RU2639791C1 - Marking additive to explosive, method of its preparation, method for determination of explosive origin - Google Patents

Abstract

FIELD: blasting.SUBSTANCE: marking additive contains material having electret properties and having residual polarisation obtained by means of bulk-charge polarisation of electron or ionic types. Natural mica is used as material having the electret properties. In order to prepare the marking additive, a plate made of material having electret properties is placed in electric field for electrostatic recording of information code by means of bulk-charge polarisation of electron or ion types. Then the plate with information code is ground to obtain particles of required shape and size and mixed with explosive substance. For identification, the sample is taken in polarised light, the presence of marking additive it is determined by presence of luminescence, the selected samples are placed in the form of splines in a reading device for reading the information code, the code of the marking substance is compiled and compared with available base.EFFECT: determination of explosive origin, including the manufacturer of the explosives, in the event of an unauthorised distribution of explosives or terrorism, when explosion has already occurred and only the explosion products are available.16 cl

Description

The invention relates to explosives and can be used for marking explosives (EXPLOSIVES) in order to determine the origin of the explosives, including the manufacturer of explosives, according to the code in the case of unauthorized distribution of explosives or a terrorist act, when the explosion has already occurred and are available only explosion products.

Known marking of objects (US patent, No. 3772099, 1973), marking additive containing a marking substance in the form of small material points (particles), which are made of luminescent material and added to the main explosive. This marking allows identification of explosives both before the explosion and in detonation products. This allows you to detect material points when irradiated with light with a short wavelength, ultraviolet radiation. Under the action of light radiation from an ultraviolet lamp, material points emit light in a different spectral region with a wavelength greater than the wavelength of light with which the material points are irradiated. The color gamut (spectrum) of the emitted light radiation by all material points is determined by the type of substances from which the individual material points are made. To detect material points, for example, in explosion products, they are pre-bonded with inorganic cement or a joint and form phosphor grains (conglomerate), which are added to the main explosive. Since substances of material points can react chemically with an explosive and change its properties, the marking substance of material points is coated (encapsulated) with an organic plastic such as polyethylene (US patent No. 3961106.1976).

The disadvantage of this invention is that the plastic coating of material points can lead to the electrification of explosives and the possibility of spontaneous explosion.

A marking solution is known (US Pat. No. 3,993,838, 1976), in order to prevent electrostatic charge from friction between the encapsulated material points, an antistatic coating such as amorphous carbon is proposed.

The disadvantage of this invention is that the substance that binds the material points in the conglomerate grains weakens the luminescence intensity and reduces the sensitivity of the method.

The invention is known (US patent No. 3897284, 1975) as a connecting part for material points, plates of magnetite (ferrites) are proposed to which material points are attracted by the action of a magnetic field.

The disadvantage of this invention is that after blasting may change the magnetic properties of the material, which will lead to the inability to identify explosives.

Known invention (US patent No. 4131064, 1978), in which it is proposed to use material points of magnetic material.

The disadvantage of this invention is that after blasting may change the magnetic properties of the material, which will lead to the inability to identify explosives.

Known marking additive (US patent No. 5059261, 1991) containing a marking substance inside the microcapsule, which bursts under certain conditions of shear stresses arising, for example, when an explosive explosion. The marking substance from pressurized microcapsules is squeezed under pressure into a chemical material, mixed with it, creating changes in viscosity in the mixing area, contributing to better mixing of substances.

The disadvantage of this technical solution is that it solves the problems of directional mixing, when used as an identifier for explosives, the dispersion of the identifying substance will be characteristic, since the action of the shock wave during the explosion will be more significant than the effects of molecular adhesion due to viscosity forces, taking into account the high temperature in the epicenter of the explosion. This circumstance significantly reduces the sensitivity of the method.

Known marking additive for marking a chemical product (product), including explosive materials (US patent No. 5677187 A, 10/14/1997), a chemical composition that is a foreign chemical product. The chemical composition in the prototype contains various rare elements of the Periodic system, which are dispersed at the atomic level in the chemical composition in a detectable amount and at a natural level of isotopic distribution.

