RU2607701C2 - Resw cartridge and propellant charge - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: invention relates to ammunition, in particular, to remote electric-shock weapon (RESW) cartridges and propellant charges for them. RESW cartridge comprises a non-current-conductive case with a barrel channel, a shell with a current lead laying and a device for fixing on the target, as well as a propellant charge with an obturator. Barrel channel is made with a blind bottom with a thickness of at least 1.5 of the barreled channel wall thickness in the most thick section place. Inside the barreled channel there is an output of the conductive element from the external surface of the case or the current lead inside the case. Laying of the current lead is made in a solid or a deformable shell with an output and fixing of the current lead end from the laying rear end to the front end of the case. Propellant charge of the RESW cartridge is sensitive to an electric-spark and a thermal initiating pulse. Charge is a mixture of a fuel and an oxidizer. As the fuel the charge comprises dehydrated with partial thermal decomposition of potassium hexacyanoferrate(II), and as the oxidant – potassium perchlorate.

EFFECT: provided is higher efficiency of the ammunition.

14 cl, 6 dwg

Description

FIELD OF THE INVENTION

The invention relates primarily to throwing devices for remote stun guns (DESO), specifically to unitary and special purpose ammunition DESHO, can be used in other types of special weapons.

The level of technology.

Known double cartridge according to the patent of the Russian Federation No. 2351871. The cartridge consists of an inner body of polymer mass with barrel channels, in which are installed probes (shells) with devices for fixing on the target (needles with horns) and pyrotechnic propelling charges. Throwing charges in serial cartridges "BTER" and "DEK" http://www.shoker.ru/shop/accessories/bter/ http://www.shoker.ru/shop/mvd/clek/ are screwed into the thread the back of the barrel channels are plastic caps with electrodes equipped with a propelling compound, which, according to RF patent No. 2351871, uses lead styphnate (lead trinitroresorcinol) sensitive to an electric spark initiating pulse.

The electrodes of propelling charges are interconnected by a connecting conductor laid outside the inner casing. Between the barrel channels is a cavity divided by an insulating partition into two parts. In each of the two parts of the cavity (pockets) there is a laying of an electric wire (current lead) related to one barrel channel, one end of which is connected to the probe and the other to the cartridge case. The inner case is placed in the outer case and fastened to it by means of a non-separable connection (glue). The disadvantage of the cartridge is the inability to use it for firing from DESHO with special ammunition, such as arrow-shaped shells, bullets, traumatic bullets from elastic materials. The design is designed only for throwing light aluminum probes at the target, pulling the conductors behind them in flight at a speed of only 30-60 m / s, eliminating the possibility of tangling and ruptures. When fired, high-voltage electric current sources of throwing sources accelerate probes that are ejected from the barrel channels to the target. When flying probes from the pockets of the cartridge, the current lead is pulled out until the projectile hits the target and is secured to it by the device for fastening to the target. The strength of the cartridge made of a polymeric material is not designed for use as a propellant charge in a channel in amounts of more than 7-10 mg, initiating explosive (lead stifnate), which is actually detonating in the barrel channel. This does not allow to obtain significant muzzle energy of shells without mechanical destruction of the inner and outer shells of the cartridge. The probes emitted from the barrel channels are not stabilized by rotation, which means that the characteristics of their accuracy in hitting the target are small. In addition, the placement of the stacking of conductors between the barrel channels makes it impossible to place TESW devices in this place, which increases the dimensions of the weapon under such a cartridge, without giving constructive opportunities to create compact multiply charged TESWs.

