RU2816375C1 - Multiply charged remote electric shock weapon and unitary cartridges to it - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: group of inventions relates to multiply charged remote electric shock weapon (RESW). Remote electroshock weapon comprises a housing, a power source, a damaging voltage generator, a microcontroller control system, electric current switching devices, fuse-switch and detachable magazine. Removable magazine is a shaped hollow shell with contact points and is made with possibility of its loading with unitary cartridges. Damaging voltage of electric current from generator is supplied to contact points of cartridges along contact points of magazine. Removable magazine is fixed in the body by a spring-loaded latch having a drive for forced unlocking of the magazine from the body of the weapon, acting from the fingers of the user’s hand holding the weapon. Current leads of the generator of damaging voltage of electric current from the switching device to electric contact places of cartridges in the magazine are located on external side surfaces of the front part of the body.

EFFECT: creation of multiple-shot RESW with possibility of obtaining effective immobilization of target by paired shots or multiple single shots.

18 cl, 24 dwg

Description

Field of technology to which the invention relates

The invention relates to a multi-charged remote electroshock weapon (DESHW), with an electric means of destruction for the self-defense of citizens, use in law enforcement agencies and protection from aggressive animals.

State of the art

The DESH of the world's leading company in the field of electroshock weapons, Axon Enterprise, Inc., is widely known. (formerly "Taser Int." USA) models Taser X2 and Taser 7 [1], made in the form of a pistol, consisting of a body that contains an electronic part with an electronic high-voltage unit that hits a target (offender, biological target, bio-target) with electric current and a special a pocket (a cavity in the front of the weapon) in which two firing cartridges are placed. Firing cartridges are installed in the housing and held in it by means of latches. The cartridges are in contact with the DESH contact electrodes (electrodes for direct contact impact on the target by pressing the target to the body without firing the firing cartridges). When firing from the firing cartridges, current conductors with devices for holding them on the target (probes with needles with barbs) are thrown at the target. Through the current conductors that hit the target, the high-voltage damaging voltage of the electric current generated by the high-voltage unit is transmitted from the DESH to the target. The advantage of analogues is the ability to fire shots at a target with two cartridges one after the other (duplicate shot) and the ability to make an arrest (capture). The arrest mode is carried out in all models of DASH of the company "Axon Enterprise, Inc.". in which the firing cartridges, after firing, hitting the target and releasing the trigger by the DESH user, are not automatically extracted from the DESH, but are removed from the DESH only manually. In such DESHOs, when the trigger is released after a shot and the conductors hit the target, the spent cartridges are not automatically removed from the weapon and the DESHOs are connected to the target by conductors until the fired cartridge is manually removed, and the damaging current voltage is applied to the target even after the trigger is released during the time of the timer. (up to 5-15 s), depending on the specific model of the emergency vehicle or its purpose (police or civilian). Thus, the law enforcement officer hits the target, releases the trigger, puts the DESH on the ground, and while the timer delivers a damaging electric current to the target and the target is immobilized, handcuffs the immobilized offender. In this way, in the United States for more than 20 years, the majority of arrests (seizures) of offenders have been made using DESHOs. In Russia, DESHOs with arrest capabilities have not been used by law enforcement agencies to date.

The disadvantage of analogues is that the firing cartridges are connected to the weapon with latches and after the shot are not automatically separated from the weapon. This significantly limits the ability to quickly and accurately fire a second shot if the next target appears behind the user of the weapon or in the plane behind the current conductors already stretching towards the first target. The conductors stretching towards the first target do not allow the user to turn with the weapon towards the target that appears behind him, because this is prevented by the strong conductors secured by the barbs of the probe needles on the clothing of the first target. These wires prevent the shooter from physically turning and quickly aiming the weapon at the target. In addition, on the line of the next shot there may be conductors from the previous shot, stretching towards the first target, which will inevitably change the trajectory of the probes of the new shot, and they will not hit the target even with correct aiming. The production of two consecutive aimed shots is possible only in an arc, from left to right, which is associated with the order in which cartridge shots are initiated (from left to right) each time the trigger (trigger element) is pressed. In the same way, the wires of the previous shot will deflect the flight path of the probes of the subsequent shot when a subsequent target appears in the plane behind the wires reaching towards the first target. The disadvantage of analogues is also that spent cartridges for reloading weapons have to be removed from the DESH using both hands of the user. Removal of the spent cartridge after a shot is not provided automatically or with the help of one hand of the user holding the weapon. Thus, in order to reload the weapon if necessary to quickly continue shooting, the user loses time to remove the spent cartridge using both hands.

DESHO was chosen as a prototype based on a patent [2] for the sale of a serial sample of which, the model "Taser 10" manufactured by the company "Axon Enterprise, Inc." for testing by US law enforcement agencies began in February 2023. This AES has been called by the US media and US law enforcement experts [3] as a “revolutionary invention”, “a new era in less lethal technology” and a breakthrough in non-lethal technology akin to the landing of man on the moon in the program "Apollo 11". The DESHO prototype has a pistol body in which there is a power source in the form of an electric battery, a generator of damaging electric current voltage that generates pulses of damaging electric current at the output, a microcontroller switching system, measuring the effective values of the damaging electric current, indicating operating parameters and many additional functions, a fuse-switch, removable a magazine inserted into the body from the bottom of the front part of the body and held by a latch with a specified release force when the magazine is pulled out of the weapon. The magazine, which has cylindrical cartridge sockets, is equipped with unitary metal cartridges in the form of a stepped cylindrical body of rotation, containing a charge of pyrotechnic propellant, a probe with laying of the current conductor and a device for securing to the target, a tray for pushing the probe when firing and obturation of the barrel bore from the release of throwing gases into the atmosphere after shot. When firing from a DESH, shots are fired by throwing one probe at the target for each time the user presses the trigger of the weapon. At the same time, automatic recognition of the passage of damaging current into the target allows you to automatically select pairs of conductors through which the greatest current flows to the target and disconnect those conductors through which the damaging current flows to the target with insufficient force to immobilize the target.

The advantage of the prototype compared to analogues lies in the declared possibility of achieving reliable immobilization of the target due to the possibility of multiple repetitions of shots after the first hit (up to 9 shots). The disadvantage of the prototype is that when the user fires the first shot (with the first probe attached to the target), the target is not hit, since the user needs to fire a second shot (with the second probe attached to the target to form a conductive circuit) with a change in point aiming at the location of the target's body located at a distance of at least 0.3 m from the first point of impact (such a distance between the places where the probes are attached to the target is necessary for reliable immobilization of the target with an electrical output power of the DEShO of no more than 2-4 W, installed in the USA and the EU for DESHO analogues and prototype). If you fire the first two shots instantly (quickly pressing the trigger), that is, without shifting the aiming point, then the probes will hit the target’s body very close to each other (since the DESH has virtually no recoil when firing, shifting the point of impact of the probes during fast shots) , without providing the necessary current loop [4] and, accordingly, without causing reliable immobilization of the target.

