RU207272U1 - Remote Electric Shock Cartridge - Google Patents

Abstract

The utility model relates to remote-acting electroshock devices, in particular, to means for delivering electric current from an electroshock device to a target using projectile flexible electrical conductors. electrodes of an electroshock device, located in two accelerating channels made in the body symmetrically relative to the central longitudinal axis of the body, two projectiles electrically interacting with the corresponding mentioned electrical contacts, two projectile flexible electrical conductors, each of which electrically interacts with one of its ends with the corresponding said electrical contact, and the other end - with the corresponding aforementioned projectile, one working channel is placed in the body, made along the center longitudinal axis of the body, in which a propellant charge is installed, equipped with a protective cover, and a pusher of projectiles, the pusher is made in the form of a fork having a base, the rear part of which interacts with the propellant charge, and two teeth interacting with the corresponding projectile projectiles. the front part of the cavity has flat parallel side walls and convex semicircular tops, an insert is installed in the cavity, which has flat side walls and concave semicircular tops of the same size as the convex tops of the cavity, and the mentioned accelerating channels are formed by mechanical interaction of the corresponding convex and concave tops of the said cavities and inserts.

Description

The utility model relates to remote-acting electroshock devices, in particular, to the means of delivering electric current from the electroshock device to the target using projectile flexible electrical conductors.

There are known means of delivering electric current from a remote-action electroshock device (DESHU) to the target, also called cartridges for DESHU [1, 2]. As a rule, such a means comprises a body provided with electrical contacts arranged with the possibility of electrical connection with an electroshock device, propelling charges and projectiles, respectively, placed in the working and accelerating channels made in the body, as well as projectile flexible electrical conductors placed in a cavity made in the body ...

The disadvantage of such devices is the increased likelihood of an ineffective shot or misfires associated with the fact that it is technologically difficult to make propelling charges absolutely identical, which can lead to an asymmetric flight of projectiles both in time and in initial velocity. In addition, the series electrical connection of the propellant initiation circuits provided in these devices increases the likelihood of misfire (i.e., the failure of one of the propellant charges). This fact is explained by the fact that even with a high probability of correct operation of one element, the serial connection of two such elements reduces the overall probability of their correct operation (the probabilities of correct operation of each element are multiplied).

Of the known devices, the closest to the proposed one is a cartridge for an electroshock device of remote action, containing a housing equipped with electrical contacts arranged with the possibility of electrical connection with an electroshock device, two propelling charges and two projectiles are placed in the working and accelerating channels made in the housing, and two projectiles, respectively, and also two ejected flexible electrical conductors placed in cavities made in the body [3]. The cartridge is realized as a product "BTER" manufactured by the Russian company "MART GROUP".

The disadvantage of this device is the increased likelihood of an ineffective shot or misfire associated with the fact that it is technologically difficult to make propellant charges absolutely identical, which can lead to an asymmetric flight of projectiles both in time and in initial velocity. In addition, the series electrical connection of the propellant initiation circuits provided in these devices increases the likelihood of misfire (i.e., the failure of one of the propellant charges). This fact is explained by the fact that even with a high probability of correct operation of one element, the serial connection of two such elements reduces the overall probability of their correct operation (the probabilities of correct operation of each element are multiplied).

The problem solved by the proposed device is to create a cartridge, devoid of the shortcomings of the prototype. The technical result provided by the proposed device consists in increasing the reliability of actuation by using one working channel with one propellant charge installed in it, acting on both projectiles.

The problem is solved by the fact that in a cartridge for an electric shock device of remote action, containing a housing equipped with electrical contacts located with the possibility of electrical interaction with the corresponding working electrodes of the electric shock device, located in two accelerating channels made in the housing symmetrically relative to the central longitudinal axis of the housing, two electrically interacting with the corresponding mentioned electrical contacts of the projectile, placed in the cartridge cavities two projectile flexible electrical conductors, each of which electrically interacts with one end with the corresponding mentioned electrical contact, and the other end with the corresponding mentioned projectile, one working channel made along the central longitudinal axis of the body, in which a propellant charge is installed, equipped with a protective cover, and a projectile pusher made in the form of a fork having a base, the rear part of which interacts with the propelling charge, and two prongs interacting with the rear ends of the corresponding projectiles.

An additional feature of the device is that the said working channel is made in the form of a cavity made up of two coaxial front and rear cylinders, and the diameter of the rear cylinder is greater than the diameter of the front cylinder, the propellant charge is located in the rear part of the rear cylinder, the diameter of the rear part of the pusher base is made corresponding to the diameter of the rear cylinder, and the diameter of the front part of the pusher base is made corresponding to the diameter of the front cylinder.