As a prototype of the present invention, a unitary cartridge for throwing an electric wire according to the patent of the Russian Federation No. 2308668, described both in variants having a shot sound and in noiseless variants, was selected. In the polymer case, which is a sleeve of a unitary cartridge cartridge of the “barrelless type” weapon according to Russian terminology with an internal barrel channel, a shell is placed with laying a current lead and a device for securing it to the target and propelling charge. When fired, a propelling charge initiated by a source of electric current from DESO accelerates a projectile that is thrown from the barrel to the target. When a projectile is flying from its casing or cemented wire laying without a casing, a current-carrying wire is pulled until the projectile hits the target and is attached to it by the fixing device on the target. As a propellant charge in the cartridge, either a pyro mixture standard for many types of pyrotechnic devices is used with a small required initiation energy from an electric spark discharge pulse or from a thermal pulse of an incandescent bridge of an electric igniter. The pyro mixture is made of lead styphnate on a binder (or mixtures of lead styphnate and other nitrogen compounds, for example diazodinitrophenol, tetrazene, etc. on a binder) or a mixture of lead rhodanide and potassium chlorate on a binder. The RF patent No. 2308668 describes a mixture (in wt.%) Of thiourea - 20% and potassium chlorate-80%, which is also sensitive to a spark discharge and does not give a carbon residue that completely violates the DESO. The main disadvantage of these pyro mixtures is the high rate of increase in pressure upon initiation and the subsequent increase in the burning rate up to explosive burning, which causes the destruction of the power case of the cartridge with an increase in the weight of the considered compositions over 10-12 mg.

For lead styphnate, the cause of this phenomenon is the brisance of this compound, which is the initiating explosive with an almost instantaneous transition of combustion to detonation even in trace amounts of matter even without a shell (sleeve). For pyro mixtures on an oxidizing agent, potassium chlorate causes a rapid increase in pressure with the transition of combustion to explosive combustion even in trace amounts, this is the endothermicity of potassium chlorate, which decomposes extremely easily with heat, and the presence in the mixture of powerful reducing agents with a high affinity for potassium chlorate, such as thiocyanate lead, potassium hexacyanoferrate II, thiourea, red phosphorus (i.e., the Armstrong mixture is uniquely detonating even in micro quantities at a low speed without a shell).

The disadvantage of all of these compositions is the excessively high sensitivity to the initial initiating spark spark. These compounds have the ability to be initiated even from the discharges of static electricity accumulating on the shooter’s body under certain conditions (woolen or synthetic clothing, very dry weather, stormy weather). The decrease in their sensitivity by the introduction of inert substances or additional amounts of an oxidizing agent either reduces the propellant properties of the compositions or does not allow regulating the sensitivity over a wide range and at the same time reduces the propellant properties. The introduction of an increased amount of fuel as a diluent is also impossible, since in this case the mixture emits an unacceptable carbon or carbon-lead residue of combustion of the mixture, completely disrupting the operation of DESO.

At the same time, the sensitivity of the propellant to the initial initiating electric pulse should be not too large due to the danger of static, and not too small due to the need for reliable initiation in case of excessive discharge of the power source during operation, or a decrease in the charging capacity of the power sources (from which depends on the energy of impulses DESHO) during storage and multiple recharges. In addition to the aforementioned, an important drawback of these compositions (in addition to the composition of thiourea-potassium chlorate) is the toxicity of lead compounds released during the decomposition of pyrocompositions that fall into the air when shot in the form of aerosols and affect both the shooter and other people.

