RU2781908C1 - Revolver remote electric shock weapon - Google Patents

Abstract

FIELD: protection technology.

SUBSTANCE: revolver remote electroshock weapon contains a body, which is a revolver frame, a power source, an electronic circuit for generating an electric current voltage striking the target, a drum with radially arranged charging chambers of firing cartridges with a throwable current line. The drum is made with the possibility of rotation relative to the body when the trigger is pressed, firing two firing cartridges from the chambers of the drum and breaking the conductive circuit between the weapon and the target before the subsequent shot.

EFFECT: RESW in the form of a revolver, an increase in the number of shots without reloading, a reduction in the dimensions of a multi-shot RESW.

13 cl, 18 dwg

Description

The technical field to which the invention belongs

The invention relates to a multi-charged remote electric shock weapon (DESHO), with an electric means of destruction for the self-defense of citizens and use in law enforcement agencies.

State of the art

As an analogue of the proposed invention, the DESHO according to the patent [1] was chosen. DESHO made in the form factor of a pistol consists of a housing in which a power supply is located, a fuse for turning on the power supply, an electronic circuit that generates a high-voltage electric current that hits the target, a trigger element, firing cartridges with projectile current ducts located in the firing cartridge. Two cartridges are fixed in the body with latches, which have a drive for releasing the cartridges from the body, actuated with the fingers of the hand holding the DESHO. Cartridges are inserted into the DESHO with forced compression of two springs for removal (extraction) of cartridges from the housing. After pressing the fingers of the hand holding the DESHO on the release drives, the cartridges under the action of the compressed extraction springs can be extracted from the DESHO body. Cartridges have a propellant pyrotechnic charge initiated from a low-voltage electrical current of the power supply supplied through special cartridge launch contacts located on the end of the cartridge when the trigger is pressed. When fired, the propellant charge of the cartridge ignites and emits probes with current ducts at the target with combustion gases. The conductor laid in the probes, during the flight of the probes to the target, is unwound from the probes and, when the probes hit the target, a closed electric circuit of the DESO-target is formed. Through the conductors stretched from the DESHO to the target, the high-voltage damaging voltage of the electric current generated by the high-voltage node is transmitted from the DESHO to the target. After the first shot, the user of the DESHO can, by pressing the finger of the hand holding the DESHO on the drive for releasing the fired cartridge, extract it from the DESHO by acting on it by the spring compressed when the cartridge is loaded into the DESHO and fire again from the second firing cartridge, and then by pressing the fingers of the hand holding the DESHO by pressing on the release drives, extract the second firing cartridge from the DESHO by acting on it with the second spring compressed when the cartridges are loaded into the DESHO. The main drawback of the analog is that a non-lethal self-defense weapon should, by its very appearance, when it is demonstrated to the offender, stop the aggression of the attacker, who must consider that it is deadly in the same way as a firearm. As is known from centuries-old practice, the demonstration of firearms alone reduces the degree of aggressiveness of the attacker in the vast majority of cases and, with a high probability, makes it possible to avoid the use of weapons. However, all DESHO models produced in the world, including the analogue, either have a design that is not defined as a weapon, for example, Taser Pulse, Taser C1, (Axon Enterprise, Inc.) or only remotely resemble a pistol and only to people who are completely unfamiliar with short-barreled weapons. The majority of offenders are aggressive men who are well aware of the type of handguns. Thus, an analogue only remotely resembling a pistol has an extremely low "relative psychological stopping effect" (RPS) [2].

Another drawback of the analog is the small number of charges (only two firing cartridges (2 shots without reloading). At the same time, the only relatively 3-charge DESHO Taser X3 in the world (Axon Enterprise, Inc.) released for the US police is no longer produced like this how the police refused to use and purchase it due to the inconvenience of wearing it due to its large dimensions (208x55x127 mm), while the Taser X3 has no resemblance to firearms in terms of form factor. one hand, so it is not a direct analogue of the alleged invention.A multiply charged DESHO should be produced and used primarily in Russia, and here one more property of the Taser X3 could manifest itself, which is a disadvantage for using a DESHO of a similar design in our country.In Russia, there are currently no production technologies DuPont™ Tefzel ® ETFE high-voltage conductor analogs [3] with insulation dielectric strength 11-16 kV AC (for one core) used in DESHO of Axon Enterprise, Inc. Current conductors of all models of Russian DESHO used in the Russian Federation, without exception, are a common installation wire of the MS, MSE or MGTF type with a sintered or twisted winding made of fluoroplast-4D without sintering and designed for a rated voltage of 250-500 V AC (for a common core of a stranded wire) . Therefore, in the event of intersection (contact) of the current conductors of the DESHO used by the police and citizens in the Russian Federation, with the voltages of the high-voltage damaging electric current acting in the DESHO, the inevitable electrical breakdown of the insulation of the current conductors and the corresponding short circuit of the current conductors with shunting of the electric current that strikes the target, that is, shunting the operation of the electronic high-voltage unit that strikes the target, occurs in the DESHO electric current by a closed current conductor of the first shot and the termination of the damaging effect of the electric current on the target. The intersection of current conductors of all models of remote stun guns currently used in the Russian Federation almost always occurs literally after 0.5-1 s of exposure. At the same time, if the probes do not hit the target and the subsequent fall of even DuPont™ Tefzel ® ETFE conductors with excellent dielectric strength to ground also causes the conductors to be shunted through the ground. For a second shot at a target not hit by the first shot and shunted conductors, it is necessary to quickly extract the spent cartridge of the first shot with crossed conductors. In Taser X3, in contrast to the analogue described above [1], the extraction of the first cartridge after the first shot (and the second and third cartridges) could not be performed with one hand due to the fact that the cartridges could be disconnected from the DESHO only with the help of two hands of the user (latches, located on the weapon so that they cannot be opened with one hand holding the weapon). Due to the need to use both hands of the user to extract the cartridges, the time for the second shot is increased. DuPont™ Tefzel ® ETFE wire is prohibited from deliveries to Russia as a dual-use product (used in space vehicles).

The prototype of the alleged invention was not found by patent search. DESHO similar in form factor to a classic firearm revolver does not exist in the world.

Disclosure of invention

The technical problem is to create a DESHO in the form of a revolver to increase the "relative psychological stopping effect" (RPS) that reduces the degree of aggression of the offender during the self-defense of citizens and law enforcement officers and does not allow the escalation of the conflict.

The technical result consists in the implementation of the invention for its intended purpose, i.e. creation of DESHO in the form of a revolver. At the same time, the claimed invention also provides additional technical results, which consist in increasing the number of shots without reloading (in comparison with the above analogue) and reducing the dimensions of a multiply charged DESHO.

The specified technical result is achieved by the fact that a revolving remote electric shock weapon, containing a body representing the frame of a revolver, a power source, an electronic circuit for generating an electric current that strikes the target, a drum with radially arranged charging chambers of firing cartridges with a projectile current lead, made with the possibility of rotation relative to the body when the trigger is pressed, firing two firing cartridges from the drum chambers and breaking the conductive circuit between the weapon and the target before the next shot.

