RU2006239C1 - Aerosol-forming fire-extinguishing composition - Google Patents

Abstract

FIELD: fire extinguishing. SUBSTANCE: composition contains, mass % : potassium nitrate 40-70, carbon 5-15, centralite or diphenylamine or their mixture 0.5-2.0, industrial or machine oil 0.5-2.5, stearic acid salts (sodium stearate or zinc stearate or their mixture or their mixture together with sulforicinate and with gelatin) 0.02-0.5, plasticized nitrocellulose or its mixture with polyvinylacetate - the rest. Composition contains also diethyleneglycoldinitrate or triethyleneglycoldinitrate or their mixture or triacetine as plasticizer for nitrocellulose. Mass ratio nitrocellulose and diethyleneglycoldinitrate or triethyleneglycoldinitrate or their mixture is (40-50): (60-50), mass ratio nitrocellulose and triacetine being (45-68): (55-32). EFFECT: improves desired product quality. 3 cl, 2 tbl

Description

 The invention relates to the development of a new type of fire extinguishing compositions intended for volumetric fire extinguishing means in closed and semi-closed volumes, for example, for engine and luggage compartments of vehicles and aircraft, garages, warehouses, holds of ships, televisions, etc.

Among gas fire extinguishing agents, freons with an efficiency of about 250 g / cm ^{3 of} protected volume are widespread, which, according to the Montreal International Convention, are prohibited for use in connection with the destructive effect of fluorine and its derivatives on the ozone layer of the atmosphere.

 Also known are various fire extinguishing powders based on phosphate-ammonium salts, potassium or sodium bicarbonates, sodium chloride, boron oxide, mixtures of ammophos with potassium or sodium chlorides, aluminum hydroxide, ammonium sulfate, etc.

 Powdered mixtures have a significant tendency to moisture absorption, caking, as well as insufficient fire extinguishing ability and a relatively long period of supply of fire extinguishing powder to the fire.

Closest to the invention in technical essence is a composition for fire extinguishing according to US patent N 3972820, 1976, consisting of the following components, wt. %:
Halide compound
nye (hexachlorobenzene,
hexabromobenzene and others. 25-85
Oxidant (chlorates
and sodium or potassium perchlorates) 15-45
Binder (epoxy resin) 3-50
This fire extinguishing composition is selected as a prototype.

The prototype composition is a solid mixture obtained by curing a binder. The composition is cured in the presence of a catalyst at ⁷⁰ ° C for 17 hours.

 The principle of action of such a composition is the evaporation and supply of a halide compound with the ability to extinguish a fire as a result of burning a solid composition into a fire.

 The disadvantage of this composition is the presence of halogen derivatives in the decomposition products of the extinguishing agent, which makes them toxic and chemically aggressive with respect to equipment that may be in a protected volume.

 The damage caused by fires to the national economy is of enormous proportions and is estimated by hundreds of millions of rubles annually.

Therefore, high demands are made on extinguishing media. First of all, it is necessary to ensure a short fire extinguishing time, instant introduction of a fire extinguishing agent into the fire, high fire extinguishing efficiency, which for new modern means should not be more than 50 g per 1 m ^{3 of} protected volume.

The aim of the invention is the development of an aerosol forming fire extinguishing composition (OTS) with an efficiency of not more than 50 g / m ³ intended for volumetric fire extinguishing in closed and semi-closed volumes.

 This is achieved through the use of potassium nitrate as an oxidizing agent, and carbon as an activator of the decomposition of potassium nitrate. The fuel binder for this composition is plasticized nitrocellulose. The rheological and technological properties of the composition are provided by a technological additive consisting of industrial oil and salts of fatty acids. The set of required properties is ensured by the optimal selection of all components and their ratio.

 The principle of operation of the proposed OTS is that during combustion it forms gaseous and highly dispersed condensed products, which are an aerosol with inhibitory properties, which, falling into the fire, suppresses chain reactions of combustion and extinguishes the flame.

 The presence of potassium ions in the combustion products of the aerosol-forming composition makes it extinguishing.