An additional feature of the device is that the said body has in the front part a cavity having flat parallel side walls and convex semicircular tops, an insert is installed in the cavity having flat side walls and concave semicircular vertices of the same size as the convex tops of the cavity, and the mentioned the accelerating channels are formed by mechanical interaction of the corresponding convex and concave tops of the said cavity and the insert.

An additional feature of the device is that the said flexible electrical conductors are placed in cavities made in the housing, the pusher base is a rod with an external thread made on its front part, and the plug is made in the form of two teeth connected by a transverse plate, in the center of which there is a hole with an internal thread, the front threaded part of the base is installed in the hole, while the teeth are directed towards the projectiles.

An additional feature of the device is that the said flexible electrical conductors are placed in cavities made in the rear of the projectiles, the projectiles are made elongated in comparison with the projectiles according to claim 4, and the pusher teeth are directed towards the propellant charge, and their ends are bent at right angles ...

An additional feature of the device is that the body is equipped with a detachable installation mechanism on an electroshock device.

The design of the device is illustrated by drawings, which show:

FIG. 1. The design of the cartridge, in which flexible electrical conductors are placed in the cavities of the cartridge body, in section.

FIG. 2. The design of the cartridge, in which flexible electrical conductors are placed in the cavities of projectiles, in section.

FIG. 3. Variants of the pusher design.

FIG. 4. Illustration of the technological process of installing the pusher base into the booster channel.

FIG. 5. Illustration of the technological process of installing the pusher fork base into the cavity of the cartridge body and connecting it to the base.

FIG. 6. Illustration of the technological process of installing the propellant charge into the accelerating channel.

FIG. 7. Illustration of the technological process of installing the protective cover into the boost channel.

FIG. 8. Illustration of the technological process of insertion into the cavity of the insert.

FIG. 9. Illustration of the technological process of installing projectiles into the throwing channels.

FIG. 1a. The device contains a housing 1, in the front part of which a cavity 2 is made, and in the rear part along the central longitudinal axis a working channel 3 is made. - in the working channel 3. Behind the base of the pusher, in the propelling channel 3, there is a propellant 5 containing a working substance (mainly a microdose of a pyrotechnic charge), equipped with a protective cover 6. In the front part of the cavity 2, an insert 7 is installed in the body. Due to the special configuration of the cavity 2 and inserts 7 (see below), accelerating channels 8 are formed, in which projectiles 9 are installed. Each projectile is connected to a flexible electrical conductor laid in a separate cavity of the cartridge body (conductors are not shown in Fig. 1).

FIG. 1b illustrates the operation of the working substance of the propellant charge 5, during the combustion of which a high-pressure gas cloud 10 is formed, acting on the rear part of the pusher 4. Methods for initiating the ignition of the working substance are widely known in the art, in particular, ignition can be provided by a spark discharge, shock action, thermal action etc. Under the influence of the gas pressure, the pusher 4 moves forward, mechanically acting with its teeth on the projectiles, simultaneously pushing them out of the cartridge in the direction of the target.

FIG. 2a illustrates a design variant of the device in which a flexible electrical conductor is laid in a cavity made in the body of the projectile 9, respectively, the projectile 9 is made elongated in comparison with the projectile shown in FIG. 1, in order to accommodate a flexible electrical conductor of great length (in Fig. 2 the conductor is not shown). To ensure the compactness of the cartridge, the pusher 4 has a more complex design, in which the pusher fork is made with teeth directed towards the propellant charge, and the ends of the teeth are bent at right angles and mechanically interact with the rear ends of the corresponding projectiles. The pusher base can be made elongated, extending into the hole made in the insert. Such a technical solution can provide a more reliable design of the device for protection against mechanical influences, for example, when the cartridge falls.

FIG. 2b illustrates the actuation of the working substance of the propellant charge 5, upon ignition of which a high-pressure gas cloud 10 is formed, which acts on the rear part of the pusher 4. Methods for initiating the actuation of the working substance are widely known in the art, in particular, the actuation can be provided by a spark discharge, shock, thermal effect etc. Under the influence of the gas pressure, the pusher 4 moves forward, mechanically acting with its teeth on the projectiles, simultaneously pushing them out of the cartridge in the direction of the target.

FIG. 3a illustrates an embodiment of the pusher according to FIG. 1. The pusher is made with a base 11 and a fork 12 having teeth connected by a transverse plate. The teeth can be made in the form of cylinders. A threaded hole is made in the center of the plate, into which the base is screwed, the front part of which is also made with a thread corresponding to the thread of the mentioned hole in the plate. This design provides a convenient assembly process for the device (see below).