An additional feature is that the housing contains two holes or recesses, or bypass, or combinations thereof for removing firing cartridges from the drum.

An additional feature is that the revolving DESHO additionally contains a fuse for switching on the power supply.

An additional feature is that the shot is fired by firing cartridges from oppositely located drum chambers.

An additional feature is that the firing cartridges after firing are extracted from the revolver drum forcibly or automatically.

An additional feature is that the drum has devices for fixing cartridges in chambers with unlocking from chambers forcibly from external mechanical action or automatically from the impulse of movement of the firing cartridge when fired forward or backward relative to the drum, or from the operation of a gas engine or the impact of parts of the equipment of firing cartridges or from combinations of the last two methods.

An additional feature is that the devices for fixing the firing cartridges in the chambers are unlocked when interacting with a part that imitates the trigger of a revolver using transfer parts.

An additional feature is that the drum chambers or body parts have extraction springs for firing cartridges.

An additional feature is that the devices for fixing the firing cartridges in the chambers contain locks with spring-loaded tongues that are unlocked when the firing cartridge is released with locking gases in the cartridge, cutting off gases when the cartridge is pushed forward in the drum when fired or from the application of additional mechanical force to remove the cartridge from chambers.

An additional feature is that the devices for fixing the cartridges in the chambers contain locks with spring-loaded tongues that unlock when the cartridge is kicked back in the drum at the time of the shot.

An additional feature is that the devices for fixing firing cartridges in the chambers contain locks with spring-loaded tongues or tongues without springs, which are unlocked when they are exposed to combustion gases of the propellant charge of the cartridge.

An additional feature is that the devices for fixing firing cartridges in the chambers contain locks that are unlocked when they are exposed to combustion gases of the propellant charge of the cartridge and are separated from the drum when fired.

An additional feature is that the devices for fixing firing cartridges in the chambers contain locks that are unlocked when they are mechanically impacted by a projectile or projectile obturator.

Brief description of drawings

Fig. 1. Two types of DESHO with forced extraction of firing cartridges through a false barrel and a recess in the front end of the frame with side unlocking locks.

Fig. 2. DESHO with half of the frame removed and side release locks (some parts are duplicated outside the frame for a better understanding of the work, the trigger pawl is removed from the drum ratchet).

Fig. 3. Longitudinal central section of the DESHO with locks of the side release drum.

Fig 4. Section of the side release drum on the lock (view of the firing cartridge and details of one chamber).

Fig 5. DESHO with half of the frame removed and central unlocking locks (the trigger dog is removed from the drum ratchet).

Fig. 6. Longitudinal central section of the DESHO with central release drum locks.

Fig. 7. Section of the central release drum along the release lock (the firing cartridge and details are shown in the section of one chamber).

Fig. 8. Two types of DESHO with unlocking the locks of the drum "front recoil" of firing cartridges with a cut-off of the gases of the shot through the recesses or contours of the front end of the frame.

Fig. 9. Two types of DESHO with half of the frame removed and front recoil locks.

Fig. 10. Section of a drum with charged cartridges with a cutoff of shot gases and the axis of the drum.

Fig. 11. Section of a drum with spent cartridges with a cutoff of the gases of the shot and the axis of the drum.

Fig. 12. Description of the operation of the drum locks when loading the DESHO with unlocking the drum locks with normal recoil. Three types. External view of the drum with the axis of the drum. A section of the drum with cartridges in a charged state and a section of the drum along the lock in a state loaded with cartridges.

Fig. 13. Description of the operation of the drum locks DESHO with unlocking the drum locks with normal recoil when firing. Two kinds. A section of the drum with firing cartridges along the lock when fired and a section of the drum along the lock after the shot.

Fig. 14. Description of the operation of the drum locks when loading the DESHO with unlocking the drum locks by a gas engine. Three types. External view of the drum with the axis of the drum. A section of the drum with cartridges in a charged state and a section of the drum along the lock in a state loaded with cartridges.

Fig. 15. Description of the operation of the DESHO drum locks with the drum locks unlocked by a gas engine during firing. Two kinds. A section of the drum with firing cartridges along the lock when fired and a section of the drum along the lock after the shot.

Fig. 16. Description of the operation of the drum locks when loading the DESHO with unlocking the drum locks by removing part of the gas engine. Three kinds. External view of the drum with the axis of the drum. A section of the drum with cartridges in a charged state and a section of the drum along the lock in a state loaded with cartridges.

Fig. 17. Description of the operation of the DESHO drum locks with unlocking the drum locks by removing part of the gas engine during firing.

Fig. 18. Three views of the working model of the DESHO with forced extraction of firing cartridges through a false barrel and a recess in the front end of the frame with central unlocking locks.

Fig. 19. Three types of working model DESHO with unlocking the locks of the drum by a gas engine.

Implementation of the invention

Fig. 1. DESHO (revolver) with forced extraction of firing cartridges consists of a polymer body (frame) 1 assembled from two halves, a polymer drum 2 containing chambers 3 for polymer firing cartridges, a trigger 4, a trigger simulator (trigger) 5 of a revolver, a button or an engine 6 safety switch, button 7 of contact action, false barrel 8, cutout (window) for extraction of firing cartridges 9 in the housing for extraction of firing cartridges, protective electrodes 10, slider 11 of the folding electrode, electrode 12 of constant protrusion on the false barrel, backup button or switch slider 13 , holes 14 indicator LEDs. On the drum 2, a common current-conducting current-collecting ring 15 is installed, locks 16 for forced fixation of firing cartridges, the front ends of which extend into the valleys of the drum, recesses 17 for fixing the drum before firing are made in the drum body, and recesses 18 for fixing the drum during firing are made in the ring and drum.

Fig. 2. Plug-contacts 19 of drum chambers are installed in the drum, and locks 16 whose rear ends go to the rear plane of the end of the drum. The plug-contacts 19 of the chambers are connected by channels 20 with conductors embedded in them (not shown) in pairs symmetrically, respectively, with the drum chambers opposite from the axis of the drum. Parts 21 and 22 having pushers 23 installed in parts 21 and 22 with an angular displacement from the central axis of the drum and the vertical plane passing through this axis, have the ability to move in the frame body 1 under the action of the protrusions 24 of the trigger simulator 5. At the same time, part 25 with its bevel interacts with the bevel of part 21 and is geared from the trigger simulator 5 to part 21. Spring-loaded contact 26 passing through the hole in the wall of the frame adjacent to the rear end of the drum, contacts with plug-contacts 19 during rotation of the drum and is connected by an unshown conductor through a switch to the first of revolver battery poles. The movable contact 27 of the trigger 4 is also a retainer of the drum when fired and interacts with the ring 15 of the recesses 18 and is connected by an unshown conductor to the second of the battery poles. A removable low-voltage battery 28 and an inverter 29 are installed in the handle of the frame, which can include an electronic circuit for controlling the initiation of cartridges (for example, a solid-state key for turning on the low-voltage battery supply voltage) and indication. The button 7 of the contact action installed with a spring in the trigger simulator 5 can interact with the microswitch 30, and the adjustable protrusion 31 of the trigger 4 can interact with another microswitch 32 (for reference, Fig. 3).

