RU2758476C1 - Small-bore electroshock bullet and cartridge for its use - Google Patents

Abstract

FIELD: weaponry.

SUBSTANCE: small-caliber electroshock bullet contains a housing, a power supply, a switch, a DC voltage converter of a power supply into an alternating or impulse voltage, a shock absorber, electrodes in the form of needles. Inside the case there is a battery, which is made up mainly of thin-film microgalvanic cells, accumulators or supercapacitors. An axial conductive needle with an electrically insulating coating along the length of the needle and an uncoated front end with a device for fastening to the target and an inertial or pyrotechnic device for extending the needle outside the body of the body when throwing a bullet or after hitting a target is located inside the body along the axis of the body of the body. The electroshock cartridge contains a sleeve, a propelling powder charge, and an electroshock bullet. The electroshock cartridge contains a sleeve, a propelling powder charge, and an electroshock bullet. At the front end of the shell generatrix of the liner there is a radial hole passing through the shell wall and elongated along the liner axis; inside the shell of the liner there is a running cylinder, one bottom facing the bottom of the liner and having a hole in the bottom of the shell of the cylinder. An electroshock bullet is placed in the travel cylinder.

EFFECT: creation of an electroshock bullet with increased efficiency of immobilization of bio-targets and a cartridge for its use in semi-automatic pistols and long-barreled weapons.

15 cl, 13 dwg

Description

The technical field to which the invention relates

The invention relates to a remote electroshock weapon (DESHO) of non-lethal action with an electric weapon for use against offenders and aggressive animals by law enforcement officers and citizens.

State of the art

The TASER XREP electroshock bullet from Taser International (Axon Enterprise Inc.) according to the patent [1] and information [2] was chosen as an analogue of the alleged invention. At the present time, it is the only sample of a serially produced electroshock bullet in the world. The bullet has a body, consisting of two parts connected before and during the shot, but having the possibility of separation after hitting the target parts. In most of the case, there is a power source (an electric battery or accumulator) and a generator of an electric current that damages a biological target (target, bio-target, offender). On most of the body, folding aerodynamic stabilizers (wings) are also installed, and (or in another version, pointed needles) to which one pole of the damaging electric current generator is connected. The second pole of the generator of damaging electric current is connected to an elongated conductor and a strong leash, which are connected to pointed electrodes attached to a smaller part of the body (bullet head). When fired by a bullet from a smoothbore gun of 12th hunting caliber with a weakened powder charge, the bullet flies into the target. At the same time, the aerodynamic stabilizers, pressed against the body before the shot, fold back and aerodynamically stabilize the bullet in flight to the target. Upon hitting the target, the pointed electrodes of the head are stuck into the bio-target, as a result of hitting the target, the bullet is divided into two parts, while the head remains stuck in the place of impact, and most of the bullet is detached from the head and hangs on a leash along the body of the bio-target. In this case, the damaging electric current of the generator of the damaging electric current that is turned on when the shot is fired passes into the body of the bio target along the current loop between the electrodes of the head and the conducting aerodynamic stabilizers or needles of the greater part of the body.

In the patent [1] it is noted that: "Without the present invention, electroshock bullets will not be widely used in military, law enforcement and defense purposes." However, the TASER XREP bullets under the patent [1] themselves did not receive any significant distribution among law enforcement agencies even in the United States, and even more so, did not receive distribution in the world, despite all the attempts of Taser International (Axon Enterprise Inc.) to promote them. to the world market. The main disadvantage of the analogue is the large weight of a large-caliber bullet having a 12th hunting caliber (18.53-18.9 mm), which does not make it possible to use a bullet at short distances due to the fact that at short distances, at which, according to statistics, most cases occur When using non-lethal weapons, the muzzle energy of a bullet should not exceed 50 J. Since a large muzzle energy causes "commotio cordis" at the target [3]. At the same time, for a long range of use for flatness of the trajectory, the muzzle energy of the bullet is much higher than 50 J. Thus, attempts to use a bullet at short distances (which inevitably arise in police conflicts with offenders) will lead to mechanical injuries up to "commotio cordis", which is incompatible with the concept of “non-lethal weapon”. The output electric power of the destructive electric current generated by the generator of the destructive electric current of the bullet is extremely low and insufficient for the immobilization of bio-targets. In addition, the analogue bullet has an unacceptable cost for use (160 $ USA for 1 pc.) Due to a complex device and an expensive generator of damaging electric current. At the same time, the bullet has no proven effectiveness of the effect (immobilization) on the bio target. In the media, there is not a single video of the actual use of the TASER XREP bullet by the police in hundreds of videos of the use of wired stun guns from Axon Enterprise Inc. In the only resonant case of the use of TASER XREP on an offender since 2011 [4] "Expert: Taser no part in Raoul Moat death", the TASER XREP bullet did not have an immobilizing effect on the offender.

As a prototype, a bullet with electrodes extended from the inside of the body was selected according to US5698815A [5], FIG. 8A and 8B. The bullet has a housing in which a source of electricity is located in the form of an electric battery, electrodes with sharp ends are located on the housing or in the housing; in versions of the bullet, a DC voltage converter of the power supply into an alternating or impulse voltage is also used. A bullet is fired from a rifled firearm and, when it hits the bio-target, is stuck into it with sharp electrodes located on the body or pulled out of the body under the action of inertial forces. A constant or pulsed electric current from an electric power source passes through the electrodes to the biocele, which has a damaging (immobilizing) effect on the biocele.

Lack of FIG prototype bullet. 8A and 8B is that between the electrodes pos. 86 and 86 'by the inertial introduction of a bullet of the specified 9 mm caliber (see below) into the bio target body, only a very small current loop (current path) can be formed, which inevitably causes, respectively, only a weak physiological effect of the current. In the design of the prototype, the current path passes almost immediately between the electrodes introduced into the body of the biocele after the epidermis in the dermis, and not along the path between the ends of the electrodes embedded into the body of the biocele. Since the thickness of the epidermis is from 0.1 mm to 2 mm (on average 1 mm), then between the electrodes introduced into the body of the biocele, the path of the current in the dermis pierced by nerve endings will be from 9-10 mm, at what distance the tips of pos. 88 and 88 'of the bendable electrodes no longer matter. In addition, the extension of the electrodes in the FIG. 8A and 8B occurs simultaneously with the deceleration of the bullet on the target and thus the body of the bullet rotates when the electrodes are extended. Due to the large torque, bending and breakage of the electrodes extended into the body of the bio target is inevitable, or the inertial extension is slowed down to such an extent that the electrodes cannot be extended to the calculated length. The prototype bullets described in [5], the electrodes obliquely located relative to the bullet axis, are effective only if the bullet velocity coincides with the angular velocity of rotation at the angle of the rifling pitch in the weapon for shooting bullets, but this is impossible, since the bullet always loses its forward velocity much faster than the angular velocity of rotation. If the indicated speeds do not coincide, the electrodes will be subjected to fracture and deceleration in the body of the bio-target.

