RU2368591C1 - Method of explosive material marking - Google Patents

Abstract

FIELD: explosive materials.

SUBSTANCE: method of explosive material marking includes introduction of marking composition into explosive material. The marling composition contains identifiers whose quantity is equal to that of the technical figures subject to marking. The identifiers are oil-fat-soluble chemical stable in the media with different pH, free radical resistant, chemical resistant to explosive material components, free from surface active agent properties of the first kind, chemical resistant to explosion products and free from toxic properties. Polymethylsiloxane, polyethylsiloxane or their mixture is used as the identifier.

EFFECT: accuracy and reliability of explosive material marking according to different technical parametres.

4 cl, 1 tbl

Description

The invention relates to chemical methods for the examination of explosives and can be used in investigative, forensic, forensic and judicial practice.

Investigations into the circumstances of terrorist acts involving explosives (explosives) require not only establishing the type of explosive device and explosives used, but also identifying the manufacturer of this explosive, as well as tracking its path from the manufacturer to the place of use.

Investigations into the circumstances of industrial accidents involving explosives, as a rule, require the establishment of a date for the manufacture and loading of wells (holes) in order to further investigate compliance with the manufacturing technology of explosives and their loading.

In a number of mining enterprises, blasting operations use industrial explosives (including emulsion explosives), supplied directly from several manufacturers. Often, the prepared unit can be charged with several types of explosives at once from several manufacturers. This makes it difficult to identify the causes of possible failures, and also makes it impossible to uniquely identify the manufacturer and type of explosives in the failed well.

In addition, there is the problem of identifying accidentally lost explosives when they are detected.

A known method of marking explosives, in which a fine powder of a metal alloy — the so-called “marker” —is introduced into the explosives at the manufacturing stage. The component composition of the alloy used for these purposes corresponds to the specific manufacturer of the explosive, and the mass ratio of a number of metal components of this alloy indicates the date of manufacture or other technological parameters, or the consumer to whose address the shipment of the finished product is planned. Aluminum or aluminum-magnesium alloy is used as the base of the alloy, and rare-earth elements - “Chemistry and Life” No. 3, 2005, p. 4, as marking additives.

In this case, the identification of the explosive used is quite simple, because during the explosion of an explosive device, a certain amount of unexploded explosive always remains in place due to the so-called “edge effect”, in which the outer layers of the charge are scattered without undergoing chemical reactions in them. It is obvious that particles of a metal powder marker will be detected in the same residues of unreacted explosives. Identification by manufacturer and production date comes down to a qualitative and quantitative analysis of the constituent components of the metal alloy.

The disadvantages of this method of marking explosives include the following:

- the density of aluminum is 2.7 g / cm ³ . When additives are added to the alloy — rare-earth elements (which are, as a rule, heavy metals) —the density of the alloy increases further. The density of the molten trinitrotoluene does not exceed 1.6 g / cm ³ . Thus, the particles of the metal powder will settle rather quickly in the molten TNT, which will complicate the marking during the manufacturing process (uniformity% in volume), but will simplify the removal of the marking (for example, in preparation for terrorist acts) by conventional melting and natural deposition of the powder in liquid density difference count;

- it is known that explosives such as RDX and HMX do not have a liquid state of aggregation. Therefore, their marking is possible only by mixing crystalline explosives with metal powder. Metal powders have abrasive properties, and explosives are capable of exploding when grinding (mixing) with abrasive materials. This makes the marking of crystalline explosives (RDX, HMX) with the proposed method — the introduction of metal powders — an extremely dangerous operation;

- rare earth metals and alloys based on them are extremely expensive. The raw material base of rare-earth metals is very limited, their finished industrial production is also limited;

- rare earth metals, which are proposed to be used as components of an alloy-marker, are usually heavy metals. It is known that all heavy metals are poisonous. In the world for one calendar year, more than a million tons of industrial and other explosives are used. The introduction of metallic additives into their composition will entail significant emissions of heavy metals into the atmosphere;