FIG. 3b illustrates an embodiment of the pusher according to FIG. 2. Its assembly is similar to that of the pusher shown in FIG. 3a, the front part of the pusher base 11 can protrude significantly beyond the fork plate 12 for subsequent placement of the front part of the base 11 in the insert 7.

FIG. 4 illustrates the technological process of installing the pusher base into the working channel.

FIG. 4a shows a sectional view of the cartridge body 1. The working channel 3 is made in the form of a cavity made up of two coaxial front and rear cylinders, and the diameter of the rear cylinder is greater than the diameter of the front cylinder, the propellant charge is located in the rear part of the rear cylinder, the diameter of the rear part of the pusher base located in the rear cylinder is made corresponding the diameter of the rear cylinder, and the diameter of the front part of the pusher base located in the front cylinder is made corresponding to the diameter of the front cylinder. The cavity 2 has flat side walls parallel to the side walls of the body and convex semicircular tops. These tops serve as parts of the accelerating channels after insertion into the cavity of the insert 7.

The pusher base 11 is inserted into the working channel from the rear side of the cartridge body (Fig. 4b and Fig. 4c). The arrow shows the direction of movement of the pusher base when it is installed in the housing. The narrowing of the diameter of the front part of the working channel 5 on the one hand and the expansion of the diameter of the rear part of the base 11 of the pusher 4 on the other hand makes it impossible for the pusher 4 to completely exit the cartridge body when the propellant charge 5 is triggered, while the working channel is locked with the restriction (cutoff) of the workers gases. This technical solution reduces the volume of the cartridge shot and at the same time ensures the environmental friendliness of the shot (there are no gas emissions into the surrounding space).

FIG. 5 illustrates the technological process of installing the pusher fork 4 into the cavity 2 of the housing 1 of the cartridge. The arrow shows the direction of movement of the pusher fork when it is installed in the body. The plug is inserted into the cavity (Fig. 5a) and then attached to the pusher base (the base is screwed into the center hole of the plug as shown in Fig. 3).

It should be noted that in this assembled design, the pusher cannot be installed in the cartridge body.

FIG. 6 illustrates the technological process of installing the propellant charge 5 into the cartridge housing, and FIG. 7 - the technological process of installing the protective cover 6. The overall dimensions of the propellant charge correspond to the dimensions of the rear part of the working channel. The propellant charge 5 is installed mainly close to the base 11 of the pusher 3. The arrow shows the direction of movement of the propellant charge when it is installed in the working channel.

If this design provides for the initiation of a propellant charge by the electrospark method by applying a high voltage to the electrodes, between which a high-voltage discharge occurs, initiating the working substance of the propellant charge, then base 11 is used as one electrode, in the rear end of which a pointed projection is made (in Fig. 6 not shown), and the second electrode, made, for example, in the form of a screw with a pointed end directed towards the propellant charge, is installed in a hole made in the center of the protective cover (not shown in Fig. 7). The sharp ends of the electrodes contribute to the appearance of an electric spark along the central axis of the working channel with its development in the entire region of the propellant charge, which ensures the operation of the working substance in the entire volume of the propellant charge. The circuit for supplying high voltage to the said electrodes is not shown; it is widely known in the art of creating cartridges of remote-acting electric shock devices with high-voltage initiation of propellant charges and is used, for example, in [3]. The actual output signal of the electroshock device [3] can be used as an initiating signal.

If this design provides for the initiation of the propellant charge by a thermal method by applying a current pulse to the heating thread, which ignites the working substance of the propellant charge, then the corresponding contacts for supplying current to the thread can be placed in the protective cover 6 (not shown in Fig. 7). This is how, for example, electric ignition devices (EVU) are arranged, which are widely used in various means of active self-defense, for example, the product EVF-SP2 manufactured by the Russian company Glyf-Inzhpribor [4].

Other options for initiating the working substance are also possible, for example, mechanically - by striking the striker into the rear end of the propellant charge, etc.

The protective cover 6 can have an external thread, and the rear part of the working channel can have a counter thread. In this case, the protective cover is screwed into the working channel, mainly using an adhesive, which significantly enhances the tightness of the cover and its mechanical resistance to high pressure of gases formed during the combustion of the working substance of the propellant. The arrow shows the direction of movement of the protective cover when it is installed in the working channel.

FIG. 8 illustrates the design and technological process of inserting the insert 7 into the cavity 2 of the cartridge body. The arrow shows the direction of movement of the insert when it is installed into the cavity of the cartridge body. The insert 7 has flat side walls and concave semicircular tops, the dimensions of which correspond to the dimensions of the convex tops of cavity 2.

The insert 7 is placed into the cavity 2, mainly along a tight fit, including with the use of an adhesive, which significantly enhances the tightness of the insert and its mechanical resistance. Additional strengthening of the fastening of the insert 7 to the body 1 can be provided by installing mechanical fastening elements, for example self-tapping screws (not shown in Fig. 8).