 The effectiveness of OTC depends on the quality of the resulting aerosol. To obtain a highly dispersed aerosol of potassium in the OTS combustion products, it is necessary that potassium nitrate is completely decomposed during its combustion. This is ensured by the use of carbon with a large developed surface, which plays the role of a sorbent capable of increasing the viscosity of the burning layer and retaining potassium nitrate on the OTS burning surface, facilitating its thermal decomposition. At the same time, carbon is also an activator of the decomposition of potassium nitrate.

 Specific examples of the compositions of the proposed OTC are given in table. 1, the main properties of OTC are presented in table. 2.

The main characteristic of OTS is its fire extinguishing efficiency (OTE) - this is the minimum mass of OTS, which provides extinguishing of fire in a volume of 1 m ^{3 of} air.

The higher the content of potassium nitrate in the OTC, the higher its OTE. However, introducing more than 70% of potassium nitrate into the proposed OTS is impractical, since it will also require introducing a large amount of carbon (in order to ensure complete decomposition of potassium nitrate during the combustion of OTS). The total high content of dispersed additives (over 70% KNO ₃ and 15% carbon) negatively affects the mechanical and technological properties of the composition. When the content of potassium nitrate is less than 40% and carbon is less than 5%, the flammability and combustion stability of the OTC deteriorate and the OTE decreases.

 The considered compositions of the proposed aerosol forming OTC are highly filled compositions in which plasticized nidrocellulose is used as a binder. The ratio between nitrocellulose and plasticizer and their quantity determine the complex of physico-mechanical and technological properties of OTC and are established specifically depending on the purpose and conditions of use of OTC, i.e., taking into account the requirements for mechanical strength, rheological and other properties.

 As the plasticizer of nitrocellulose, diethylene glycol dinitrate, triethylene glycol dinitrate, mixtures thereof or triacetin can be used.

 For each type of plasticizer, in accordance with its plasticizing ability, its optimum amount is selected with respect to nitrocellulose.

 Diethylene glycol dinitrate and triethylene glycol dinitrate are identical in terms of the complex of physicochemical, chemical properties and plasticizing ability with respect to nitrocellulose and therefore can be used interchangeably in the OTC composition or can be used together in any mass ratio.

 For plasticizers - diethylene glycol dinitrate, triethylene glycol dinitrate and mixtures thereof, the ratios between nitrocellulose and plasticizer from 50/50 to 40/60 are technologically acceptable. Above the 50/50 ratio, the viscosity of the OTC increases, and below the 40/60 ratio, the composition becomes very elastic. In both cases, the rheological characteristics of OTS are deteriorating, which leads to technological difficulties in the processing of aerosol forming compounds.

 For triacetin, for the same reasons, the ratios between nitrocellulose and plasticizer from 68/32 to 45/55 are optimal.

 In the practical selection of the amount and ratio between nitrocellulose and plasticizer, it is also necessary to take into account the content of highly dispersed solid fillers in the OTS.

With a high filling of the OTC composition with carbon and potassium nitrate (over 55% KNO ₃ ) to increase the viscosity of the system in order to ensure satisfactory rheological characteristics, it is advisable to introduce polyvinyl acetate (PVA) in the amount of 1 to 10% as an additional binder, depending on the content in composition of dispersed components and requirements for OTS for mechanical and operational properties. The preferred PVA content is up to 5%.

 When the content of PVA in the composition is less than 1%, its effect as a binder is shown to a small extent, and when the content is above 10%, the viscosity of the composition increases so much that it causes technological difficulties.

 The necessary indicators of the rheological and technological properties of OTS are provided by using a combination of industrial (instrument) oil and salts of fatty acids, for example, sodium and zinc stearates. Sodium and zinc stearates are identical compounds both in chemical structure and in a set of physicochemical properties, therefore, in OTS compositions can be interchanged or used together in any proportions without changing all their characteristics. For the same reasons, industrial and instrument oils are interchangeable.

 The amount of industrial (instrument) oil less than 0.5% and salts of fatty acids less than 0.02% is insufficient to reduce the specific external friction - one of the main characteristics that determine the rheological properties of the composition, and the amount of more than 2.5% of industrial (instrument) oil and more than 0.5% of salts of fatty acids impairs cohesion and adhesion of components and mechanical properties of OTC. Therefore, the content in the aerosol-forming compositions of industrial oil in the range from 0.5 to 2.5% and salts of fatty acids from 0.02 to 0.50% is optimal.