Fig. 3. The microswitch 32 interacts with the protrusion 31, the protrusion of which from the trigger 4 can be adjusted by a screw (not visible in the section). The screw 33 serves to adjust the moment of supplying electric current to contact 26, which is possible in different versions of the revolver. The drum 2 can rotate on a hollow axis 34 fixed in the housing 1 with a front cover 35 through and a back cover 36. Inside the axis 34 there is a high-voltage block 37 input wires from which output to the inverter 29 located in the handle through the cover 36. The output high-voltage wires from the unit 37 output through the front cover 35 to the electrodes 10, 12, and folding electrode (reference figure 6). On the plugs 19 of the drum 2 in each chamber of the drum, the internal springs 38 of the extraction of firing cartridges are supported, interacting with the ejector contacts 39, and around the internal protrusions of the drum chambers for placing the ejector contacts 39, springs 40 are placed interacting with the contact bushings 41. In this case, the bushings through their springs and conductors embedded in the body of the drum (not shown in the figure) are galvanically connected to a common current collector ring 15. Bushings 41 and ejectors 39 are pressed against the side and central contacts of industrially produced electric igniters 42 of the "EVU" type, which also contain a small pyrotechnic propellant charge installed in the firing cartridge (body, hereinafter “cartridge body” and “cartridge” are equivalent) 43 containing also an obturator inside, a split plug of the cartridge bore (cartridge cavity) and a probe 44 with a current conductor inside (not shown). Contact 27, when the trigger 4 is pressed, can interact with the slip ring 15, and contact 26 contacts in series with the plug-contacts 19 when the drum rotates. Cartridges 43 have a semi-circular cavity 45 for ball locking.

Fig 4. Drum 2, chambers 3, ring 15, lock 16, plug-contact 19, channels 20 (conductors embedded in them are not shown), extraction spring 38, spring 40, sleeve 41, electric igniter 42, housing 43 of the firing cartridge, probe 44, recess 45 of the firing cartridge body, ball 46 for locking the firing cartridge in the drum chamber. Conductor placed inside the cavity of the probe and electrically connected to the front end of the cartridge (not shown in the figure).

DESHO with lateral unlocking works as follows. The user pushes the locks 16 forward relative to the drum beyond the ends of the locks extending into the valleys of the drum 2. In the chambers 3 of the drum 2 from the front end of the frame 1 containing the recess for loading, sequentially scrolling the drum manually, firing cartridges are inserted containing in the internal cavity of their polymer housing 43 electric igniters 42 employees at the same time with a propellant charge, obturators (wads) probes 44 with laying a current conductor inside them and a fixing device on the target (a needle with a beard), with split plugs that prevent them from being pulled out of the cavity before the shot. When the cartridges are inserted into the chambers 3, they rest with electric igniters 42 against the ejector contacts 39 extended by the force of the springs 38 and compress the springs 38. With further insertion of the cartridges into the chambers, the electric igniters 42 through the contact bushings 41 advanced by the springs 40 compress the springs 40. After the cartridge is inserted into the drum chamber until it stops, the user presses his finger on the end of the lock of the drum protruding into the valley, moving it back relative to the drum, while the ball 46, extended from its final seat in the drum, when inserted into the cartridge chamber by the bevel of the lock step, moves into the seat completely and simultaneously extends into the drum chamber, falling into semicircular cavity 45 of the cartridge. The lock 16 pushed into the drum with its step blocks the ball 46 preventing it from moving out of its final seat due to the shearing force on the ball from the cavity 45 of the cartridge, which is shifted forward by the force of the springs 38 and 40. The cartridges inserted into the chambers are locked in the drum chambers.

The design of the side release lock for cartridges in chambers may be different than the ball-lock design presented here, but the main feature will be that with any design, the side release lock will be opened by pressing on its end or the end of the part transferring to the lock in the rear end of the drum located on the side of the cartridge axis at some angular distance from the cartridge axis and the vertical axis of the drum in the firing position.

After loading all the cartridges into the drum chambers, the user removes the DESHO with the safety switch engine 6 (turns off the fuse) and can fire at the target. When the trigger 4 is pressed, its pawl, spring-loaded at the rear end of the trigger, interacts with the drum ratchet as in a classic revolver, the drum rotates with the installation of symmetrical drum chambers opposite the false barrel 8 and opposite the cutout (window) for the extraction of firing cartridges 9, while the spring-loaded contact 27 of the trigger 4 sinks into the recess 18 for fixing the drum of the ring 15, fixing the drum in the firing position. At the same time, the adjustable protrusion 31 of the trigger presses the button of the microswitch 32, which turns on the inverter 29 powered by the battery 28. In this case, the inverter generates a supply voltage for the high-voltage unit 37 that generates an electrical voltage that strikes the target, which is supplied to the protective electrodes 10 and the ends of the firing cartridges in the chambers drum opposite the false barrel 8 and opposite the cutout 9. At the same time, the initiation of the firing cartridges does not yet occur, since the high voltage does not enter the initiation circuit of the electric igniters 42. Simultaneously or with a slight delay in time (0.01-0.1 s using the electronic delay timer control circuit) a low-voltage voltage is supplied from one pole of the battery 28 to one electrode of the electric igniter 42 of the lower cartridge in the drum through contact 26 with a flexible conductor suitable for it from the electronic control circuit, plug-contact 19, spring 38, ejector contact 39 and through the wire ku channel 20 on the plug-contact 19, spring 38, contact-ejector 39 of the upper cartridge in the drum. From the other pole of the battery, low-voltage voltage is supplied to contact 27 with a flexible conductor suitable for it from the electronic control circuit and through it to ring 15, and from the ring through conductors to springs 40 and through them to bushings 41 and from them to another electrode of electric igniters 42 of the upper and lower cartridges in the drum. In this way, the electric current for initiating the electric igniters is applied simultaneously to the electric igniters of the upper and lower cartridges in the drum. There are shots of the upper and lower cartridges in the drum, while the probes 44, together with obturators, are ejected from the cartridges by combustion gases of the propellant charge of electric igniters and fly out to the target through the opening of the false barrel 8, and the cutout 9 in the body frame. During the flight of the probes to the target, the conductors laid in them are unwound, connecting the devices for fixing the probes to the target and the ends of the firing cartridges, to which a high voltage of electric current that strikes the target is connected. When the probes hit the target, the electric current that hits the target flows through the circuit from the high-voltage block 37 through the conductors of the firing cartridges to the target. The damaging current passes to the target while the user keeps the trigger pressed or is cut off after a certain time by a timer that limits the temporary dose of electricity to the target. When the trigger is released, contact 27 exits the fixation recess 18, and the protrusion of the front end of the trigger enters the drum fixation recess 17 before firing, fixing the drum. To extract the spent cartridges and fire the next shot after hitting the target, the user of the DESHO with the thumb of the hand holding the DESHO reproduces the cocking of the trigger simulator 5 as the cocking of the classic revolver. The upper protrusion 24 of the trigger simulator 5, through the part 25, advances the part 21 relative to the frame, and the lower protrusion 24 advances the part 22 forward relative to the frame. locks 16 coming out to the rear end of the drum and, by pressing on them, move the locks forward relative to the drum. The lock step moves from the ball 46 pressed against it, which comes off its final seat from the shear force of the cavity 45 of the cartridge. By the force of the springs 38 and 40 compressed when loading the cartridge, by means of the ejector contacts 39 and bushings 41 vigorously moving forward relative to the drum, the fired cartridges with the conductors extended to the target are energetically extracted from the drum and the revolver forward through the false barrel 8, and the cutout 9. The electric circuit of the DESHO is broken for the purpose . After that, the user can fire the next shot by pulling the trigger again, and the next extraction of the spent cartridges. To shorten the DESHO, the false barrel may be even shorter than in the figure and may be completely absent, as on Pepperbox revolvers with a closed frame of the Apache revolver type. In fact, the false barrel 8 and the cutout 9 may have a different design, for example, simply bending the frame or thinning it to perform the function of closing the frame and allowing the cartridges to be extracted forward relative to the DESHO.