The patent [5] indicates the "standard 9-mm cartridge" used for the declared electroshock bullets, that is, the most widespread cartridge 9x19 Para (9 mm NATO) of 9 mm caliber, (standard 9 mm cartridge; standard firearm) weight of a standard bullet in which it is 6.0-9.5 g (average 7.75 g). Such a bullet for electroshock bullets can be considered small-caliber, since the only TASER XREP electroshock bullet produced in the world had a caliber of 18.53-18.9 mm. A bullet according to (FIGS. 8A and 8B) with the indication of the "standard 9 mm cartridge" and the drawing of a standard pistol cartridge case may have a similar weight to a standard pistol bullet due to the known and significant weight of the known types of power sources (batteries) included in the bullet.

The muzzle energy of a bullet at a speed of 115 m / s and a bullet weight of 7.75 g exceeds 50 J. The impact energy of a bullet equal to or exceeding 50 J in the region of the heart of the bio target causes "commotio cordis" [5]. In this case, the specific energy of a 9 mm caliber bullet with a muzzle energy of 50 J is 0.781 J / mm2, which already exceeds the permissible specific energy of 0.5 J / mm2, taken as the specific energy of projectiles, which does not bring serious mechanical injuries. Thus, according to the criterion of the permissible specific energy of projectiles that do not bring serious mechanical injuries, the speed of a bullet weighing 7.75 g cannot exceed 90 m / s. The bullet electrode [5] (FIGS. 8A and 8B) is 25 mm long and 0.8 mm in diameter (the standard diameter of the DEShO electrode needles) has a weight of only about 0.1 g. 90 m / s will be only 0.0009 kg⋅m / s. In this case, the shock absorber pos. 94, located in the bullet head, is flattened against the target and squeezing the retractable electrodes due to friction against the shock absorber under load will further reduce the impulse to extend the electrodes. With such an insignificant impulse, the introduction of an electrode into a biocoel, moreover, taking into account also the friction of the electrodes in the guiding oblique channels, at least 5-10 mm long, seems to be practically impossible. Mentioned in [5] by FIG. 8A and 8B, the supposedly achievable distance between the tips of the needles (after impact (bullet on the target): "from one to two inches") is generally unattainable both due to the lack of impulse of the pistol cartridge 9x19 Para with a total length (together with a bullet) of 29.7 mm, it is simply physically impossible to place electrodes that extend to a distance of 25-50 mm between them. 84 and 84 'since the calculated pulse of the electrodes is not enough even for full penetration into the biocoel, and, accordingly, it is still far from enough for wedging and fixing the connectors 85 and 85' in the rings at positions 84 and 84 '. 8A and 8B the supposedly achievable distance between the tips of the needles (after impact (bullet on the target): "from one to two inches") is completely unattainable at all due to the fact that in a standard pistol cartridge (cm. below) with a total length (including the bullet) of 29.7 mm. it is physically impossible to place electrodes that move apart at a distance of 25-50 mm between them. Declared in the patent [5] shock absorber pos. 94 cannot work at all, since when hitting the target, its expansion with energy absorption is prevented by the housing 90, and thus the shock absorber 94, compressed in the housing 90 without the possibility of expanding to the sides to increase the impact area, increases its density and compressing the electrodes pos. 86 and 86 'only inhibits their exit of the electrodes from the body of the bullet, further reducing the possibility of introducing a bio target into the body. In this case, the front sharp edge of the body 90 will inevitably cause an annular cut or crushing injury to the biological tissues of the target's body.

With an increase in the caliber of a bullet (and hence its weight), the bullet velocity, with the obligatory condition for non-lethal weapons that it is impossible for a "commotio cordis" to occur or that the safe specific energy of 0.5 J / mm2 is exceeded, should be even less than 90 m / s, which is even more reduces the possibility of inertial introduction of the electrode into the biocoel through a layer of clothing and especially dense or leather.

Lack of FIG prototype bullet. 8A and 8B is also that the FIG. 9 [5] due to the fact that FIG. 8A and 8B the volume of the battery or accumulator pos. 100 together with a storage capacitor pos. 104 and the arrester pos. 106 should occupy no more than 1/4 of the sleeve volume (like the battery of pos. 80) due to the fact that 2/4 of the sleeve volume is used only to accommodate the inserted electrodes, and about 1/4 is the volume of the powder charge. With such a small ratio of the volume of a bullet with an electronic electric shock part (mainly with the volume of a power supply (battery) with a total volume of a standard pistol cartridge of 9 × 19 Para, it is impossible to obtain the physiological effect indicated in the patent [5] on the target, even under the condition of a large the current loop of which, as indicated above, is already small (only 9-10 mm).

In the patent [5] criticizing analogs (Shimizu devices) it is noted: "The above devices are not particularly effective, which can be confirmed by the fact that none of them have been very successful in the commercial market." company Taser International (Axon Enterprise Inc.), just like the Shimizu device did not have any success in the commercial market (although the said company, the world leader in electric shock weapons, had all the possibilities of both the technical implementation of the patent [5] and all the possibilities of commercial implementation on the world market), which can serve as decisive proof of the impossibility of obtaining at least any efficiency of the operation of an electroshock bullet under a patent [5]. Even prototypes of such a bullet are not known.

