RU2102689C1 - Aerosol-generating compound - Google Patents

Abstract

FIELD: facilities for attack or defense actions with employment of gas flame or smoke, in particular, substances and compounds producing fog for active counter- action to optoelectronic facilities of reconnaissance and weapon control. SUBSTANCE: gas-producing compounds containing ammonium nitrate, dicyandiamide, Berlin blue, iditolm graphite are used. The mass of the gas-producing mixture makes up 10% of the mass of the main aerosol- generating mixture. The results of comparative estimate testify the superiority of the offered optopreservation of other properties at the level of the prototype. Introduction of 10 percent by mass of the gas-producing mixture increases the deceptive capacity by 29%, and the utilization factor - by two times. EFFECT: enhanced deceptive characteristics of standard optoelectronic facilities. 1 dwg, 1 tbl

Description

 The invention relates to means for conducting offensive or defensive actions using a flame of gas or smoke, and in particular to substances and compositions that form a fog for active counteraction to optoelectronic means (ECO) of reconnaissance and weapon control. Known aerosol-forming substances, compositions (AOS), capable of effectively counteracting the optoelectronic means of reconnaissance and control of weapons in the optical spectrum of electromagnetic radiation; based on chlorine-substituted hydrocarbons, anthracene, based on white and red phosphorus, liquid self-smoking compositions, compositions based on petroleum products. These AOCs are used in regular smoke products or are offered for use as promising products in various ways: combustion and thermal sublimation followed by condensation, spraying with compressed gas and explosion (A. Shidlovsky. Fundamentals of pyrotechnics. M. GIOP, 1954, 281 s).

 Known pyrotechnic compositions for producing signal smoke used abroad, having in their composition "semi-explosive" substances that do not give a solid residue during its combustion. As such substances, ammonium nitrates and guanidine nitrates and nitroguanidine are indicated in the literature (application N 2384732 from 11.24.78 France; application N 2531071 from 07.28.82 France; application N 2004536 from 04.04.79 Great Britain).

Closest to the claimed object are AOC from UK application N 2004536 dated 04/04/79, where "injection molding pyrotechnic tracer composition" is proposed, which contains: a synthetic resin that decomposes at 190 300 ^o C, a mixed oxidizing agent containing sodium or potassium chlorate or ammonium, sodium or potassium perchlorate and guanidine nitrate and a sublimate organic dye. In addition, metal oxide can be introduced into the composition to catalyze the decomposition of chlorate or perchlorate.

 The disadvantages of this composition include the lack of masking action of this composition.

 The standard anthracene composition of black smoke was adopted as the prototype of the invention, including: potassium chlorate 50% anthracene 50% (Soloviev N.K. Smoke and flamethrower incendants. M. VIVM USSR, 1951, 308 pp.). This composition has a low value of masking ability.

 The objective of the invention is to increase the masking characteristics of the standard AOS.

 The problem is achieved by the use of gas-generating mixtures containing ammonium nitrate, dicyandiamide, Prussian blue, iditol, graphite.

 A common feature with the prototype is the use of a composition based on anthracene and potassium chlorate.

 The use of dicyandiamide, ammonium nitrate, Prussian blue, iditol, graphite distinguishes the proposed composition from the prototype and provides an increase in masking characteristics.

Composition characteristics
The presence in the proposed composition of widely available compatible components does not require separate equipment. In general, the proposed AOS have significant differences in their masking characteristics from analogues and prototype.

 Significant differences are provided by the specific properties of the selected AOS components. The main gas-emitting substance in the mixture is ammonium nitrate, upon decomposition of which hydrogen, nitrogen and oxygen are released (G. Remy. Inorganic chemistry course. M. Mir, 1974, v. 1, 377 pp.).

Dicyandiamide in the composition is used as fuel and, at the same time, as a flame arrester. Melts at 209 ^o C, density 1.4 g / cm ³ , decomposes when heated above 180 ^o C, splitting off ammonia, thereby increasing gas yield (Shidlovsky A.A. Sidorov A.I. Silin I.A. Pyrotechnics in the national economy. M. Engineering, 1978. 232 S.). The remaining components of the composition are used as a binder (iditol) and stabilizers of the combustion process of the mixture (graphite) and as additional gas-emitting components, Prussian blue decomposes at 200,280 ^° C and forms ammonia. (Shidlovsky A.A. Fundamentals of pyrotechnics. M. GIOSh, 1954, 284 p.).