In the case of firing with compounds based on lead stifnate or lead thiocyanate-potassium chlorate, the mass of lead (in the form of an aerosol of oxides) of lead from each shot is not 6-10 mg per cartridge, that is, only 12-20 mg. Pairs of lead oxides belong to the first hazard class SN 245-71. MPC = 0.01 mg / m ³ in the working area). MPC = 0.0007 mg / m ³ (in atmospheric air). Hazard class -1, state of aggregation - A (aerosol). Only five double shots DESHO pollutes the air volume of 10,000 m ³ to MPC. Thus, the common disadvantage of the prototype cartridge and the propellant charges of the prototypes is the impossibility of using cartridges and their charges for firing from DESHO with heavy shells with an elongated current lead made of well-conducting materials (copper) for firing at long ranges. The prototype cartridge cannot be used for throwing special munitions with high muzzle energy, such as swept shells, bullets, traumatic bullets from elastic materials. The cartridge case in all versions has a through barrel channel extending from the front to the rear end of the cartridge. The back blind part in all versions is a threaded plug or a plug with a press fitting. Such options always weaken the strength of the back of the cartridge, causing either undercuts from the thread and stress concentrators both from mechanically cut threads and from cast due to uneven residual stresses when cooling thick walls and thin tops of the threads. In the case of pressing with a small length of the pressed part and a small wall thickness of the cartridge, in addition to the tensile stresses that arise, the very strength of such a connection is insufficient to withstand muzzle pressures of more than tens of atmospheres. Since the “barrelless weapon” using the indicated type of cartridges does not have a strong barrel with a chamber, which is replaced by the cartridge with the barrel channel inside itself, the destruction of such a cartridge as part of the weapon can cause injuries to the shooter with fragments of the cartridge and destroyed weapons.

Prototype cartridges are characterized by a low accuracy of hitting the target, as the shells are accelerated along a smooth barrel channel of a very short length (30-40 mm) and are not stabilized by rotation. At the same time, according to GOST R 50940-96 Rev. No. 1 "Electroshock devices. General technical conditions ”agreed with the Ministry of Health of the Russian Federation, DESHO should have a distance between the probes discharged to the maximum length of conductors - not more than 300 mm. In modern DESHO, the length of the conductors reaches a length of 4.5 m to 11 m. With such lengths of the conductors, the expansion along the vertical and horizontal axes is not stabilized by the rotation of the probes, which pull the laying of the conductors and are released from short stems even at a distance of 4.5 m, has a value of 0.5 m or more. PCT application WO / 2009/025575 A1 (PCT / RU2007 / 000456) describes a DESO cartridge with helical rifling in the barrel channel and a projectile with ready-made protrusions. Such a device is permissible only when throwing light shells, when using heavy shells of increased range with a current lead or kinetic shells with high muzzle energy, rifling serve as stress concentrators in the barrel channel, to a large extent increasing the probability of its destruction under the influence of enhanced propellant charges.

When scattering probes, a large component of the expansion is always obtained along the vertical axis, due to the impossibility of accurately obtaining the same speed of the probes on the trajectory and a large drop in the trajectory due to the low speed of the probes. PCT application WO / 2009/025575 A1 (PCT / RU2007 / 000456) describes a method for adjusting the DESO, which allows to reduce the angle of vertical expansion of the probes. However, this method turned out to be difficult to implement in a real DESHO device and is not currently used.

Disclosure of invention

The invention is aimed at solving the problem of creating a cartridge with an unstable polymer body, which makes it possible to obtain increased muzzle energy and accuracy of a shot for throwing both heavy shells with a conductive cable over long distances, and special types of shells with minimum weight and dimensions in ordinary and silent versions.

The essence of the invention lies in the fact that the DESO cartridge containing a non-conductive sleeve with a barrel channel, a projectile with laying a current lead and a device for securing it to the target, a propellant charge with a shutter, contains one or two barrel channels made with a blind bottom with a thickness of at least 1.5 wall thickness of the barrel channel at the thickest section location having a smooth transition to the walls of the barrel channel; inside the barrel channel, the exit of at least one conductive element from the outer surface of the sleeve or current lead in those of the liner, the barrel channel has the orientation of its axis relative to the axis of the liner according to the conditions of external ballistics and the internal structure of the channel, laying the current lead in a solid or deformable shell with the outlet and securing the end of the current lead from the rear end of the installation to the front end of the sleeve, or a kinetic striking element, throwing charge with improved ballistic characteristics, a shutter with a conductive element, or combined with a propellant charge, a shutter with a conductive element or propellant a battery and a shutter with a conductive element, which are separate assembly units, or a propellant charge and a shutter with a conductive element, or a shutter with a conductive element, are part of the projectile.