If it is necessary to make a contact action on the target, the user with the slider 6 folds back, by pressing the slider 11, the folding electrode (for reference in Fig. 6, position 54) connected to the lower protective electrode 10. The electrode 12 of the constant protrusion is connected to the upper protective electrode 10. After that, the user presses DESHO towards the body of the target and presses the thumb of the hand holding the DESHO on the button 7 of the contact action. Button 7 turns on only the high-voltage striking part of the revolver and does not turn on the low-voltage current to initiate the electric igniter 42. The electric current that strikes the target flows through the circuit from the high-voltage block 37 to the electrode 12 and the folding electrode to the target.

Button 7 also serves to demonstrate a high-voltage spark damaging electrical discharge of the DESHO to the offender without making a contact action and firing shots to reduce the aggression of the offender. If it is necessary to discharge the DESHO, the user, by successively scrolling the drum manually, pushes the locks 16 forward relative to the drum beyond the ends of the locks protruding into the valleys of the drum 2. In this case, the cartridges are extracted from the drum.

Fig 5. Plugs-contacts 47 with axial holes, pushers 48, central locks 49, ejectors-contacts 50, drum 51, contact 26, parts 21 and 22. Springs 38, 40 and sleeve 41 in drum 2 do not differ in drum 51 from these details according to Fig.4., Figs. 6. Plug-contacts 47 with an axial hole, pushers 48, contact 26, parts 21 and 22, ejector contacts 50, drum 51, firing cartridges 52, depressions 53 of the bodies of firing cartridges, folding electrode 54.

Fig 7. Drum 51, firing cartridge (body) 52, plug-contact 47, lock 49, ejector-contact 50, cavity 53 of the firing cartridge body, spring 55 of lock 49.

The design of the electrical part of the DESHO with central unlocking does not differ from that described above with lateral unlocking. The mechanical part of the revolver frame is no different, except that the pushers 48 are installed in parts 21 and 22 along an axis coinciding with the axes of the drum chambers installed in the firing position. At the same time, parts 21 and 22 remain unchanged since they have ready-made mounting threaded holes for the possibility of installing both pushers 23 and pushers 48 in them, depending on whether the DESHO will use lateral or central unlocking. DESHO with central unlocking differs from the above-described DESHO with lateral unlocking only in the arrangement of the drum and drum locks.

DESHO with central unlocking works as follows.

The user introduces cartridges into all chambers of the drum 51 from the front end of the frame 1 containing recesses for loading firing cartridges 52 by successively scrolling the drum manually. When the cartridges are introduced into the chambers, they rest with electric igniters against the ejector contacts 50 extended by the force of the springs and compress the springs. With further insertion of the cartridges into the chambers, the electric igniters also compress the springs of the bushings through the contact bushings advanced by the springs. The rear flange of the cartridge presses the tongue of the lock 49 of the drum, pushed into the cavity of the chamber by the force of the spring 55. When the cartridge is inserted into the chamber of the drum until it stops, the tongue of the lock 49 jumps (enters) into the cavity 53 of the body of the firing cartridge and fixes it in the chamber of the drum. The force of the compressed springs of the contact-ejector 50 and the sleeve is not enough to push the cartridge out of the chamber, since the force of the spring 55 and the shape (angle) of the lock tongue 49 and the shape of the cavity 53 (angle) of the cartridge body are selected to prevent the cartridge from being ejected from the chamber. The cartridges introduced into the chambers are locked in the drum chambers.

After loading all the cartridges into the chambers of the drum, the user fires shots or demonstrates a shocking electric discharge in the same way as in the description of the operation of Fig. 4. To extract spent cartridges, the user reproduces the cocking of a classic revolver. The upper protrusion 24 of the trigger simulator 5, through the item 25, advances the item 21 relative to the frame, and the lower protrusion 24 advances the item 22 forward relative to the frame. At the same time, the pushers 48 of the parts 21 and 22 through the holes of the frame wall adjacent to the rear end of the drum along the vertical axis of the drum , interact with the contacts-ejectors 50, the rear ends of which go to the rear end of the drum through the holes in the plugs-contacts 47 and, by pressing them, increase the force to push the spent cartridges forward from the drum chambers. The initial ejection force when cocking the trigger simulator 5 due to the significant ratio of the arms of the trigger simulator lever (changed during its course) can reach several tens of kilograms. The force of the springs 55 of the lock 49 is no longer enough to hold the cartridges in the chambers of the drum and the fired cartridges, by the force of the springs compressed when loading the cartridge, by means of the ejector contacts 50 and bushings vigorously moving forward relative to the drum, together with the conductors extended to the target, are extracted from the revolver forward through the false barrel 8, and notch 9. The electrical circuit of the DESHO with the target is broken. If it is necessary to discharge the DESHO, the user, sequentially manually scrolling the drum, presses the ends of the locks 49 that go into the valleys of the drum 51. In this case, the cartridges are extracted from the drum. In a different design, it is possible to perform a device for extracting spent cartridges from a drum and extracting cartridges when the weapon is unloaded not by the force of pre-compressed springs in the drum, but by the force of the user only when “cocking” the trigger simulator. In this case, the extraction springs are not located in the drum, but directly in the parts 21 and 22, which in this case can have a longer stroke in the frame. With an elongated stroke of parts 21 and 22, when the trigger simulator is “cocked”, the extraction springs are compressed, resting their front ends against the rear ends of the cartridges, and when the drum locks are opened, the cartridges are vigorously extracted from the drum chambers. In such a design, the length of the drum will be less than in the above version, but the length of the frame will be greater.

Fig. 8. DESHO with unlocking the locks of the drum "front recoil" consists of a polymer body-frame (frame) 56 assembled from two halves, a polymer drum 51 (structurally the same as the drum described in Fig 7), a trigger 57, a button or an engine 6 safety switch, button 58 of contact action, false barrel 59, cutout 60 in the frame for firing and extracting firing cartridges, protective electrodes 61, slider 11 of the folding electrode 54, electrode 62 of constant protrusion on the false barrel, slider 63 of the drum reverse, backup button or switch slider 13, holes 64 indicator LEDs, cutout 65 of the false barrel 59 for firing and extraction of firing cartridges, contact lever 66.