The disadvantage of the prototype is the extremely high complexity of the detection control electronics (monitoring the reliable connection of the probes to the target) and re-switching the passage of the damaging voltage of the electric current to the probes connected to the target with the best conductivity. The electronic circuit for such switching contains 10 small-sized high-voltage solid-state switches (transistors or thyristors) of foreign production, the cost of which is extremely high, and determines the final price of the components, and the production of which is completely absent in the Russian Federation. Also in the Russian Federation there is completely no production of the remaining microelectronic components of the “Taser 10”, or the production of some electronic components similar in functionality is available in the Russian Federation, but with dimensions and electrical characteristics that completely exclude their use in DASH in the dimensions of a pistol. The cost of just creating programs to control the Taser 10 electronic systems is tens of millions of dollars, and this cost is included in the price of the serial product. In general, the cost of developing “Taser 10” (R&D expenses [5] of the company “Axon Enterprise, Inc.”) is physically incomparable with the capabilities of all the companies developing DASH in the Russian Federation (and the combined developers of all types of non-lethal weapons in the Russian Federation). The Taser 10 prototype device costs US$2,000 and is sold at a discount to US law enforcement agencies only. This cost is completely unacceptable for Russian Federation users, both civilian and even law enforcement users. At the same time, it is physically impossible to produce a product of such complexity in the Russian Federation due to the complex of indicated shortcomings in the element base and technologies and the complete lack of state support for developers of electroshock weapons in the Russian Federation.

The disadvantage of the prototype is also that when multiple shots are fired at an inevitably moving target in an attempt to establish a reliable connection between the probes fired at the target and the target to create a circuit conducting the current striking the target, the current conductors of the shots become confused and overlap the trajectory lines of the next fired probes with the conductors, which increases the likelihood deviation of probes from the aiming line due to touching previous conductors reaching towards the target with corresponding misses on the target.

The disadvantage of the prototype is also that removing the magazine from the weapon after shooting unitary cartridges is carried out with both hands, since the magazine is fixed in the weapon body using a spring or magnetic fixation, which requires physical effort from the user both when inserting the magazine into the weapon (pressure) and when removing the magazine from the weapon (pulling force). With this method of removing a spent magazine and quickly inserting a new magazine, time is lost to reload the weapon.

The disadvantage of the prototype is also that it is impossible to hit multiple targets with its help, since automatic switching selects the best connection of probes to the target, and an attempt to hit a second offender after the first will not lead to immobilization of the second offender if a reliable connection has already been established with the first offender.

The disadvantage of the prototype is also that it cannot be used to make an arrest.

The disadvantage of the prototype is also that with its help it is impossible to carry out contact impact on the offender since the prototype does not have external combat electrodes for contact impact, and in addition, the developed damaging voltage of the electric current of the prototype is no more than 1000-2000 V (1000 V according to the given characteristics "Taser 10"), which is not enough to penetrate the target's clothing. The disadvantage of the prototype is also the impossibility of demonstrating a warning combat high-voltage electric spark discharge to the enemy (for the purpose of psychological impact to reduce aggressiveness before using contact or remotely) due to the insufficiency of the damaging voltage to produce a spark discharge visible and audible to the offender. At the same time, it is well known that when a user threatens to use an electric shock weapon with a demonstration of a damaging electric spark discharge, accompanied by a characteristic noise and glow of spark discharges, in many cases the offender stops aggressive actions, realizing that he will have to deal with electricity and, accordingly, subsequent pain. It is also well known that aggressive animals (for example, dogs, wild animals) almost always stop their aggression when a person demonstrates electric discharges, reacting with noise, crackling and ozone released during the electric discharge. Instead of a warning spark discharge, the prototype uses a warning sound reminiscent of a police siren. The prototype developers believed that the signal from the beeper installed in the weapon would frighten criminals and aggressive animals.

The disadvantage of the prototype is also that it does not have anti-snatchers (electrodes under a damaging voltage on the surface of the weapon, preventing the offender from trying to snatch the weapon from the hand of a law enforcement officer) since the conductors of the damaging voltage of the electric current supplying the cartridges are placed inside a non-conductive body and a protruding magazine. The offender may seize the law enforcement officer’s weapon and attempt to either snatch it from the law enforcement officer’s hand, or point the muzzle of the weapon away from himself, preventing him from firing shots.

As an analogue of the cartridge, the cartridge for the Taser 10 DASH was chosen according to the application [6] manufactured by the company Axon Enterprise, Inc. The cartridge has a metal cylindrical stepped body in the form of a rotation detector, in which there is a pyrotechnic propellant charge initiated from a low-voltage or high-voltage electric current source, a wad shutter, a metal probe with an electric wire laid inside and a device for securing to the target in the form of a needle with a barb. One end of the current conductor in the installation is in contact with the metal probe, and the other end of the current conductor in the installation is in contact with the metal body of the cartridge through a conductive wad seal. The only advantage of the cartridge is that it is used as part of the Taser 10 DESH. The disadvantage of the cartridge lies in its complex structure, illustrated in Fig. 4 V; fig. 5C; fig. 6C; fig. 7 V; fig. 7C.[6]. For example, the probe body is made of precision stainless steel pipe with a polished internal surface (due to the necessary requirements for equipping the probe body with laying of the current conductor to the cleanliness of the internal surface), the cartridge body is also turned from precision pipe. The parts of the initiating-throwing device are redundant in terms of the required functionality of the action and are performed on the most precise equipment. The patenting of a cartridge device of such an overcomplicated design was intended solely to circumvent the patent [7] by Axon Enterprise, Inc. In the Russian Federation, the production of cartridges of such a design is generally impossible for reasons such as the lack of precise technologies and the absolutely unacceptable final cost in the case of special (virtually manual) production.

The cartridge for the DEShO according to the patent [8] was chosen as a prototype cartridge. The cartridge has a polymer body with a barrel channel, a pyrotechnic propellant charge, a wad tray with an electrode, a probe with a hard or elastic shell with a conductor laid inside it and a device for securing it to the target. One end of the conductor is electrically fixed to the head, which weights the probe in which it is electrically fixed and to the device for fastening on the target or directly to the device for fastening to the target, and the other end of the conductor with the exit from the barrel channel from the rear end of the stack is fixed to the front end of the body, covered with a conductive coating. The barrel channel has the orientation of its axis relative to the axis of the body and the internal structure of the channel required by the conditions of external ballistics. The advantages of the cartridge are that the cost of two cartridges per shot is less than the cost of all models of serial DESHO shooting cartridges produced by Russian companies, and the price is hundreds of percent less than the price of serial shooting cartridges from Axon Enterprise, Inc. The disadvantage of the cartridge is that it uses only high-voltage spark initiation of pyrotechnic propelling charges of cartridges and cannot be used in any other type of DESH except with high-voltage spark initiation of shots. The disadvantage of high-voltage spark initiation is the sensitivity of firing cartridges or unitary cartridges to electrostatic discharges, for example, accumulated on the user, which can lead to an unauthorized shot as when handling cartridges and cartridges, as well as an unauthorized shot if the weapon gets into, for example, atmospheric precipitation . At the same time, at present, in the DASH technology, a transition is being made to initiating shots with increased voltage and low-voltage electric current, which provides great opportunities for the design of a multi-charge DASH [9]. Modern DASH models made in the USA have shot initiation only with a low-voltage electric current of 6.0-14.0 V or a high voltage of 1000-2000 V.

