ES2687849T3 - Pyrotechnic mixture for the generation of an aerosol - Google Patents

Abstract

Pyrotechnic mixture for the generation of a camouflage fog, which contains at least one oxidation agent, at least one reducing agent as well as at least one mixture of substances that can evaporate, which forms fog, characterized in that in the case of Mist-forming substance mixture is a mixture of at least one saturated, long-chain aliphatic monocarboxylic acid and at least one emulsifier.

Description

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DESCRIPTION

Pyrotechnic mixture for the generation of an aerosol

The invention relates to a pyrotechnic mixture for the generation of an aerosol, which contains at least one oxidation agent, at least one reducing agent as well as a mixture of substances that can evaporate, which forms fog. The aerosol can be used, for example, for daytime signaling, as a means of non-lethal action in police and military use scenarios and also as camouflage fog.

A pyrotechnic mixture of this type (pyrotechnic composition) is known for example from EP 0 329 718 B1. In this respect, the inorganic salts, potassium chloride and sodium chloride are used as substances that can evaporate, which form mist.

However, it is disadvantageous in the case of this known pyrotechnic mixture that high temperatures (> 1450 ° C) are necessary for the evaporation of sodium chloride. Therefore, magnesium powder is used as the reducing agent, so that the reaction temperatures of> 1450 ° C result in the union with potassium nitrate and potassium perchlorate. Due to these high temperatures, metal containers containing the pyrotechnic mixture (fog containers) must generally have a correspondingly expensive thermal insulation.

From US 4,032,374 a pyrotechnic mixture is known, in which an organic compound (cinnamic acid) is used as a mist-forming substance, for its evaporation a relatively low temperature in the order of magnitude of 300 ° C is necessary. It is disadvantageous in the case of this mixture, however, that cyclic hydrocarbon compounds, which are harmful to health, such as styrene, are produced in the mist that forms.

From US 5,154,782 a pyrotechnic mixture is known, in which an aliphatic dicarboxylic acid is used as the fog-forming substance.

The invention is based on the objective of indicating a pyrotechnic mixture for the generation of an aerosol, which can be prepared in a simple and economical manner and, if possible, is innocuous from the human toxicological and ecotoxicological point of view.

This objective is solved according to the invention by the features of claim 1. Other especially advantageous configurations of the invention are disclosed by the dependent claims.

The invention is based on the requirement to generate an aerosol if possible innocuous from the human toxicological and ecotoxicological point of view, which has a good optical activity (large extinction, low transmission). The temperature necessary for evaporation of the mixture of substances that form fog should be as low as possible in this regard. This has the advantage that special insulation of the fog container is no longer necessary. In addition, the flame formation should be as low as possible, so that in combination with the low combustion temperature the heat load in the environment is low.

This requirement is essentially realized because a mixture of at least one saturated, aliphatic monocarboxylic acid (fatty acid) with a carbon chain length C14 to C24 and an emulsifier of the group of as a fog-forming mixture is used according to the invention. mono- or mono-di-glyceride-fatty acid esters or mono- or mono-di-glyceride-fatty acid esters esterified with fruit acid (= monoglycerides and diglycerides as well as a mixture of monoglycerides and diglycerides).

The pyrotechnic composition is preferably used then in containers, containers, etc. closed, which are for example made of metal or cardboard and have at least one hole. For the generation of the aerosol, the pyrotechnic composition is ignited by means of a corresponding ignition composition. The thermal energy released is used to evaporate the aliphatic monocarboxylic acid and the emulsifier. The fog composition burns with relatively low temperature and low flame. The fog container itself must not be specially insulated; The heat load in the environment is relatively low.

For the combustion control, a thermally stable charge can be added to the pyrotechnic mixture, which behaves chemically inert in relation to the other constituent parts of the composition and porous. In this regard, it may be, for example, amorphous, natural silicic acid (diatomaceous earth) or natural clays, such as kaolin.

During evaporation of the carboxylic acid and the emulsifier they flow out of the container hole and form microscopically small mixed particles, which form a fatty phase. The fatty phases of fatty acid and emulsifier are known and represent the basis for emulsions of oil in fat or fat in oil, which are used for example in the food or cosmetic industry. According to the determination, these fatty phases must accumulate or store water, that is, they must physically bind water, so that an emulsion is produced.

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Depending on the humidity of the air, the evaporated particles behave during the combustion of the pyrotechnic mixture in the air as condensation germs, that is they can accumulate or physically store water from the air and can form an aerosol of solid and liquid particles, that disperses and absorbs visible light like a natural fog.

