RU2408835C2 - Arrangement of service cartridge of remote electric-shock weapon (versions) - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: according to the first version, the throw shell of electric conductor has plastic housing in which there is support-and-guide pin around which the conductor routing is arranged. Shell has needle to be attached to the target and internal pyrotechnical charge. In support pin there located is conductor passing from internal electrode of the housing, which projects to external rear end face of the housing to pyrotechnical charge. Shell is arranged on support pin, one end of the conductor is attached to the shell, and the other end of conductor is located on external surface of cartridge. According to the second version, noise-free throw cartridge of electric conductor has plastic housing in which there is support-and-guide pin around which the conductor routing is arranged. Shell has needle to be attached to the target, internal pyrotechnical shell and movable tight piston with elongated electrode fixed in the piston passing through support pin from rear external end face of cartridge to pyrotechnical charge. Conductor is fixed in a way similar to that of the first version.

EFFECT: improving reliability of cartridges.

21 cl, 6 dwg

Description

FIELD OF THE INVENTION

The invention relates to devices for throwing an electric wire of a weapon for remote destruction of biological targets by electric current, specifically to cartridges (cartridges) of propelling devices of an electric wire of a remote electroshock weapon (DESO). Currently, a typical representative of such weapons is the DESO company Stinger Systems (USA).

State of the art

A device is known according to US patent No. 5654867, containing a double cartridge (cartridge) missile electric wire for remote destruction of various targets.

The cartridge contains a common casing, inside of which there are two barrels with missile projectiles, which are oblong cylindrical rods equipped with needles with horns at the ends, the projectiles are pushed out of the barrels with the help of a pyrotechnic charge initiated by a high-voltage shot used in DESO to hit targets. The special pockets of the cartridge contain two stacks of electrical wire (laid in the form of a frameless coil) pulled by shells when fired from the body.

When shells hit the target, they are fixed on it with needles with horns, and the high-voltage shock voltage from the DESO electronic circuit is transmitted to the target via two wires extended from the cartridge.

The described type of cartridge, in fact, is a double unitary cartridge containing in its composition a common housing and an energy source for throwing (powder or pyrotechnic charge), means for initiating an energy source (electric igniter), two (or more) barrels, two (or more ) shells for pulling the electric wire from the cartridge housing and securing the electric wire to the target, two (or more) compact locations for a correctly laid electric wire for its correct (without the possibility of tangling and ruptures during unwinding at a speed of at least 30 m / s) delivery to the target when fired.

However, in comparison with the unitary cartridge for firearms, combining in one case (sleeve) the initiation means (capsule), the energy source for projectile throwing (gunpowder) and the missile projectile itself (for example, a bullet), the described cartridge (cartridge) device has a significant difference. In the case of the described type of cartridge also contains (combined) and a means of initiation, and a pyrotechnic source of energy, and a projectile (shells), and the laying of an electric wire necessary for this type of cartridge, but they are located separately from each other, thus occupying a volume significantly larger than the volume of a unitary firearm cartridge, in which all the components necessary for firing are placed in the common cavity of the body (sleeve). A separate arrangement of the components necessary for the shot, in addition to increasing the volume (i.e. dimensions) of the cartridge, automatically increases the total weight of the cartridge, since a separate arrangement of the elements of the shot entails the need to increase the volume of material for making the case with separate places for placing the components of the shot, and hence, an increase in the weight of the body material.

The need to combine at least two shells and at least two mutually isolated stackings of the electric wire in the case of one cartridge is dictated by the impossibility of efficiently transmitting electricity to the target, except by means of a two-wire method of transmitting electricity using two mutually insulated air gap or insulation of wires. In the cartridge of the described type, two pyrotechnic sources of throwing energy of two shells can be used, each of which works on a separate barrel, the design principle does not change from this, the general pyrotechnic source of throwing energy is used only to reduce the dimensions and reduce the price of the product.

A device of a unitary cartridge for throwing electric wire DESHO according to the application of the Russian Federation No. 2005113206, consisting of a body in the form of a barrel, inside which is placed a projectile (probe) in the form of a sealed laying electric wire in the form of a single-layer, multilayer or hybrid frameless coil in a cylindrical shell (power shell ), one end of the laying wire of such a projectile is rigidly or movably fixed in the cartridge case, and the other end is equipped with a device for securing to the target.

The disadvantage of this cartridge is the practical impossibility of placing in the cavity of the shell of the projectile (probe) sufficient for effective firing at effective distance of effective firing for DESOs from 4.5 m to 10 m of the number of insulated stacking wires that have already been accepted today, with the size of the cartridge used in weapons according to the application of the Russian Federation No. 2005113752 (the size of a rectangular cartridge is 55 × 12 × 12 mm, or the diameter of a cylindrical cartridge is 10-12 mm with a length of 55 mm). The cartridge on the specified application already has the maximum possible dimensions for hand weapons of one hand (in the form of a pistol) in terms of designing weapons of acceptable overall dimensions and weight, weight and dimensions of removable magazines for such weapons. When a cartridge is placed in the shell of the projectile (probe), for example, 10 m of non-insulated wire 0.11 mm thick (the thickness of the wire used for the minimum required strength when throwing it), its volume in the probe is only 0.095 cm ³ . The volume of 10 m of insulated wire thickness (with insulation) of 0.47 mm is already 1.73 cm ³ . Such a volume of insulated wire of the indicated diameter simply does not fit into the cavity of the shell of the projectile in the cartridge with the indicated maximum dimensions for hand weapons of one hand, having a maximum volume of 0.57 cm ³ .

