RU2648562C1 - Remote cartridge for electric shock device with individual initiation of procedures - Google Patents

Abstract

FIELD: safety devices.

SUBSTANCE: invention relates to the field of electroshock devices, in particular to remote cartridges for an electric shock device with individual initiation of projectiles. Remote cartridge contains a body with a surface for attaching to the electric shock device. Electrocontacts are placed on the body and made with the possibility of high-voltage contact with the electrodes of the electric shock device, and inside it there is an inner body installed with two channels in which projectiles are placed, contacting them mobile electrically conducting pistons with seals-insulators installed on them and baric arresters with electrodes. Inner case is made with sinuses for laying the wires, each of which is connected on one side with the projectile to be projected, and on the other side with the electrode of the baric discharger of the opposite channel and with the corresponding electrical contact of the cartridge.

EFFECT: increase in the efficiency of the application, an increase in reliability, safety in circulation is achieved.

15 cl, 6 dwg

Description

The invention relates to the field of electric means of destruction of objects, in particular to electroshock devices with the function of remote destruction of biological targets by pulsed electric current of high voltage, and can be used as a single-shot removable cartridge for weapons with the function of non-lethal remote destruction of targets.

The prior art device is a unitary cartridge throwing an electric wire of a hand weapon for remote destruction of targets by electric current (RU 2308668, 10/20/2007). The cartridge contains a body with a cavity, a projectile with a head having a device for securing to the target, laying an electric wire, one end of which is fixed in the cartridge case, and the second end is attached to the head of the projectile. The laying of the electric wire is made in the form of a frameless coil, and a pyrotechnic charge with electric or mechanical initiation is placed in the cavity of the cartridge case, while the charge is made with the possibility of the formation of non-conductive combustion products.

The disadvantages of the cartridge are:

- The inability to quickly reload the ESD in combat conditions. To conduct a shot requires the simultaneous initiation of two rounds, therefore, to reload a single shot requires reloading two rounds. As a result, the use of a magazine for cartridges is required, which increases the overall dimensions of the cartridge.

- Low-tech operation of the cartridge equipment with a pyrotechnic charge (the charge must be placed in the deep cavity of the cartridge case).

- The actual low-tech design of the sheath for laying the wire on the KTR product (discharge transport cartridge), which is carried out with adhesive tape.

- The location of the pyrotechnic charge directly behind the laying of the wire can lead to damage to the wire when initiated by the pyrotechnic charge and wire breakage, and also can not ensure the stability of the kinetic characteristics of the projectile due to the lack of a feeding structural element between the projectile and the pyrotechnic composition (for example, wad or piston).

- It is required to keep the cartridge airtight or present special storage conditions to the cartridge due to the combination of the projectile chamber and the pyrotechnic charge. Leakage of the cartridge can lead to damage to the pyrotechnic composition due to climatic conditions of storage or use.

- Limited wire laying. In fact, in the KTP product, the volume of laying the wire is f7.2 × 40 = 1.62 cc. Stacked 3.5 m of wire with a diameter of 0.4 mm.

- When casting the cartridge housing, taking into account the casting slopes of 1.5-2 degrees, the length of the wire in the laying can actually be reduced even more. Injection slopes also reduce the accuracy of projectile throwing.

- An embodiment using a wad and a tapering channel requires an increase in the strength of the walls of the cartridge (an increase in their thickness) and reduces the accuracy of projectile throwing, as the projectile is almost entirely located in the narrowing channel of the wad. The option of using heat-resistant and refractory material in laying the wire complicates the design and assembly of the cartridge. The use of wad does not imply the existence of special channels for air access for the projectile to prevent the formation of reduced pressure behind the projectile when it leaves the cartridge case.

An electronic weapon is known with a compartment for initiating electrodes with an initiation unit installed in it, from which electrodes are fired, connected to the unit by wires. A stimulating signal is transmitted to the target, which stops the movement of the target. The compressed gas compartment is used to push out the electrodes. The compartment is located in the initiation unit (US 9080840, 07/14/2015).

The disadvantages of such an initiation block are:

- The use of compressed gas to propel projectiles increases the cost of initiation blocks.

- The presence, along with the pyrotechnic initiator of a compartment with compressed gas, requires higher requirements for the storage and transportation of initiation units.

- Since the initiation of the gas cylinder is carried out using low voltage, and high voltage is applied to the cable laying, it is necessary to constructively separate these sections, increasing the distance from the gas compartment to the missile shells using a channel of complex shape.

- The design of the cartridge allows the projectile to rotate in the accelerating channel around the longitudinal axis during vibrations during transportation and operation. This can cause the projectile to rotate relative to the laying of the wire and wire breakage.