Disclosure of the Invention

The technical problem lies in the need to create a multi-charge DESH with the ability to effectively immobilize a biological target with paired shots or multiple single shots, with the ability to hit several targets one after another, with the ability to arrest an offender, with the ability to prevent an offender from snatching a weapon from the hands of a law enforcement officer with the possibility of contact action, demonstration to the offender of a high-voltage discharge, with the possibility of creating improved conditions for shooting and reloading weapons and manufactured from components available on the market under international sanctions at a low cost of the device. The technical problem also lies in the need to create low-cost ammunition (cartridge) for the specified DESH.

The technical result consists in the implementation of a multi-charge DESHO with a solution to the specified technical problems. The technical result also consists in the implementation of a low-cost unitary cartridge with initiation of a low-voltage or high-voltage electric current for a multi-charge DASH.

The specified technical results are achieved by the fact that a multi-charge DESH has a housing, a power supply, a generator of a striking electric current voltage, a microcontroller control system, electric current switching devices, a fuse-switch, a removable magazine, and the magazine is a profile hollow shell with contact points equipped with unitary cartridges located without gaps close to each other and loaded from the rear end of the cartridges by the force of the springs of electrical contacts located inside the housing, the magazine is fixed in the housing by at least one spring-loaded latch having a drive for forced release of the magazine from the body of the weapon, operated by the fingers of the user's hand holding the weapon, conductors of the damaging voltage generator from the switching device to the electrical contact points of the cartridges in the magazine are located on the outer side surfaces of the front part of the housing.

An additional feature is that the housing has contact points for the voltage output of the power supply to the outer surface of the housing, switched by buttons on the housing.

An additional feature is that on the case there are contact points where the damaging voltage of the electric current exits onto the outer surface of the case, switched by buttons on the case.

An additional feature is that a high-voltage pulse transformer with contact-action electrodes is electrically connected to the contact points where the damaging voltage of the electric current is released and fixed to the housing.

An additional feature is that on the outer surface of the profile shell of the magazine there is part of the sighting devices of the open sight.

An additional feature is that the magazine has on its inner walls protrusions for spring-loading cartridges in the magazine or protrusions for fixing cartridges with reciprocal depressions in the cartridges.

An additional feature is that the magazine is designed to extend beyond the dimensions of the weapon body and has contact points with conductive tracks on the outer surface of the magazine.

An additional feature is that the spring-loaded latch is repositionable on both sides of the case.

An additional feature is that electric current switching devices generate pulses of damaging electric current.

An additional feature is that the microcontroller control system is made with the ability to select the operating mode of the weapon before the moment of firing, setting the order of shooting of the specified cartridges.

A unitary cartridge of a remote electric shock weapon having a body with a barrel channel, a charge of pyrotechnic propellant composition with an electrical initiation device of the bridge, current-conducting or spark type of electric ignition, a probe with laying of a current conductor in the shell, a wad-pan for obturation of the barrel channel, on the front end of the body there are symmetrical recesses extending into the barrel channel, and the end of the probe conductor coming out of the barrel channel is electrically connected to the contact point on the outer generatrix of the cartridge surface near the front end of the housing.

An additional feature is that the contact area is made of adhesive metal foil or metallization.

An additional feature is that the probe contains a non-conductive shell and has an electrically conductive path on the surface of the probe, one end of which is electrically connected to the contact point of the cartridge body, and the other end of the wad-pallet adjacent to the electrode, passing from the generatrix of one end of the wad-pallet to the generatrix of the other end.

An additional feature is that the probe contains a conductive shell and has two contacts electrically connected to the conductive shell, with one contact electrically connected to the contact point of the cartridge body and the other contact adjacent to the electrode of the wad-pallet passing from the generatrix of one end of the wad-pallet to the generatrix of the other end.

A unitary cartridge of a remote electric shock weapon having a body with a barrel channel, a charge of pyrotechnic propellant composition with a device for electroinitiating a bridge, current-conducting composition or spark composition, a probe with a conductor laid in a shell and a device for fastening to the target, a wad-pan for obturation of the barrel bore, the end of the probe conductor coming out of of the barrel channel is fixed on a destructible element protruding near the front end of the body on the outer generatrix of the cartridge body, made directly integral with the body or in the form of an easily removable separate element fixed to the body with a given separation force from the body, and on the opposite side of the outer generatrix of the body, relative to the destructible or easily removable element, is made a recess extending into the barrel channel, while the end of the current conductor, attached to a destructible element or an easily disposable part, is electrically connected to the contact point on the outer generatrix of the cartridge surface near the front end of the housing.

An additional feature is that the contact area is made of adhesive metal foil or metallization.

An additional feature is that the probe contains a non-conductive shell and has an electrically conductive path on the surface of the probe, one end of which is electrically connected to the contact point of the cartridge body, and the other end of the wad-pallet adjacent to the electrode, passing from the generatrix of one end of the wad-pallet to the generatrix of the other end.

An additional feature is that the probe contains a conductive shell and has two contacts electrically connected to the conductive shell, with one contact electrically connected to the contact point of the cartridge body, and the other contact adjacent to the electrode of the wad-pallet passing from the generatrix of one end of the wad-pallet to forming the other end.

Brief description of drawings

Fig. 1. The appearance of a multi-charged remote electroshock weapon with a conventional magazine installed in it and the appearance of a conventional and extended magazine with cartridges for it.

Fig. 2. Types of weapons with half of the body removed 1 type.

Fig. 3. Types of weapons with half of the body removed. 2nd view.

Fig. 4. Types of weapons and high-voltage transformer unit in a disconnected and attached state to the weapon 1 type.

Fig. 5. Types of weapons and high-voltage transformer unit in a disconnected and attached state to the weapon 2nd view.

Fig. 6. Types of weapons and high-voltage transformer unit in a disconnected and attached state to the weapon 3rd view.

Fig. 7. Type of weapon with an extended magazine.

Fig. 8. Right and left standard unitary cartridges initiated by a striking voltage of electric current (external views).

Fig. 9. Right and left standard unitary cartridges for initiation by striking electric current voltage (section and type of probe).

Fig. 10. View of the magazine with the right and left standard cartridges installed in it, triggered by a striking electric voltage.

Fig. 11. Right cartridge of current line break with initiation by striking voltage (external view of the housing).

Fig. 12. Right cartridge of a broken current line with initiation by a striking voltage (appearance of a loaded cartridge).

Fig. 13. Left cartridge of a broken current line with initiation of a damaging electric current voltage (appearance).

Fig. 14. View of the magazine with the current line break cartridges and standard cartridges installed in it.

