RU2736785C1 - Odor additive for odor simulator of cyclic and heterocyclic nitrocompounds - Google Patents

Abstract

FIELD: service dog breeding.

SUBSTANCE: invention relates to field of dog breeding, namely to training dogs, and can be used for training and stating dogs of dog services used to search for explosive devices based on nitro-containing compounds. Odor flavor additive of cyclic and heterocyclic nitrocompounds contains a mixture of dinitrotoluene, trinitrotoluene, trinitroresorcine, dinitronaphthalene, trinitrophenol, benzofuroxane and an inert carrier. Content of each component of the additive does not exceed 5 wt%, and content of the inert carrier does not exceed 95 wt%.

EFFECT: proposed additive ensures prolonged memorizing of the smell of explosives by the dog on the basis of cyclic and heterocyclic nitrocompounds.

8 cl, 5 ex

Description

The invention relates to the field of service dog breeding, namely to the field of training of service dogs, and can be used for training and scenting dogs of canine services used to search for explosive devices based on nitro-containing compounds.

Most of the explosives (explosives) used in practice contain nitro groups or nitrate groups bound by carbon atoms. Explosive compounds containing a nitrate group are called nitroesters (nitroglycerin, nitroglycol, etc.), and compounds containing a nitro group are called nitro compounds (TNT, hexogen, dinitronaphthalene, etc.).

Nitro compounds, in which the hydro group is linked directly to the carbon atoms of the benzene ring, are distinguished by high chemical resistance. They are not capable of spontaneous decomposition and spontaneous combustion, their chemical composition and physical properties are very stable (they can withstand heating to the melting point without noticeable chemical decomposition). Such nitro compounds include TNT.

Compounds in which the nitro group is bonded to a carbon atom via nitrogen are physically and chemically less stable than nitro compounds and are highly sensitive and hazardous to handle. Thus, tetryl, which has a melting point of about 128 ° C, can ignite upon prolonged exposure at a temperature of 140 ° C, while TNT, which has a melting point of about 80 ° C, can withstand heating for several hours at a temperature of 240 ° C.

All nitro compounds are insoluble or slightly soluble in water, practically non-hygroscopic, waterproof, with an increase in the number of nitro groups, the explosive properties of nitro compounds increase, and their toxicity decreases.

TNT (trinitrotoluene or tol) is one of the most common chemical explosives. It is a solid with a solidification point of 80.2 ° C. TNT is obtained by nitration of toluene with mixtures of nitric and sulfuric acids (for dehydration) according to the reaction:

C ₆ H ₆ CH ₃ + 3HNO ₃ = C ₆ H ₂ (NO ₂ ) CH ₃ + 3H ₂ O.

Pure TNT consists of crystals of a rhombic shape, ranging in color from light to dark yellow. The bulk density of powdered TNT is 0.9 g /. When pressed under a pressure of about 4000 kg / density reaches 1.6 g /. Cast TNT has a density of 1.54-1.59 g /.

TNT is practically insoluble in water and has high chemical resistance. Its outbreak is usually not accompanied by an explosion. The flash point of TNT is 310 ° C. The transition from combustion to detonation is observed only when TNT is burned in a confined space or in very large quantities.

TNT is used in powder, pressed, flake, granular form, and sometimes in the form of lumps and cast charges. When sand or other solid impurities get into TNT, its sensitivity to shock and friction increases sharply, which must be taken into account when loading wells. Powdered TNT is most susceptible to initiation, and cast TNT is the least susceptible.

Powdered and pressed TNT explodes from a detonator cap or from several turns of an accident. To detonate granular or cast TNT, a more powerful intermediate detonator of TNT sticks or ammonite cartridges is required.

Alumotol. To increase the explosion energy and efficiency, aluminum powder is introduced into TNT. The optimum aluminum content in the fused mixture with TNT can be considered 15-20%. The alumotol produced by our industry contains 15% aluminum. It is advisable to use alumotol only in a water-filled state, and even better in a mixture with a solution; ammonium nitrate.

Alumotol is a powerful (heat of explosion 1240 kcal / kg), waterproof explosive with a specific gravity of 1.5-1.6 g /. The detonation speed is 6 km / s, the working capacity is 420. In blasting operations, due to the rather high cost (485 rubles per 1 ton), it is advisable to use alumotol in conjunction with cheaper explosives, using it to charge the bottom of the well. Due to the high efficiency and strong local action of alumotol, when it is used in combined charges, a good explosive working out of the open pit bottom is achieved and the quality of rock crushing is improved.