The disadvantage of this solution is the high cost of the marking additive, and the known invention cannot be used to reliably determine the origin of the explosive from the products of the explosion due to dispersion of the chemical composition in the event of an explosion to an undetectable and / or suitable quantity before identification.

A known method for detecting trace amounts of impurity substances in a basic substance and an apparatus for determining the spectral characteristics of chemical elements (US patent No. 6069695 A, 05/30/2000) by laser excitation of impurity and basic substances in the form of a plasma formation, which is ejected from the substance in the form of a cone in the direction opposite to the laser beam, and the excitation transverse to the laser beam, a spark discharge of a substance ejected from the point of influence of the laser beam. The radiation from the obtained joint plasma formation is analyzed by a spectrum analyzer and the composition of impurity substances is determined, which is used to identify impurity substances.

The disadvantage is that the radiation of the plasma induced by laser radiation for the analysis of microimpurities contains a high level of background noise caused by high temperature due to the continuous bremsstrahlung of the electronic component of the discharge in the region of the effect of laser radiation on the substance containing microimpurities. Reducing background noise by reducing laser power leads to loss of sensitivity of the spectrum analyzer. A spark discharge in the transverse direction compensates to some extent the loss of sensitivity from interference, but not to the full extent, since most of the substance ejected by laser radiation does not fall into the spark discharge region due to its transverse orientation relative to the cone and the direction of action of the laser beam. This circumstance significantly limits the sensitivity of the possibility of spectral analysis of impurities in the identification of explosives and explosion products.

A known method of marking explosives (RF patent No. 2595245, publ. 08/20/2016, bull. No. 23), which consists in introducing into the explosive a marking composition containing identifiers, the number of which is equal to the number of technical indicators to be marked. As identifiers, a mixture of polyorganosiloxanes with different molecular chain lengths is used, in which each one technical indicator corresponds to an identifier in the form of polyorganosiloxane with the corresponding molecular chain length and the corresponding “retention time” (“retention”) on the chromatogram. Thus, a “chemical barcode” is formed in the composition of the explosive, the reading of which is carried out on the chromatogram on the basis of the presence or absence of a component with a certain value of its “exit” time (“retention”).

The disadvantage of this invention is the high cost of the marking substance and the high complexity of its preparation and subsequent recognition.

A known method of marking explosives (RF patent No. 2426171, publ. 08/10/2011). The method of marking explosives is implemented using a reader and a microchip, which is used as a marking additive. The reader contains a master oscillator, power amplifiers, a circulator, a horn transceiver antenna, a phase detector, a recording unit, an amplitude limiter, a light and sound beacon. The microchip contains a piezocrystal with an aluminum thin-film interdigital transducer deposited on its surface connected to a microstrip antenna and a set of reflectors. The interdigital transducer of surface acoustic waves (SAW) contains two comb systems of electrodes, buses, which connect the electrodes of each of the combs to each other. The tires are connected to a microstrip antenna.

The disadvantage of this invention is the high cost of the marking substance and the high complexity of its preparation and subsequent recognition.

A known method for marking explosives (RF patent No. 2238481, 07/10/2008, bull. No. 19). A method for marking an explosive by introducing into the explosive a marking composition in an amount of at least 200 grams per ton of explosive is proposed. The marking composition contains identifiers, the amount of which is equal to the number of technical indicators, from synthetic organic or inorganic compounds of the class of dyes and / or low molecular weight polymers from the international CAS register of chemicals with a molecular weight of less than 1000 g / mol. Moreover, it is proposed to use identifiers with oil-fat solubility, chemical resistance in environments 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, lack of toxic properties . When using compounds of the class of dyes and low molecular weight polymers, identifiers should not enter into chemical reactions with each other.

The disadvantage of this invention is the high cost of the marking substance and the high complexity of its preparation and subsequent recognition with low information content.