The total internal volume of the 9x19 Para cartridge with a bullet is about 2 cm3. Power source (battery) of a bullet according to FIG. 8A and 8B occupies about 1/10 of the cartridge volume, i.e. 0.2 cm3 (0.0002L). With the energy density of modern lithium batteries and accumulators of about 800 Wh / L (or about 250 Wh / kg), the amount of electricity contained in a 0.0002 L battery would be 0.16 Wh. With a voltage of 15 V supplied by the power source and specified in [5] as the minimum voltage for holding the bio-target, the battery capacity will be 10 mAh. With an admissible short-term discharge current for lithium batteries at 50C, a battery of the specified capacity with a small area of the anode and cathode can deliver a current of 0.5 A for 1-2 s after which the delivered current will sharply decrease and will not be of interest for the problem of electrocution of the bio-target. However, a current of 0.5 A with an initial potential of a battery of 15 V is generally impossible with a generally accepted resistance of a bio-target of 1000 Ohm [6], and can be only from 15 mA to a maximum of 25 mA, which with an insignificant current loop and an insignificant voltage of 15 V across the load cannot have an effective physiological effect that causes not only immobilization of the target, but even the initial stop of the target. The value of the damaging current of commercial stun guns of 3 mA indicated in the patent does not have a convincing force at all, since such a magnitude of current has a physiological effect only with impulses at a load of 1000 Ohms in the range of 1500-2000 V completely unattainable at the indicated current strength (i.e. the output power of the bullet is as much as 4.5-6 W, which is an indicator of the output power of dimensional stun guns, including those for police use [7], with powerful power supplies. the physical impossibility of obtaining at least to some extent an output power acceptable for hitting the target when using a step-up transformer and a Latour-Delon-Grenacher voltage multiplier due to losses on the transformer and the multiplier itself, and in addition to the practical uselessness of even powerful voltage multipliers for electroshock damage.

Lack of FIG prototype bullet. 8A and 8B also lies in the fact that the shape of the bullet, which does not have a cylinder-ogival part, does not allow it to be sent into the chamber of a standard short-barreled semi-automatic firearm due to the inevitable sticking of a cartridge with such a shape of the bullet head at the entrance to the chamber of the weapon. This limits the use of the prototype bullet only in short-barreled revolver-type weapons, which are currently no longer used by law enforcement officers in Europe, and in the United States is occasionally used only as a "second" weapon purchased at their own expense.

Lack of FIG prototype bullet. 8A and 8B also consists in the fact that when the power supply of the bullet is turned on with acceleration, it is possible to turn on the electrical circuit of the bullet when a cartridge with a bullet hits the ground, for example, when loading, carrying cartridges in weapons or magazines, etc. Even if the bullet electrodes are not closed by the bio-target, in this case the discharge of the power supply is inevitable due to current leakage in the bullet capacitors, continuing until the complete discharge of the power supply during long-term storage.

The disadvantage of the prototype bullet is also that it cannot be used when firing from a standard semi-automatic firearm due to the fact that, if the target is required to prevent mechanical injury, the bullet must have a low muzzle velocity, and, accordingly, the cartridge of the firearm must have a small impulse, that is, weakened a powder charge, which is not enough for the normal functioning of the automatic weapon reloading. Thus, the use of a prototype bullet would be limited only to the use in a non-automatic police firearm in a short-barreled version in revolvers, and in a long-barreled version in a rifle (for example, with a bolt action or pump action, or a reloading bracket). At the same time, the standard (standard) short-barreled firearms used on a daily basis and in the overwhelming majority of cases in almost all countries of the world, except for an insignificant number of underdeveloped countries, is a semi-automatic pistol, not a revolver. This means that the prototype bullet is completely unsuitable for use in law enforcement agencies.

Disclosure of invention

The technical problem lies in the creation of an electroshock bullet with an increased efficiency of immobilization of bio-targets compared to the prototype, and a cartridge for its use in semi-automatic pistols and long-barreled weapons.

The technical result consists in solving the specified technical problem.

The specified technical result is achieved in a small-caliber electroshock bullet containing a housing, a power supply, a switch, a DC voltage converter of a power supply to an alternating or impulse voltage, a shock absorber, electrodes in the form of needles, characterized in that a battery is located inside the housing, recruited from thin-film microgalvanic cells, batteries or supercapacitors with separate elements made in the form of a disk with a hole along the axis of the disk, or a battery in the form of a plurality of cylinders with separate elements for generating or storing electricity inside, located radially around the axis of the housing; an axial conductive needle with an electrically insulating coating along the length of the needle and an uncoated front end and an inertial or pyrotechnic device for extending the needle outside the body of the body when throwing a bullet or after hitting a target is placed inside the body along the axis of the body of the body.

The switch is made of inertial-rotary type or inertial type, or push-type, or pyrotechnic type.

The needle advance device is an inertial weight attached to the rear end of the needle.

The needle extension device is a pyrotechnic charge initiated by an inertial shock or by means of a pyrotechnic retarder, in turn, a bullet throwing powder charge initiated by hot gases, and a piston is located at the rear end of the needle.

The needle is made of tungsten or tungsten alloy with nickel, copper or silver plating.

The DC voltage converter of the power supply is mounted in a stack containing SMD capacitors and an SMD gas discharge tube.

The DC / DC converter of the power supply is mounted in a shelf containing SMD capacitors and a solid state DC / AC inverter.

The axial needle has an electrically insulating coating along the length of the needle, and the front end is uncoated with a device for fastening to the target in the form of at least one barb, and at the rear end of the bullet, a metal coating is applied over the electrically insulating coating or a thin-walled tube is fixed, while the needle and a metal coating or thin-walled the tube is mutually insulated.

At the front end of the body, a shock absorber is fixed in the form of an easily flowable in a shell or a gel-like body.

Has an ogival multi-leaf split head made of elastic or brittle material.

The axial conductive needle has a device for fixing on the target in the form of at least one barb.

The specified technical result is also achieved in an electroshock cartridge containing a sleeve, a propelling powder charge, an electroshock bullet, characterized in that at the front end of the sleeve forming the sleeve it has at least one radial hole passing through the sleeve wall, inside the sleeve shell there is a running cylinder with one bottom facing the bottom of the liner and having at least one hole in the bottom of the shell of the cylinder, the shell of the cylinder has at least one spring-loaded whisker stamped on the generatrix of its diameter, which interacts with the corresponding radial opening of the shell of the liner when the travel cylinder is pulled out of the shell of the liner, in an electroshock bullet is placed on the travel cylinder.

The bullet has a protrusion at its rear end with a shock-igniting primer composition applied to it, and the sleeve is made with a thinning of the bottom in the center.

The sleeve is made with an inner cylindrical cone-free surface and without a capsule socket.

The bullet is connected to the travel cylinder with the possibility of disconnecting from it at a certain pressure of the powder charge gases.