C ₆ H ₂ (NO ₂ ) NCH ₃ NO ₂

Tetrile (trinitrophenylmethylnitramine) is a light yellow fine crystalline explosive. The bulk density is about 1 g /, and the density achieved by pressing is equal to 1.68 g /. The detonation velocity of tetrile at a density of 1.63 g / is 7200 m / s. The flash point of tetryl is 190-194 ° C. When burned, even in relatively small quantities, tetryl can explode. Tetrile belongs to the category of explosives that are very sensitive to thermal and mechanical stress. An admixture of even 0.05% of sand dramatically increases the sensitivity of tetryl to impact and friction. Tetrile has a high susceptibility to detonation and transfers it very well to other explosives. Tetrile is used mainly to equip detonator caps as a secondary initiating explosive. In open blasting operations, tetryl in the form of checkers is used as intermediate detonators to initiate low-susceptible explosives.

Hexogen (cyclotrimethylenetetramine) and HMX (cyclotetramethylenetetranitramine) are similar in chemical structure and properties. RDX is a white crystalline powder, tasteless and odorless, has a high sensitivity to external influences, flash point 290. Bulk density is about 1.1 g / cm ³ . Melting point 203.5. It is almost insoluble in water.

RDX is toxic, chemically stable: signs of decomposition are noticeable at a temperature of 200. The detonation speed of RDX at a density of 1.7 g / is 8600 m / s, efficiency is 475, heat of explosion is 1500 kcal / kg. RDX is used to equip detonator caps (as a secondary initiating explosive) and detonating cords, as well as as a component of some varieties of ammonites in order to increase their power and for the manufacture of charges and torpedoes used in the shooting of oil wells.

Known (Methodical recommendations “The use of odor simulators of explosives and explosive devices for training and training of search dogs for special purposes”, Rostov-on-Don, 1998). Simulators of explosives based on organic nitrogen compounds, which are solutions of TNT and RDX in an organic solvent, in which supersaturated solutions are dipped flannel fabric, which is an adsorbent that absorbs and releases odor particles.

The disadvantages of using these simulators of explosives include the impossibility of creating a real equivalent of an explosive when using, for example, flannel fabric.

In addition, there is a rapid change in the odor of the fabric. fabric as an adsorbent has a very low sorption capacity.

Known simulators of explosives (RU, patent 2160528, publ. 20.12.2000), representing a polymolecular layer of an industrial explosive, applied to a base of sorption material, in particular, microcrystalline cellulose, or activated carbon, or silica gel, or polysorb,

The disadvantage of the known simulator is the need to apply a significant amount of explosives to the surface of the sorption material (up to 5%), which makes these simulators unsafe in some cases. In addition, special precautions must be taken when storing these simulants.

Known (RU, patent 2467564, publ. 27.11.2012) simulator of the smell of improvised explosive devices based on nitrogen-containing compounds, which is an inert carrier, on which an odorological substance is applied, which is a mixture containing aluminum powder or powder, nitrogen compounds containing ammonium nitrate , with a nitrogen content of at least 34%.

Known (RU, patent 2535113, publ. 10.12.2014) Simulator of the smell of an explosive - tetrile for training service dogs, containing a mixture of an inert carrier and an odorological substance, and as an odorological substance, a mixture containing HMX and TNT is used, and the mixture is placed in an air-permeable polymer container.

Also known (RU, patent 2526124, publ. 08/20/2014) simulator of the smell of an explosive - RDX for training service dogs, containing a mixture of an inert carrier and an odorological substance, and as an odorological substance, a mixture containing RDX and trinitrotoluene is used, and the mixture is placed in breathable polymer container.

The disadvantage of all the listed odorological substances should be recognized as a rather narrow area of application of each of them.

In the course of a search in the patent and scientific and technical literature, no analogue was found containing information about an odorological additive designed to train service dogs to search for explosives based on cyclic and heterocyclic nitro compounds.

The technical problem solved by the developed invention is to create a reliable inventory for training service dogs to search for explosives based on cyclic and heterocyclic nitro compounds

The technical result obtained by the implementation of the developed technical solution consists in ensuring the possibility of stable memorization by the dog of the smell of explosives based on cyclic and heterocyclic nitro compounds.

To achieve this technical result, it is proposed to use an explosive odor simulator based on cyclic and heterocyclic nitro compounds containing, as an odorological additive, a mixture of dinitrotoluene, trinitrotoluene, trinitroresorcinol, dinitronaphthalene, trinitrophenol, benzofuroxan and an inert carrier. Microcrystalline cellulose, silica gel, activated carbon, alumina and other carriers having a finely porous structure, including woven and nonwoven materials on natural and artificial bases, can be used as an inert carrier. The above list does not limit the nomenclature of materials used.