Fig. 15. Left cartridge of current line break with initiation by low voltage voltage (appearance).

Fig. 16. Left cartridge of current line break with initiation by low voltage voltage (cut).

Fig. 17. A cartridge with an easily resettable insert (a type of cartridge body with a separate insert).

Fig. 18. A cartridge with an easily removable embedded element (a type of cartridge with an installed embedded element and a probe without a split plug for fixing the probe in the cartridge).

Fig. 19. Simplified block diagram of a weapon with the initiation of cartridges by a damaging electric voltage (description of operation).

Fig. 20. Simplified block diagram of a weapon with the initiation of cartridges by low-voltage electric current (description of operation).

Fig. 21. Types of design of devices for holding cartridges in the magazine 1 type.

Fig. 22. Types of design of devices for holding cartridges in the magazine, type 2.

Fig. 23. External views of an experienced DESHO 1st view.

Fig. 24. External views of an experienced DESHO 2nd view.

Carrying out the invention

Fig. 1. The weapon has a body 1 consisting of two halves, into which a magazine 2 is installed, having a front sight 3, unitary cartridges 4, contact points 5 located on both sides of the magazine, and a recess 6 of the magazine retention latch in the body of the weapon. Housing 1 has a double-sided safety switch 7, a trigger 8, double-sided buttons 9, mainly with a lock that allows each button to be set in two firing mode positions, a latch 10 for holding the magazine in the weapon body with a button 11, conductive tracks 12 located on both sides of the housing 1, attachment slides 13, rear sight 14. The elongated magazine 15 has contact points 16 extending from both sides of the magazine surface to the conductive tracks 12.

Fig. 2. Latch 10 with an adjustable button 11 (for clarity, shown additionally separately from the weapon) has leaf springs 17 and can either be moved from one side of the weapon to the other (with the installation of a hole plug in the body on the unused side of the weapon), or be installed on both sides (in this case, the reliability of fixing the magazine in the weapon increases, for example, when using an elongated magazine, but the immediate possibility of extracting the magazine with only one hand holding the weapon disappears), the trigger 8 can interact with the firing switch 18 shots, a board 19 is installed in the handle of the housing 1 microcontroller (and low-voltage initiation switch in the low-voltage initiation version), a generator of striking electric current voltage 20, a power source in the form of a rechargeable battery 21 with a charging socket 22, in housing 1 there are boards of 23 high-voltage switching solid-state switches (Fig. 2 shows 2 boards installed above each other) with high-voltage transistors or thyristors in TO-220 and larger standard sizes), a board of 24 pogopins (spring contacts, “pogo pins”) with pogopins 25, a laser target designator (LCU) 26 and pogopins 27 of the low-voltage battery output or damaging electric current on the outer surface of the housing 1.

Fig. 3. The fuse-switch 7, with the help of its carrier 28, can interact with the switch 29 of the battery 21. The pogopins 25 interact with the contact electrodes of the cartridges 4 when the magazine 2 is inserted into the weapon. The battery 21 can be permanent as shown in the figure or removable.

Fig. 4, 5, 6. Pogopins 27, block 30 of the high-voltage pulse transformer, output high-voltage electrodes 31 of the block 30, hole 32 for the laser beam passage 26, contact electrodes 33 (response to the pogopins 27), skids 13 of the housing 1.

When operating, the generator of a damaging voltage of electric current DESH can produce at the output damaging pulses of a capacitor discharged to the target through fired conductors with a charging voltage of 1000-3000 V. In this regard, to convert such voltage into classic high-voltage voltage pulses for long-known electroshock weapons at the output of electroshock devices (40-90 kV) the output of the damaging voltage generator is connected through the pogopins 27 on the body to the block 30 containing a high-voltage pulse transformer and connected to the DESH on the skid 13 as an attachment. In this case, the user has the opportunity to exert contact pressure on the offender, as well as demonstrate a high-voltage electric discharge. To do this, the user presses the finger of the hand holding the weapon on one or the other button 9, setting the mode of contact action or demonstration of electric discharge. In this case, the damaging voltage generator operates by supplying capacitor pulses of damaging electric current only to the unit 30 attached to the weapon, but does not supply them to initiate cartridges (since neither the high-voltage switching switches nor the low-voltage switching switches are turned on in this mode of operation of the weapon). The operation of keys in different versions of weapons and cartridges, see below. A high-voltage spark discharge develops between the electrodes 31 of block 30, which is used both for contact action through the offender’s clothing and for demonstrating an electric discharge before using a weapon. In another design, block 30 may include, in addition to the high-voltage pulse transformer, additional elements such as a “current” capacitor, diodes, gas dischargers [10], and the number of output pins 27 for a weapon may be more than two. In another design of the weapon, the low-voltage voltage of the weapon's power supply is output to the pogopins 27 and the housing sled 13 can be used to connect other additional attachments, for example, a flashlight, a green laser (which, due to the large dimensions of green lasers available in the Russian Federation, cannot be built into weapon design without increasing its dimensions), sirens, etc. At the same time, additional attachments do not require their own power source. Switching on and off the attachments can be done by pressing the finger of the user's hand holding the weapon on buttons 9. Using the weapon's own power supply to operate the attachments allows you to reduce their dimensions, and therefore the dimensions of the weapon with attachments, which improves the convenience of carrying and using the weapon.

Fig. 7. Weapon with an extended magazine 15 installed in it.

The use of an elongated magazine on elongated cartridges, which do not differ from those described below except for the length, allows you to increase the length of the aiming line (since the front sight of the weapon is located on the magazine itself), and therefore the accuracy of hits, use an elongated probe with a large amount of conductor in the laying, that is, an increase in range shot and, due to increased ballistic data, equip the weapon with an attached butt, attached to the handle of the weapon to turn it into a carbine pistol.

Fig. 8. Right and left standard unitary cartridges initiated by a striking voltage of electric current. Cartridges 4 (position 4 also denotes the cartridge body itself) have a non-conductive body (polymer sleeve) with a barrel channel inside, a split plug 34 for fixing the probe in the cartridge, an output 35 of the rear end of the probe conductor, a contact point 36 of the cartridge made of adhesive metal foil or metallization , initiating conductor 37 of the probe, recesses 38 symmetrically located on the sides of the cartridge and extending into the barrel channel, ledge 39 for fixing the cartridge in the magazine, one of the holes 4 (located symmetrically on one side of the front end of the body) securing the end of the conductor 35. The right and left cartridges will differ from each other only by fastening the end of the conductor 35 at the end of the cartridge in one or another hole 40, respectively, by the location of the contact point 36 near one or the other hole 40 and by the orientation of the conductor 37 of the probe near the contact point 36.