The pyrotechnic mixture according to the invention has the advantage that the aerosol formed by the solids that can evaporate, in particular the monocarboxylic acids, disperses the light already very well, that a good optical activity is also provided with low air humidity. This outstanding property of the active substance components gives the pyrotechnic mixture a certain environment of independent properties. This property is further reinforced because the pyrotechnic mixture according to the invention generates during combustion, that is, during the oxidation reaction with the reducing agent, a significant amount of water vapor, which allows fog formation ( dense) "insitive." - Classic pyrotechnic signaling smoke compositions, that is pyrotechnic compositions that generate solid aerosols from organic dyes in the air and whose particles are hydrophobic, do not exhibit these properties. The transmission by these aerosols is greater, therefore they can be used not for camouflage purposes or non-lethal means of action but according to the determination only for signaling purposes.

The active substance components, indicated in the pyrotechnic mixture according to the invention, monocarboxylic acids and emulsifiers are known as such and can be found in the food industry outside the sector. In particular, carboxylic acids and emulsifiers are routinely authorized for use in foods or constituent parts of natural foods. Because of this these components can be easily obtained. The active substance components do not contain any cyclic hydrocarbon. - The active components in the aerosol, carboxylic acids and emulsifiers, are innocuous in themselves from the human toxicological and ecotoxicological point of view.

It has been advantageous when palmitic acid (hexadecanoic acid), stearic acid (octadecanoic acid) and / or behenic acid (docosanoic acid) is used as mono-carboxylic acid. As is known, the amount of the melting point of monocarboxylic acids depends on the length of the carbon chain. They must also withstand pyrotechnic mixtures, especially for military applications, temperatures above 64 ° C also for a longer period of time, and not lose their safety and function. The chemical stability of the low melting monocarboxylic acids although provided in the proposed pyrotechnic mixture, however they have the disadvantage that they begin to melt already below 60 ° C in the mixture. This modifies the solid structure of the pyrotechnic mixture - as a rule, in a disadvantageous manner.

The melting point of low melting waxes can be raised by adding a high melting polymer, for example with polyethylene glycol. - In tests it was found that also polyethylene, with a melting point of approx. 110 ° C, raises the melting point of for example stearic acid from 58 ° C to 88 ° C, when both substances are mixed in a mixing ratio of 50:50. In the case of mixing ratios of polyethylene with stearic acid from 5:95 to 10:90, a reduction in melting point by approx. 4 ° C, that is, these mixtures melt below the melting points of the individual components. In case of mixtures above 10% polyethylene, the melting point increases above the melting point of low melting stearic acid. In case of 15% polyethylene, the melting point of the mixture rises to approx. 78 ° C

To compensate for the aforementioned drawback of low-melting monocarboxylic acids in the inventive mixture, it is envisaged adding to the low-melting mono-carboxylic acids a higher melting point substance, preferably polyethylene glycol or polyethylene in proportions of 10 % - twenty %.

Chlorates of the alkali metal group can be used as the oxidizing agent. In particular potassium chlorate has been advantageous as an oxidation agent.

In the case of the reducing agent, it may be a carbohydrate or a mixture of different carbohydrates of the mono- or di-saccharide groups.

Preferably it can be treated in the case of the glucose, sucrose and lactose reducing agent.

The pyrotechnic mixture may additionally contain a charge. Hydrated aluminum silicates, in particular natural kaolins such as Bolus alba, have been particularly advantageous for the composition according to the invention.

The constituent parts of the pyrotechnic mixture can be mixed and processed in powdered form. The mixture can also be granulated with water without the addition of a binder. The powder mixture or the granulate can then be introduced directly into a corresponding container etc. The mixture is usually pressed together with the ignition composition in the container / containers etc. Because of this the fog composition can be prepared or else the fog body simply and economically.

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The burning rate depends among others on the surface size (grain size, geometry) of the granulate. For special applications, for example when the pyrotechnic mixture must burn very quickly (spontaneous fog), this granulate introduced into a container can be used. Additionally, the granulate may still be wrapped with a pyrotechnic ignition mixture to improve the initial combustion of the granulate. To increase the mechanical strength of the granulate, however, a binder may be added to the pyrotechnic mixture, which is preferably derived from the group of cellulose esters, dextrins or the like.

To increase the chemical stability of the pyrotechnic mixture, which in itself does not contain acidic constituent parts and shows with the addition of water an almost neutral reaction, salts that act in a neutralizing manner to prevent acid formation can be added to the mixture Chlorine self-igniting. In the case of neutralizing agents, they are preferably carbonates or hydrocarbonates of the alkaline earth group, such as, for example, calcium carbonate and magnesium hydroxide carbonate, or aluminum hydroxide. Usually, an addition of these 2% neutralizing agents to the pyrotechnic mixture is sufficient. Depending on the added amount of the neutralizing agent, they can regulate, like aluminum silicate, the combustion of the pyrotechnic mixture and replace a part of the aluminum silicate.

To reduce the sensitivity to friction and the impact of the pyrotechnic mixture, graphite or boron nitride can be added to it.