- the list of rare-earth metals themselves is limited (no more than 25 metals can be attributed to this group). The number of manufacturers of explosives only in Russia is approaching two hundred. This will require the preparation of rather complex and multicomponent alloys for reliable marking;

- with small quantities of introduced markers, their visual control is impossible;

- with large quantities of injected markers, explosives may lose their explosive properties. At the same time, the price of explosives marked in this way becomes unreasonably high;

- the need to indicate in the marking not only the manufacturer, but also the production date, will require the creation of the own metallurgical production at the manufacturing enterprise of the explosive (manufacturing alloys and subsequent manufacture of powders from them), because large metallurgical enterprises will not be able to serve such numerous and small orders. If powders are made in ball mills, then the mill will be contaminated with marker components from previous grindings, which will make the labeling so contaminated with impurities - powders - unreliable.

Thus, the known method of marking with metal powders is excessively expensive and also complex, toxic, time-consuming and not reliable.

The prototype of the invention is a method for marking explosives, comprising introducing into the explosive a marking composition in an amount of at least 200 grams of a marking composition per ton of explosive, using a marking composition containing identifiers, the number of which is equal to the number of technical indicators to be marked, from synthetic organic or inorganic compounds of the class of dyes and / or low molecular weight polymers from the international chemical CAS register substances with a molecular mass of less than 1000 g / mol, possessing oil-fat solubility, chemical resistance in media with any pH range, resistance to free radicals, chemical inertness to explosive components, lack of properties of surface-active substances of the first kind, chemical inertness to explosion products, the absence of toxic properties, while using compounds of the class of dyes and low molecular weight polymers, they should not enter into chemical reactions with each other - RF patent №2328481, C06B 23/00, 2008

The disadvantages of this method of marking explosives include:

- the complexity of identification (two-stage: first, qualitative, then quantitative analysis);

- errors in the quantitative determination of markers (concentration of dyes and / or polymers), which, in turn, gives mixed results of the numerical value of the determined normalized technical parameters of explosives;

- introduction of a relatively large number of markers into the explosive composition (at least 200 grams per tonne of explosive) for a more accurate quantitative determination of them in the future;

- all chemicals, including the dyes in question tend to diffuse into the environment. Moreover, at different speeds (chromatography methods are based on this). Thus, the change in the concentration of several dyes in explosives in contact with the environment over time will be uneven. Therefore, the main meaning of the method is lost - the determination of the numerical value of the normalized indicator by the concentration of the dye. The method will only work if there is no contact of the explosive with the environment. But in this case, it loses its versatility.

Thus, the technical problem solved by the proposed method consists in increasing the accuracy, reducing the complexity and quantity of the substance used for marking.

This problem is solved in a method for marking explosives, including introducing into the explosive a marking composition containing identifiers, the number of which is equal to the number of technical indicators to be labeled, while the identifiers have oil-fat solubility, chemical resistance in environments with any pH range, resistance to free radicals, chemical inertness to the components of an explosive, the lack of properties of surface-active substances of the first kind, chemical inertness to food there is an explosion, the absence of toxic properties, as well as identifiers are used polydimethylsiloxanes or polyethylsiloxanes, or a mixture thereof.

Particular cases of the implementation of the method are as follows:

- when marking emulsion explosives, the marking composition is introduced into the fuel phase;

- compounds of the class of phosphors are additionally introduced into the marking composition;

- marking composition has a chemical inertness to the components of the solutions of gas-generating additives and the products of the chemical reaction of the interaction of the components of the explosive with gas-generating additives.

Consider the effect of each of these properties on the totality of these characteristics.

Oil-fat solubility implies that this substance is insoluble in water, i.e. it is lyophilic and hydrophobic, but soluble in petroleum products. The marker dissolves in the fuel phase of the emulsion explosive (emulsion explosive). Explosives are placed in a well drilled in rocks where there is contact with water. In the presence of hydrophilic properties, the dye will be washed out, i.e. go diffusely into the surrounding water. And since polymethylsiloxanes and polyethylsiloxanes are hydrophobic, there will be no leaching.