Fig. 9. Section of the cartridge and view of the probe. In the barrel channel 41 of the cartridge there is a probe 42 (laying the current conductor inside the shell (body) of the probe is not shown), a split plug 34, a wad-pan 43 with an embedded electrode 44, a pyrotechnic propellant charge 45 of current-conducting or spark ignition type, an embedded electrode 46 of the rear the end of the cartridge. The charge 45 can be located both in the cavity of the wad-pallet 43 itself, and in the cavity between the rear end of the barrel channel with the electrode 46 and the wad-pallet 43 with the electrode 44, but without a cavity for the charge. The initiating conductor 37 of the probe, electrically connected to the contact point 36 on the side surface of the cartridge, extends out to the front end of the cartridge. The initiating conductor 37 is made primarily of adhesive metal foil glued to the surface of the non-conductive probe shell. In this case, the end of the conductor 37 at the rear end of the probe 42 is adjacent to the electrode 44. If the probe shell is made conductive, front and rear conductors made of metal foil are glued onto it, one of which is adjacent to the contact point 36, and the other is bent onto the rear end of the probe for contact with electrode 44. This design performs the function of a conductor along the body of the probe, similar to the current conductor 37. The probe 42 has an output 35 of the current conductor 47 from the rear end of the current conductor in the probe and a device for fastening to the target 48 in the form of a needle with a barb.

Fig. 10. Magazine 2 with standard cartridges, magazine guide 49 for fixing it vertically in the weapon body, right cartridges 50, left cartridges 51.

Fig. 11. The non-conductive housing 52 of the cartridge for a current line break (right) initiated by a damaging electric current voltage has a protrusion 53 with an undercut 54 on the front end near the exit of the barrel channel. On the side of the cartridge opposite to the protrusion 53 there is a recess 55 that extends into the barrel channel.

Fig. 12. The end of the current conductor 56 from the rear end of the current conductor in the probe is fixed to the protrusion 53 and is adjacent with an electrical connection to the contact point 57 on the side surface of the cartridge. The internal structure of the cartridge is similar to that described in Fig. 8, an initiating conductor 37 is electrically adjacent to the contact point 57.

Fig. 13. The housing 58 of the cartridge break of the current line (left) initiation of a striking electric current voltage differs from the housing 52 in the inverse symmetry of the location of the protrusion 53 and the recess 55 relative to the ledge of fixing the cartridge in the magazine.

Fig. 14. Magazine 2, cartridges 52 (right), cartridges 58 (left), standard cartridge 50 (right), standard cartridge 51 (left).

Fig. 15, 16. Non-conductive housing 59 of the cartridge break of the current conductor (left) with initiation of low-voltage electric current, wad-pallet 60, housing 61 of a standard industrially produced electric ignition-projection device (EED), pyrotechnic propellant charge 62 of low-voltage bridge ignition EED, central electrode 63 EED . The body of the current line break cartridge (right) with initiation by low-voltage voltage differs from the body 59 in the inverse symmetry of the location of the protrusion 53 and recess 55 relative to the ledge of fixing the cartridge in the magazine.

Fig. 17, 18. Non-conductive housing 64 of the current line break cartridge, easily removable embedded element 65. To simplify the manufacturing technology of current line break cartridges with reverse symmetry (two molds), a single cartridge (one mold) can be produced with an easily removable separate element 65 fixed to the body with a given separation force from the cartridge body. In this case, the cartridge body has two identical symmetrical recesses 55 on both sides of the housing 64, in one or the other of which an easily removable element 65 is secured when assembling the right or left cartridge. The easily removable element 65 is attached to the body 64, for example, with glue or by pressing with a given force of tearing it away from the body 64.

In general, in various designs, the inventive weapon can use both cartridges with shots initiated by a damaging electric voltage, and with low-voltage initiation. The main difference between cartridges with low-voltage initiation, both standard (right and left) and with a broken conductor (right and left), is the absence of an initiating conductor 37, an embedded electrode 44 in the wad pan, and the presence of an electronic device. That is, for example, the right and left standard unitary cartridges (i.e., without a wire break) with low-voltage initiation differ from the cartridges in Fig. 8 the absence of an initiating conductor 37, the presence of a wad-pallet 60 and the presence of an electronic device.

The DESHO prototype uses cartridges with shot gas cut-off, which allows for silent shots. All types of claimed cartridges can also use a silent shot. To implement silent shots, the barrel channel of the inventive cartridges simply has a muzzle constriction that stops the wad pan 46 or 60 in the barrel channel when firing and thus prevents the release of shot gases into the atmosphere.

Fig. 19. Block diagram of a weapon with the initiation of cartridges by a damaging electric voltage. The weapon works as follows. Magazine 2 is loaded from behind with right and left cartridges in a row vertically (5 right cartridges and 5 left cartridges) and the ledge of 39 cartridges rests against the corresponding ledge of the magazine and allows the cartridges to move further than to the front edge of the magazine aligned with the front sight 3. Magazine 2 with cartridges 4 is installed in the guide grooves of the weapon body 1 with its guide protrusions 49 and sent to the weapon body. In this case, the pogopins 25 are compressed under the influence of the electrodes of the 46 cartridges. When the magazine recess 6 reaches the latch 10, the latch rotates on its axis under the action of the spring 17, snaps its front locking part into the recess 6 and keeps the magazine from falling out of the weapon body. To simplify the figures, the block diagram shows only three pairs of right and left cartridges (and not 5 pairs as in the figures of weapons and magazines) designated in pairs on the block diagram as -1-2-; -3-4-; -5-6-. numbers on rectangles indicating cartridges. When removing the weapon from the safety switch (item 7 of Fig. 1), switch 29 is turned on. In this case, the voltage of battery 21 6-14 V is supplied to microcontroller board 19.

After aiming at the offender, the user of the weapon presses the trigger (pos. 8 of Fig. 1) which turns on the switch 18 of the microcontroller board 19. The microcontroller turns on a generator of a striking electric current voltage 20 (which produces capacitor pulses of electric current at the output with a frequency of 50-150 Hz and a voltage of 1000-3000 V) and simultaneously closes one high-voltage key 66 (in Fig. 12, key 66 (pairs of cartridges -1-2- shown closed) (the keys are installed on the board pos. 23 of Fig. 2). The striking electric current voltage from the generator 20 along the conductive paths 12 of the weapon body is supplied to the mating contact points 5 of the magazine and then to the contact points 36 of the right and left cartridge (pairs of cartridges -1 -2-) or contact points 57, if cartridges with a broken current line are used. The electrodes 46 of both cartridges are connected in series through pogopins 25. Pulses of damaging electric current pass through the initiating current leads 47, through the electrodes 44 of the wads of the shutters 43 and through the pyrotechnic propellant charges 45 of the right and left cartridges.In this case, charges 45 of both cartridges are initiated as pyrotechnic compositions of either conductive or spark type ignition. The use of one or another type of pyrochemical composition is determined depending on the value of the damaging voltage, for example, conductive type at 1000-1500 V, and spark type at 3000 V or more. When the charges 45 burn, the probes 42 are accelerated in the barrel channels 41 by combustion gases and fly out of the barrel channels, breaking the current conductors 47 and pulling out the conductor laying electrically connected to the contact places 36 of the right and left cartridge. Upon reaching the target, the probes are secured to the target with barbed corners, and the needles enter the epidermis of the target's body. Through the resulting closed circuit, a damaging electric current between the probes passes through the target’s body, causing it to be immobilized from the action of damaging electric current pulses. To increase the current loop with cartridges located close to each other horizontally, one cartridge from the fired pair (for example, the left one) should have a barrel bore predominantly inclined at a downward angle, as, for example, described in the patent of the prototype cartridge. The damaging current passes to the target while the user holds down the trigger 8.