Known marking additive in an explosive, a method for its preparation, a method for determining the origin of an explosive and a device for its implementation, adopted as a prototype (RF patent No. 2283823, publ. 09/20/2006). A marking additive to an explosive is proposed, comprising a marking substance, a foreign explosive and retaining its properties under explosion conditions, and a substance forming an alloy with a marking substance for microencapsulation of the marking substance under explosion conditions. As a marking substance, the additive contains at least one rare element of the Periodic system (for example, lanthanide), and aluminum as a substance for microencapsulation. A method for preparing a marking additive in an explosive, a method for determining the origin of the explosive into which it is introduced, and an apparatus for determining the spectral characteristics of the chemical elements of a marking substance in an explosive are also proposed.

The disadvantage of this invention is the high cost of the marking additive and the high complexity of its preparation, as well as subsequent recognition with limited information content.

The technical result of the invention is to reduce the cost of marking additives, reduce the complexity of its preparation, as well as subsequent recognition for the organization of the initial coding system of the explosive manufacturer before and after its use for primary coding in microimpurities after the explosion with increasing information content.

The technical result is achieved in that in a marking additive in an explosive containing a marking substance, a foreign explosive and retaining its properties under explosion conditions, according to the invention, as a marking substance, it contains a material having electret properties - a natural mica having a residual polarization obtained by space-charge polarization of electronic or ionic types.

The technical result is also achieved by the fact that as a material having electret properties, muscovite is used.

The technical result is also achieved by the fact that as a material having electret properties, paragonite is used.

The technical result is also achieved by the fact that as a material having electret properties, phlogopite is used.

The technical result is also achieved by the fact that as a material having electret properties, biotite is used.

The technical result is also achieved by the fact that as a material having electret properties, lepidomelan is used.

The technical result is also achieved by the fact that as a material having electret properties, lepidolite is used.

The technical result is also achieved by the fact that as a material with electret properties, use cinnamaldite.

The technical result is also achieved by the fact that as a material having electret properties, tagnolite is used.

The technical result is also achieved by the fact that as a material having electret properties, Roscoelite is used.

The technical result is also achieved by the fact that as a material having electret properties, fuchsite is used.

The technical result is also achieved by the fact that a material having electret properties is crushed to particles of the desired shape.

The technical result is also achieved by the fact that a material having electret properties is crushed to particles of the required size.

The technical result in terms of the preparation method is achieved by the fact that in the method of preparing the marking additive in the explosive, including the operations of preparing the marking additive, it is achieved by the fact that from a material having electret properties, a plate of arbitrary shape is made, a plate is placed in an electric field for electrostatic recording of information code using space-charge polarization of electronic or ionic types, then the plate with the information code is crushed to obtain particles of the desired shape and size, after which the marking additive is mixed with the explosive.

The technical result in terms of the method for determining the origin of an explosive is achieved by the fact that in a method for determining the origin of an explosive, including sampling, determining the presence of particles of a marking additive in a sample, determining the characteristics of a marking substance, make up a code for the marking substance, identify the explosive with the marking code the manufacturer of the explosive into which the additive was introduced, for its subsequent detection, is achieved by the fact that the sample is taken in polar ovannom light marking material mounted on a shade additives glow under polarized light, samples are placed in the form of concentrates in a reading device for reading the information code marking additives comprise code marking substance and collate it with the existing base.

The technical result in terms of the method for determining the origin of the explosive is achieved by the fact that the marking code is in the form of a barcode in which the stroke width is directly proportional to the type of material or particle shape of the marking additive, and the distance between the strokes is proportional to the particle size of the marking additive.

The invention is aimed at creating a marking additive suitable for organizing an explosive coding system for its production with the aim of subsequently determining the explosive manufacturer using binary or ternary code, for example, during the removal of an explosive or in microimpurities of dust or rock after its explosion.