It is currently not possible to reduce the thickness of the insulation of an insulated wire so that its diameter is less than 0.47 mm, since such a diameter has the best insulated wire used for DESHO with an electric insulation strength of ETFE (Tefzel) (with an electric insulation strength of 80 kV / mm) with its thickness of 0.17 mm, having a breakdown voltage of about 27 kV, used in DESO of the world's leading manufacturers of DESO Taser International, Inc. and Stinger Systems (USA).

Currently, the world industry does not produce wires for DESHO of smaller diameter (i.e. less than 0.47 mm) with the indicated breakdown voltage of insulation.

The impossibility of using the amount of insulated wire specified for the effective firing distance in this cartridge design currently allows the use of a cartridge of this design with a bare wire and the tactical “stop target” function in DESHO. There is no possibility of using a cartridge with an uninsulated wire for the more important tactical function “stop and capture the target”.

A device for a silent unitary cartridge for throwing electric wire DESHO according to the application of the Russian Federation No. 2005111260, consisting of a housing with an internal cavity, inside of which there is a single-layer, multilayer or hybrid laying of an electric wire in the form of a frameless coil, a projectile (probe) for pulling an electric wire from the cartridge case is known and securing to the target, in the form of a power cylindrical shell, inside of which there is a pyrotechnic charge with an electric initiation device, the front blind end face of the shell is supplied with a device for securing to the target (for example, a needle with a horn), and one end of the stacking electric wire is fixed to the rear movable-sealed end, and the second end of the stacking wire is fixed in the cartridge case.

The disadvantage of this cartridge is small in comparison with the internal diameter of the cavity, the diameter of the front passage of the guide part of the cartridge. The front part of the cartridge is small in comparison with the internal cavity of the diameter to give a rectilinear directional movement to the probe (projectile), which pulls the laying wire behind it towards the target when firing. When pulling the laying of the wire through a small diameter compared to the maximum diameter of laying the wire in the cavity of a large diameter of the cartridge, the wire drawn at a high speed (more than 35-45 m / s) is braked in the specified narrowing of the diameters, leading to its frequent tangling and rupture at the transition point from a large diameter of the internal cavity to a small diameter of the guide part of the cartridge. The braking of the wire in the specified narrowing and the corresponding loss of probe energy in the process of drawing the wires out of the cartridge cavity, while maintaining the probe’s movement without significantly dropping the flight path, makes the initial departure speed of the probe out of the cartridge increase, which accordingly entails an even greater likelihood of a breakdown of the current-carrying wire. The probe’s energy loss for pulling it out of the cavity and the probability of its breakage when using a thick insulated wire with insulation having a breakdown voltage for one wire of at least 15–20 kV and with an outer diameter of the insulated wire of 0.46 mm are especially great.

According to the application of the Russian Federation No. 2005113752, the manual multi-charged remote stun gun, designed to use these types of cartridges, does not have a barrel (the barrel is the guiding part of the cartridge) or has guide channels, the diameter of which, however, is equal to the diameter of the probe, i.e. equal to the small diameter of the guide part of the cartridge. When you try to increase the diameter of the guide passage of the cartridge when firing a barrelless weapon, the accuracy of shooting drops sharply, since the outgoing probe is devoid of the guide part. With an increase in the diameter of the guide part in the version of the weapon with guide channels, the probe is stuck when fired at the breech of the guide channel with the destruction of the weapon, and when the transition cone part of the breech part of the guide channel is used, tangling and wire breaks occur in this transition cone part, since the wire is braked in connection with its transition from the large diameter of the cartridge cavity to the small diameter of the guide channel is not eliminated.

The disadvantage of all options for the cartridge is the need to place a flexible conductor in the form of a wire or tape, designed to break the initiation circuit and switch to the mode of supplying current to the target on the outer surface of the cartridge. Such an arrangement of a thin and weakly fixed (for the possibility of breaking the circuit) conductor makes the handling of cartridges inconvenient in practical use and especially when loading weapons quickly and inaccurately in combat conditions. In case of accidental breakage during inaccurate handling or fast charging of the flexible conductor, it excludes the initiation of a cartridge when trying to fire a shot.

Disclosure of invention

The aim of the invention is to eliminate the disadvantages of the closest analogues.

The essential distinguishing features of the invention is that a non-conductive tubular support and guide rod is made in the inner cavity of the cartridge, rigidly connected to the rear end of the cartridge case, a radial stacking of the current-carrying wire is placed around the rod, and a metal power cylindrical shell shell inside of which is placed a throwing a pyrotechnic charge located between the inner blind front end of the shell with the locking device fixed to the outer end On the target, for example in the form of a needle with a horn or several needles or an adhesive part and the front end of the rod pulled into the shell, a conductor is located in the axial channel of the rod, which can freely move along the channel axis, passing from the front end of the rod, adjacent to the pyro charge fixed at the end of the axial channel of the electrode extending through the rear end of the cartridge housing to its rear end outer surface. The shell of the projectile is centered on the rod, while one end of the stacking wire is fixed in front of the cartridge and extends to its end or side surface, and the second end of the stacking wire is attached to the rear of the power cylindrical shell of the shell. As a pyrotechnic charge, a specially designed pyrocharger with a spark or electrothermal (for example, wire or graphite bridge heated by an electric current) igniter can be used, as well as a standard shock igniter capsule used for ignition, powder charge of pistol or rifle cartridges.

Unlike the closest analogue, where the pressure of the gases burning during the shot of the pyro-charge is perceived by the inner walls of the body from non-conductive and fragile plastic material, in the present invention the pressure of the gases of the gas burning during the shot of the pyro-charge is perceived by the durable metal shell of the shell. Thus, the walls of the cartridge housing can have a small thickness sufficient only for the mechanical strength of the cartridge during handling. In this regard, the free volume of the inner cavity increases in comparison with the closest analogue, which makes it possible to place in the radial cavity between the inner walls of the cartridge cavity and the power shell of the projectile an amount of wire of 2.57 cm ³ , i.e. 2.57 cm ³ : 0.57 cm ³ = 4.5 times more than in the closest prototype, which makes it possible to lay in an increased volume the amount of insulated wire with a thickness of 0.47 mm not less than 10 m with a sealing coefficient of 1.47 m ³ : 2.57 = 0.57 of the possible.