Chemical resistance in environments with any pH range is the absence of chemical degradation and the absence of loss of coloring properties of the marking composition in these environments. Explosives may have a different pH. The environment (water, rock) can also have a different pH. There are a number of dyes that significantly change the color and intensity of staining depending on the pH of the environment. Similarly, another series of dyes is destroyed when the ambient pH goes beyond the established ranges. In the present labeling method, such dyes are not applicable.

Resistance to free radicals is the property of dyes to not be chemically destroyed and not to lose coloring properties in the presence of free radicals in their environment. Free nitro groups are always present in the composition of explosives: explosive molecules, as a rule, are chemically unstable in time, breaking down with the formation, including free nitro groups, which are strong oxidizing agents (radicals). Explosives can be, for example, mixed. The components included in these explosives may have the properties of oxidizing agents.

Chemical inertness to the components of an explosive means the non-entry of identifiers into chemical reactions with these components of explosives - polymethylsiloxanes and polyethylsiloxanes are chemically inert to components of explosives.

For the manufacture of emulsion explosives use surface-active substances (surfactants) of the 2nd kind (when creating reverse, or "invert" emulsions). If the identifiers possess the properties of a surfactant of the first kind, their introduction into the emulsion will destroy it. For this reason, the sign of the absence of the properties of surfactants of the first kind is also significant - polymethylsiloxanes and polyethylsiloxanes do not have surfactant properties.

After the explosion, new chemicals are obtained from the components of the explosive with which the identifiers should not react, i.e. they must be chemically inert to explosion products. Polymethylsiloxanes and polyethylsiloxanes are chemically inert to explosion products.

The absence of toxic properties refers to the creation of identifiers based on non-toxic and relatively harmless to humans compounds (toxicity class not higher than 3rd). Polymethylsiloxanes and polyethylsiloxanes are non-toxic (used as a component in female lipsticks).

There is a problem in the visual detection of failed charges: explosives in their color are often difficult to distinguish from blasted rock. It is proposed that the manufacturers of explosives introduce special coloring additives in their composition that sharply contrast with the colors of the rocks. Particular attention should be paid to the possibility of using UV-luminescent dyes, which, when the UV source is turned on and off (a flashing light with a UV emitter), create a clear perception contrast and facilitate the visual detection of traces of a substance with the addition of a UV phosphor.

Chemical inertness to the components of GGD solutions and the products of the chemical reaction of the interaction of explosive components with GGD: in the case of using the chemical method of gas generation of emulsion explosives, identifiers should be inert to GGD. Polymethylsiloxanes and polyethylsiloxanes are chemically inert to GHD and to the products of the reaction of GHD with explosives.

In addition, polymethylsiloxanes (PMS) and polyethylsiloxanes (PES) have hydrophobic properties - they are also used in construction, as waterproofing impregnations for wood and concrete. They have a high flash point - they are used as fire-retardant impregnations of various materials (fabrics, wood, etc.) to give them fire resistance.

PMS and PES are linear polymers with different chain lengths (different degrees of polymerization). Chemically, PMS and PES can be obtained with a strictly defined length of the polymer chain. The length of the polymer chain of PMS and PES determines the viscosity (kinematic) of these substances, which allows them to be used as viscosity standards (PMS and PES have a low temperature gradient of viscosity: their viscosity varies slightly with temperature). PMS and PES are mutually soluble and do not enter into chemical reactions with each other. PMS and PES are hydrophobic and are not washed out by water, as a result of which it is proposed to use PMS and PES with various molecular chain lengths as chemical markers (identifiers) of explosives. Mixtures thereof may also be used.

Consider the implementation of the proposed method.

Manufacturers of explosives (including emulsion ones) during their manufacture for unambiguous identification: the manufacturer of explosives, the date of manufacture, shift, time, production line and other necessary information, introduce special chemical markers into their composition. The principle of the manufacturer's coding and the date of manufacture of explosives by chemical markers based on PMS and PES is as follows. Suppose you want to mark a digital code: 4120081231

Where:

41 - manufacturer number

2008 - year of manufacture

12 - month of manufacture

31 - the day of manufacture.