 The idea of using such compositions is to crush the resulting hot slag due to the production of a large amount of gas released during the combustion of gas-emitting mixtures that are part of the main pyrotechnic AOS, and the release of fine slag into the atmosphere due to the gas formed and the combustion energy of the main pyrotechnic mixture. In addition, it is known that in aerosol formulations the presence of a gas phase in the products of a combustion reaction allows particles of various aerosol forming agents to be ejected from the reaction zone into the atmosphere. However, the amount of gas that is released during the combustion of the main aerosol forming mixture is small. Therefore, it is proposed the introduction of additional compositions into pyrotechnic compositions, during the combustion of which additional gas is released.

 The components that make up AOS are manufactured by the domestic industry, are compatible, do not require the use of special safety measures during cooking.

 Execution example.

 To optimize the components in the proposed composition and confirm the feasibility of its implementation as intended, experiments were conducted in laboratory conditions.

 The experimental studies consisted of a comparative assessment of the masking characteristics of the prototype and compositions containing different amounts of gas-emitting mixture.

 The composition was prepared by adding to the main AOC gas-generating composition, which had the following ratio of components, wt.

Ammonium Nitrate 7.5.8.4
Prussian blue 0.3.0.7
Iditol 0.6.1.0
Dicyandiamide 0.3.1.8
Graphite 0.05.0.1
Experimental compositions were created in which the gas-generating composition was 10, 20, 30, 40% of the mass of the main composition. The components of the main and gas-generating composition were thoroughly mixed and placed in metal cylinders with a diameter of 30 mm. The weight of the samples was taken in the amount of 10 g.

The prepared samples of model blocks with the tested mixtures were burned in an aerosol chamber with a volume of 25.3 m ³ .

 After burning samples of standard and tested AOS in model pieces, the masking ability and mass concentration of aerosol in the chamber were determined. The determination of these parameters in the laboratory was carried out using methods that were sufficiently tested in various organizations. In this method, when measuring the attenuation of direct EMW radiation, it is assumed: compliance with the Bouguer law; The method of obtaining aerosol in model samples of aerosol products (model checkers) simulates the real process of AOS conversion in real samples.

 In the course of the experiments, the following parameters are determined: initial and transmitted aerosol layer, intensity of a parallel light beam, aerosol layer thickness, AOS mass, filter mass before and after aerosol sampling, respectively, air suction rate, experiment time, air humidity. To determine the masking ability, a collimated light source was used as a radiation source in the range 0.4.0.76 μm, and the detector was a standard constant-source photometer device that allows photometric measurements of light sources having a continuous or mixed emission spectrum.

In the course of laboratory studies of the tested compositions, at least five experiments were carried out with each of them at a temperature of 18 to 22 ^o C and a relative humidity of 55.60% based on the requirements for a relative error of the average result of 5% with a confidence level of 0.95.

 Comparative results of laboratory tests of a standard AOS RDG-2 h and the claimed AOS when adding various amounts of gas-generating mixtures to it are presented in the drawing.

An analysis of the data obtained shows that the composition in which the gas-generating mixture is on the order of 10% has a higher utilization and masking ability than the standard composition of the RDG-2 h by 71% and 50%, respectively. The amount of slag after combustion of compositions containing gas-generating compounds is reduced by 10 15%
A further increase in the percentage of gas-generating compositions in the tested mixtures does not lead to an increase in masking compositions.

 A comparative assessment of the proposed AOC and prototype are presented in table 1.

 The results of a comparative evaluation of the prototype and the proposed AOC indicate the superiority of the latter in terms of utilization and masking ability while maintaining other properties at the level of the prototype. The claimed invention allows to increase the utilization rate by 71% and the masking ability by 50.

Claims (1)

 Aerosol-forming composition, including anthracene and potassium chlorate in equal proportions, characterized in that it additionally contains a gas-generating composition, amounting to 10% of the main composition in the following ratio of components, wt. Ammonium Nitrate 7.5 8.4
Prussian blue 0.3 0.7
Iditol 0.6 1.0
Dicyandiamide 0.3 1.8
Graphite 0.05 1.0 rub

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