As the closest analogue of the claimed invention, you can take a cartridge for an electroshock device with a remote lesion, known from patent RU 2351871, published. 04/10/2009. The cartridge case is made integral of the external and internal blocks located therein. On the external unit there is a mechanism for removable fastening of the cartridge on the stun device. In the indoor unit, guide channels are made, each of which is formed by an output channel and a working channel having a larger diameter. Throwing shells are placed in the output channels, and in the working channels are baric dischargers and pistons equipped with o-rings made with a variable diameter. Electrical contacts are placed on the external unit, which form the first primary open circuit with the working electrodes of the stun device, projectiles, baric arresters and connecting conductor. The second primary open electrical circuit is formed by ejected flexible current conductors located in the cavities of the indoor unit, working electrodes, electrical contacts and projectiles.

The disadvantages of the cartridge are:

- The stabilization of shells in flight to the target occurs with the help of a flexible conductor pulled from the side cavities. Since the shells do not have a forward center of gravity displaced forward relative to the longitudinal axis, in order to ensure its guaranteed fixing on the target, it is necessary to provide additional resistance to the flight of the projectile with a flexible current lead, which reduces the accuracy of throwing by reducing the flight speed and increases the likelihood of wire breakage.

- the fastening of the fixation element on the target (needle) to the projectile is provided with epoxy resin, which is an unreliable and low-tech type of connection of an aluminum liner and a metal needle (cartridge according to TU 7399-002-55233808-05).

- When the projectile leaves the exit channel, a reduced pressure is created behind the projectile due to the lack of special channels for air access for the projectile. This leads to an unstable initial phase of the projectile flight.

- The inability to ensure safety during assembly of the cartridge, as The cartridge is equipped with baric arresters installed in the indoor unit before liners are installed, wires are laid, information labels are stickers and an initiation circuit is created.

- The design of the cartridge allows the projectile to rotate in the accelerating channel around the longitudinal axis during vibrations during transportation and operation. This can cause the projectile to rotate relative to the laying of the wire and wire breakage.

- The conductive piston contacts its back surface with a baric arrester, therefore, when a baric arrester is initiated, a high-voltage current flows from the piston to its electrode along the inner wall of the baric arrester, i.e. there is no high-voltage discharge through the air, which leads to ignition of the pyrotechnic composition from its edge and unstable combustion.

- To initiate a cartridge, an initially open circuit of pressure arresters is created, which opens when pyrotechnic charges are triggered. The pyrotechnic compositions of pressure arresters can not be triggered synchronously, especially in those cases when the power supply of the electroshock device is not fully charged and cannot provide enough power to quickly initiate a cartridge. If one of the baric arresters is initiated earlier than the other, the initiation circuit opens and the second baric arrester will not be initiated. This will misfire the cartridge.

- There are no sealing elements in the design of the cartridge, therefore, the protection of the internal elements of the cartridge from unwanted environmental factors is not provided.

- In the case of fixing on a target dressed, for example, in thick winter clothes, when the breakdown distance from the projectile is not enough to affect the target, to exclude high-voltage breakdown of wires between themselves, an idle discharge passes between the cutting electrodes of the stun device itself. This forces the manufacturer to minimize the distance between the cutting electrodes of the stun device, which negatively affects the capabilities of the device working contactlessly without a cartridge.

- Laying the wire in the sinuses is performed in the form of a multilayer coil with the winding of the wires of each subsequent layer mainly inclined to the turns of the previous layer. This type of stacking when throwing a projectile toward the target is the reason for its complete removal from the cavity with the subsequent unwinding of the wire already outside the cartridge. In this case, the laying of the wire performs rotational-translational motion at high speed, which can lead to tangling of the wire and its breakage.

The technical problem to which the proposed invention is aimed is to increase the operational characteristics and expand the arsenal of remote cartridges for an electroshock device with individual initiation of shells, parameters whose characteristics provide separation of the initiating chains of pressure arresters, destruction of the connecting track by high voltage (the lower the current, the longer the track is destroyed and the more time it takes to initiate a projectile), a stable initial speed projectile due to air access for the projectile, the presence of its own group of combat electrodes for contacting the target, the ability to quickly equip the stun device of the cartridge, if the stun device is operated without a cartridge.

The technical result achieved by the implementation of this invention is to increase the operational efficiency of the remote electroshock device: application efficiency, reliability, maneuverability, and safe handling.