Brief Description of Drawings

FIG. 1 - Section of a bullet with inertial extension of the needle before hitting the target.

FIG. 2 - Section of a bullet with inertial extension of the needle after the bullet hits the target.

FIG. 3 - Section of a bullet with a pyrotechnic shock-initiated extension of the needle before hitting the target.

FIG. 4 - Section of a bullet with a pyrotechnic shock-initiated extension of the needle after the bullet hits the target.

FIG. 5 - Section of a bullet with a pyrotechnic retarder for the extension of the needle until it hits the target.

FIG. 6 - Section of a bullet with a pyrotechnic retarder with a needle extension after the retarder is triggered when the bullet hits the target.

FIG. 7 - Section of a bullet with a single needle and inertial extension of the needle until it hits the target.

FIG. 8 - Section of a bullet with a single needle and inertial extension of the needle after the bullet hits the target.

FIG. 9 - Section of a cartridge equipped with a bullet with inertial extension of the needle.

FIG. 10 - Cut through the cartridge during the shot.

FIG. 11 - Appearance and section of the cartridge compared to the standard cartridge 9x19 Para (9 mm NATO).

FIG. 12 is an illustrative electromechanical diagram of the bullet of FIG. 1-6.

FIG. 13 - An illustrative electromechanical diagram of the bullet of FIG. 7.

Implementation of the invention

FIG. 1. A bullet with an inertial extension of the needle consists of a thin-walled metal body 1 with a leading belt 2, a cylinder 3 made of mainly polymer material, an inertial disk 4, a contact pad 5, a battery or accumulator assembly (assembly) 6 (power supply), a capacitor-converter assemblies 7 with needles 8 having barbs, a cover 9, a shock absorber 10, a multi-lobed ogival split head 11, a central conductive needle which consists of a body 12 with a pointed front end with barbs, an insulating coating 13 and a weighting agent 14 connected to the body 12 made of metal with a large density (for example tungsten). The body 12 of the metal needle is covered with a thin layer of electrical insulation 13 (for example, fluoroplastic varnish or coating, oxide, phosphate or ceramic coating) with a coating thickness of 0.01-0.1 mm. It is possible to use a thin-walled tube made of an electrically insulating material, for example, heat-shrinkable, as a coating. The diameter of the needle together with the electrical insulation 13 does not exceed 0.8-1 mm, corresponding to the usual diameters of medical syringe needles. The battery or accumulator 6 in this embodiment and on a real scale (production drawing) is made up of 7 pieces of composite separate cylindrical elements located radially around the cylinder 3 (body axis) and connected in series, with 7 pieces. separate, predominantly thin-film or three-dimensional microvoltaic cells or batteries in each cylinder, also connected in series, that is, a total of 49 cells, which in total, when using lithium cells, gives a voltage of about 3.7-4.2 V × 49 = 180-206 V.

The central needle with a weighting agent 14 can move inside the cylinder 3. The inner diametrical surface of the body 1 is covered with an electrically insulating thin-layer coating to prevent the outer surfaces of the individual battery cells from joining the body. The capacitor-conversion assembly 7 consists of a stack 15 of printed circuit boards, on which mainly ceramic SMD capacitors 16 are mounted and a converter that converts the direct voltage of the electric current of batteries or accumulators into an alternating or impulse voltage that damages the target of an electric current. In a simple case, a Pearson-Anson relaxation generator circuit is used as a transducer. As a gas discharger 17 of such a circuit, for example, gas SMD dischargers with an ignition voltage of 75 V can be used, for example, of the ZD2R75TP1 type with body dimensions 4.5x3.2x2.7 mm, SD4-75 with body dimensions 3.5x5.4x4.4 etc. "ceramic smart spark gap". In other versions of the bullet, if increased voltage is required, solid-state converters mounted in a stack 15 are used (for example, in the simplest case, a step-up converter with SMD inductance (for example, type LQH32MN101J, 100 μH, 1210 (Murata Manufacturing) or DC / AC converters without increasing the output voltage.

The inertial disk 4 located in the housing 1 with the possibility of rotation is made of heavy metal (for example, copper, bronze, lead alloy) and has two insulated pads, to which in the idle state of the bullet adjoin the spring contacts of the contact pad 5 connected to the pole of the battery or accumulator 6. Current batteries in this state are not supplied to the capacitor-converting assembly 7. The shock absorber 10 located in the multi-lobed ogival split head 11 is made of a gel-like material such as Flubber or Slime (dimethylsiloxane, polydimethylsiloxane, decamethylcyclopentasiloxane). The shock absorber can also be a liquid of varying viscosity, enclosed in an easily destructible shell, for example, from a polymer or gelatinous film. The head 11 is made predominantly of a brittle polymer material, which is easily destroyed under the action of a deformable and expanding shock absorber when hitting a target, but it can also be made of an elastically elastic material such as cast polymers. The function of the multileaf ogival split head 11 and partly of the shock absorber 10 is also to protect the user's fingers from being pricked by needles when using bullets and cartridges loaded with such bullets when loading and unloading the weapon magazine with cartridges, and to ensure the supply (sending) of the bullet into the chamber of the weapon ...

FIG. 2 Bullet cut with inertial extension of the needle after the bullet hits the target. When a bullet is fired from a rifled barrel, the body 1 of the bullet gets rotation, and the disk 4, due to its inertia at rest, maintains its initial position for a certain time, while the spring contacts of the contact pad 5, rigidly connected to the body, rotate relative to the isolated areas of the disk, closing on its conducting body. In this case, the current of the battery or accumulator 6 is supplied to the capacitor-converter assembly 7, and, accordingly, the bullet is in a waiting working state to hit the target. Such an inertial-rotary device for turning on the power source, which turns on only when the bullet passes the rifled barrel of the weapon, protects the bullet from discharging the battery to work (or waiting state) of the capacitor-converter assembly 7, as well as from abnormal activation of the bullet when cartridges with bullets fall during use ... When a bullet hits the target, the shock absorber 10 deforms, absorbing the energy of the bullet hitting the target and, spreading out to the sides, destroys or opens the petals of the head 11 to the sides, while ensuring free penetration of the needles 8 connected to the first pole of the capacitor-converter assembly 7 into the target. The length of the needles 8 in real scale in the drawing reaches 5-8 mm with a diameter of 0.5-0.8 mm. Since the material of the shock absorber predominantly does not possess resilient shape-recovery properties or has such properties in a very small extent, the needles 8 do not leave the target due to the resilient rejection of the bullet body. Simultaneously with the impact of the bullet on the target, the weighting agent 14 together with the body 12 of the needle due to inertia moves forward in the cylinder 3, while the needle, energetically moving out of the body of the bullet, enters the target and by the end of the stroke in the cylinder 3 it is locked by the conical expansion of the rear end in the axial hole cover 9, providing galvanic contact of the body 12 with the second pole of the capacitor-converter assembly 7 and the bio target. The impulse of the needle penetration into the biocele with the weight of the tungsten weighting agent 14 (diameter 3 mm, length 4 mm) in real scale in the drawing will be 0.01134 kg⋅m / s, and in comparison with the impulse of the electrodes of the prototype bullet [5] (FIG. 8A and 8B) 0.0009 kg⋅m / s will be 12.6 times more, i.e. by an order of magnitude. The body 12 of the needle is expediently made of tungsten or tungsten alloy, preferably with a nickel, copper or silver coating for better electrical conductivity. The execution of the body itself 12 made of heavy metals makes it possible to further increase the impulse for inserting the needle into the biocoel.