To ignite the pyrolysis, the end of the conductor is centered on the axial channel of the rod so as to prevent electrical contact between the conductor and the metal shell of the projectile. In this case, the pyrolytic charge will be ignited when fired by a spark discharge, piercing a special or standard capsular pyrocomposition from the centered end of the conductor onto the metal shell of the projectile or capsule body adjacent to the metal shell.

If a standard shock igniter capsule is used as a pyro charge, the end of the conductor is centered directly adjacent to the impact pyrotechnic composition of the capsule, the outer end of which is adjacent to the inner end of the blind end of the power cylindrical shell of the shell.

The pyrotechnic charge may have a wire or graphite filament bridge, electrically connected to the conductor and the shell of the shell, to ignite the pyrocomposition not with the high combat (output) voltage of the stun gun, as is customary in most TESO systems, but with a low voltage, for example, a DESO power source (battery or battery) )

The conductor may have, at the end adjacent to the pyrotechnic charge, a cylindrical plug of elastic material that enters the axial channel of the tubular support and guide rod, such a conductor device facilitates its extraction after a shot to break the initiation chain.

The conductor may be made of a mixture of conductive fuel and an oxidizing agent molded in the form of a rod or plate, or of a mixture of conductive fuel and an oxidizing agent on a fibrous support, such a device replaces the extraction of the conductor to break the initiation circuit.

The end of the insulated laying wire, connected to the back of the power cylindrical shell of the projectile, is fixed to it by gluing or soldering or fastening it with adhesive tape or tying the end of the wire to a loop soldered or welded to the shell outside, or passing its end inside the shell from the rear open end of the shell with an exit through the hole in the stamping on the back of the shell to the outer surface of the shell, and the formation of insulation of the end by melting into a mold with dimensions that do not allow return passage through the hole in the stamping.

Between the radial laying of the current-carrying wire and the power cylindrical shell of the projectile is a separator in the form of a cylinder of paper or plastic with a side longitudinal section.

The cavity of the cartridge with the laying of the wire and the projectile located in it has a tear-off or destructible front cover or a film seal that protects the cartridge from being patronized and seals the cavity.

The essential distinguishing features of the invention (option) of a silent cartridge is that in the inner cavity of the cartridge there is a tubular support-guide rod rigidly connected to the rear end of the cartridge case and placed inside the radial laying of the current-carrying wire, the metal power cylindrical shell of the projectile has a pyrotechnic charge located between inner blind front end of the shell with a device mounted on the outer end of the device for fixing on the target, for example in the form of a needle with silt and several needles or an adhesive part, and a short movable-sealed pushing piston of non-conductive material inserted into it, having a central conductive electrode passing through the piston and hermetically fixed in it.

The rear end of the shell has a narrowed inner diameter less than the outer diameter of the movable-sealed pushing piston, the shell is worn on a support-guide rod having an outer diameter of not more than the inner diameter of the narrowed part of the shell until its end contacts the piston. The central electrode of the piston passes into the central hole of the tubular support-guide rod passing through the support-guide rod and the end face of the cartridge, and ends near the rear outer end of the cartridge case, the shell of the projectile is centered on the tubular support-guide rod with its narrowed back part with a diameter less than the diameter of the movable-tight piston, one end of the laying wire is fixed in front of the cartridge and goes to its end or side surface, and the second end of the laying wire is connected ene to the rear portion of the power of the cylindrical shell of the projectile.

As a pyrotechnic charge, a specially designed pyrocharger with a spark or electrothermal (for example, wire or graphite bridge heated by an electric current) igniter can be used, as well as a standard shock capsule igniter used to ignite the powder charge of pistol or rifle cartridges.

Unlike the closest analogue, where the direct linear movement of the projectile serves as a narrowing of the front of the cartridge, equal to the diameter of the projectile, in the present invention, the direct linear motion of the projectile serves as a supporting guide rod, and there is no narrowing of the dulc. Due to the absence in this embodiment of the present invention of the interaction of the current-carrying wire drawn from the cartridge cavity with narrowing of the barrel, the main disadvantage of the closest analogue is eliminated, i.e. the possibility of breakage or confusion with subsequent breakage of the current-carrying wire.

In contrast to the closest analogue, a rupture of the initiating circuit is achieved by pulling the central electrode of the piston from the axial channel of the support-guide rod at the moment of descent (departure) of the projectile from the support-guide rod. This eliminates the disadvantage of the closest analogue having an external initiation rupture circuit that is easily damaged when the cartridge is not handled carefully.

For reliable ignition of the pyro charge, the end of the central conductive electrode of the movably sealed piston of the conductor is centered adjacent to the pyro charge or shock pyrotechnic composition of the capsule, which, in turn, adjoins the outer end of the blind end of the power cylindrical shell of the projectile.

In this case, the pyrolytic charge will be ignited when fired by a spark discharge, piercing a special or standard capsular pyrocomposition from the centered end of the central conductive electrode to the inner end of the capsule or the metal shell of the shell.

The pyrotechnic charge may have a wire or graphite filament bridge electrically connected to the central conductive electrode and the shell of the shell to ignite the pyrocomposition not with the high combat (output) voltage of the stun gun, as is customary in most DESHO systems, but with a low voltage, for example, a DESO power supply (battery or battery).