The specified technical result is achieved in a remote cartridge for an electroshock device with individual initiation of shells, comprising a housing with a surface for mounting on / in an electroshock device, and the electrical contacts made with the possibility of high-voltage contact with the electrodes of the electroshock device are placed on the housing, and an internal case with two channels in which throwing shells are placed, moving electrically conductive pistons in contact with them are installed E them seals-isolators and baric arresters with the electrodes, wherein the inner housing is formed with sinuses for laying wires, each connected on one side to the meta shell and on the other - with the electrode of the pressure discharger of the opposite channel, and to the corresponding electric contact of the cartridge.

The cartridge is equipped with shutters for closing the channels and their corresponding sinuses for laying wires, and the case is closed with a front cover holding the shutters for closing the channels and their corresponding sinuses for laying wires in the case. The shutters have an insulating seal (silicone seal), which protects all structural elements of the cartridge from undesirable effects of climatic environmental factors.

The missile projectiles contain a metal probe with an element for fixing on the target, plumage made of dielectric material and a swivel bracket for attaching the wire laying, which leads to stabilization of the projectile in flight due to the shifted center of gravity and the application of stabilization force to the swivel bracket (along the longitudinal axis of the projectile) and , as a result, increases the effectiveness of shooting when hitting a target.

A split sleeve is placed in each channel between the missile projectile and the shutter, and each channel contains grooves for accommodating the fins of the missile projectile and a limiter for the movement of the electrically conductive piston is made in the channel.

When a cartridge is initiated, an electrically conductive piston with a seal insulator seals the pyrotechnic gases in the channel, which prevents the pyrotechnic gases from escaping into the atmosphere. As a result of the access of air behind the projectile, a stable initial velocity of the projectile is ensured (and hence the firing efficiency when the target is hit), since the seal-insulator creates an air gap for the formation of an initiating high-voltage discharge from the electrically conductive piston to the baric electrode.

The body has a surface for positioning in an electroshock device on the firing line, which further increases the firing efficiency when hitting a target.

The cartridge additionally contains an open sight for aiming (to increase firing efficiency when hitting a target) and there are mounted battle electrodes electrically connected to electrical contacts or through a high voltage gap. The presence of its own group of combat electrodes for contact action on the target enhances the effectiveness of shooting when the target is hit.

Sinuses for laying wires are made in the form of technological glasses, which are divided into two volumes for laying wires.

Between the branches connecting the electrical contacts of the cartridge and the electrodes of the baric arrester of the opposite channel, a high-voltage cutting arrester is installed.

The electrical connection of the electrical contact and the electrode of the baric arrester of the opposite channel includes a track-jumper destroyed by high voltage.

The claimed technical result is obtained by implementing the entire set of essential features reflected in the independent claim and providing increased operational efficiency of the remote electroshock device due to reliability (separation of the initiating circuits of pressure arresters, destructible track-jumper (connecting track), while the lower the current, the longer the track is destroyed and the more time it takes to initiate a projectile); shooting efficiency when hitting a target (provided by the accuracy (accuracy) of the shot); maneuverability (the ability to quickly equip an electroshock device with a cartridge using a surface for fastening to / in an electroshock device) and safety in handling is ensured (double case).

The invention is illustrated by drawings.

In FIG. 1 - A section of a cartridge.

In FIG. 2 - Electrical circuits in the cartridge.

In FIG. 3 - Missile projectile.

In FIG. 4 - General view of the cartridge. One of the options for implementation.

In FIG. 5 - Implementation of the design of the inner case.

In FIG. 6 - Implementation of the design of technological glasses.

In the design of the cartridge in one housing two lines of current transmission to the target are combined, because it is not possible to efficiently transfer high voltage electric current to a biological target except by means of two wires isolated from each other by an air gap or wire insulation.

The cartridge shown in FIG. 1 in section, made in the housing 1 with a surface 2 for fixing on / in the stun device. Electrical contacts 3 for high voltage contact with electrodes of an electroshock device, shown in FIG. 2. The cartridge has an inner case 4 in which two channels 26 shown in FIG. 5. Each channel is an acceleration channel for a missile projectile 5 and a tapering working channel for the movement of an electrically conductive piston 6 with an insulator seal 7 installed on it and pressure gages 8 with electrodes 9. A missile projectile 5 is placed in its front part, made from a metal probe 21, plumage 22, a swivel bracket 23 for attaching the corresponding laying of wire 10, a needle with a beard 20 for fixing on the target (shown in Fig. 1 and 3). In FIG. 1 stacking wires for clarity spaced along the height of the inner housing 4.