The length of the needle inserted into the body of the body bio-target 12 in real scale reaches 24 mm. Even when a bullet is applied to a bio target in clothing, the conductive end of the needle reaches the hypodermis and subcutaneous tissue of the bio target body, providing a current loop of at least 15-20 mm between the uninsulated end of the central needle, which has penetrated into the body of the bio target, and the needles 8. At the same time, electrical discharges generated by the converter assembly 7 and acting directly on deeper tissues rich in nerve endings, much more than the epidermis, which is affected by all types of contact electroshock devices, cause no less strong tonic-clonic reaction and "Electro-Muscular Disruption" than in contact electroshock devices with a larger current loop, but acting only on the epidermis.

FIG. 3. A bullet with a pyrotechnic shock-initiated extension of the needle consists of the same main parts as the bullet in Fig. 1, but in the cavity of the protrusion of the bottom of the body there is a striker 18, predominantly of heavy metal (for example, tungsten) and a small shock pyrotechnic composition 19. Battery or accumulator 6 is composed of mainly thin-film microvoltaic cells or batteries with separate galvanic cells made in the form of a disk 20 with a hole along the axis of the disk (washer). The galvanic cells of the battery are collected on a cylinder 3 within which the central needle 12 connected to the piston 21 can move. FIG. 3 shows 20 flat battery lithium cells connected in series. With an individual cell voltage of about 4.2 V, the total voltage of the 20 cells shown in the figure in real scale would be 84 V. The figure shows the type of conventional flat clock batteries. The use of thin-film batteries or accumulators, for example, lithium (ultra thin film lithium-ion battery [8]), having an energy density 2.5 times more than that of conventional lithium batteries and a smaller thickness and a new type of organic thin-film batteries (super-ultra- extra thin) “Organic Radical Battery” [9]) (which allows the battery voltage to be proportional to the increase in the number of individual cells, that is, from a decrease in the thickness of an individual cell) much more than the mentioned 84 V), allows to increase the effectiveness of the destruction of the bio target by hundreds of percent due to an increase in several times the acting voltages (and, accordingly, the amplitude of the voltage on the bio-target) and currents. In this case, in comparison with the batteries of the description of FIG. 1, the current delivered by the battery from the orifice disks is significantly higher than the current delivered by the batteries of FIG. 1, since the area of each individual such element is many times larger, and in addition, the filling factor of the volume of the power supply compartment for disks with a hole is many times higher than for batteries according to FIG. 1. In the proposed bullet, in addition, an increase in its internal volume is achieved in comparison with the prototype due to the increased volume of the sleeve (see the description of the cartridge below). The general increase in volume makes it possible to increase the volume of the power source, and hence to increase the output energy characteristics of the bullet. It is also possible to use thin-film supercapacitors [10], for example, graphite ones. The use of power sources in the form of flat disks with holes along the axis gives the highest possible filling factor of the volume of the claimed bullet. Due to the high values of the self-discharge current of supercapacitors, and hence the short storage time of bullets in a charged state, it is advisable to supply bullets on supercapacitors that are not intended for patronage (for example, for use with pneumatic weapons with separate bullet loading) with leads for recharging them, located mainly on the back or on the side of the bullet body. ...

FIG. 4. When a bullet is fired, an inertial-rotational device for turning on the power supply is triggered and then the bullet hits the target, decelerating the target of its body with the introduction of needles 8 into the target, crushing the shock absorber 10 and destroying or opening the petals of the head 11. The piston 21 is fixed in the cylinder 3 with some by interference and when the bullet hits the target, it practically does not budge along with the body of the needle 12. The striker 18, continuing to move by inertia, pricks the shock pyrotechnic composition 19 which, igniting, throws the piston 21 with the body 12 of the needle along the cylinder 3. The charge of the composition is selected quantitatively so that it there was not enough energy to destroy the bullet structure. In this case, the needle, energetically extending from the body of the bullet, is introduced into the body of the bio-target at an impulse significantly exceeding the inertial extension of the needle, as in a bullet with inertial extension of the needle according to Fig. 1. The impact energy of the striker 18 (its weight), the shape of the striking (pierced) part, the sensitivity of the pyrotechnic composition 19 is selected so that the composition cannot be pierced when a cartridge with a bullet falls on a solid concrete or steel base from a height of less than 1.5 m, but at the same time it was reliably initiated when a bullet hit a biological target in clothing at the maximum firing distances of weapons for the use of cartridges with the claimed bullet. The connection of the poles of the capacitor-transformer assembly 7 with the bio-target occurs in the same way as in the description of FIG. 2.

FIG. 5. A bullet with a pyrotechnic needle retarder consists of the main parts as in FIG. 1, but the body 12 of the needle is connected to the piston 21, and a glass 22 with a pyrotechnic retardant composition 23 and a fire-conducting hole 24 and a small propellant pyrotechnic composition 25 are pressed into the cavity of the protrusion of the body bottom.