The central conductive electrode can be made in the form of an insulated wire with high dielectric strength, which reduces the possibility of spark breakdown when the pyro charge is ignited not through the pyrocomposition, but directly onto the inner generatrix of the cylindrical shell.

The end of the supporting guide rod in contact with the movably sealed piston is made conical or hemispherical, and the counterpart of the movably sealed piston has a conical or hemispherical recess. This design centers the projectile, having a narrowing of the rear part on the supporting guide rod smaller than the inner diameter of the shell, the diameter when assembling the cartridge and during the movement of the projectile along the rod at the time of the shot.

The end of the insulated laying wire, connected to the back of the power cylindrical shell of the projectile, is fixed to it by gluing, or soldering, or fixing it with adhesive tape, or by tying the end of the wire to a loop soldered or welded to the shell from the inside, or by passing its end inward from the rear open the end face of the shell with an exit through the hole in the narrowed part of the shell to the outer surface of the narrowing of the shell and the formation of insulation of the end by melting, in a shape with dimensions that do not allow reverse the passage through the hole in the narrowed part, or with the exit of the wire through the first hole by bending it 180 °, and then passing through the second hole in the narrowed part into the shell and forming the insulation of the end by melting, into a shape with dimensions that do not allow a return passage through the second hole in the narrowed part.

Between the radial laying of the current-carrying wire and the power cylindrical shell of the projectile is a separator in the form of a cylinder of paper or plastic with a side longitudinal section.

The cavity of the cartridge with the laying of the wire and the projectile located in it has a tear-off or destructible front cover or film seal, which protects the cartridge from being emitted and seals the cavity from the ingress of foreign particles of dirt or moisture.

The tubular support-guide rod can be made entirely of non-conductive material or have a front metal guide, in which case a support-guide rod made of metal has a non-conductive part in the rear part longer than the length of the spark gap of ignition of the pyrotechnic charge.

The narrowed inner diameter of the shell can be made in the form of a polyhedron, and the tubular support and guide rod should have on its surface a reciprocal number of faces with their angular rotation relative to the central axis.

Brief Description of the Drawings

FIG. 1. The cartridge according to claim 1 with a pistol capsule according to claim 2, centering according to claim 3, fixing the current-carrying wire according to claim 7, the separator according to claim 8 and the lid according to claim 9.

FIG. 2. The cartridge of FIG. 1 at the time of the shot.

FIG. 3. The cartridge according to FIG. 1 with a conductor according to claim 5.

FIG. 4. Silent cartridge according to claim 10 with a pistol capsule according to claim 11, centering according to claim 12, execution of the electrode according to claim 14, execution of the end of the support-guide rod according to claim 15, fastening of the current-carrying wire according to claim 16, the separator according to claim. 17 and a lid according to claim 18.

FIG. 5. The cartridge according to FIG. 4 at the time of the shot.

FIG.6. The cartridge according to FIG. 4 with the execution of the guide part of the rod of metal according to claim 19 of the claims and cutting Whitworth according to claim 20 of the claims.

The implementation of the invention

Depending on the availability of production technology, various cartridge arrangements may be used.

The cartridge device according to claim 1, claim 2, claim 3, claim 7, claim 8, claim 9 of the claims of FIG. 1 consists of a housing 1 of plastic mass, inside the cavity 2 of which a projectile is placed, which is a metal power a cylindrical shell 3 having a blind front end, for example in the form of a rolled head 4, having a device for securing to the target in the form of, for example, a needle with a horn 5. A pyrotechnic charge adjoins the blind end, for example, a standard Berdan 6 pistol capsule or capsules pressed into the shell Boxer without anvil. The capsule 6 in case of discrepancy in its outer diameter with the inner diameter of the shell 3 has a centering part 7 (for example, in the form of a ring). In the rear inner end of the housing 1, a non-conductive tubular support and guide rod 8 is molded (which can be made as a separate plastic part fixed in the housing 1, for example, on a thread). Inside the axial channel of the rod 8 is a conductor 9, with the possibility of free running in the axial channel. At the end of the housing 1, a embedded electrode 10 is rigidly and hermetically fixed, extending into the axial channel of the rod 8 and onto the outer surface of the rear end of the housing 1. A current-carrying wire 11 is laid in the annular cavity 2 in the form of a single-layer, multilayer, or hybrid frameless coil (shown in FIG. 1 in the form of a two-layer coil). One end of the current-carrying wire 11 is fixed (by knot, gluing, welding, fixing by a jamming part) in the front of the housing 1 and goes to its front side surface through the hole 12, or (and) simultaneously to the end and side front surfaces, and the other end is fixed to the back of the shell 3, by gluing or soldering, or attaching duct tape to its outer surface, or by tying the end of the wire to a loop soldered or spot-welded to the outer surface of the shell, or prop accelerating its end into the shell from the rear open end of the shell with the exit through the hole in the stamping on the back of the shell to the outer surface of the shell, and forming the insulation of the end by melting, into a shape with dimensions that do not allow a return passage through the hole in the stamping. The shell 3 is worn on the rod 8 so that the front end of the conductor 9 is practically in contact with the pyrotechnic composition of the capsule 6, and this end coincides with the axis of the capsule (i.e., centered relative to the pyrotechnic composition).

Between the radial laying of the current-carrying wire 11 and the power cylindrical shell 3 of the projectile is a separator 13 in the form of a cylinder of paper or plastic with a side longitudinal section.

The separator 13 is necessary to prevent the interaction of a beginner acceleration when firing a projectile with turns of a current-carrying wire, which could entail tangling and subsequent breaks of the current-carrying wire. The separator 13 with its rear end can reach almost the end of the rear part of the shell 3, its front end to the cover of the front end of the housing 1.