An additional feature is that at the point of transition of the dead bottom to the wall of the barrel channel, a radius transition is made with a radius of not less than 1/4 of the wall thickness of the barrel channel in the thickest section section.

An additional feature is that a metal electrode, a conductive film or coating, or a small diameter hole is used as a conductive element. An additional feature is that the axis of the barrel channel is parallel to the axis of the sleeve or has an angular difference of 0.1-5 ° with the axis of the sleeve.

An additional feature is that the barrel channel is arranged in the form of an elliptical channel with a Lancaster drill along the entire length.

An additional feature is that the barrel channel is arranged with a Fosbury type cut, having a length of no more than 2/3 of the total length of the barrel channel from the muzzle of the channel to the blind bottom of the channel.

An additional feature is that the barrel channel is arranged with an internal annular recess at the end of the channel, and in the annular recess, or annular recess of the obturator, combined with a propelling charge, or on top of them in the receiver channel is a spring split ring.

An additional feature is that the end of the laying current lead is bent 180 ° relative to the plane of the rear end face of the laying and laid along the laying body with a direction to the front end of the sleeve, then it is bent 180 ° relative to the plane of the front end of the sleeve and laid along the body of the sleeve with the direction to the rear the end face of the cartridge case in the hole in the body of the cartridge case with access to the recess on the surface of the cartridge case or in the recess outside the body of the cartridge case, then rotated 180 ° with the direction to the front end of the cartridge case, reaches the plane the front end of the sleeve and is secured in the sleeve adhesive fastening hub or wedge-shaped element or the clamping element. An additional feature is that the end of the current lead on the plane of the front end of the sleeve is adjacent to the conductive coating of the front end of the sleeve.

An additional feature is that the conductive elements with the exit from two barrel channels are interconnected by an electric current conductor, laid outside the rear end of the sleeve or inside the body of the cartridge case.

An additional feature is that the sleeve has external protrusions on the body or depressions in the body.

The propellant charge of the DESHO cartridge, which is sensitive to an electric spark and thermal initial initiating pulse, consisting of a mixture of fuel and an oxidizing agent, has improved ballistic characteristics, contains, as fuel, a partial thermal decomposition of potassium hexacyanoferrate II, and as an oxidizing agent, potassium perchlorate containing components, wt.%:

Potassium perchlorate 55-85 Potassium hexacyanoferrate II (dehydrated partially decomposed) 15-45 preferably wt.%; Potassium perchlorate 70-75 Potassium hexacyanoferrate II (dehydrated partially decomposed) 25-30

An additional feature is that the charge additionally contains a phlegmatizer-oxidizer of potassium nitrate with a content in the mixture, wt.%, From 0.1 to 10.0.

An additional feature is that the charge additionally contains a binder with a content in the mixture, wt.%, From 0.05 to 5.0.

Brief Description of the Drawings:

Figure 1. External view of the cartridge.

Figure 2. A section of a cartridge with a DESO shell according to claim 1; item 2; item 3; item 4; item 8; item 9; claim 11 and claim 12 of the claims.

Figure 3. A section of a cartridge of silent action with a DESO shell according to claim 1; item 2; item 3; item 7; item 8; item 9; claim 11 and claim 12 of the claims.

Figure 4. Section of a cartridge of silent action with a DESHO shell during a shot.

Figure 5. The external view of the double (with two barrel channels) cartridge according to claim 1; item 2; item 3; item 5; claim 10 and claim 12 of the claims.

6. A section of a cartridge with two barrel channels with a swept projectile according to claim 1; item 9.

Figure 1. The polymer sleeve 1, a split plug 2 of the barrel channel, the ending 3 of the conductors, drops 4 glue.