The complexity of the task lies in the fact that when adding a labeling substance, it is necessary to fulfill a number of requirements of industrial manufacturers of explosives. Among them, the most important are the following: the encoding substance should not change the energy properties of explosives, it should retain the ability to long-term storage, sensitivity to friction and shock, and should not lead to a significant increase in the cost of explosives. In addition, when identifying explosives, it is necessary to take into account the decrease in the detecting ability of the labeling substance due to a decrease in its concentration during product expansion at the time of the explosion, as well as the effect of background concentrations on the ground. It should also be taken into account that coding substances introduced into explosives should not be a source of environmental pollution.

The problem is solved in that the marking additive in the explosive containing a marking substance, a foreign explosive and retaining its properties in an explosion, as a marking substance contains a material with electret properties.

Electrets (materials with electret properties) are dielectrics that maintain a polarized state for a long time after the removal of the external effect that caused the polarization. If a substance whose molecules have constant dipole moments is melted and placed in a strong constant electric field, then the molecules are partially oriented along the field. When the melt is cooled to hardening and the electric field is turned off in the hardened substance, the rotation of the molecules is difficult, and they retain their orientation for a long time. An electret made in this way can remain in a polarized state for a fairly long time (from several days to many years). The first such electret was made of wax by the Japanese physicist Yeghuchi in 1922.

The residual polarization of the dielectric can also be caused by the orientation of the “quasidipoles” in the crystals (2 vacancies, migration of the opposite sign, impurity atom and vacancy, etc.), migration of charge carriers to the electrodes, and also injection of charge carriers from the electrodes or interelectrode gaps into the dielectric during polarization. Carriers can be introduced artificially, for example, by irradiating a dielectric with an electron beam. The polarization of the electret decreases with time, which is associated with relaxation processes, as well as with the movement of charge carriers in the internal field of the electret.

Almost all known organic and inorganic dielectrics can be converted to an electret state. Stable materials with electret properties can be obtained from waxes and resins (carnauba wax, beeswax, paraffin, etc.), from polymers (polymethyl methacrylate, polyvinyl chloride, polycarbonate, polytetrafluoroethylene, etc.), inorganic polycrystalline dielectrics (alkaline earth metal titanates, steatite, porcelain and other ceramic dielectrics), single-crystal inorganic dielectrics (for example, alkali metal halides, corundum), glasses and glass, mica, etc. Stable electrets can be obtained by heating di electricians to a temperature lower than or equal to the melting temperature, and then cooling them in a strong electric field (thermoelectrets), lighting in a strong electric field (photoelectrets), by radiation (radio electrets), simply placing them in a strong electric field (electrets), in a magnetic field (magnetoelectrets), when organic solutions solidify in an electric field (cryoelectrets), by means of mechanical deformation of polymers (mechanoelectrets), by friction (triboelectrets), placing the dielectric in the corona discharge field poisons (coronoelectrets). All materials with electret properties have a stable surface charge of 10 ^-8 k / cm ² . (Gubkin A.N. Electrets. M., 1961; Fridkin V.M., Zheludev I.S. Photoelectrets and electrophotographic process. M., 1960; Brown V., Dielectrics. Transl. From English, M., 1961 ; Physical Encyclopedic Dictionary. T. 5, M., 1966, p. 442; G. Leshchukin, Polymeric electrets. M., 1976.)

As a material having electret properties, natural mica can be used, for example, muscovite, paragonite, phlogopite, biotite, lepidomelan, lepidolite, cinnivaldite, tainiolite, roscoelite, fuchsite. These are natural mica, having electret properties, having a rather low cost and allowing to solve the problem of marking explosives. The following mica groups are distinguished by chemical composition:

1. Aluminum mica:

- muscovite KAl ₂ [AlSi ₃ O ₁₀ ] (OH) ₂ ,

- paragonite NaAl ₂ [AlSi ₃ O ₁₀ ] (OH) ₂ ,

2. magnesia-iron mica:

- phlogopite KMg ₃ [AlSi ₃ O ₁₀ ] (OH, F) ₂ ,

- biotite K (Mg, Fe) ₃ [AlSi ₃ O ₁₀ ] (OH, F) ₂ ,

- lepidomelan KFe ₃ [AlSi ₃ O ₁₀ ] (OH, F) ₂ ;

3. lithium mica:

- lepidolite KLi _2-x Al _{1 + x} [Al _2x Si _4-2x O ₁₀ ] (OH, F) ₂ ,

- Zinnwaldite KLiFeAl [AlSi ₃ O ₁₀ ] (OH, F) ₂ ,

- Tagnolith KLiMg ₂ [Si ₄ O ₁₀ ] (OH, F) ₂

There are also vanadium mica - Roscoelite KV ₂ AlSi ₃ O ₁₀ ] (OH) ₂ , chrome mica - chrome muscovite, or fuchsite, etc. Isomorphic substitutions are widely manifested in mica: K ^{+ is} replaced by Na ⁺ , Ca ²⁺ , Ba ²⁺ , Rb ⁺ , Cs ⁺ , etc .; Mg ²⁺ and Fe ²⁺ octahedral layer - Li ⁺ , Sc ²⁺ , In ²⁺ and others; Al ^{3+ is} replaced by V ³⁺ , Cr ³⁺ , Ti ⁴⁺ , Ga ³⁺ , etc.

Material with electret properties can be crushed to particles of a certain shape to enable the formation of a binary code.

Material with electret properties can be crushed to particles of a certain size to enable the formation of a binary code.

The range of particle size ratios of the additive to the initial particle size of the explosive is determined by the requirements for preserving the energy properties of the explosive, minimizing the losses of the marking substance during the explosion and obtaining stable traces of the substances when identifying the products of the explosion and explosives.

A method of preparing a marking additive is as follows. An arbitrary shape plate is made from a material having electret properties (for example, mica). You can also use a base with a fixed thin layer of material with electret properties. Then the plate is placed for a short time in an electric field for electrostatic recording of the information code in the form of a volume charge of effective magnitude on a material with electret properties. An information code is obtained, for example, by creating a space-charge polarization of electronic or ionic types. These types of polarization are created during a short-term exposure to an electric field and are stored in an almost unlimited amount of time. The information code is obtained by applying a charge of electrets, for example, by combining a positive, negative and neutral charge, which allows you to get a ternary code with full identification of the manufacturer of the explosive, including location, product composition, shift number, etc. This ternary code can be read from any detected marking additive particles. To read information (measure the charge of electrets), you can use known devices that work on the methods of electrostatic induction, vibration or compensation. Thus, the information content of determining the origin of an explosive increases sharply. The information code can be applied either with a needle (like on a gramophone plate, for example) or with a laser beam (like on a CD, for example). Then, the resulting plate with an information code is crushed to obtain particles of the desired shape and size, for example, in a laboratory crusher, and then the marking additive is mixed with the explosive in the factory or field conditions (for example, for marking emulsion explosives).

The method for determining the origin of the explosive is carried out according to the following.

Marking additive is sampled. This can be done directly from the explosive before the explosion, and after the explosion from rock samples or dust. In the field, some characteristics of the marking substance are determined. This is done in polarized light, for example, using polarizing glasses or a polarizing microscope. The sample is taken in polarized light to identify by the glow of the presence of particles of a marking additive in mica in this sample, the material of the marking additive is identified by the shade of the glow in polarized light (for example, each type of natural mica, depending on the chemical composition, has its own shade). If each producer uses his own type of mica, then immediately identification of the producer is possible. Next, place the collected samples in the form of concentrates in a reader for reading the information code. They compose a code for the marking substance and verify it with the existing database, or decode the encoded information in the form of a binary or secondary code. The marking agent code is composed as a barcode in which the stroke width is directly proportional to the type of material or particle shape of the marking additive, and the distance between the strokes is proportional to the size of the marking additive particles (in relative units, convenient for use).

A marking agent containing a marking agent is introduced into the explosive in a detectable amount.