The front end of the housing 1 has a lid 14 that can be easily torn off or destroyed (for example, brittle) when fired, covering the cavity 2 with the projectile located in it and laying the current lead. The lid can be replaced with easily torn adhesive paper or plastic film.

The separator 13 may have front petals that go to the front end of the frameless coil, preventing the coils of the current-carrying wire from the frameless coil into the space in front of the probe and the corresponding interruption of the current-carrying wire when the probe takes off from the cartridge when firing.

FIG. 2 shows the cartridge of FIG. 1 at the time of the shot. When fired, the capsule pyrotechnic charge (already shown burnt in FIG. 3) is initiated by a spark electric breakdown upon application of bipolar potentials of a high voltage electric current to the electrode 10 and the end of the current-carrying wire 11, which exits the outside of the housing 1 through the hole 12. The current flows through the laying of wire 11 and enters the metal shell 3, then through the metal housing of the capsule 6 passes through the pyrotechnic charge of the capsule in the form of a spark discharge and then passes through the conductor 9 to the electrode 10 and then to the DESO shutter contact. The distance of the thickness of the pierced pyrotechnic charge of the capsule 6 is small compared with the distance from the conductor 9 centered along the axis of the capsule 6 to the inner walls of the capsule 6, therefore, the spark discharge passes exactly through the pyrotechnic charge, igniting it.

With the ignition of the pyrotechnic charge in the power cylindrical shell 3, the pressure of the combustion gases of the pyrotechnic composition increases. The pressure of the combustion gases is also transmitted to the end face of the rod 8. The reaction of the recoil of the shell movement of the projectile is transmitted through the rod 8 to the rear end of the housing 1, to the shutter DESHO and then the total mass of DESHO.

The shell 3 begins to move inside the separator 13 forward without contact with the turns of laying the wire 11, while the needle of the end face of the shell knocks (or destroys) the cover 14 (or tears the film).

Combustion gases of the pyrolysis enter the axial channel of the rod 8 between its inner walls and the conductor 9 and fill the channel to a hermetically fixed electrode 10.

The accelerated shell 3, moving along the rod 8 forward relative to the housing 1 of the cartridge and accumulating a mechanical impulse of movement, carries along the wire 11, which ejects the split separator 13 (shown in FIG. 2 shown open along the longitudinal section), which is separated by the flow of incoming air from the wire 11 when exit from the cavity 2 of the cartridge.

When disconnecting the shell 3 with the rod 8, the pyrolysis combustion gases in the axial channel of the rod 8, expanding sharply, throw the conductor 9 out of the channel in the direction of the projectile, with little energy. When the conductor 9 leaves the channel of the rod 8 in the axial channel of the rod 8, an air gap is formed with a length that guarantees protection from air breakdown between the electrode 10 and the wire 11 (even in case of damage to the high-voltage insulation and incomplete exit of the wire 11 from the cavity 2 at close proximity hit target from DESHO).

Further, the projectile accelerated on the rod 8, which serves as a guide for rectilinear movement, consists of a power cylindrical shell 3, head 4, needle 5 and capsule 6 flying to the target, completely pulling the current-carrying wire 11 from the stacking inside the cavity 2 of the cartridge case 1, and hits the target, securing on it with a needle 5.

FIG. 3 shows a cartridge that is not fundamentally different from the cartridge device of FIG. 1 except that the conductor device has a design according to claim 5. In this embodiment, the conductor 9 is made of thin wire with a diameter of 0.1-0.5 mm and at the end adjacent to the capsule 6 has a plug 15 of elastic material inserted into the axial channel of the rod 8.

The mechanism of the shot of the cartridge according to FIG. 3 does not differ from that described in FIG. 2 except that the conductor 9 is not ejected from the axial channel of the rod 8. When the gas pressure exerts the shot on the plug 15, it begins to move along the axial channel of the rod 8 in the direction to the electrode 10, while compressing the thin conductor 9 (pressing it in the axial channel of the rod 8). In this case, the length of the conductor 9 decreases several times, thereby achieving the effect achieved when the conductor 9 is completely removed during the shot from the cartridge case, i.e. the formation of an air gap with a length guaranteed to protect against air breakdown between the electrode 10 and the wire 11.

Achieving the effect of increasing the air gap after firing, which is necessary for the normal operation of the DESO, can also be carried out in the manufacture of the conductor 9 from a mixture of conductive fuel and an oxidizer molded in the form of a rod or plate, or from a mixture of conductive fuel and an oxidizer on a fibrous carrier. For example, conductor 9 may be made of a strip of nitrocellulose coated with a mixture of potassium chlorate with aluminum or graphite or gas soot. In this case, the amount of propellant pyrocharge can be significantly reduced, or it can be completely absent, since the combustion of a conductor made of pyrotechnic mixture itself will be accompanied by a propellant effect similar to the usual pyrocharge in the description of FIG. 1 and FIG. 2. During the oxidation of the conductive fuel, non-conductive oxides are formed which, similarly to the physical removal of the conductor 9 from the channel of the rod 8, create an air gap guaranteed against breakdown.

The spark ignition described in FIG. 2 can be replaced by thermal ignition provided that a wire or graphite incandescent bridge is electrically connected to the conductor 9 and the metal shell 3 of the projectile in a pyrotechnic charge. In this case, ignition of the pyro-charge during firing can be carried out not by a high TESO output voltage (voltage) of 30-50 kV, which can form a spark igniting discharge, as is customary in most TESHO systems, but by a low voltage, for example, a TESHO power source (battery or battery), or an additional power source, galvanically (and statically) isolated from the general DESHO electrical circuit, which may be applicable in some DESHO designs.