If it is necessary to carry out the arrest mode, the user presses button 9 before shooting. In this case, after the shot, the microcontroller implements a timer mode in which, even after the user releases the trigger 8, the damaging voltage continues to flow to the target for a time that is safe according to medical standards, but sufficient to to arrest the offender. To fire the next shot without engaging the arrest mode, the user releases the trigger and presses it again. In this case, the high-voltage key 66 of the first fired pair of cartridges (-1-2-) opens, cutting off the flow of damaging current from the target, and the second high-voltage key 66 closes, repeating the above-described cycle of initiating cartridges and shots, but for the second pair (-3-4-) . If the next shot is needed, the pair of fired cartridges (-3-4-) is switched off and the next pair (-5-6-) is initiated. In total, in this way, 5 pairs of cartridges in the magazine can be initiated sequentially with the disconnection of the previous fired pairs of cartridges with conductors leading to the targets (Fig. 6). Disconnecting the previous fired pairs of cartridges from the target is necessary because the leakage of the damaging and at the same time initiating electric current to the previous target can cause a voltage drop to initiate the next pair of cartridges (partial or complete shunting of the electric current already struck by the conductors of the previous fired pairs of targets) and failure of the shots. In the given version of 5-shot weapons and cartridges, only 10 pieces are used. There are 24 pogopins installed on the board (one pogopin per cartridge) and 5 high-voltage transistors or thyristors for switching the striking voltage of the electric current and initiating the cartridges). Pairs of cartridges are fired primarily from the lower pairs of cartridges in the magazine upwards (toward front sight 3) to reduce the possibility of subsequent fired probes deviating from the conductors of previously fired probes that are already reaching toward the targets. Since on one side of the weapon the conductive paths 12 during shots are constantly under the potential of the first pole of the generator of the damaging voltage of the subsequent shot, it increases the possible current loops between the previously hit probes of the first pole and the probe of the second pole that has again entered the body, which increases the effectiveness of the physiological effect on the offender by creating body additional electric current loops. Due to the fact that the damaging current voltage is transmitted to the cartridges via conductive tracks 12 located on the surface of the weapon body, the tracks will perform the functions of anti-snatch electrodes.

When the offender attempts to take the weapon away from the user by grabbing the body of the weapon with his hand, the user only needs to fire a shot and at least two tracks 12 will be energized with a damaging electric current, which will have a painful effect on the offender’s hand grasping the weapon and will force him to release the weapon he has captured. When the user shoots all pairs of cartridges from the magazine or if it is necessary to reload the magazine, the user presses the index finger of the hand holding the weapon on the button 11 of the latch 10. The latch 10 rotates on its axis, its front locking part comes out of the recess 6 of the magazine and the magazine is under the influence of a buoyant force 25 pogopins compressed during loading are energetically thrown out of the weapon. In this way, extraction of the magazine from the weapon is achieved without the help of a second hand, increasing the speed of reloading the weapon with the next magazine. To fire the next shot in the arrest mode, the user releases the trigger, but the damaging voltage continues to flow into the arrested person until the timer expires. But if the next shot is needed, the user can press the trigger. In this case, the striking voltage will be turned off from the first pair of cartridges, but the next pair of cartridges will be initiated and the arrest mode will work again.

Fig. 20. Block diagram of a weapon with the initiation of cartridges by low-voltage voltage (weapon power supply voltage) of electric current. The weapon works as follows. Loading of cartridges with initiation by low voltage voltage is carried out similarly to that described in Fig. 19. When inserting the magazine, the pogopins 25 are compressed by the influence of the central electrodes 63 of the ECU of the cartridges and the end of the housing 61 of the ECU, which is the second electrode of the ECU. Unlike the weapon design of FIG. 19 on the board 24 pogopins are installed 20 pcs. pogopins (two pogopins per cartridge).

To simplify the figures, the block diagram shows only three pairs of right and left cartridges (and not 5 pairs as in the figures of weapons and magazines) designated in pairs on the block diagram as -1-2-; -3-4-; -5-6-. When removing the weapon from the safety switch (item 7 of Fig. 1), switch 29 is turned on. In this case, the voltage of battery 21 6-14 V is supplied to microcontroller board 19. After aiming at a certain part of the offender's body, the user of the weapon presses the trigger (pos. 8 of Fig. 1) which turns on the switch 18 of the microcontroller board 19. The microcontroller turns on a generator of a striking electric current voltage 20 (which produces capacitor pulses of electric current at the output with a frequency of 50-150 Hz and a voltage of 1000-3000 V) and simultaneously closes one high-voltage key 66 (in Fig. 13, key 66 (pairs of cartridges -1-2- shown open).The damaging electric voltage from the generator 20 along the conductive paths 12 is supplied to the mating contact points 5 of the magazine and then to the contact points 36 of the right and left cartridge (pairs of cartridges -1-2-) or contact points 57 if cartridges with a break are used wires. At the same time, the low-voltage switch of the microcontroller board supplies low-voltage voltage (closes the low-voltage transistor switch) of the battery 21 to electrode 68 (one pogopin of the cartridge -2- (from the pair -1-2-), adjacent to electrode 63 of the ECU), the second electrode 67 (the second pogopin of the cartridge -2-) is adjacent to the end of the housing 61 of the EVU and is permanently connected to one of the poles of the battery 21. Low-voltage electric current passes through the bridge of the EVU and initiates the pyrotechnic propellant charge 62 of the EVU. When the charges 62 burn, the probe 42 accelerates in the barrel channel of the cartridge and flies out of it, pulling out the conductor laying out of itself. When the target is reached, the probe is fixed to the target. The user moves the aiming point to another part of the target's body and, again pressing the trigger of the weapon, fires the next shot. In this case, the low-voltage switch supplies low-voltage voltage to the ECU of cartridge -1- (from the pair -1-2-), the second cartridge of the pair is fired and the second probe hits the target, after which the damaging voltage of the electric current forms a closed circuit "damaging voltage generator - body goals", immobilizing the offender. In the absence of immobilization (for example, a broken conductor, a small current loop, insufficient depth of penetration of the probe needle into the target due to the thick clothing of the offender), the user of the weapon fires the next shot. In this case, the second key 66 of the pair -3-4- cartridges is turned on and a low-voltage voltage is supplied to initiate the cartridge -4- of the next pair and the next probe hits the target. Key 66 of a pair of -1-2- cartridges, depending on the microcontroller program, can either turn off the first circuit of the damaging voltage or leave a damaging potential on it. In this case, a current loop between three probes entering the target’s body can form or change, increasing the effectiveness of the attack. With the next shot, the probe of the cartridge -3- pairs -3-4- will hit the target’s body, further increasing the variability of the current loop and again increasing the effectiveness of the kill. Thus, the user can, as in the prototype device, fire only 9 additional shots after the first probe hits the target’s body with each shot, increasing the variability of the current loop. With different programming, when firing each subsequent pair of cartridges, the damaging voltage can be switched off with keys 66 for switching the damaging voltage to pairs of cartridges from the previous pair of cartridges. This mode of firing in pairs of cartridges at once is effective when acting not on one, but on several offenders appearing sequentially one after another, since each offender will be struck by the full value of the current damaging electric current on a pair of conductors, and not by a reduced value due to a voltage drop across the loads previously struck goals.