Fig. 9. In the frame 56, a trigger 57 is installed with a spring-loaded pawl having a protrusion 67 and a lever 66, in turn, interacting with the rocker arm 68, the upper end of which interacts with the slider 69 with a spring-loaded contact 70 (pogo pin) installed in it, and the lower end interacts with a microswitch 71. A removable battery 28 and an inverter 29 are installed in the handle of the frame. A pusher 72 movable in the frame associated with the engine 63 can interact with the protrusion 67 of the trigger pawl 57. A cover 73 with samples 74 is installed in the hollow axis 34 of the drum.

Fig. 10. In a DESHO with the drum shown in FIG. 8 and FIG. 9, a silent-type firing cartridge with a cut-off of the gases of the shot is used. This type of firing cartridges, but not with low-voltage, but with high-voltage initiation of the propellant charge, is described, for example, in [4]. The cartridge consists of a body 75 with a choke 76 (choke in specific designs of cartridges is performed in various ways), a probe 77 is placed in the cavity of the cartridge with an outer diameter not exceeding the inner diameter of the choke with laying a current conduit (not shown) inside it, an electric igniter 42 which is separated from the probe with a rigid plastic obturator 78, the muzzle hole of the cartridge is closed by a split plug. The cartridge 75 has firing cartridge body cavities 79 similar to the cavities 53 of firing cartridge bodies 52. In FIG. 10, the cartridges are shown in the state loaded into the drum and are held by the troughs 79 of the locks 49 as shown in FIG. 7, but in the sectional plane of FIG. 10 locks do not fall and they are not visible on the figure. In this case, the front ends of the cartridges are flush with the front plane of the drum end and are not included in the selections 74 of the front cover 73 of the hollow axis of the drum.

Fig. 11. Spring 38, spring 40, bushing 41, lock 49, ejector contact 50, cover 73 with recesses 74, body 75 of the firing cartridge with choke 76, probe 77, obturator 78, depression 79.

DESHO with unlocking the locks of the drum "front recoil" works as follows.

The user enters into all the chambers of the drum 51 from the front end of the frame 56 containing recesses for loading adjacent to the cutout 60 and cutout 65 firing cartridges 75, sequentially scrolling the drum manually. When the cartridges are inserted into the chambers, they rest with electric igniters against the ejector contacts 50 extended by the force of the springs and compress the springs. With further insertion of the cartridges into the chambers, the electric igniters of the cartridges, through the contact bushings advanced by the springs, also compress the springs of the bushings. The rear flange of the cartridge presses the tongue of the lock 49 of the drum, pushed into the cavity of the chamber by the force of the spring 55. When the cartridge is inserted into the chamber of the drum until it stops, the tongue of the lock 49 jumps (enters) into the cavity 79 of the body of the firing cartridge and fixes it in the chamber of the drum. The force of the compressed springs of the contact-ejector 50 and the sleeve is not enough to push the cartridge out of the chamber, since the force of the spring 55 and the shape (angle) of the lock tongue 49 and the shape of the cavity 79 (angle) of the cartridge body are selected to prevent ejection. The cartridges introduced into the chambers are locked in the drum chambers.

After loading all the cartridges into the drum chambers, the user removes the DESHO with the safety switch engine 6 (turns off the fuse) and can fire at the target. When the trigger 57 is pressed, its pawl, fixed with a spring at the rear end of the trigger, interacts with the drum ratchet as in a classic revolver, the drum rotates with the installation of symmetrical drum chambers opposite the false barrel 59 and opposite the extraction cutout 60 of the firing cartridges 75. At the same time, the trigger 57 through the lever 66 of the contact and the rocker 68 moves the slider 69 with the contact 70 installed in it forward relative to the frame 56. The spring-loaded contact 27 (not different from the description of Fig. 2 and Fig. 3) of the trigger 57 sinks into the recess 18 of the fixation of the drum of the ring 15, fixing the drum in shot position. At the same time, the lower end of the rocker arm 68 presses the button of the microswitch 71, which turns on the inverter 29 powered by the battery 28. In this case, the inverter generates a supply voltage for the high-voltage unit 37 that generates an electrical voltage that strikes the target, which is supplied to the protective electrodes 61 and the ends of the firing cartridges in the drum chambers opposite the false barrel 59 and opposite the notch 60. At the same time, the initiation of the firing cartridges does not yet occur, since the high voltage does not enter the initiation circuit of the electric igniters 42. Simultaneously or with a small time delay (0.01-0.1 s using a delay timer) a low-voltage voltage is supplied from one pole of the battery 28 to one electrode of the electric igniter 42 of the lower cartridge in the drum through contact 70 with a flexible conductor suitable for it from the electronic control circuit, which, having passed through the hole in the wall of the frame adjacent to the rear end of the drum, has already reached and contacted the con tact-ejector 50 and through the channel conductor 20 to the plug-contact 19, the spring 38, the ejector contact 50 to one electric igniter electrode 42 of the upper cartridge in the drum.

From the other pole of the battery, low-voltage voltage is supplied to contact 27 and through it to ring 15, and from the ring through conductors to springs 40 and through them to bushings 41 and from them to another electrode of electric igniters 42 of the upper and lower cartridges in the drum. In this way, the electric current for initiating the electric igniters is applied simultaneously to the electric igniters of the upper and lower cartridges in the drum. The upper and lower cartridges in the drum are fired, while the probes 77 are ejected from the cartridges and fly out to the target through the cutout 65 of the false barrel and the cutout 60 in the frame. During the flight of the probes to the target, the conductors laid in them are unwound, connecting the devices for fixing the probes to the target and the ends of the firing cartridges, to which a high voltage of electric current that strikes the target is connected. When the probes hit the target, the electric current that hits the target flows through the circuit from the high-voltage block 37 through the conductors of the firing cartridges to the target. The damaging current passes to the target while the user keeps the trigger pressed or is cut off after a certain time by a timer that limits the temporary dose of electricity to the target. When the silent type cartridge is fired, the probe 77 accelerated by the pressure of the combustion gases of the propellant composition is ejected from the cavity of the cartridge, which is a false barrel, and the obturator 78 gets stuck in the choke 76. When fired, the body of the silent cartridge experiences double recoil. The usual recoil impulse of throwing a projectile (probe) is directed, as in a classic revolver, back relative to the drum body and further weapons (DESHO), the second recoil impulse called “forward recoil” is added from the transfer of the kinetic energy of the accelerated obturator 78 to the cartridge body when the obturator is braked in the muzzle constriction 76. The momentum of the "forward recoil" is significant in comparison with the usual recoil and depends on the ratio of the obturator mass and the mass of the projectile being thrown. When fired, the “front recoil” momentum increases the effort to push the spent cartridges forward from the drum chambers. The force of the springs 55 of the lock 49 is no longer enough to hold the cartridges in the chambers of the drum and the fired cartridges, by the force of the springs compressed when loading the cartridge, by means of the ejector contacts 50 and bushings that move forward relative to the drum, together with the conductors extended from them to the target, move forward from the drum chambers entering with their ends (dultsy) in the selection 74 of the front cover 73 of the axis of the drum. In this case, the springs 38 and 40 are not fully released, but only partially.