In FIG.4 silent cartridge (option) according to claim 10, clause 11, clause 12, clause 14, clause 15, clause 16, clause 17, clause 18 of the claims, consisting of a plastic housing 1 mass, inside the cavity 2 of which a projectile is placed, which is a metal power cylindrical shell 3 having a blind front end, for example, in the form of a rolled head 4, having a device for securing to the target in the form of, for example, a needle with a horn 5. A pyrotechnic charge is adjacent to the blind end e.g. Berdan 6 standard pistol capsule or Boxer capsule without internal anvil. The capsule 6 in case of discrepancy in diameter with the inner diameter of the shell 3 has a centering part 7 (for example, in the form of a ring). A movable-sealed pushing piston 16 of non-conductive material adjoins the capsule 6, in which a central conductive electrode 17 is fixed rigidly, hermetically and centered with respect to the axis of the capsule 6 and passes through the piston 16.

The rear end of the shell 3 has a narrowed inner diameter 18 less than the outer diameter of the piston 16 (narrowing is obtained, for example, by flaring the rear end of the shell 3), the shell is worn on a support-guide rod 8 having an outer diameter of not more than the inner diameter of the narrowed part of the shell until it touches end face with piston 16.

In the rear inner end of the housing 1 there is a non-conductive tubular support and guide rod 8 (which can be made as a separate plastic part fixed in the housing 1, for example, on a thread, as in FIG. 4, or can be cast at the same time with the housing 1). The electrode 17 passes through the axial channel of the rod 8 and goes flush on the outer surface of the rear end of the housing 1.

A current-carrying wire 11 is laid in the annular cavity 2 in the form of a single-layer, multilayer, or hybrid frameless coil, shown in FIG. 4 as a three-layer coil. One end of the current-carrying wire is fixed in the front of the housing by knot, gluing, welding or, as in FIG. 4, fixing the jammed wire with the conductive part 19, and the other end is fixed in the back of the shell 3, by gluing, or by soldering or fixing the adhesive tape to its outer surface, or by tying the end of the wire to a loop soldered or welded to the inside of the shell after the narrowed part, or by passing its end inward from the rear open end of the shell with an exit through the hole in the narrowed part bechayki on the outer surface of the narrowing of the shell and the formation of insulation of the end by melting, in a shape with dimensions that do not allow reverse passage through the hole in the narrowed part, or with the output of the wire through the first hole by bending it 180 °, and then passing through the second hole in the narrowed part inside the shell and forming the insulation of the end by melting, into a mold with dimensions that do not allow a return passage through the second hole in the narrowed part.

The shell 3 is worn on the rod 8, while the front end of the electrode 17 is practically in contact with the pyrotechnic composition of the capsule 6, and this end coincides with the axis of the capsule (i.e., centered relative to the pyrotechnic composition).

Between the radial laying of the current-carrying wire 11 and the power cylindrical shell 3 of the projectile is a separator 13 in the form of a cylinder of paper or plastic with a side longitudinal section. The separator 13 is necessary to prevent the initiation of acceleration during the firing of the projectile with the turns of the current-carrying wire, which could entail tangling and subsequent breaks of the current-carrying laying. The separator 13 with its rear end reaches almost the end of the rear part of the shell 3, and the front end to the cover 14 of the front end of the housing 1. At the front, the separator 13 can have petals that go to the front end of the frameless coil, preventing the coils of the current-carrying wire from the frameless coil from entering the space before the probe and the corresponding interruption of the current-carrying wire when the probe takes off from the cartridge when firing.

The front end of the housing 1 has a lid 14 that can be easily torn off or destroyed (for example, brittle) when fired, covering the cavity 2 with the projectile located in it and laying the current lead. The lid can be replaced with easily torn adhesive paper or plastic film.

Figure 5 shows the cartridge according to figure 4 at the time of the shot. When fired, the capsule pyrotechnic charge (already shown burnt in FIG. 5) is initiated by a spark electric breakdown upon application of bipolar potentials of a high voltage electric current to the electrode 17 and the end of the current-carrying wire 11 stuck in front of the conductive part 19. The current flows through the laying of wire 11 and enters the metal shell 3, then through the metal housing of the capsule 6 passes through the pyrotechnic charge of the capsule in the form of a spark discharge and then passes to the electrode 17, and then to the contact kt DESHO shutter.

The distance of the thickness of the pierced pyrotechnic charge is small compared to the distance from the electrode 17 centered on the axis of the capsule 6 to the inner walls of the capsule 6, therefore, a spark discharge passes through the pyrotechnic charge, igniting it.

With the ignition of the pyrotechnic charge in the power cylindrical shell 3, the pressure of the combustion gases of the pyrotechnic composition increases. The pressure of the combustion gases is transmitted to the head 4 and to the piston 16, which, in turn, transfers the reaction of the recoil of the shell movement of the projectile to the rod 8 and through it to the rear end of the housing 1 and further to the DESO shutter and then the total DESO mass.

The shell 3 begins to move inside the separator 13 forward without contact with the turns of laying the wire 11, while the needle of the end face of the shell knocks (or destroys) the cover 14 (or tears the film).

The accelerated shell 3, moving along the rod 8, forward relative to the cartridge case 1 and accumulating a mechanical impulse of movement, carries along the wire 11, which ejects the split separator 13, which is separated by the flow of incoming air from the wire when leaving the cavity 2 of the cartridge.

The piston 16 at the end of the stroke inside the shell 3 fits into the narrowing 18 and is braked in it. Thus, the cut-off of the shot gas and the noiselessness of the shot are achieved. The shell 3, pulling the wire 11 behind it, moves towards the target, by inertia pulling the rod 8 and the electrode 17 from the axial hole of the rod.