FIG. 6. The bullet can have several modes of needle extension, depending on the time of its slowing down. For example, one mode is carried out with a minimum deceleration of the needle extension. When a bullet is accelerated in the barrel of a firearm, a fire pulse from the actuation of the propellant charge of a cartridge with a bullet through the fire-conducting holes 26 ignites the retardant composition 23 of a short delay time, which almost instantly transmits a fire impulse to the propellant pyrotechnic composition 25 which, in turn, ignites the piston 21 with the body 12 the needle along the cylinder 3. In this case, the needle, depending on the set deceleration time, can be extended from the body of the bullet 1 even while it passes through the barrel of the firearm, and the bullet flies to the target with the needle already pushed forward of the body. Another mode is carried out with the maximum deceleration of the needle extension. When a bullet is accelerated in the barrel of a firearm, a fire pulse from the actuation of a propellant charge of a cartridge with a bullet through the fire-conducting holes 26 ignites the retardant composition 23 with a long delay time, which after a certain time transmits a fire impulse to the propellant pyrotechnic composition 25, which, in turn, igniting, throws the piston 21 with the body 12 of the needle along the cylinder 3. In this case, the needle, depending on the set deceleration time, can be extended from the body of the bullet 1 at a certain segment of the bullet's path to the target, and with a known distance to the target and a known drop in the bullet velocity, it is possible to calculate the deceleration time before the needle extends practically in contact with the target. That is, the bullet in this mode flies to the target with the needle not yet pushed forward of the body or extended only at a certain distance from the muzzle of the weapon. And in this case, the needle extended from the body of the bullet is introduced into the body of the biocele with an impulse significantly exceeding the inertial extension of the needle as in a bullet with inertial extension of the needle according to Fig. 1 since the needle is embedded in the target of impulses of the entire attached mass of the bullet. The actuation of the inertial-rotational device for turning on the bullet power supply during firing does not differ from that described in FIG. 2. The connection of the poles of the capacitor-converter assembly 7 with the bio-target occurs in the same way as in the description of FIG. 2.

FIG. 7. A bullet with a single needle and inertial extension of the needle consists of practically the same main parts as in Fig. 1, but has a stack 27, devoid of needles 8 (according to Fig. 1), a spiral 28 (as shown in Fig. 4) or another the form of laying the soft (non-elastic) conductor, and changed in comparison with the details in FIG. 1 weighting agent 29, 30, a layer of electrical insulation 31, as well as an electrically conductive metal coating 32 (or a thin-walled metal tube) wherein the coating or tube is rigidly connected (for example glued) to the weighting agent 29 and a layer of electrical insulation 31, which in turn is rigidly connected to the body 30 needles. The rear end of the needle is connected to one end of the coil conductor 28, but the needle is separated by a layer of electrical insulation 31 from the electrically conductive metal coating 32. The second end of the coil conductor 28 is welded to the body 1 in its rear projection. Cover 32 and body 1 are not galvanically connected. It is possible to design a bullet with a single needle both with inertial extension of the needle and with a pyrotechnic shock-initiated extension of the needle or with a pyrotechnic retarder for the extension of the needle as in FIG. 3 and FIG. 5. In this case, the helix 28 fits around the striker and the percussion composition of FIG. 3 or around the retarder and propellant of FIG. 5. Due to the fact that the spiral is made of metal, the combustion gases of pyrotechnic compositions do not violate the strength or integrity of the spiral when the needle is extended due to the short duration of the action. In this case, the general scheme of action of a single needle, described below, remains unchanged.

FIG. 8. The actuation of the inertial-rotational device for turning on the power supply of the bullet when fired does not differ from that described in FIG. 2. When a bullet hits the target, the shock absorber 10 deforms, absorbing the energy of the bullet impact on the target and spreading out to the sides, destroys or opens the petals of the head 11 to the sides, while providing a free exit of the body 30 of the needle connected to one pole of the capacitor-converter assembly (spiral 28 with metal body 1) into the target from body 1. The length of the full exit of the body 30 of the needle with its diameter 0.8 mm (with coating 32) from body 1 reaches 23 mm. Simultaneously with the impact of the bullet on the target, the weighting agent 29, together with the body 30 of the needle, due to inertia moves forward in the cylinder 3, while the needle energetically advancing from the body of the bullet enters the target and by the end of the stroke in the cylinder 3 it is counterbalanced by a slightly conical expansion made on the coating 32 (or thin-walled metal tube) of the rear end of the needle in the axial hole of the housing cover 33, isolated from the housing 1 (as opposed to the galvanically connected to the housing 1 of the covers 9 in Fig. 1; Fig. 3 and Fig. 5) providing galvanic contact of the coating 32 with the capacitor pole transformative assembly and bio-target. The second pole (body 1 of the bullet) is connected to the bio-target through a spiral 28 stretched inside the cylinder 3 and connected to the body 30 of the needle. The spiral 28 is made of a soft annealed copper or nickel wire in order to eliminate the loss of momentum of the extended needle for stretching the spiral wire. In this case, a loop of the damaging current is formed in the body of the biocoel between the coating 32 that has penetrated into the body as part of the extended needle and the end of the body 30 of the needle with a pointed front end with barbs. The length of the needle inserted into the body of the body bio-target 12 in real scale reaches 24 mm.

In versions of the claimed bullet, it may not have a bottom protrusion, in which an inertial weight and elements of impact extension and retardation of extension of the central conductive needle are located on the presented figures. These elements can be located in the cylinder 3 that does not go beyond the plane of the main (caliber) bottom of the bullet. However, the use of the protrusion makes it possible to increase the length of the extended central needle, as well as to use a system of central ignition of a powder charge without a capsule socket, as will be discussed below in the description of a cartridge with an electroshock bullet.

FIG. 9. Sectional view of a cartridge equipped with a bullet with inertial extension of the needle according to FIG. 1. The cartridge consists of a sleeve 34 having at the front end of the generatrix of its shell radial passing through the wall of the shell, through the sleeve elongated along the axis of the sleeve and rounded closer to the sleeve of the sleeve holes 35, a running cylinder 36 with a bottom facing the bottom of the sleeve and having an opening 37 in the bottom, the shell of the cylinder 36 has radially stamped through on the generatrix of its diameter springy whiskers 38, which unbending can fall into the counter openings 35 of the liner when the cylinder 36 is pulled out of the liner, an electroshock bullet 39 is placed inside the running cylinder, the protrusion of the bottom of which passes through the hole 37 in the bottom of the cylinder 36, in the recess of the bottom of the bullet protrusion, which is actually a capsule anvil, an impact-igniting pyrotechnic composition 40 is located, and between the bottom of the sleeve and the bottom of the electroshock bullet 39, a propelling powder charge 41 is placed around the bullet bottom protrusion (powder grains are not shown in connection with the worst opportunity to see other details of the device when depicted and). When equipping (assembling) the cartridge, the cylinder 36 is inserted into the sleeve 34 with the tightening of the spring mustache 38, which remain in the cartridge during storage in a stressed state. The hole 37 is predominantly cylindrical, but it can also have a different shape (for example, a polyhedron) corresponding to the shape of the protrusion of the bottom of the bullet body, if any. The holes 37 can also be several (that is, the transmission of the pressure pulse to the bottom of the bullet can be made through several holes) and their location can be misaligned with the axis of the sleeve if the bullet does not have a bottom protrusion.