Figure 2. The polymer sleeve 1 with the barrel channel 5 has an angular difference of 0.1-5 ° axis of the sleeve with the axis of the channel. A metal electrode 7 is installed in the dead bottom 6 of the channel, which can be replaced by an ultra-thin hole with a diameter of 0.001-0.1 mm (hereinafter die), and a propellant charge 8 combined with a throwing gas trap 9 having an electrode 10 or an ultra-thin hole. A projectile 11 with a retention device on the target, for example, a needle with a horn 12 and with laying inside its current lead (not shown in the drawing due to the variety of laying types), is installed in the barrel channel. The end of the current lead 13 is rotated 180 ° relative to the rear end of the projectile, passes along the body of the projectile, bends at the exit from the sleeve 180 ° relative to the front end of the projectile, then is again bent 180 ° and goes to the front end of the sleeve in the form of a tip 3 (see Fig. .1) to the conductive coating 14 (e.g., metallization or conductive paint coating) of the end face. The current lead is secured in the sleeve, for example, by drops of glue 4 (see Figure 1).

In front of the projectile one of the sectors of the split plug 2 is shown.

Initiation of a propellant charge is carried out by a high-voltage spark-striking electrical discharge DESHO.

The angular divergence of the barrel channel with the axis of the sleeve 0.1-5 ° is performed in order to compensate for the expansion of the probes along the vertical axis of the shot due to the fall of the probe on the trajectory. Depending on the design of the TESA and the initial exposure of the point where the probes hit the target, both a pair of cartridges with angular compensation (reducing the axes of both barrel channels to the center of the aiming point) and only one lower TESA cartridge with compensation for lowering the trajectory can be used, i.e. the direction of the axis of the barrel channel up to the target relative to the axis of the sleeve. On the outer surface, the cartridge may have protrusions or depressions of various shapes for interaction with the mechanical elements of the DESO fixing or moving the cartridge. Figure 3 The silent-action cartridge consists of a polymer sleeve 15 with a barrel channel 16, in which a propellant charge is installed, combined with a shutter 17 of throwing gases. An annular recess is made on the obturator, in which a compressed radially spring split ring 18 is laid with an expanded diameter greater than the inner diameter of the barrel channel. At the beginning of the barrel channel 16, an internal annular recess 19 is made. In the barrel channel, a projectile 11 with a current lead is installed. The front of the projectile depicts one of the sectors of the split plug 2. Figure 4. When fired, a burnt propellant pushes the obturator 17 with the split ring 18 and the projectile 11 through the barrel channel 16. When the ring 18 gets into the inner annular recess 19 of the barrel channel, the ring is unclenched, abuts against the end face of the recess 19 and does not allow the obturator 17 to exit the barrel channel , which in turn also abuts against the decomposed ring 19 with the end face of its annular recess. The projectile 11 flies out of the barrel channel and flies toward the target, unwinding the laying of the current lead, and the obturator 17 with the ring 19 remain in the barrel channel, and the obturator shuts off the combustion gases of the propellant pyro-composition. The so-called "shot gas cut-off" occurs, which almost completely eliminates the sound of the shot. The front of the projectile shows the divided sectors of the split plug 2.

Figure 5. Polymeric double sleeve 20 with a jumper between the barrel channels, breakthrough conductive membranes 21. The arrow-shaped projectile 22 assembly (boom body and obturator) is shown nearby.

6 In a polymer double sleeve 20 with two barrel channels 23 with a Lancaster drill (small ellipse and pitch are not visible), at the bottom of which propellant charges are pressed into the cavities 24. Sealants 25 with a die 26 are installed on top of the charges, while being deformed when loading in barrel channels obturator 25 are simultaneously the tail of the bodies 27 swept shells. During casting, a metal conductor 28 is laid in the body of the polymer sleeve 20, with its ends extending to the bottom of the cavities to accommodate propellant charges.