When the electrode 17 is completely pulled out of the axial channel of the rod 8, an air gap is formed in the axial channel of the rod 8 with a length that guarantees protection from air breakdown between the current-supplying part of the DESO gate, in contact with the rear end of the housing 1 and wire 11 (even if the high-voltage insulation is damaged on it and incomplete exit of the wire 11 from the cavity 2 with the proximity of the target from the DESO).

Next, the projectile accelerated on the rod 8, which serves as a guide for rectilinear motion, as part of a power cylindrical shell 3, head 4, needle 5, capsule 6, piston 16, electrode 17 makes a flight to the target, completely pulling the current-carrying wire 11 from it inside the cavity 2 of the housing 1 cartridge, and hits the target, fixing on her nose 5.

The spark ignition described in FIG. 5 can be replaced by thermal ignition provided that a wire or graphite filament bridge is electrically connected to the conductor 9 and the metal shell 3 of the projectile in the pyrotechnic charge. In this case, the ignition of the pyro-charge during firing can be carried out not by a high combat (output) voltage of a stun gun with a voltage of 30-50 kV, which can form a spark ignition discharge, as is customary in most TESHO systems, but by a low voltage, for example, a TESHO power source (battery or battery) or an additional power source galvanically (and statically) decoupled from the general DESHO circuitry, which can be applied to some DESHO designs.

Figure 6 shows a cartridge having a tubular support and guide rod with the execution of the guide part of the rod of metal, and cutting Whitworth, made on the guide part of the rod.

The tubular support and guide rod has a metal guide part 20 and a fastening part 21. The fastening part 21 is molded either integrally with the housing 1 or is made separately of non-conductive material and is installed in the housing 1, for example, on threads, ultrasonic welding, glue, or press fitting. The guide portion 20, in turn, is secured to the fastening portion in the same manner as above. The longitudinal length of the non-conductive fastening part 21 from the rear end of the cartridge to the rear end of the metal part 20 is selected more than the length of the spark gap in which the pyrotechnic charge is ignited during spark ignition.

The execution of the guide part 20 of the rod of metal somewhat complicates the design of the cartridge in comparison with a non-conductive rod cast at the same time with the body, but increases the longitudinal stiffness of the rod as a guide for the rectilinear movement of the projectile. The greater stiffness of the metal rod prevents its oscillations during firing and thus increases the accuracy of shells hitting the target.

The narrowed part 18 of the shell 3 has a cross-section in the form of a polyhedron (for example, rolling is carried out on a faceted mandrel). On the guide part 20 of the rod, reciprocal faces are made with angular rotation about a central axis. This design is an analogue of polygonal slicing Whitworth. When fired, the multifaceted narrowed part 18 of the shell interacts with the response faces of the swirling guide part 20, while the shell 3 and the probe in its composition receives rotation around its longitudinal central axis and thus stabilizes in flight similarly to a bullet of rifled weapons. Such a device increases the accuracy of probes hitting the target, compensating for the small length of the guide part of the support-guide rod for good stabilization of rectilinear motion.

In well-known designs of multi-charged DESHO, the initiation of a shot is carried out by moving the cartridge to the position of the shot at a distance exceeding half the breakdown distance of a combat electric discharge through the air, preventing the abnormal initiation of cartridges located in the holder. In order to be able to initiate the cartridge without moving it to the firing position and thus reduce the total length of the DESO, the central through hole of the tubular support and guide rod has a membrane 22 with high electrical strength in the rear part facing the outer surface of the cartridge end face. The initiation of a cartridge in this design is carried out by puncturing the membrane with a current-supply electrode-needle of a DESO without moving the cartridge case. During the firing of the electrode-needle DESHO pierces the membrane 22, while galvanic coupling between the electrode-needle and the electrode 17 of the cartridge is carried out and then ignition propellant pyrotechnic charge.

In the cartridge embodiment not shown in FIG. 6, instead of the membrane 22, the back part of the central hole of the tubular support-guide rod or its execution with the metal guide part is filled with plastic non-conductive material with high electrical strength, for example, silicone sealant, waxy synthetic materials, etc.

Claims (21)