The plumage 22 is connected to the probe 21 by threading or in any other way. The probe 21 and the needle 20 have a special coating, applied mainly galvanically, allowing you to attach the needles to the probes by soldering with solder paste without prior tinning. The plumage 22 is made mainly of a dielectric material lighter in specific gravity than the probe 21. This allows you to transfer the center of gravity to the front of the projectile 5 relative to its longitudinal axis while maintaining the diameter of the projectile unchanged over its entire length. The dielectric properties of the plumage 22 make it possible to exclude the closure of missile shells with each other when they are closely fixed to the target to each other. The offset center of gravity of the projectile allows it to move towards the target with minimal resistance to stabilize the wire, i.e. without significantly affecting the resistance of the wire when unwinding from the sinuses 27 shown in FIG. 5, on the speed of the projectile.

A swivel bracket 23 is mounted on the back of the projectile 5, to which the laying of the wire 10 is connected. In the running state, the bracket 23 is rotated so that the piston 6 accelerates the projectile by applying force to the probe 21. After the projectile 5 leaves the channel, the bracket 23 rotates, providing a force from unwinding the wire along the axis of the projectile. The piston 6 stops at the end of the working channel, and the seal-insulator 7 prevents the pyrotechnic gases from escaping into the atmosphere.

The installed projectile 5 is fixed from rotation around the longitudinal axis in the barrel using protruding feathering ribs 22. The grooves 25 in the inner housing 4 around the feathering 22 allow air to be accessed behind the projectile 5, eliminating the formation of a rarefied space behind the projectile when they fly out of the accelerating channel.

In addition, the formed grooves 25 in the housing allow casting slopes to be set at the acceleration channel of not more than 0.2 degrees during casting of the housing, setting the casting slopes necessary for extraction from the mold in the grooves 25. The minimum casting slopes in the accelerating channel positively affect accuracy of throwing shells.

At the rear of the channel, a baric arrester 8 is made, made of a dielectric material and having a conductive electrode 9. The second electrode for the baric arrester is an electrically conductive piston 6, the piston not in contact with the baric arrester, and by means of a seal-insulator creates an air gap to form an initiating high-voltage discharge from the piston 6 to the electrode 9. Between the electrodes 9 of the baric arrester 8 and the piston 6 is a pyrotechnic charge 11, which, when passing through n high voltage (level) of the current pulse is initiated. The pyrotechnic gases formed as a result of the initiation move the piston 6 with the seal-insulator 7 forward, pushing the projectile 5 out of the cartridge.

Two sinuses 27 for laying insulated wires 10, shown in FIG. 5. Each shell has its own styling. The use of bare wires 10 for transmitting electrical pulses to the object of exposure is unacceptable, because when firing at a target, it is necessary to withstand the time interval for influencing the object from 1 to 10 s to bring the object into a shock state. At that time, the target can intuitively grab one of the wires with his hand, significantly increasing the current loop and the striking characteristics of the weapon. An increase in the damaging characteristics can lead to an uncontrolled fall of the object, trauma during a fall and death from traumatic consequences. Laying the wire is a block winding (section winding). Each block is a cross winding of several turns in such a way that when unwinding the wire from the sinus, it is unwound in blocks, and each block is a projectile being unwound from the inside alternately. This provides a minimum resistance to inertia of the projectile, guaranteed the absence of wire breakage during unwinding, as well as the possibility of dense filling of the sinus volume. So in the sinus 1.63 cm ³ fit at least 5 m of wire ∅ 0.4 mm.

The front parts of the channels are closed by the shutters 12 shown in FIG. 1, torn off by shells at the beginning of the movement and diverging in different directions when the projectile leaves the cartridge. Each channel has its own curtain that covers the projectile and the corresponding wire laying. The shutters may have an insulating seal 14 shown in FIG. 1, and for their pushing, split sleeves 13 can be used, consisting of at least two parts and located between the projectile and the corresponding shutters 12.

The cartridge case has a front cover 15 that holds the shutters 12 to close the channels 26 and their corresponding sinuses 27 for laying the wires of the inner housing 4, and the front cover 15 is designed to facilitate the assembly of the cartridge.

The cartridge has an open sight 24 for aiming, shown in FIG. four.

Any variant of the electrical connection in the initiation circuit of each projectile is possible: an electrode 9 of a baric arrester 8 of the opposite channel, corresponding to an electrode of an internal arrester 19, a combat electrode 16, laying of wire 10 and electrical contact 3, including with high-voltage gaps. The following is an advantageous embodiment of the electrical connection.