When fired, high voltage initiating potentials are applied to the front ends of the metal swept shells. The supply of high voltage from the DESO combat electrodes to the ends of the shells can occur both through the breakdown of air gaps to the ends of the shells, and the laying of thin wire, tracks of conductive paint or conductive membranes in the barrel channel. High voltage passes through the bodies of the swept elements, after which the spark discharge pierces the air gaps of the dies, then the propellant layers are closed on the conductor 28. The propellant charges 24 are initiated, the combustion gases of the pyrocomposition of the propellant charge accelerate the swept elements in the barrel channels at the same time giving them what is accepted for lancet and elongated rocket shells of rotational motion, with a small number of revolutions, determined by the large increment of Lancaster drilling and muzzle velocity.

With small steps of cutting, projectiles (bullets) of the usual length, including traumatic effects, can be stabilized. Lancaster drilling is performed to stabilize the projectile by rotation to completely eliminate stress concentrators from rifling along the entire length of the barrel channel.

Fosbury cutting in the front of the sleeve is performed to stabilize the projectile by rotation, with the exception of stress concentrators in the most loaded pressure force when firing the "breech" part of the barrel channel. To obtain the response shape of the projectile corresponding to the shape of the leading channel of Fosbury, a deformable DESHO projectile is used according to the patent for utility model of the Russian Federation No. 105020 (application: 2010151520/11, 12/16/2010), but can be molded when loaded directly in the barrel channel, and during molding the deformable material the shell fills the grooves of the trunk channel. To obtain the reciprocal form of kinetic shells corresponding to the shape of the Lancaster or Fosbury lead channel, the tail parts of arrow-shaped shells from deformable polymers preserving the deformation form (for example, fluoroplastic) of a soft lead bullet or an inelastic (non-elastic) deformable material like plasticine are used, crude rubber, etc. To increase the specific load of the bullet, such materials may contain powders of heavy metals and their compounds (for example, tungsten).

Unlike a projectile with rifled shells, according to PCT application WO / 2009/025575 A1 (PCT / RU2007 / 000456), the shells for the Fosbury and Lancaster slices do not have ready reciprocal rifling and they are formed directly in the barrel channel when loading and inertial loads at the beginning of movement projectile when fired.

To obtain the proposed pyrotechnic propellant mixture, it is necessary to use exclusively hexacyanoferrate II (yellow blood salt) dehydrated with partial decomposition of potassium.

In the delivery state (technical product) it is K ₄ [Fe (CN) ₆ ] ⋅ 3H ₂ O trihydrate. For use in the composition, only a salt of the composition K ₄ [Fe (CN) ₆ ] with products of partial thermal decomposition of the salt is used. The amount of withdrawn water (physical and chemical moisture) from 100 g of technical K ₄ [Fe (CN) ₆ ] -3H ₂ O trihydrate is 27.6 g, that is, the amount of dehydrated (K ₄ [Fe (CN) ₆ ] obtained out of 100 g of the starting trihydrate, this is 72.4 g. The practically necessary amount of withdrawn water to obtain the product needed to obtain the indicated properties of the mixture significantly exceeds the theoretical value of the water content, both chemical and physical, in the composition of the trihydrate. in dehydrated K ₄ [Fe (CN) _6] are present and n odukty further thermal expansion, such as iron carbide, tsianovokisly potassium, elemental iron propellant properties are optimal mixture composition, wt.%.:

Potassium perchlorate 70-75 Potassium hexacyanoferrate II dehydrated 30-25

Due to the predominant use of the shock DESHO electrospark discharge for initiating propellant charges of DESHO cartridges, the proposed experimental mixtures were initiated by an electrospark discharge with a breakdown length in air sufficient to break down a layer of a compacted mixture or a mixture on a nitrocellulose binder with a thickness of at least 2-3 mm. The mixtures are faultlessly initiated by single high-voltage electric spark pulses with the following characteristics: Uimp = 4.5-5 kV; timp = 10 ns; Eimp = 0.00005 J. The initiation energy below the indicated value was not used due to the difficulty in obtaining electric spark discharges with lower energy.