1. The throwing cartridge of an electric wire, comprising a body of non-conductive material with an internal cavity for accommodating the laying of an uninsulated or insulated current-carrying wire in the form of a single-layer, multilayer or hybrid frameless coil, a shell in the form of a power cylindrical shell with a device for fixing to the target in the form of needles or needles with with an antiferous or adhesive part, a pyrotechnic charge with electrical initiation, characterized in that in the inner cavity of the cartridge housing a non-conductive tubular is made th support and guide rod rigidly connected to the rear end of the cartridge case and placed inside the radial laying of the current-carrying wire, the metal power cylindrical shell of the projectile has a pyrotechnic charge located between the inner blind front end of the shell with the target-fixing device mounted on the outer end and pushed into the shell the front end of the tubular support guide rod, in the axial channel of the tubular support guide rod is a conductor having the ability free movement along the channel axis, passing from the front end of the tubular support guide rod to the electrode sealed at the end of the axial channel of the electrode, which exits through the rear end of the cartridge case to its rear end outer surface, the shell of the projectile is centered on the tubular support guide rod, one end of the wire laying is fixed in front of the cartridge and goes to its end or side surface, and the second end of the laying wire is attached to the back of the power cylindrical shell shell Yes. 2. The cartridge according to claim 1, characterized in that the standard percussion igniter capsule for pistol or rifle cartridges is used as a pyrotechnic charge. 3. The cartridge according to claim 1, characterized in that the end of the conductor is centered adjacent to the pyro charge or percussion pyrotechnic composition of the capsule adjacent its outer end to the inner end of the blind end of the power cylindrical shell of the projectile. 4. The cartridge according to claim 1, characterized in that the pyrotechnic charge has a wire or graphite filament bridge electrically connected to the conductor and the metal shell of the projectile. 5. The cartridge according to claim 1, characterized in that the conductor has, at the end adjacent to the pyrotechnic charge, a cylindrical plug of elastic material that enters the axial channel of the tubular support-guide rod. 6. The cartridge according to claim 1, characterized in that the conductor is made of a mixture of conductive fuel and an oxidizing agent, molded in the form of a rod or plate, or from a mixture of conductive fuel and an oxidizing agent on a fibrous carrier. 7. The cartridge according to claim 1, characterized in that the end of the insulated laying wire connected to the back of the power cylindrical shell of the projectile is secured to it by gluing or soldering, or fixing it with adhesive tape, or tying it to a loop soldered or welded to the shell, or by passing its end into the shell from the rear open end of the shell with an exit through the hole in the stamping on the back of the shell to the outer surface of the shell, and forming the insulation of the end by melting into a mold with dimensions not allowing return passage through the hole in the stamping. 8. The cartridge according to claim 1, characterized in that between the radial laying of the current-carrying wire and the power cylindrical shell of the shell is a separator in the form of a cylinder of paper or plastic with a side longitudinal section. 9. The cartridge according to claim 1, characterized in that the cavity of the cartridge with the wire laying in it and the projectile has a tear-off or destructible front cover or film seal that protects the cartridge from being unprotected, and a sealing cavity. 10. Silent cartridge throwing an electric wire containing a body of non-conductive material with an internal cavity for accommodating the laying of an uninsulated or insulated current-carrying wire in the form of a single-layer, multilayer or hybrid frameless coil, a projectile for pulling the electric wire from the cartridge case and securing it to the target in the form of a needle or needles with a horn, or an adhesive part, which is a power cylindrical shell with a device for fixing on the target on the front deaf end, inside of which a pyrotechnic throwing energy source with an electric initiation device is supported, and a movable-sealed pushing piston, characterized in that a tubular support-guide rod is made in the inner cavity of the cartridge housing, rigidly connected to the rear end of the cartridge case and placed inside the radial laying of the current-carrying wire, metal power cylindrical the shell of the shell has a pyrotechnic charge located between the inner blind front end of the shell and the short movable with a sealed pushing piston made of non-conductive material having a central conductive electrode passing through the piston and sealed in it, the rear end of the shell has a narrowed inner diameter less than the outer diameter of the movable-sealed pushing piston, the shell is worn on a supporting guide rod having an outer diameter of not more than the inner diameter of the narrowed part of the shell, until its end contacts the piston, the central electrode of the piston passes into the central hole of the tubular support the core, passing through the supporting guide rod and the end face of the cartridge, and ends near the rear outer end of the cartridge housing, the shell of the projectile is centered on the tubular supporting guide rod with its narrowed rear part with a diameter less than the diameter of the movable-sealed piston, one end of the laying wire is fixed to the front part of the cartridge and goes to its end or side surface, and the second end of the stacking wire is attached to the rear of the power cylindrical shell of the shell. 11. The cartridge according to claim 10, characterized in that a standard percussion igniter capsule for pistol or rifle cartridges is used as a pyrotechnic charge. 12. The cartridge according to claim 10, characterized in that the end of the central conductive electrode of the movable-sealed piston of the conductor is centered adjacent to the pyro charge or shock pyrotechnic composition of the capsule, adjacent its outer end to the inner end of the blind end of the power cylindrical shell of the projectile. 13. The cartridge according to claim 10, characterized in that the pyrotechnic charge has a wire or graphite filament bridge, electrically connected to the Central conductive electrode and the metal shell of the projectile. 14. The cartridge according to claim 10, characterized in that the central conductive electrode of the movable-sealed piston is made in the form of an insulated wire with high dielectric strength. 15. The cartridge of claim 10, characterized in that the end of the supporting guide rod in contact with the movably sealed piston is made conical or hemispherical, and the counterpart of the movably sealed piston has a conical or hemispherical recess. 16. The cartridge according to claim 10, characterized in that the end of the insulated laying wire connected to the back of the power cylindrical shell of the projectile is secured to it by gluing or fixing with adhesive tape, or tying it to a loop soldered or welded from the inside to the shell, or passing its end inward from the rear open end of the shell with the exit through the hole in the narrowed part of the shell to the outer surface of the narrowing of the shell and the formation of insulation of the end by melting into a mold with dimensions that do not allow reverse the first passage through the hole in the narrowed part, or with the exit of the wire through the first hole by bending it 180 °, and then passing through the second hole in the narrowed part into the shell and forming the insulation of the end by melting into a mold with dimensions that do not allow a return passage through the second hole in the narrowed part. 17. The cartridge of claim 10, characterized in that between the radial laying of the current-carrying wire and the power cylindrical shell of the shell is a separator in the form of a cylinder of paper or plastic with a side longitudinal section. 18. The cartridge according to claim 10, characterized in that the cavity of the cartridge with the wire laying in it and the projectile has a tear-off or destructible front cover or film seal, which protects the cartridge from being patronized and seals the cavity. 19. The cartridge of claim 10, characterized in that the tubular support guide rod is made entirely of non-conductive material or with a front guide part made of metal, and the metal made of metal support guide rod has a non-conductive part in the rear part longer than the length of the spark gap ignition of a pyrotechnic charge. 20. The cartridge of claim 10, characterized in that the narrowed inner diameter of the shell is made in the form of a polyhedron, and the tubular support and guide rod has on its surface a reciprocal number of faces with their angular rotation relative to the central axis. 21. The cartridge of claim 10, characterized in that the Central hole of the tubular support guide rod passing through the support guide rod and the end face of the cartridge has in the rear part facing the outer surface of the end face of the cartridge, filling with plastic non-conductive material or non-conductive membrane with high electric strength.

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