In preferred embodiments, the content of each of the listed components (dinitrotoluene, trinitrotoluene, trinitroresorcinol, dinitronaphthalene, trinitrophenol, benzofuroxan) does not exceed 5% by weight of the additive, and the content of the inert carrier does not exceed 95% by weight of the additive.

In a preferred embodiment of the odorological additive, the starting components to a size of less than 1 mm are mixed with an inert carrier, which, in addition to using woven and nonwoven materials, is also pre-ground.

The quantitative composition of the odorological additive of the developed composition for detecting the odor of cyclic and heterocyclic nitro compounds may vary depending on age and experience, as well as the detection limit of the odor characteristic of each particular dog. In addition, the quantitative composition of the odorological additive is influenced by the stage of preparation of the service dog for the search for an explosive based on cyclic and heterocyclic nitro compounds.

Below are examples of the implementation of the developed odorological additives simulating the smell of explosives based on cyclic and heterocyclic nitro compounds.

1. Mixed 0.5 g of dinitrotoluene, trinitrotoluene, trinitroresorcinol, dinitronaphthalene, trinitrophenol, benzofuroxan, crushed to a particle size of 0.05 mm. Mixing was carried out in a rotary mixer for 1 hour. 0.5 grams of the resulting mixture was mixed with 9.5 g of alumina. Mixing was carried out in a rotary mixer for 2 hours. The resulting mixture was placed in a plastic bag and sealed. 5 g of tetrile was placed in a similar bag and also sealed. A trained service dog found both packages in a car garage.

2. Mixed 0.3 g of dinitrotoluene, trinitrotoluene, trinitroresorcinol, dinitronaphthalene, trinitrophenol, benzofuroxan, crushed to a particle size of 0.05 mm. Mixing was carried out in a rotary mixer for 1 hour. 0.5 grams of the resulting mixture was mixed with 9.5 g of microcrystalline cellulose. Mixing was carried out in a rotary mixer for 2 hours. The resulting mixture was placed in a polypropylene container and closed with a lid. In a similar container was placed 5 g of trinitrotoluene and also closed with a lid. A trained service dog in a roadside forest belt found both containers.

3. Mixed in 0.1 g of dinitrotoluene, trinitrotoluene, trinitroresorcinol, dinitronaphthalene, trinitrophenol, benzofuroxan, crushed to a particle size of 0.05 mm. Mixing was carried out in a rotary mixer for 1 hour. 0.5 grams of the resulting mixture was mixed with 9.5 g of alumina. Mixing was carried out in a rotary mixer for 2 hours. The resulting mixture was placed in a plastic bag and sealed. 3 g of tetrile was placed in a similar bag and also sealed. An experienced service dog found both packages in the apartment.

4. Mixed each 0.5 g of dinitrotoluene and trinitrotoluene and 0.3 g each of trinitroresorcinol, dinitronaphthalene, trinitrophenol, benzofuroxan. Mixing was carried out in a rotary mixer for 2 hours. 0.5 grams of the resulting mixture was mixed with 9.5 grams of silica gel. Mixing was carried out in a rotary mixer for 2 hours. The resulting mixture was placed in a nonwoven bag of cotton fibers. 3 g of RDX was placed in a similar bag. An experienced service dog found both packages in the apartment.

5. Mixed in 0.4 g of trinitrotoluene trinitroresorcinol, dinitronaphthalene, trinitrophenol, benzofuroxan, crushed to a particle size of 10 μm. Mixing was carried out in a rotary mixer for 2 hours. The resulting mixture in the amount of 0.5 g was placed in a polypropylene bag and sealed. 5 g of tetrile was placed in a similar bag and also sealed. A trained service dog in a hostel found only a package with tetril.

Claims (8)

1. Odorological additive simulating the smell of cyclic and heterocyclic nitro compounds, characterized in that it contains a mixture of dinitrotoluene, trinitrotoluene, trinitroresorcinol, dinitronaphthalene, trinitrophenol, benzofuroxan and an inert carrier. 2. The additive according to claim 1, characterized in that the dinitrotoluene content is not more than 5% by weight of the additive. 3. The additive according to claim 1, characterized in that the content of triitrotoluene is not more than 5% by weight of the additive. 4. The additive according to claim 1, characterized in that the content of trinitroresorcinol is not more than 5% by weight of the additive. 5. An additive according to claim 1, characterized in that the trinitrophenol content is not more than 5% by weight of the additive. 6. The additive according to claim 1, characterized in that the dinitronaphthalene content is not more than 5% by weight of the additive. 7. The additive according to claim 1, characterized in that the benzofuroxan content is not more than 5% by weight of the additive. 8. The additive according to claim 1, characterized in that the content of the inert carrier is not more than 95% by weight of the additive.