If it is necessary to make a quick shot at the next target, the user again presses the trigger 57, which, by means of a pawl, scrolls the drum to the position of installing not yet fired cartridges in the drum opposite the cutout 65 of the false barrel and the cutout 60 in the frame. When this fired cartridges come out of interaction (from the stop) with the selections 74 of the front cover 73 of the axis of the drum and come out in the cutout 60 and cutout 65 with a flow area greater than the diameter of the body of the firing cartridge. At the same time, springs 38 and 40 that are not fully unclenched, by means of ejector contacts 50 and bushings, vigorously extract the fired cartridges with conductors extended to the target from the chambers of the DESHO drum and the cutouts of the front end of the frame forward. The electrical circuit of the DESHO with the target is broken. With further rotation of the drum until it is fixed in the firing position, new cartridges from the drum are installed opposite the cutout 65 of the false barrel and the cutout 60 in the frame, contact 27 fixes the drum, and a new shot is fired with two cartridges.

If it is necessary to extract the spent cartridges without a subsequent shot, the user, after firing the shots and releasing the trigger with the index finger of the hand holding the weapon, presses the engine 63 to reverse the drum back relative to the frame, and with the thumb of the hand holding the weapon, scrolls the drum by the ring 15 counterclockwise until the tactile sensation of the increased the efforts of turning the drum and the click of fixing the drum in the position before the shot produced by the protrusion of the front end of the trigger, which is included in the recess 17 of fixing the drum before the shot. In this case, the spent cartridges are extracted from the drum. When you press the engine 63, the pusher 72 associated with it, moving back in the frame, presses its end on the protrusion 67 of the trigger pawl 57, squeezing the pawl from the ratchet of the drum and thus providing the possibility of turning the drum in the opposite direction from the direction of its rotation during firing (counterclockwise) . After ejecting the spent cartridges, the user rotates the drum with his thumb in the opposite direction until a tactile sensation of increased drum rotation force and a click of the drum lock, and the empty chambers of the drum are again installed against the cutout 65 of the false barrel and the cutout 60 in the frame. If necessary, make the next shot, the user presses the trigger. In this case, opposite the cutout 65 of the false barrel and the cutout 60 in the frame, new unfired cartridges are installed and a new shot occurs. Thus, conceptually, the DESHO with automatic unlocking of the locks of the spent cartridges in the drum when fired and semi-automatic extraction of the spent cartridges when the drum is turned for the next shot is more suitable for fast (tempo) shooting at successively appearing targets, or for quickly repeating a shot at a target if the target is not immobilized with the first shot, which happens periodically for various reasons when using DESHO. If it is necessary to discharge the DESHO, the user sequentially scrolls the drum manually and presses the ends of the locks 49 that go into the valleys of the drum 51. In this case, the cartridges are extracted from the drum. In fact, cutout 65 and cutout 60 may have a different design, for example, simply bending the frame or thinning it to perform the function of closing the frame and allowing the cartridges to be extracted forward relative to the DESH.

All the designs of drums and locks described below also use automatic unlocking of the locks of fired cartridges in the drum when fired.

Fig.12. Drum 80, lock 81, firing cartridge 82 in the cavity of which there is a probe 44 with a current conductor (not shown) inside it, an electric igniter, obturator, a slotted plug closes the muzzle of the cartridge. Cartridge 82 has depressions 83. Drum parts 38; 40; 41; 42; 44; 47; fifty; 55; 73; 74 do not differ from those described above. The tongue 84 of the lock 81 enters the cavity 83 of the cartridge 82. The bushing 41 and the ejector contact 50 are pressed against the contacts of the electric igniter by the forces of their springs acting on the cartridge in the direction of its extraction from the drum and pressing against the tongue 84 by the stop of the cavity 83. When loading the cartridges 82 of the drum, the user enters into all chambers of the drum 80 from the front end of the frame 56 containing recesses for loading, adjacent to the cutout 60 and cutout 65 cartridges sequentially scrolling the drum manually. When the cartridges are inserted into the chambers, the user presses with his finger on the parts of the lock 81 protruding from the windows of the drum for locks. The cartridges rest with electric igniters against the ejector contacts 50 extended by the force of the springs and compress the springs. With further insertion of the cartridges into the chambers, the electric igniters also compress the springs of the bushings through the contact bushings advanced by the springs. When the cavity 83 of the cartridge reaches the lock pressed by the user, the tongue 84 of the lock enters the cavity 83, and the spring 55 is compressed, after which the user stops inserting the cartridge into the chamber and releases the front mouth of the cartridge, and then releases the pressed part of the lock 81. The cartridge does not reach the end stop internal protrusions of the drum chambers for a certain distance. At the same time, the force of the spring 55 is not enough to exit the tongue 84 from the cavity 83, since this is prevented by the force of the compressed springs of the sleeve 41 and the ejector contact 50 and friction with the pointed tongue 84 cutting into the material of the cavity 83 of the cartridge. The cartridges introduced into the chambers are locked in the drum chambers.

Fig.13. DESHO shot with drum locks unlocked by normal recoil from DESHO according to Fig. eight; Fig. 9 is produced according to the description of the work of this DESHO.

When fired, the obturator with the probe 44 in the cartridge is accelerated, while the recoil of the cartridge makes it move backward relative to the drum until it stops at the end of the internal projections of the drum chambers, while fully compressing the springs of the sleeve 41 and the ejector contact 50. In this case, the tongue 84 of the lock is disconnected from the thrust part cavity 83 and the force of the spring 55 compressed during loading rises above the cavity and remains in this position.

After the departure of the probe 44 from the cartridge and, accordingly, from the DESHO, the recoil impulse dries up and the springs of the sleeve 41 and the ejector contact 50 begin to move the cartridge forward relative to the drum. In this case, the cartridge is pulled out of the drum chamber, entering with its necks into the selections 74 of the front cover 73 of the drum axis. In this case, the springs of the sleeve 41 and the ejector contact 50 are not fully unclenched, but only partially (in Fig. 13 the second view, the sleeve spring is fully unclenched, but this position is only for this version). The design of the sleeve ejector spring assembly may be different with increased forward strokes, for example, a contact spring without a sleeve). Extraction of fired cartridges when the drum is rotated is carried out in the same way as described in Fig. 11 by exiting the fired cartridges from interaction with the selections 74 of the front cover 73 of the drum axis and extracting them by the springs of the bushings 41 and ejector contacts 50 through parts of the cutout 60 and cutout 65 with a flow area greater than the diameter of the firing cartridge body. The repetition of shots also occurs as described in FIG. 11, since the DESHO device with normal recoil extraction, except for the drum device and cartridge retention locks, does not differ from the DESHO with “front recoil” extraction. If it is necessary to discharge the DESHO, the user, sequentially scrolling the drum manually and presses the barrels of the cartridges in the drum, while the locks 81 are unlocked and the cartridges are extracted from the drum.

Fig. 14. Description of the operation of the drum locks when loading the DESHO with unlocking the drum locks by a gas engine.