FIG. 10. When fired, the cartridge is initiated by striking the firing pin of the weapon in the center of the bottom of the sleeve 34, which may have a slight thinning of the bottom for better penetration of the firing pin into the bottom of the sleeve to break the percussion-igniting compound against the bullet anvil. The striker pushing through the bottom of the liner (without breaking the liner material) breaks the percussion-igniting composition 40 between the bottom of the liner and the bottom of the bullet protrusion 39. The force of the flame of the composition 40 ignites the powder charge 41, which, igniting, exerts pressure on the bottom of the cylinder 36 and at the same time on the bottom of the bullet protrusion 39 Due to the larger area of the effective pressure of the powder gases on the cylinder 36, it, together with the bullet 38, first moves out of the sleeve 34, while the springy whiskers 38 at the end of the cylinder stroke in the sleeve fall into the holes 35 of the sleeve and, unbending under the action of the spring-loaded force, lock the cylinder 36 in the sleeve, preventing it from fully extend out of the sleeve. The ends of the whiskers 38 and the mating holes 35 of the sleeve are rounded to optimize the breaking forces, while at high-speed locking, reducing the stress concentration in the sleeve at the points of impact of the whiskers to the edge of the hole facing the barrel of the sleeve. In the real operation of a firearm, cylinder 36 actually remains in place in the chamber of the weapon, since its front end, which plays the role of the muzzle of a conventional sleeve, rests against the shoulder of the weapon barrel (shoulder of the shoulder of the sleeve of the sleeve) in the bullet inlet. Only the sleeve 34 itself moves relative to the weapon, pushing the bolt of the weapon. When the sleeve 34 begins to move, it imparts some movement impulse to the shutter of a semi-automatic weapon (for example, a pistol). On a certain path of pushing the cylinder out of the sleeve, the bullet, under the action of the pressure exerted on its bottom by those emerging in the hole, also begins to move forward along the barrel, and then its protrusion comes out of the hole 37, completely opening the bullet to the access of the powder gases formed in the sleeve, the pressure acting on the bullet itself at the same time it increases, continuing its acceleration in the barrel. In a specific version of the cartridge, the protrusion of the rear end of the bullet can have both free movement in the hole 37, and have a fit into the hole 37 with a certain interference (landing force) to be able to regulate the moment of access of the powder gases to the pressure on the full area of the bullet bottom to obtain the resulting effect as for the operation of automatic weapons, and for giving the bullet the required speed of movement. The bolt, which received a movement impulse and captured the cartridge case 34 with the ejector, moves back, the bullet 38 continues to move along the barrel of the weapon. When the cylinder 36 is locked in the liner, the shutter continues to move backwards and removes the liner with the cylinder extended from it and, reaching the rear position, ejects the liner with the cylinder using the weapon reflector. At this time, the bullet is already flying out of the barrel and flying towards the target.

The cartridge case has the outer dimensions of standard pistol or revolver cartridges, but it is made predominantly of steel (although brass is not excluded) and predominantly thin-walled, like the steel cases of .22 LR cartridges due to the low pressure of the powder gases developed during the shot, that is, the propellant charge is small in compared with the powder charge of combat pistols and revolvers. Due to a decrease in the thickness of the bottom of the case and the thickness of the walls of the rear part of the case (a thin-walled case without a tapered narrowing of the inner generatrix to the bottom of the case) in comparison with cases for military firearms of the central battle, having an internal taper of the case material to withstand the high pressure of a normal powder charge, the internal volume increases a cartridge case that allows you to accommodate a bullet of a larger volume than a bullet from a military firearm. In the claimed cartridge, the volume of the propellant (powder charge) is significantly reduced, since the cartridge is designed for non-lethal effects while providing a bullet throwing at a low initial velocity (40-80 m / s) to prevent serious mechanical injuries of the bio target when a bullet hits it at close range ... Also, to increase the volume of the cartridge, a primer is used, an igniter of the central battle, formed by the bottom of the sleeve and the protrusion of the bottom of the bullet body, facing the inside of the sleeve. In the case of a standard firearm, the capsule socket occupies a significant volume of the case. The pyrotechnic igniting composition is located in the projection of the bullet, which also serves as a capsule anvil. The powder charge is placed around the bullet bottom protrusion. At the same time, due to the expanding design of the sleeve, transmitting an impulse to the bolt of the weapon at the moment of the highest pressure of the powder gases, even a reduced powder charge giving a small impulse to the bullet is sufficient to activate the automatic reloading of the weapon. At the same time, some standard semi-automatic pistols for the use of the claimed bullets and cartridges can use a weakened or remote forced locking system, acting only with a free bolt and / or have a weakened bolt return spring.

The bullet can be used both in firearms that have cartridges with casings, including semi-automatic pistols, and revolvers, and in pneumatic weapons that do not have cartridges and, accordingly, casings, except for the version of the bullet with a pyrotechnic retarder for the extension of the needle until it hits the target. The above figures show a bullet and a cartridge in the dimensions of a 9x19 Para cartridge (9 mm NATO), however, it is more expedient to produce it in the dimensions of cartridges of large calibers with the same structure of the bullet and cartridge as: .40 S&W; 10 × 25mm, Auto; .45 ACP. The use of the claimed bullets and cartridges in such calibers makes it possible to simplify the manufacturability of production due to the need for less miniaturization of parts and components.

FIG. 11. External and section of the cartridge in real scale compared to the standard cartridge 9x19 Para (9 mm NATO).