 To ensure uniform distribution of all components in the OTC compositions and to reduce the time of their mixing, it is allowed to use surfactants such as sulforicinate and gelatin in amounts of 0.1-0.3% and 0.01-0.03%, respectively.

 Centralites and diphenylamine are introduced as anti-oxidants in OTS, the action of which is based on the binding of nitrogen oxides, if the release of these occurs for one reason or another during the manufacture and operation of OTS at elevated temperatures. Depending on the operating conditions of the OTC, the composition and amount of the anti-aging agent are selected. As a rule (from the practice of cross-breeding), the amount of anti-aging agent from 0.5 to 2.0% is sufficient to provide the necessary reserve of chemical resistance of OTS.

 In the practice of fire extinguishing, OTS is used in the form of pressed monolithic products in a fire extinguishing medium - an aerosol generator.

 Production of OTS is carried out by mixing all the components in certain proportions with the subsequent formation on the screw press of products of the required sizes and configurations.

 A pressed OTS sample of the required mass is placed in an aerosol generator installed in a protected volume. The generator operates in automatic mode. From the igniter, which is an electric igniter or other source of energy, the OTC sample in the generator is ignited. Combustion of the OTS is accompanied by the formation of a large number of gaseous and highly dispersed condensed products - aerosol flowing out of the generator at high speed. An aerosol fills the protected volume and, reaching the flame, extinguishes the fire.

 The mass of the OTS and the number of generators are calculated depending on the volume of the protected object, based on the fire extinguishing efficiency of the OTS, the design of the generator and the safety factor of 1.2-2.0.

 Aerosol-forming OTS in the form of extruded products are simple and easy to use, characterized by constant readiness for use, speed in assembly of a fire extinguishing generator, and high efficiency. The fire is extinguished during the combustion of the OTS sample and the spread of the resulting aerosol in a protected volume.

 OTE of aerosol-forming composition is widely tested in laboratory conditions when extinguishing burning solvents: acetone, gasoline, ethyl and isopropyl alcohols.

 The study of OTE aerosol-forming compounds was carried out according to the following methods.

 I method. A burning spirit lamp was placed in a fume hood, a sample of OTC of a certain mass was set on fire, and at the same time they were covered with a 10 l glass cap. Through the transparent glass of the hood, the process of extinguishing the flame of the spirit lamp was observed. The extinguishing of the flame of the spirit lamp for a time of not more than 5 s after the combustion of the OTC sample was taken as a positive result. For comparison, a control experiment was conducted on the burning of an alcohol lamp under a closed hood. The natural attenuation of the flame of the spirit lamp due to the consumption of oxygen in the air enclosed under the hood occurred in 75 s.

II method. A cup with 40 ml (S = 63 cm ² ) of gasoline or other flammable liquid and a sample of OTC of a certain mass were placed in a 85-liter cabinet. They set fire to the flammable liquid in the bowl, ignited the OTC sample, and closed the cabinet door. For a positive result, the quenching of the flammable flammable flame was taken for no more than 5 s after the combustion of the OTC sample. For comparison, a control experiment was conducted on the combustion of flammable liquids in a closed cabinet. The time during which the decay of the LVH flame took place was 35 s.

 The aerosol-generating composition of the aerosol was determined by the minimum mass of the sample, providing complete extinguishing of the flame.

 The results of testing the OTC according to the I and II method give identical results on the OTE.

The test results of the OTE compositions of the aerosol forming composition are given in table. 1, from which it follows that the OTE of the proposed OTS is 20-46 g / m ³ .

 The high OTE of the aerosol forming composition was confirmed by tests on the extinguishing of the burning engine of a ZIL-130 truck.