The principle of initiation of the cartridge is as follows: the equipped cartridge is installed on the stun device so that the electrical contacts 3 enter into high-voltage contact with the corresponding high-voltage electrode of the stun device. As a result, a high voltage initiating circuit is created for each channel, as shown in FIG. 2: electrical contact - combat electrode - laying of the wire - electrically conductive piston - electrode of a baric arrester of the opposite channel - combat electrode of the opposite channel - electrical contact of the opposite channel. The fighting electrode and the electrode of the baric arrester 8 of the opposite channel are connected by a branch 17, which may have a section in the form of a destructible track-jumper 18, which is designed to structurally disconnect the electrode 9 of the baric arrester 8 after its initiation in those cases when it is necessary to break the initiation circuit by increasing electrical isolation of the baric arrester electrode and the opposite electrical contact of the cartridge, if they are structurally insulated only by the thickness of the cartridge housing.

After the cartridge is initiated, the initiation chains are broken, because movable electrically conductive pistons 6 are shifted forward and the voltage of each high-voltage electrode of an electroshock device is switched to the target by the circuit corresponding to it: electrode of an electroshock device - electrocontact - combat electrode - laying of wire - swivel bracket - probe - needle with a goatee - target.

Between the branches connecting the electrical contacts of the cartridge 3 and the electrodes 9 of the pressure arresters 8 of the opposite channel, a high-voltage cutting arrestor 19, shown in FIG. 2, in order to eliminate the breakdown of the insulation of wires after the initiation of the cartridge and the possibility of contact use of an electroshock device against the same target for which shooting was performed, without resetting the cartridge, using cartridge fighting electrodes 16. In FIG. 2, a cutting arrestor 19 is installed for example between the branches 17 and is taken out of the housing for clarity.

To increase the manufacturability of the cartridge assembly operations, the laying of the wire 10 can be installed in the inner case in the technological cups 28 shown in FIG. 6, and the beakers themselves 28 can be divided into two volumes for laying the wire. In FIG. 6 one of the glasses is pulled out of the inner housing 4 for clarity.

The cartridge assembly technology allows the cartridge to be assembled in such a way that the installation of pressure arresters and the installation of the inner housing assembly into the housing are final.

The claimed invention allows to increase the operational efficiency of the remote stun device: efficiency, reliability, maneuverability, safety in use.

Claims (16)

1. Remote cartridge for stun device with individual initiation of shells, characterized in that it contains a housing with a surface for mounting on / in the stun device, and on the housing are electrical contacts made with the possibility of high-voltage contact with the electrodes of the stun device, and inside it is installed an inner case with two channels in which throwing shells are placed, moving electrically conductive pistons in contact with them with seals installed on them and -insulators and baric arresters with electrodes, while the inner case is made with sinuses for laying wires, each of which is connected on one side with a missile projectile, and on the other with an electrode of a baric arrester of the opposite channel and with the corresponding cartridge electrical contact. 2. The cartridge according to claim 1, characterized in that it is equipped with shutters for closing the channels and their corresponding sinuses for laying wires. 3. The cartridge according to claim 1, characterized in that the housing is closed by a front cover holding the curtains to close the channels and their corresponding sinuses for laying wires in the housing. 4. The cartridge according to claim 2, characterized in that the curtains have an insulating seal. 5. The cartridge according to claim 1, characterized in that the missile projectiles contain a metal probe with an element for fixing to the target, a plumage of a dielectric material and a swivel bracket for attaching a wire laying. 6. The cartridge according to claim 1, characterized in that in each channel between the missile projectile and the curtain there is a split sleeve. 7. The cartridge according to claim 6, characterized in that each channel contains grooves for accommodating fins of the missile projectile. 8. The cartridge according to claim 7, characterized in that the limiter for the movement of the electrically conductive piston is made in the channel. 9. The cartridge according to claim 8, characterized in that upon initiation of the cartridge, the electrically conductive piston with seal-insulator closes the pyrotechnic gases in the channel. 10. The cartridge according to claim 3, characterized in that the housing has a surface for positioning in an electroshock device on the firing line. 11. The cartridge according to claim 1, characterized in that it further comprises an open sight for aiming. 12. The cartridge according to claim 1, characterized in that it has mounted combat electrodes that are electrically connected to the electrical contacts or through a high voltage gap. 13. The cartridge according to claim 1, characterized in that the sinuses for laying the wires are made in the form of technological glasses. 14. The cartridge according to claim 13, characterized in that the technological glasses are divided into two volumes for laying the wire. 15. The cartridge according to claim 1, characterized in that between the branches connecting the electrical contacts of the cartridge and the electrodes of the baric arrester of the opposite channel, a high-voltage cutting arrester is installed. 16. The cartridge according to claim 1, characterized in that the track-jumper destroyed by high voltage is included in the electrical connection of the electrical contact and the electrode of the baric arrester of the opposite channel.

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