FIG. 12. An illustrative electromechanical diagram of the bullet according to FIG. 1-6. The bullet is shown with the inertial-rotational device included in the operation of the bullet and the needle extended when the bullet hits the target. In this case, the positions in the figure designate the following elements: a power source 42 (battery or battery), conductor 43 (bullet body), contacts 44 of an inertial-rotational power-on device, a stack 45, with capacitors 46 and a gas discharger 47, a needle 48 (needle 8 1), a coated needle 49 (needle body 12 with coating 13 of FIG. 1), a weight 50 (weight 14 of FIG. 1), and an inertial disc 51 (an inertial disc 4 of FIG. 1).

FIG. 13. An illustrative electromechanical diagram of the bullet according to FIG. 4. A bullet with an inertial-rotational device turned on and a needle extended when a bullet hits a target. In this case, the positions in the figure indicate the following elements: a power supply 42 (battery or battery), conductor 43 (bullet body), contacts 44 of an inertial-rotational power switch, a stack 45, with capacitors 46 and a gas spark gap 47, a needle 52 (the body of the needle 30 with coating 31 of FIG. 7) and coating 53 (coating 32 or metal tube of FIG. 7), weighting agent 54 (weighting agent 29 of FIG. 7), coil 55 (coil 28 of FIG. 7), cover 56 (cover 33 of Fig. 8).

In the versions of the claimed bullet, the power supply can be switched on not only with an inertial-rotational type switch, but also with an inertial-type switch based on moving the body mass of the contactor to the contacts or moving parts and assemblies of the bullet itself to the contactor contacts, but also using a push action switch which is pressed by the pressure of the throwing gases directly or through an intermediate part (membrane, piston), or by a pyrotechnic-type switch in which the contacts are closed due to the burning out of the insulating pyrotechnic composition during a shot or the action of gases of an additional pyrotechnic charge in the bullet on the intermediate part (membrane, piston) and then on to the switch.

List of cited sources:

1. Patent US 7984676 B1

2.https://www.thefirearmblog.com/blog/2010/02/10/taser-xrep-up-close-and-p

3.https://en.wikipedia.org/wiki/Commotio_cordis

4.https://www.independent.co.uk/news/uk/crime/expert-taser-no-part-in-raoul-moat-death-2358513.html

5.Patent US 5698815 A

6. GOST R 50940-96 Electroshock devices.

7. Ladyagin Yu.O. "Remote electroshock weapon" Moscow: Stalingrad Foundation Publishing House, 2017, pp. 69-73.

8.https://www.grepow.com/page/ultra-thin-battery.html

https://www.fentcell.com/en/product_show.php?id=158&gclid=EAIaIQobChMIg5P2xNCZ7wIVDSwYCh1Q9g77EAAYASAAEgJPzPD_BwE

9.https://www.androidauthority.com/nec-organic-radical-battery-71631/

10.https: //www.vital-ic.com/murata/item/688-murata- announced-- release-supercapacitors-with-ultthin-profile-dmh

Claims (15)

1. A small-caliber electroshock bullet containing a housing, a power supply, a switch, a DC voltage converter of a power supply to an alternating or impulse voltage, a shock absorber, electrodes in the form of needles, characterized in that a battery is located inside the housing, recruited from thin-film microgalvanic cells, batteries or supercapacitors with separate elements made in the form of a disk with a hole along the axis of the disk, or a battery in the form of a plurality of cylinders with separate elements for generating or storing electricity inside, located radially around the axis of the housing; an axial conductive needle with an electrically insulating coating along the length of the needle and an uncoated front end and an inertial or pyrotechnic device for extending the needle outside the body of the body when throwing a bullet or after hitting a target is placed inside the body along the axis of the body of the body. 2. Electroshock bullet according to claim 1, characterized in that the switch is made of inertial-rotational type, or inertial type, or push-type, or pyrotechnic type. 3. An electroshock bullet according to claim 1, characterized in that the needle extension device is an inertial weight attached to the rear end of the needle. 4. An electroshock bullet according to claim 1, characterized in that the needle extension device is a pyrotechnic charge initiated by an inertial shock or by means of a pyrotechnic retarder, in turn initiated by hot gases of a propellant charge of propelling a bullet, and a piston is located at the rear end of the needle. 5. The electroshock bullet according to claim 1, characterized in that the needle is made of tungsten or tungsten alloy with nickel, copper or silver plating. 6. Electroshock bullet according to claim. 1, characterized in that the DC voltage converter of the power supply is mounted in a stack containing SMD capacitors and an SMD gas spark gap. 7. Electroshock bullet according to claim 1, characterized in that the DC voltage converter of the power supply is mounted in a stack containing SMD capacitors and a DC / AC solid-state inverter. 8. An electroshock bullet according to claim 1, characterized in that the axial needle has an electrically insulating coating along the length of the needle and a front end without a coating with a device for fastening to a target in the form of at least one barb, and a metal coating is applied to the rear end of the bullet over the electrically insulating coating or a thin-walled tube is fixed, with the needle and the metal coating or thin-walled tube mutually insulated. 9. An electroshock bullet according to claim 1, characterized in that a shock absorber is fixed on the front end of the body in the form of an easily flowable in a shell or a gel-like body. 10. An electroshock bullet according to claim 1, characterized in that it has an ogival multi-petal split head made of an elastic or brittle material. 11. Electroshock bullet according to claim. 1, characterized in that the axial conductive needle has a device for fixing on the target in the form of at least one barb. 12. An electroshock cartridge containing a sleeve, a propelling powder charge, an electroshock bullet, characterized in that at the front end of the shell forming the shell it has at least one radial hole passing through the shell wall; inside the shell shell there is a running cylinder with one bottom facing the bottom of the liner and having at least one hole in the bottom of the shell of the cylinder, the shell of the cylinder has at least one radially springy mustache stamped on the generatrix of its diameter, which interacts with the corresponding radial opening of the shell of the liner when the travel cylinder is pulled out of the shell of the liner, is located in the running cylinder electroshock bullet. 13. Electroshock cartridge according to claim 12, characterized in that the bullet has a protrusion at its rear end with a shock-igniting primer composition applied to it, and the sleeve is made with a bottom thinning in the center. 14. Electroshock cartridge according to claim 12, characterized in that the sleeve is made with an inner cylindrical cone-free surface and without a capsule socket. 15. Electroshock cartridge according to claim 12, characterized in that the bullet is connected to the travel cylinder so that it can be disconnected from it at a certain pressure of the powder charge gases.

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