To do this, you need ICP (PES):

with a viscosity of 4.100.000.000 (or the corresponding molecular chain length) is a constant component, the identifier of the manufacturer:

with viscosity 20.080.000 - year of manufacture;

with a viscosity of 1.200 - month of manufacture;

with viscosity 31 - year of manufacture.

Total: 4 samples of ICP (PES).

The residual explosives during a qualitative analysis method (for example, liquid chromatography) will show the presence of precisely these markers in it. The analysis is carried out in one stage. The sensitivity of modern liquid chromatographs reaches 10 ^-12 mg / ml, which allows the introduction of very small ("trace") amounts into the markers. In this case, the concentration of markers will not matter (namely, the determination of the concentration of the marker and the resulting errors are the main disadvantages of the prototype). Therefore, the marking composition is required to enter less than 200 grams per ton of explosives, which is a significant difference from the prototype.

To mark the above digital code, it is possible to use more markers: 4.000.000.000, 100.000.000, 20.000.000, 80.000, 1.000, 200, 30, 1.

For convenience, the year designations from “2008” can be reduced to “08” by deleting the 20.000.000 marker.

And the markers 4.000.000.000 and 100.000.000 lower to 41.000.000 and 1.000000, respectively.

Such markers with a certain viscosity (molecular chain length) can be called "discharge markers" (hereinafter - MR).

Thus, for the implementation of the method, it is necessary to have a “cash desk” in the laboratory of the manufacturer for “dialing” a chemical digital code, namely, the presence of a certain nomenclature of MPS (PES). But in very small quantities.

For example, in order to encrypt production dates at manufacturing plant No. 41, in 2008, the MRs shown in the table will be required.

The MR numbers shown in the table correspond to the brands of polymethylsiloxanes (polyethylsiloxanes):

PMS-41.000.000.000 (PES-41.000.000.000),

PMS-80.000 (PES-80.000)

And etc.

Since PMS and PES with indices of more than 100,000 are quite viscous liquids (dynamic viscosity, respectively, 100,000 cP), it is proposed that two labels be produced simultaneously: PMS and PES, i.e. their mixture.

For example, for the marking "manufacturer" take PES-41.000, and for marking the date of manufacture - MR from the PMS range:

PMS-80.000, PMS-1.200, PMS-30, PMS-1.

Or vice versa.

Since the liquids PMS-1 and PMS-2, for example, are difficult to distinguish (have close peaks in the chromatograms), it is advisable to increase the marks used for marking MR by a discharge:

PMS-12.000, PMS-300, PMS-10.

The peaks in the chromatograms from PMS-10 and PMS-20 will already differ significantly.

And the marking of the year of manufacture can be taken to the MR from the PES class: PES-80.

Thus, the technical problem of creating a reliable and simple method for chemical marking of not only explosives, but also any other materials, has been solved.

Unlike the prototype, the method is more reliable, since the decoding of the digital code of the marking composition consists only in the identification (absence-presence) of the corresponding markers, and not in determining their concentration.

Claims (4)

1. A method for marking explosives, comprising introducing into the explosive a marking composition containing identifiers, the number of which is equal to the number of technical indicators to be marked, identifiers having oil and fat solubility, chemical resistance in environments with any pH range, resistance to free radicals are introduced, chemical inertness to the components of the explosive, the lack of properties of surface-active substances of the first kind, chemical inertness to the products explosion and the absence of toxic properties, characterized in that as identifiers use polymethylsiloxanes or polyethylsiloxanes, or a mixture thereof. 2. The method according to claim 1, characterized in that when marking emulsion explosives, the marking composition is introduced into the fuel phase. 3. The method according to claim 1, characterized in that compounds of the class of phosphors are additionally introduced into the marking composition. 4. The method according to claim 1, characterized in that the marking composition has a chemical inertness to the components of the solutions of gas-generating additives and the products of the chemical reaction of the interaction of the components of the explosive with gas-generating additives.