With a very high sensitivity to electric spark and thermal impulse, not different from the sensitivity of the compositions indicated as a prototype, the sensitivity of the proposed mixture to mechanical stress (shock, friction) is an order of magnitude lower than that of substances and mixtures of prototypes. However, when additional potassium nitrate is introduced into the mixture, its sensitivity to the action of an electric spark and thermal pulse decreases sharply. Potassium nitrate, which requires a large amount of heat for decomposition, serves as a powerful phlegmatizer for the proposed mixture, while being an oxidizing agent, and does not reduce its propellant properties to its content in the mixture up to 10% by weight.

Introduction to the mixture of potassium nitrate allows a wide range to adjust the sensitivity of the proposed composition to the spark and thermal impulse. When potassium nitrate is added to the mixture in an amount up to 5%, the mixture is not even initiated by high-voltage electric pulses of 1-1.5 J. Such widest limits for regulating the sensitivity of the mixture allow the production of propellant charges of DESO cartridges with the necessary sensitivity limits, depending on the operating conditions of the DESO ( dry climate, increased safety requirements for static charges, requirements for the initiation of TESHO power sources when discharged). After making up the mixture and equipping it with cartridges or seals, it is necessary to take measures to seal the mixture with a varnish, polymer, stanolevoy protective film, due to the slightly higher hygroscopicity compared to the prototype mixtures.

With proper sealing of the proposed mixture, its lifespan is unlimited.

The proposed pyrotechnic mixture as a propellant charge has improved ballistic characteristics compared to the prototype, which consists in the possibility of increasing the weight of the propellant charge by more than 5-8 times compared to the weight of the prototype compositions. Testing of the new pyro mixture as a propellant charge of DESHO cartridges was carried out on cartridge cases made of the most durable injection molded materials polyformaldehyde (ROM) and polyamide (RA) Armamide according to the conditions of tensile strength and impact strength (including with notch) ", Polycarbonate (PC) Bayer Material Science AG" Makrolon ". The caliber of the barrel channel of the experimental cartridges is 8 mm, the wall thickness of the barrel channel is 2 mm, the length of the upper part of the barrel channel is 52 mm. Muzzle energy of shells of the same mass propelled by substances and prototype mixtures did not exceed 2-4 J, with 7-10 mg weighed. An increase in the weight of the sample to 15–20 mg caused 100% destruction of the cartridge cases made of ROM and RA materials and 20% of the PC material with a barrel channel wall thickness of 2 mm. At the same time, when weighed 20 mg of lead styphnate, the muzzle energy did not exceed 10-12 J. When replacing the prototype compositions with the proposed composition, the destruction of the cartridge cases made of ROM and RA materials occurred when weighed more than 50 mg. With a 50 mg sample, the muzzle energy of the projectile was 38 J. The Makrolon PC cartridge shells survived without damage the 8-fold sample (80 mg) of the proposed propellant piercing device, showing muzzle energy with a 64-70 J. arrow projectile. PC case destruction Makrolon with a barrel channel wall thickness of 2 mm occurred only with a 10-fold hitch of the proposed propellant composition and muzzle energy of more than 80 J.

The advantage of the new propellant charge in this way is the ability to receive muzzle energies on the polymer barrel channel of small thickness approaching the muzzle energy of short-barreled small-caliber firearms (cal. 5.6 mm) and have a larger margin of safety for the cartridge case with the same wall thickness with the cartridges described in as a prototype of pyrotechnic propellants, which dramatically increases safety when using DESHO.

