonate and / or derivatives thereof, preferably 0.1% by weight, of the halogen derivatives; % to 50 wt.%, preferably 2 to 15 wt. Srverografi ·. n. zivod 7, Moet