The principle of firing cartridges one at a time makes it possible to significantly increase the current loop when shooting a pair of cartridges due to the separation of the impact points of the probes compared to the design of the weapon in Fig. 19. where the current loop when firing a pair of cartridges is limited by the distance to the target and the angular divergence of the barrel channels of the cartridges. In the mode of firing one cartridge at a time, it is not necessary to tilt the barrel of one of the cartridges at an angle downward.

The weapon can also fire simultaneously with a pair of cartridges as described in Fig. 2, 3. In this mode, when the trigger is pressed, a low-voltage voltage initiating the cartridges is applied to a pair of cartridges at once. In this case, to increase the current loop, it is advisable to pair one cartridge with a barrel bore inclined at an angle downward. The weapon can also carry out the arrest mode both when firing single shots and a couple of cartridges at once.

For a deliberately guaranteed increase in the current loop (for example, during tempo shooting, when there is no time to transfer points of impact to targets), a weapon can have a firing mode not only with horizontal pairs of cartridges, but also with cartridges staggered relative to their position in the magazine. For example, in the mode of firing cartridges one at a time, shoot cartridge -2-, followed by cartridge -5- located farthest from it in the magazine. Then shoot cartridge -1-, followed by cartridge -6-. With 5 pairs of cartridges in the magazine (and not 3 pairs as shown in the block diagram), the distance of the possible current loop will be even greater. In the shooting mode, a pair of cartridges -2-5- are fired simultaneously with a pair of cartridges, followed by a pair of cartridges -1-6-. In this mode of shooting pairs of cartridges, it is permissible to use cartridges without using one of the cartridges with a barrel bore inclined at an angle downward.

The supply of a damaging current to the fired conductors with probes can be carried out either only when the user holds the trigger after pressing it and firing a shot, or for some time, set by a timer after releasing the trigger without specially turning on the arrest mode.

All of the specified options for firing modes (and those newly created by programming) can be changed by installing specified microcontroller programs using buttons 9 (not shown on the block diagram to avoid cluttering the block diagram). On the flat rear end of the weapon body above the pistol grip, an LED screen can be installed to display information about the state of the weapon, displaying the operating modes of the weapon, the state of charge of the battery, the condition and performance of internal components, the shot counter, the time of use of the weapon and other similar information, which is already considered classic and mandatory in DESHO manufactured by Axon Enterprise, Inc. USA, and accordingly the global trend. DESHOs without such functions are no longer allowed to participate in tenders of foreign law enforcement agencies. However, the introduction of all additional functions into a weapon other than those necessary directly for shooting (as in classic firearms) seriously increases the cost of the weapon and is actually not required for the production of the proposed weapon for Russian law enforcement officers.

When the user has fired all pairs of cartridges from the magazine or when it is necessary to reload the magazine, the user extracts the magazine in the same manner as described in FIG. 19.

Shooting pairs of cartridges is carried out mainly from the lower pairs of cartridges in the magazine upwards (towards the front sight 3) also as described in Fig. 2, 3, except for the mode of shooting cartridges in the magazine, they are inconsistent with respect to the horizontal arrangement of the pairs. Weapon according to Fig. 13 uses only 5 high-voltage transistors or thyristors for switching the striking voltage of the electric current and 10 low-voltage transistors for initiating the electronic device.

In one version of the weapon as in FIG. 19, and according to Fig. 20. The generator of the striking voltage of the electric current 20 can supply the cartridges through the switches 66 with pulses of the striking electric current already generated by the output high-voltage switch of a separate generator that sets the frequency of the striking pulses as part of the generator 20. In another design, the initiating and then the striking current pulses are formed when resistances are first connected to the circuit current-conducting ignition pyrotechnic compositions of charges 45, and when the conductors of the probes that hit the target are closed by the resistance of the target's body, switched on during initiation in series first with charges of 45 cartridges, and then in series with the target (as part of the generator 20, a threshold element (gas discharger) of the output capacitor of the generator 20 operates constantly generator 20 charged from an inverter with a constant output voltage of 1000-3000 V.). In the third version, the generator 20 itself does not contain an output high-voltage switch or threshold element, and the switches 66 themselves, when they are launched during a shot, form pulses of damaging voltage, working from a separate generator within the generator 20 that sets the frequency of the damaging pulses.

In both versions of the weapon (both in Fig. 19 and in Fig. 20) cartridges with forced breakage of current conductors can be used. Such cartridges will be used for the purpose of forcibly separating the current conductors of previous shots from the weapon in order to free the flight trajectories of the probes of the next fired cartridges from the current conductors of previous shots reaching towards the target, which can deflect the newly fired probes from the target. The firing of cartridges with a forced break in the current conductors proceeds from the lower cartridges in the magazine up to the front sight of the magazine. In FIG. 15 you can see the protrusions of the 53 lower pairs of cartridges (left and right) entering the recesses of the 55 upper pairs of cartridges when loading cartridges into the magazine. In this case, part of the protrusions 53 of the lower pairs of cartridges through the recesses 55 of the upper pairs of cartridges enter the barrel channels of the upper pairs of cartridges, partially blocking the barrel channels. The first pair, starting from the bottom of the magazine, is fired back and the conductors attached to the protrusions 53 are pulled towards the target. When shooting the second pair of cartridges from below, their probes, flying out of the barrel channels, vigorously interact with the parts of the protrusions 53 protruding into the barrel channels and break them off at the undercuts 54 and are thrown out of the barrel channels. In this case, the current conductors of the lower pair of cartridges, held by the projections 53, are disconnected from these cartridges and, accordingly, from the weapon. Thus, shooting subsequent cartridges separates the conductors of previously fired cartridges from the weapon. Throwing out previous conductors does not affect the accuracy of the probes' flight. The last pair of cartridges installed during loading near the front sight of the magazine does not have protrusions 53, that is, they are standard cartridges (without breaking the current line) since with this design of the magazine, cartridges with protrusions 53 cannot be installed in the magazine during loading. When designing cartridges with broken conductors according to Fig. 18, the force of dropping element 65 from the cartridge body must be obviously greater than the force of its separation from the cartridge body that occurs after the probe leaves the barrel channel due to the resistance force of the unwinding (exit) of the conductor from the probe shell.