PRI me R 1. The recipe for OTC, wt. %: Potassium nitrate 50.0 Technical carbon 10.0 Nitrocellulose 17.17
A mixture of diethylene
coldinitrate with
triethylene glycol-
dinitrate (in mass
Own ratio 70: 30) 20.0 Centralit 0.5 Diphenylamine 0.5
Industrial oil 1.5 Sodium stearate 0.1 Sulforicinate 0.2 Gelatin 0.03
OTS in the form of molded products with a diameter of 48 mm and a mass of 50 g was placed in an aerosol generator.

 4 generators were located in the engine compartment of the ZIL-130 truck. The engine was doused with gasoline. Additionally, two bowls with a diameter of 200 mm with gasoline were installed on both sides of the engine. The total amount of gasoline was 400 ml.

 Gasoline was set on fire. After that, after 10 seconds, the bonnet was closed and the OTC was set on fire by an electric fan. After closing the hood, a reflection and “tongues” of flame were observed through the hood blinds. When the OTS was ignited, the compartment under the hood was filled with a lot of dense white smoke - aerosol that exited through the blinds. Combustion of the OTS was followed for 8 s, but the fire in the engine compartment was extinguished until the OTS was completely burned. After opening the hood and inspecting the engine compartment, unburned gasoline was observed in both bowls.

PRI me R 2. The recipe for OTC, wt. %: Potassium nitrate 63.0 Technical carbon 9.0 Nitrocellulose 14.4 Triacetin 9.0 Polyvinyl acetate 2.0 Centralit 0.3 Diphenylamine 0.7 Instrument oil 1.5 Zinc stearate 0.1
The experimental conditions are the same as in example 1. The result of the experiment is the same - the fire in the engine compartment of the ZIL-130 is extinguished until the OTS is completely burned. Unburned gasoline remained in the bowls.

 PRI me R 3. The OTC recipe is the same as in example 1.

 OTS in the form of molded products with a diameter of 48 mm and a mass of 50 g was placed in an aerosol generator.

 3 generators were located in the engine compartment of the ZIL-130 truck. On both sides of the engine were installed two bowls with a diameter of 200 ml with gasoline. The engine was doused with gasoline.

 The total amount of gasoline was 800 ml. To simulate the movement of a car, compressed air was supplied through a radiator at a pressure of about 0.15 MPa. Gasoline was set on fire. After it was ignited, the hood was closed for 10 s, and the OTC was set on fire by an electric fan. As in examples 1 and 2, the fire in the engine compartment was extinguished until the OTC was completely burned (the OTC burned time was 8 s). Unburned gas remained in both bowls.

 The level of the main characteristics of aerosol-forming OTS (Table 2) indicates the possibility of their manufacture and use. OTC combustion products in air do not contain toxic components. (56) U.S. Patent No. 3,972,820, cl. A 62 C 1/00, 1976.

Claims (2)

1. AEROSOL-FORMING FIRE EXTINGUISHING COMPOSITION, comprising an oxidizing agent and a fuel-binding agent, characterized in that it contains potassium nitrate as an oxidizing agent, plasticized nitrocellulose or its mixture with polyvinyl acetate as an oxidizing agent, and additionally contains a center activator — carbon, anti-aging agent diphenylamine, or their mixture, technological additive - industrial or instrument oil, as well as salts of stearic acid (sodium stearate, or zinc stearate, or their mixture, or their mixture with sulforicinate and gelatin m) in the following ratio of components, wt. %:
Potassium Nitrate 40 - 70
Carbon 5 - 15
Centralit, or diphenylamine, or a mixture of 0.5 - 2.0
Industrial or instrument oil 0.5 - 2.5
Salts of stearic acid (sodium stearate, or zinc stearate, or a mixture thereof, or a mixture thereof with sulforicinate and gelatin) 0.02 - 0.5
Plasticized nitrocellulose or its mixture with polyvinyl acetate
2. The composition according to p. 1, characterized in that it contains diethylene glycol dinitrate, or triethylene glycol dinitrate, or a mixture thereof, or triacetin, as a plasticizer of nitrocellulose.  3. The composition according to p. 2, characterized in that nitrocellulose and diethylene glycol dinitrate, or triethylene glycol dinitrate, or a mixture thereof are taken in a mass ratio (40-50): (60-50), and nitrocellulose and triacetin in a mass ratio (45-68 ): (55 -32).

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