Claims (15)

1. The DESHO cartridge containing a non-conductive sleeve with a barrel channel, a projectile with a current lead and a device for securing it to the target, a propellant charge with an obturator, characterized in that the cartridge contains one or two barrel channels made with a blind bottom with a thickness of at least 1.5 the wall thickness of the barrel channel at the thickest section location having a smooth transition to the walls of the barrel channel; inside the barrel channel, at least one conductive element exits from the outer surface of the sleeve or current lead in the body of the sleeve the olny channel has the orientation of its axis relative to the axis of the sleeve according to the conditions of external ballistics and the internal structure of the channel, the laying of the current lead in a solid or deformable shell with the exit and fixing of the end of the current lead from the rear end of the laying to the front end of the sleeve, or a kinetic damaging element, propellant charge, shutter with a conductive element, or a shutter with a conductive element combined with a propellant charge, or a propellant charge and a shutter with a conductive element, which are separate assembly units, or propelling charge and a shutter with a conductive element, or a shutter with a conductive element are part of the projectile. 2. The cartridge according to claim 1, characterized in that at the point of transition of the dead bottom to the wall of the barrel channel, a radius transition is made with a radius of not less than 1/4 of the wall thickness of the barrel channel in the thickest section section. 3. The cartridge according to claim 1, characterized in that a metal electrode, a conductive film or coating, or a small diameter hole is used as a conductive element. 4. The cartridge according to claim 1, characterized in that the axis of the barrel channel is parallel to the axis of the sleeve or has an angular difference of 0.1-5 ° with the axis of the sleeve. 5. The cartridge according to claim 1, characterized in that the barrel channel is arranged in the form of an elliptical channel with a Lancaster drill along the entire length. 6. The cartridge according to claim 1, characterized in that the barrel channel is arranged with a Fosbury type thread having a length of not more than 2/3 of the total length of the barrel channel from the muzzle of the channel to the blind bottom of the channel. 7. The cartridge according to claim 1, characterized in that the barrel channel is arranged with an internal annular recess at the end of the channel, and in the annular recess of the obturator, or the annular recess of the obturator combined with a propelling charge, or on top of them in the barrel channel there is a spring split ring. 8. The cartridge according to claim 1, characterized in that the end of the stacking conductor is bent 180 ° relative to the plane of the rear end face of the stack and laid along the laying body with a direction to the front end of the sleeve, then bent 180 ° relative to the plane of the front end of the sleeve and laid along the body sleeves with a direction to the rear end of the cartridge case in the hole in the body of the cartridge case with access to the recess on the surface of the cartridge case or in the recess outside the body of the cartridge case, then rotated 180 ° with the direction to the front end of the cartridge case reaches the front plane ca sleeve and fixed to the liner with glue, fastening hub or wedge-shaped element or the clamping element. 9. The cartridge according to any one of claims 1, 8, characterized in that the end of the current lead on the plane of the front end of the sleeve is adjacent to the conductive coating of the front end of the sleeve. 10. The cartridge according to claim 1, characterized in that the conductive elements with the exit from two barrel channels are interconnected by an electric current conductor laid outside the rear end of the sleeve or inside the body of the cartridge sleeve. 11. The cartridge according to claim 1, characterized in that the sleeve has external protrusions on the body or depressions in the body. 12. The propellant charge of the DESHO cartridge, sensitive to an electric spark and thermal initial initiating pulse, consisting of a mixture of fuel and an oxidizing agent, characterized in that the fuel contains hexacyanoferrate (II) dehydrated with partial thermal decomposition of potassium, and potassium perchlorate containing components, wt. %: Potassium perchlorate 55-85 Potassium hexacyanoferrate (II) dehydrated partially decomposed 15-45 preferably wt.%: Potassium perchlorate 70-75 Potassium hexacyanoferrate (II)  dehydrated  partially decomposed 25-30 13. The propellant charge of the DESHO cartridge according to claim 12, characterized in that it further comprises a phlegmatizer-oxidizer of potassium nitrate with a content in the mixture of from 0.1 to 10.0 wt.%. 14. Throwing charge cartridge DESHO according to any one of paragraphs. 12, 13, characterized in that it further comprises a binder with a content in the mixture of from 0.05 to 5.0 wt. %

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