Fig. 21. Top view. Magazine 2 with springy tongues 69 made integral with it on its lower wall, protruding inside the magazine and pressing the cartridges to each other and to the upper inner wall of the magazine, protecting the cartridges from falling out when handling the magazine.

Fig. 22. Bottom view. A magazine with protrusions 70 protruding into the magazine, made integral with it on both side walls, and one of the cartridges with a reciprocal recess 71. When loading cartridges into the magazine, due to the elasticity of the magazine walls, the protrusions 70 can fit into the recesses 71 of the cartridges, snapping into place and protecting the cartridges from falling out when handling the store. (bottom view).

Fig. 23, 24. Appearance of a working experimental DASH made by 3D prototyping, magazine and firing cartridges.

List of cited sources:

1. https://help.axon.com/hc/en-us

2. US20220074715 patent family EP3963281

3. https://www.police1.com/police-products/less-lethal/taser/articles/why-i-think-the-taser-10-may-be-the-most-effective-less-lethal- device-in-history-dmpdMBS5efSNTL6l/

https://www.officer.com/tactical/less-lethal/ecd-electronic-control-devices/article/53060233/the-taser-10-new-and-improved

4. Ladyagin Yu.O. "Remote electroshock weapon" M.: Stalingrad Foundation Publishing House, 2017, pp. 354-355.

5. https://www.prnewswire.com/news-releases/axon-reports-q1-2023-revenue-of-343-million-up-34-yoy-raises-outlook-301820005.html

https://www.sec.gov/Archives/edgar/data/1069183/000155837022002006/axon-20211231x10k.htm

6.WO2023009456

7. RF Patent No. 2308668

8. RF Patent No. 2607701

9. Ladyagin Yu.O. "Remote electroshock weapon" M.: Stalingrad Foundation Publishing House, 2017, pp. 286-289.

10. Ladyagin Yu.O. "Remote electroshock weapon" M.: Stalingrad Foundation Publishing House, 2017, pp. 457-462.

11. RF Patent No. 2701290

Claims (27)

1. Multi-charge remote electric shock weapon, containing a housing, a power supply, a generator of a damaging electric current voltage, a microcontroller control system, electric current switching devices, a fuse switch, a removable magazine, characterized in that the removable magazine is a profile hollow shell with contact places, the magazine is configured to be loaded with unitary cartridges, which are designed to be located in the magazine without gaps close to each other and which are loaded from the rear end of the cartridges by the force of the springs of electrical contacts located inside the housing, at the same time, through the contact points of the magazine, the damaging electric current voltage from the generator is supplied to the contact points of the cartridges, which are located on the outer generatrix of the cartridge surface at the front end of the body, the removable magazine is fixed in the body by at least one spring-loaded latch, which has a drive for forced release of the magazine from the body of the weapon, operating from the fingers of the user’s hand holding the weapon, The conductors of the generator of the damaging electric current voltage from the switching device to the electrical contact points of the cartridges in the magazine are located on the outer side surfaces of the front part of the housing. 2. A weapon according to claim 1, characterized in that the body has contact points for the voltage output of the power supply on the outer surface of the case, switched by buttons on the case. 3. The weapon according to claim 1, characterized in that the body has contact points where the damaging voltage of the electric current exits onto the outer surface of the body, switched by buttons on the body. 4. Weapons according to paragraphs. 1 and 3, characterized in that a high-voltage pulse transformer with contact-action electrodes is electrically connected to the contact points of the output of the damaging electric current voltage and fixed to the housing. 5. The weapon according to claim 1, characterized in that on the outer surface of the profile shell of the magazine there is part of the sighting devices of the open sight. 6. Weapons according to claim 1, characterized in that the magazine has on its inner walls protrusions for spring-loading cartridges in the magazine or protrusions for fixing cartridges with reciprocal depressions in the cartridges. 7. The weapon according to claim 1, characterized in that the magazine is made to extend beyond the dimensions of the weapon body and has contact points with conductive tracks on the outer surface of the magazine. 8. The weapon according to claim 1, characterized in that the spring-loaded latch is rearranged on both sides of the body. 9. Weapons according to claim 1, characterized in that the electric current switching devices generate pulses of damaging electric current. 10. The weapon according to claim 1, characterized in that the microcontroller control system is configured to select the operating mode of the weapon before the moment of firing, setting the order of shooting of the specified cartridges. 11. The unitary cartridge of a remote electric shock weapon according to claim 1, containing a housing with a barrel channel , a charge of pyrotechnic propellant composition with an electrical initiation device of the bridge, conductive or spark type of electric ignition, a probe with a conductor laid in the shell, a wad-pan for obturation of the barrel bore, characterized in that At the front end of the housing there are symmetrical recesses extending into the barrel channel, and the end of the probe conductor emerging from the barrel channel is electrically connected to the contact point on the outer generatrix of the cartridge at the front end of the housing. 12. The cartridge according to claim 11, characterized in that the contact area is made of adhesive metal foil or metallization. 13. The cartridge according to claim 11, characterized in that the probe contains a non-conductive shell and has an electrically conductive path on the surface of the probe, one end electrically connected to the contact point of the cartridge body, and the other end adjacent to the electrode of the wad-pan, passing with the generatrix of one end of the wad - the pallet onto the generatrix of the other end. 14. The cartridge according to claim 11, characterized in that the probe contains a conductive shell and has two contacts electrically connected to the conductive shell, with one contact electrically connected to the contact point of the cartridge body, and the other contact adjacent to the electrode of the wad-pallet passing with forming one end of the wad-pallet onto the generatrix of the other end. 15. Unitary cartridge of remote electric shock weapon according to claim 1, containing a housing with a barrel channel, a charge of a pyrotechnic propellant composition with a device for electrical initiation of a bridge, current-conducting composition or spark composition, a probe with laying of a current conductor in the shell and a device for securing to the target, a wad-pan for obturation of the barrel bore, characterized in that the end of the probe conductor coming out of the barrel channel is fixed on a destructible element protruding from the front end of the body on the outer generatrix of the cartridge body, made directly integral with the body or in the form of an easily removable separate element, fixed to the body with a given separation force from the body, and on the opposite side of the outer generatrix of the housing relative to the destructible or easily removable element, a recess is made that extends into the barrel channel, while the end of the current conductor, attached to the destructible element or easily removable part, is electrically connected to the contact point on the outer generatrix of the cartridge at the front end of the case. 16. The cartridge according to claim 15, characterized in that the contact area is made of adhesive metal foil or metallization. 17. The cartridge according to claim 15, characterized in that the probe contains a non-conductive shell and has an electrically conductive track on the surface of the probe, one end electrically connected to contact point of the cartridge body, and the other end adjacent to the electrode of the wad-pallet, passing from the generatrix of one end of the wad-pallet to the generatrix of the other end. 18. The cartridge according to claim 15, characterized in that the probe contains a conductive shell and has two contacts electrically connected to the conductive shell, with one contact electrically connected to contact point the cartridge body, and the other contact is adjacent to the wad-pallet electrode, passing from the generatrix of one end of the wad-pallet to the generatrix of the other end.