Drum 85, lock 86, firing cartridge 87 in the cavity of which a probe 44 is placed with a current conductor (not shown), an electric igniter, a solid obturator, a slotted plug 88 closes the muzzle hole of the cartridge. generatrix of the cartridge on the internal generatrix of the cavity. Drum parts 38; 40; 41; 42; 47; fifty; 55; 73; 74 do not differ from those described above. The tongue 90 of the lock 86 having a bevel 91 enters the hole 89 of the cartridge 87. The bushing 41 and the ejector contact 50 are pressed against the contacts of the electric igniter by the forces of their springs acting on the cartridge in the direction of its extraction from the drum and pressing against the tongue 90 by the thrust part of the hole 89.

When loading with cartridges 87 of the drum, the user introduces cartridges into all chambers of the drum 85 from the front end of the frame 56 containing recesses for loading adjacent to the cutout 60 and cutout 65, sequentially scrolling the drum manually. When inserting the cartridges into the chambers, the user presses with his finger on the parts of the locks 86 protruding from the windows of the drum for locks. The cartridges rest with electric igniters against the ejector contacts 50 extended by the force of the springs and compress the springs. With further insertion of the cartridges into the chambers, the electric igniters also compress the springs of the bushings through the contact bushings advanced by the springs. When the hole 89 of the cartridge reaches the lock pressed by the user, the tongue 90 of the lock enters the hole 89 and the spring 55 is compressed, after which the user stops the effort of introducing the cartridge into the chamber and releases the front muzzle of the cartridge, and then releases the pressed part of the lock. In this case, the cartridge does not reach the stop at the end of the inner protrusions of the drum chambers by only 0.2-0.3 mm. (not visible in Fig.). At the same time, the force of the spring 55 is not enough to exit the tongue 90 from the hole 89, since this is prevented by the force of the compressed springs of the sleeve 41 and the ejector contact 50 and the friction of the tongue against the thrust part of the hole 89. The bevel 91 of the lock 86 protrudes directly into the internal cavity of the cartridge to a depth of 1 .0-1.5 mm. The cartridges introduced into the chambers are locked in the drum chambers.

Fig.15. A shot from a DESHO with unlocking the locks of the drum by a gas engine from a DESHO according to Fig. eight; Fig. 9 is produced according to the description of the work of this DESHO.

When fired, the obturator 78 with the probe 44 in the cartridge is accelerated, while at the moment the solid head of the probe or the obturator passes along the bevel 91 due to the mechanical force acting on the bevel 91 of the lock 86, the tongue 90 goes beyond the generatrix of the internal cavity with a certain impulse, which is already able to unlock lock 86, since the compressed spring 55 also acts on its unlocking force. If this impulse is not enough, then after the obturator opens the access of the compressed gases of combustion of the pyrotechnic propellant charge to the end of the tongue 90, the pressure of the gases, acting on its area with considerable force, pushes the tongue 90 out of openings 89 of the cartridge, while the spring 55, which is not fully unclenched, also helps to open the lock. Lock 86 opens fully. In fact, complete unlocking of the lock can be achieved both when using only the bevel of the lock 86, and in its absence only by the action of gas pressure on the area of the tongue 90. Therefore, the design shown in the figure is actually combined with automatic mechanical unlocking and simultaneously unlocking by a gas engine. After the lock 86 is unlocked and the probe 44 leaves the cartridge, the springs of the sleeve 41 and the ejector contact 50 begin to move the fired cartridge forward relative to the drum. In this case, the cartridge is pulled out of the drum chamber, entering with its necks into the selections 74 of the front cover 73 of the drum axis. The springs of the bushing 41 and the ejector contact 50 are not fully released, but only partially. Extraction of fired cartridges when the drum is rotated is carried out in the same way as described in Fig. 11 by means of the exit of the fired cartridges from interaction with the selections 74 of the front cover 73 of the drum axis and their extraction by the springs of the sleeve spring 41 and the ejector contact 50 through parts of the cutout 60 and cutout 65 with a flow area greater than the diameter of the firing cartridge body. The repetition of shots also occurs as described in FIG. 11, since the DESHO device with extraction by a gas engine, except for the drum device and the locks for holding cartridges, does not differ from the DESHO with "front recoil" extraction. If it is necessary to discharge the DESHO, the user sequentially scrolls the drum manually and presses the barrels of the cartridges in the drum, while the locks 86 are unlocked and the cartridges are extracted from the drum.

Fig. 16. Description of the operation of the drum locks when loading the DESHO with unlocking the drum locks by removing part of the gas engine.

Drum 92, lock 93 ejected, firing cartridge 87 in the cavity of which there is a probe 44 with laying a current conductor (not shown), an electric igniter, obturator, a muzzle hole of the cartridge closes a split plug 88. Cartridge 87 has a hole 89 cut near the muzzle passing through the outer generatrix of the cartridge on the inside. Drum parts 38; 40; 41; 42; 47; fifty; 73; 74 do not differ from those described above. The tongue 94 of the lock 93 having a bevel 95 enters the hole 89 of the cartridge 87. The sleeve 41 and the ejector contact 50 are pressed against the contacts of the electric igniter by the forces of their springs acting on the cartridge in the direction of its extraction from the drum and pressing against the tongue 94 by the thrust part of the hole 89.

When loading with cartridges 87 of the drum, the user enters into all the chambers of the drum 92 from the front end of the frame 56 containing recesses for loading adjacent to the cutout 60 and cutout 65 cartridges sequentially scrolling the drum manually. When inserting the cartridges into the chambers, the user inserts into the grooves of the drum for locks the plastic locks 93 attached to each firing cartridge and marked by painting or otherwise to indicate the orientation when inserting the locks into the drum relative to the grooves of the drum, presses with a finger on the part of the lock 93 protruding from the grooves of the drum for locks Cartridges abut with electric igniters against ejector contacts 50 extended by the force of springs and compress the springs. With further insertion of the cartridges into the chambers, the electric igniters also compress the springs of the bushings through the contact bushings advanced by the springs. When the opening 89 of the cartridge reaches the user-pressed lock 93, the lock tongue 94 enters the hole 89 and the pressed portion of the lock is fully flush with the outer generatrix of the drum into the lock slots. In this case, the cartridge does not reach the stop at the end of the inner protrusions of the drum chambers by only 0.2-0.3 mm (not visible in the figure). The user stops the force of introducing the cartridge into the chamber and releases the front muzzle of the cartridge and the lock 93. In this case, the lock 93 no longer comes out of the hole 89, as this is prevented by the force of the compressed springs of the sleeve 41 and the ejector contact 50 and the friction of the tongue 94 against the thrust part of the hole 89. The bevel 95 of the lock 93 protrudes directly into the internal cavity of the cartridge to a depth of 1.0-1.5 mm. The cartridges introduced into the chambers are locked in the drum chambers. The drum may also have additional springs permanently installed in it, working to remove the lock 93 from the groove of the drum (similar to the operation of springs 55) to reduce the force of exiting the hole 89 of the tongue 94.