The obtained marking code identifies the marking additive, the explosive and the manufacturer of the explosive into which the additive was introduced, for its subsequent detection.

The results of the study of explosion products in the form of a code are compared with the codes of explosives and codes of manufacturers of explosives. The identity of the macro sample codes and the explosive code and / or the manufacturer code of the explosive will indicate the origin of the explosive.

The use of the invention allows to preserve the energy properties of explosives and the safety of its technological storage during the introduction of the marking substance, to increase the accuracy and information content of the identification of the marking additive, explosive and the manufacturer of the explosive, to reduce the loss of marking substance in the explosion.

Thus, a marking additive in the explosive, a preparation method, a method for determining the origin of the explosive and a device that can reliably determine the origin of the explosive, including the remnants of the products of the explosion, are created.

The invention allows you to create a code and initially encode it with the explosive and the manufacturer of the explosive (before using the explosive), and using the identity of the code of the detected explosion products, for example, during a terrorist act, and the manufacturer determine the origin of the explosive.

The use of a marking additive in an explosive, a method for its preparation, a method for determining the origin of an explosive provides the following advantages:

- reducing the cost of marking additives through the use of natural materials;

- increase the mechanical strength of the filling material;

- reducing the complexity of the preparation of marking additives;

- increasing the efficiency and informative value of subsequent recognition for organizing the initial coding system of the explosive manufacturer before and after its use for primary coding in microimpurities after the explosion.

Claims (16)

1. A marking additive in an explosive containing a marking substance, a foreign explosive and retaining its properties under explosion conditions, characterized in that as a marking substance it contains a material having electret properties - natural mica having residual polarization obtained by volumetric charge polarization of electronic or ionic types. 2. Marking additive according to claim 1, characterized in that muscovite is used as a material having electret properties. 3. Marking additive according to claim 1, characterized in that as a material having electret properties, paragonite is used. 4. Marking additive according to claim 1, characterized in that as a material having electret properties, phlogopite is used. 5. Marking additive according to claim 1, characterized in that biotite is used as a material having electret properties. 6. Marking additive according to claim 1, characterized in that as a material having electret properties, lepidomelan is used. 7. Marking additive according to claim 1, characterized in that lepidolite is used as a material having electret properties. 8. Marking additive according to claim 1, characterized in that cinnvaldite is used as a material having electret properties. 9. The marking additive according to claim 1, characterized in that as a material having electret properties, tainolith is used. 10. Marking additive according to claim 1, characterized in that as a material having electret properties, Roscoelite is used. 11. Marking additive according to claim 1, characterized in that fuchsite is used as a material having electret properties. 12. Marking additive according to claim 1, characterized in that the material having electret properties is ground to particles of the desired shape. 13. Marking additive according to claim 1, characterized in that the material having electret properties is ground to particles of the desired size. 14. A method of preparing a marking additive in an explosive according to claim 1, comprising the steps of preparing a marking additive, characterized in that a plate of arbitrary shape is made from a material having electret properties, the plate is placed in an electric field to electrostatically record the information code using volumetric charge polarization of electronic or ionic types, then the plate with the information code is crushed to obtain particles of the desired shape and size, and then marking is mixed explosive additive. 15. A method for determining the origin of an explosive, including sampling, determining the presence of particles of a marking additive in a sample, determining the characteristics of a marking substance, compiling a code for a marking substance, identifying by the code of a marking additive the explosive and the manufacturer of the explosive into which the additive was added, for its subsequent detection, characterized in that the sample is taken in polarized light, set the material of the marking additive according to the shade of the glow in the polarized light e, samples are placed in the form of concentrates in a reading device for reading the information code detection agent obtained according to claim. 14, constitute the code marking substance and collate it with the existing base. 16. The method according to p. 14, characterized in that the code of the marking substance is in the form of a barcode in which the stroke width is directly proportional to the type of material or particle shape of the marking additive, and the distance between the strokes is proportional to the particle size of the marking additive.