The use of the pyrotechnic mixture in containers, containers etc. It can be multiple. For example, in the case of the container it can also be a launching body, a grenade or a grenade carrying the container, which is constituted by a plurality of different materials. However, attention should be paid to the fact that, given that certain materials, such as special plastics, however, also inorganic wastes from surface treatments of metal construction parts, at temperatures above 64 ° C and / or presence of residual moisture by formation of the dreaded chloric acid from alkali chlorate can lead to self-inflammation of the pyrotechnic mixture, do not use them.

Especially preferred embodiments of the pyrotechnic mixtures according to the invention are explained in more detail below:

a) Example mixtures for fast combustion fog compositions (% by weight):

 potassium chlorate

 I 40 II 32 III 28

 saccharose

 40 - 28

 glucose

 - 32 -

 behenic acid

 15 21 19

 emulsifier

 5 5 5

 Aluminum silicate

 - 10 20

 calcium carbonate

 +2 +2 -

 aluminum hydroxide

 - - +2

 graphite

 +3 - -

 boron nitride

 - +3 -

b) Example mixtures for slow combustion fog compositions (% by weight)

 IV V VI VII VIII IX

 Potassium chlorate

 26 28 28 28 28 35

 saccharose

 26 28 - 28 28 25

 lactose

 - - 30 - - -

 behenic acid

 - 34 30 - 24 25

 palmitic acid stearic acid

 26 26 - -

 polyethylene

 4 - - 4 - -

 emulsifier

 10 5 5 5 5 5

 Aluminum silicate

 8 5 9 9 15 10

 calcium carbonate

 - +2 +4 - +2 -

 MgCO3 Mg (OH) 2 5H2O

       +2 - +2

 boron nitride

 - +3 - - - +3

For the preparation of abrasion resistant granules, cellulose ester in proportions of 1-5% can be preferably added to the mixtures and the water-wetted mixture can then be granulated.

Claims (13)

5 10 fifteen twenty 25 30 35 40 Four. Five fifty 1. Pyrotechnic mixture for the generation of a camouflage fog, which contains at least one oxidation agent, at least one reducing agent as well as at least one mixture of substances that can evaporate, which forms fog, characterized in that in the case The mixture of substances that forms fog is a mixture of at least one saturated, long chain aliphatic monocarboxylic acid and at least one emulsifier. 2. Pyrotechnic mixture according to claim 1, characterized in that in the case of the aliphatic monocarboxylic acid it is monocarboxylic acids with a carbon chain length C14 to C24 and in the case of at least one emulsifier it is an emulsifier of the group of the esters of mono- or di-glyceride-fatty acid or mixtures thereof or esters of mono- or di-glyceride-fatty acid esterified with fruit acid or mixtures thereof. 3. Pyrotechnic mixture according to claim 1 or 2, characterized in that in the case of mono-carboxylic acid it is palmitic acid, stearic acid or behenic acid or mixtures thereof, in which the proportion of mono-carboxylic acids in the pyrotechnic mixture preferably amounts to 10-40%. 4. Pyrotechnic mixture according to claim 1 to 3, characterized in that the pyrotechnic mixture contains a substance that raises the melting point compared to monocarboxylic acid, in which the proportion of the substance that raises the melting point in Comparison with carboxylic acid preferably amounts to 10-40%. 5. Pyrotechnic mixture according to claim 4, characterized in that in the case of the substance that raises the melting point it is polyethylene glycol or polyethylene or mixtures thereof. 6. Pyrotechnic mixture according to one of claims 1 to 5, characterized in that in the case of the oxidizing agent it is chlorates of the alkali metal group, in which the proportion of the oxidizing agent is preferably from 20-45 %. 7. Pyrotechnic mixture according to claim 6, characterized in that in the case of the oxidizing agent it is potassium chlorate. 8. Pyrotechnic mixture according to one of claims 1 to 7, characterized in that in the case of the reducing agent it is a carbohydrate or a mixture of different carbohydrates of the mono- or di-saccharide groups , in which the proportion of the reducing agent is preferably 20-45%. 9. Pyrotechnic mixture according to claim 8, characterized in that in the case of the reducing agent it is glucose, sucrose, lactose or mixtures thereof. 10. Pyrotechnic mixture according to one of claims 1 to 9, characterized in that the pyrotechnic mixture contains a filler, preferably hydrated, natural aluminum silicate, in which the proportion is preferably 0-20%. 11. Pyrotechnic mixture according to one of claims 1 to 10, characterized in that graphite or boron nitride are added. 12. Pyrotechnic mixture according to one of claims 1 to 11, characterized in that the mixture is a granulate, which is preferably wrapped with a pyrotechnic ignition mixture. 13. Use of the pyrotechnic mixture according to one of claims 1 to 12 in containers, containers etc., such as for example in a launching body, a grenade or a grenade carrying the container.