Fig. 17. Description of the operation of the DESHO drum locks with unlocking the drum locks by removing part of the gas engine during firing.

When fired, the obturator 78 with the probe 44 in the cartridge is accelerated, while at the moment the solid head of the probe or the obturator passes along the bevel 95, due to the mechanical force acting on the bevel 95 of the lock 93, the tongue 94 goes beyond the generatrix of the internal cavity with a certain impulse, which is already able to unlock lock 93. If this impulse is not enough, then after the obturator opens the access of the compressed gases of combustion of the pyrotechnic propellant charge to the end of the tongue 94, the pressure of the gases, acting on its area with a significant force, throws the tongue 94 out of the hole 89 of the cartridge and then, by continuing force, the action of compressed gases is ejected from the grooves drum to the sides of the DESHO. In fact, complete unlocking of the lock can be achieved both when using only the bevel of the lock 95, and in its absence only by the action of gas pressure on the area of the tongue 94. Therefore, the design shown in the figure is actually combined with automatic mechanical unlocking and simultaneously unlocking by a gas engine. After the departure of the probe 44 from the cartridge and, accordingly, from the DESHO and the ejection of the lock 93 from the drum, the springs of the bushing 41 and the ejector contact 50 begin to move the fired cartridge forward relative to the drum. In this case, the cartridge is pulled out of the drum chamber, entering with its necks into the selections 74 of the front cover 73 of the drum axis. In this case, the springs of the sleeve 41 and the contact-ejector 50 are not fully unclenched, but only partially. Extraction of fired cartridges when the drum is rotated is carried out in the same way as described in Fig. 11 by means of the exit of the fired cartridges from interaction with the selections 74 of the front cover 73 of the drum axis and their extraction by the springs of the sleeve spring 41 and the ejector contact 50 through parts of the cutout 60 and cutout 65 with a flow area greater than the diameter of the firing cartridge body. The repetition of shots also occurs as described in FIG. 11, since the DESHO device with extraction by removing a part of the gas engine, except for the drum device and the locks for holding cartridges, does not differ from the DESHO with "front recoil" extraction. If it is necessary to discharge the DESHO, the user, sequentially scrolling the drum, manually presses the barrels of the cartridges in the drum, and with the fingernail of the fingertip, catching the lock on its upper part with an edge specially sharpened for easy extraction, removes the locks 93 from the grooves of the drum, and the cartridges are extracted from the drum.

The dimensions of the three-shot revolvers shown in the figures of the application for the invention are equal to 180x46x136 mm, which is 20% less than the volume of the three-shot Taser X3 DESHO, which is no longer produced, with the OPOD exceeding the Taser X3 OPOD by at least an order of magnitude, since the Taser X3 DESHO is not defined by any person as an object similar to firearms in general. The dimensions of the revolvers shown in the figures of the application for the invention can be further reduced by reducing the handle (lower capacity battery) and reducing the false barrel or eliminating it. Revolvers with similar dimensions are well known and are used, among other things, by law enforcement agencies of different states, for example, the large-caliber revolver "Udar" (174x44x136); "Gnome" OTs-20 "(241x45x132); "Nickel" (250x45x132); RSh-12 (357x53x150); S&W 460 XVR (254x48.7x152); Taurus 608 (238X45x152), etc..

Fig. 18. Views of the DESHO from two sides and a view with a folding folding electrode for contact use.

Fig. 19. Views of the DESHO from two sides and a view with a folding folding electrode for contact use.

List of sources cited

1. Patent for a utility model of the Russian Federation No. 197692.

2. V. A. Klevno, S. V. Rasnyuk, and V. Yu. "Limited kill firearms: forensic and psychological aspects, the concept of relative psychological stopping power". Forensic Medicine. 2019; 5(2):16-20. http://dx.doi.org/10.19048/2411-8729-2019-5-2-16-20.

"Firearms of limited destruction: forensic and psychological aspects, the concept of relative psychological stopping action" © V.A. Klevno, S.V. Rasnyuk, V.Yu. Vladimirov 1 GBUZ MO "SME Bureau", Moscow, Russian Federation 2 Department of Forensic Medicine GBUZ MO MONIKI named after. M.F. Vladimirsky, Moscow, Russian Federation 3 Federal State Budgetary Institution "RTsSME" of the Ministry of Health of Russia, Moscow, Russian Federation.

Also: https://www.forens-med.ru/book.php?id=6077

3. Ladyagin Yu.O. "Remote electric shock weapon" M .: Publishing house of the Stalingrad Foundation, 2017, pp. 173-175.

4. RF patent No. 2701290.

Claims (13)

1. A revolving remote electric shock weapon, containing a body representing a revolver frame, a power source, an electronic circuit for generating an electric current striking the target, a drum with radially arranged charging chambers of firing cartridges with a projectile current lead, made with the possibility of rotation relative to the body when the trigger is pressed, firing two firing cartridges from the drum chambers and breaking the current-carrying circuit between the weapon and the target before the next shot. 2. A weapon according to claim 1, characterized in that the body contains a false barrel or notches, or bypass, or a combination of them for firing and for removing firing cartridges from the drum. 3. A weapon according to claim 1, characterized in that it additionally contains a fuse for turning on the power supply. 4. A weapon according to claim 1, characterized in that the shot is fired by firing cartridges from oppositely located drum chambers. 5. A weapon according to claim. 1, characterized in that the firing cartridges are extracted from the revolver drum forcibly or automatically after firing. 6. A weapon according to claim 1, characterized in that the drum has devices for fixing cartridges in chambers with unlocking from chambers forcibly from external mechanical action or automatically from an impulse of movement of the firing cartridge when fired forward or backward relative to the drum, or from the operation of a gas engine or impact pieces of equipment firing cartridges, or from combinations of the last two methods. 7. A weapon according to claim 4, characterized in that the devices for fixing firing cartridges in the chambers are unlocked when interacting with a part that imitates a revolver trigger using transfer parts. 8. A weapon according to claim 1, characterized in that the drum chambers or body parts have extraction springs for firing cartridges. 9. The weapon according to claim 1, characterized in that the devices for fixing the firing cartridges in the chambers contain locks with spring-loaded tongues that are unlocked when the firing cartridge is released with locking gases in the cartridge, cutting off the gases when the cartridge is pushed forward in the drum when fired or from the application of an additional mechanical efforts to remove the cartridge from the chamber. 10. A weapon according to claim 1, characterized in that the devices for fixing cartridges in the chambers contain locks with spring-loaded tongues that unlock when the cartridge is pushed back in the drum at the time of the shot. 11. A weapon according to claim 1, characterized in that the devices for fixing firing cartridges in the chambers contain locks with spring-loaded tongues or tongues without springs, which are unlocked when they are exposed to combustion gases of the propellant charge of the cartridge. 12. A weapon according to claim 1, characterized in that the devices for fixing firing cartridges in the chambers contain locks that unlock when exposed to combustion gases of the propellant charge of the cartridge and are separated from the drum when fired. 13. A weapon according to claim. 1, characterized in that the devices for fixing firing cartridges in the chambers contain locks that are unlocked when they are mechanically acted upon by a projectile or projectile obturator.

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