FIG. 9 illustrates the technological process of installation in the cartridge housing of projectiles 9. The arrow shows the direction of movement of the projectiles when they are installed in the accelerating channels 8 of the cartridge housing. The accelerating channels are formed by a combination of convex and concave tops of the cavity 2 and the insert 7, respectively, and thus represent cylindrical cavities, the diameter of which corresponds to the diameter of projectiles, which are also made predominantly in the form of cylinders. The projectiles are mechanically and electrically connected to flexible electrical conductors, which can be placed in special cavities made in the cartridge body, or in cavities made in the projectiles themselves in their rear part (not shown in Fig. 9).

The front end of the cartridge is closed with a protective cover, mainly consisting of two halves, which, when firing, open, fly away or collapse due to the mechanical effect of projectiles flying out of the cartridge and pulling flexible electrical conductors during their flight, electrically interacting with the working electrodes of the electroshock devices.

The device works as follows.

When the propellant charge is initiated, the latter ignites, while the gases formed as a result of ignition affect the rear part of the pusher base, the latter begins to move, mechanically acting with its teeth on the rear ends of the projectiles, and pushes them out of the cartridge towards the target at a given initial speed. When moving, the pusher base with its thickened rear part rests against the narrowing of the front part of the working channel, stops and locks the working channel, preventing the gases from escaping to the outside. The projectiles are pulled along by flexible electrical conductors, which are electrically connected to the output electrodes of the electroshock device. When projectiles hit the target, high voltage current pulses generated by an electroshock device affect the target. Thus, the remote effect of the electroshock device on the target is carried out.

It should be noted that the use of one propellant charge instead of two prototype charges with equal mass of their working substance can lead to a decrease in the initial velocity of projectile projectiles, since the energy of the gases formed during the ignition of the working substance is distributed over two accelerating channels. A decrease in the initial velocity of projectiles negatively affects the tactical and technical characteristics of the device, therefore, in the proposed device, the mass of the working substance of the propellant charge is increased in comparison with the prototype. The peculiarity of the working substances used in such devices (for example, lead trinitroresorcinate - TNRS) is that their energy (gas pressure) grows not proportionally to the mass, but much more, therefore even a small increase in the mass of the working substance provides a significant increase in its energy properties.

Thus, the use of a pusher in the form of a fork with two teeth, installed in one working channel, equipped with one propellant charge, increases its operational reliability, in addition, simplifies the design of the device and reduces the cost of manufacturing it.

An embodiment of the body with a front cavity having flat parallel side walls and convex semicircular tops, into which an insert is installed, having flat side walls and concave semicircular tops of the same size as the convex tops of the cavity, and the mentioned accelerating channels are formed by mechanical interaction of the corresponding convex and concave the tops of the said cavity and insert, also increases the operational reliability of the device, simplifies its design and reduces the cost of its manufacture.

The device is implemented in production and has the following characteristics in comparison with the corresponding characteristics of the prototype:

As can be seen from the table, the proposed device in its characteristics practically does not differ from the parameters of the prototype, while having a higher operational reliability of a standard shot.

List of cited sources

1. US patent No. 6636412. Hand-held stun gun for incapacitating a human target.

2. US patent application US 20050262994 A1. Method and apparatus for improving the effectiveness of electrical discharge weapons.

3. RF patent No. 2351871. A cartridge for a stun device with a remote shock.

4.https: //glif.com.ru/products/.

Claims (6)

1. A cartridge for an electroshock device of remote action, containing a housing equipped with electrical contacts arranged with the possibility of electrical interaction with the corresponding working electrodes of an electroshock device, located in two accelerating channels made in the housing symmetrically relative to the central longitudinal axis of the housing, two projectiles placed in the cartridge cavities two throwable flexible electrical conductors, each of which electrically interacts with one of its ends with the corresponding said electrical contact, and the other end with the corresponding mentioned projectile, characterized in that one working channel is placed in the body, made along the central longitudinal axis of the body, in which a propellant charge is installed, equipped with a protective cover, and a projectile pusher, made in the form of a fork, having a base, the rear part of which interacts with the propellant charge, and two teeth mechanically interacting with the rear ends of the corresponding projectiles. 2. The cartridge according to claim 1, characterized in that said working channel is made in the form of a cavity made up of two coaxial front and rear cylinders, and the diameter of the rear cylinder is greater than the diameter of the front cylinder, the propellant charge is located in the rear part of the rear cylinder, the diameter the rear part of the pusher base is made corresponding to the diameter of the rear cylinder, and the diameter of the front part of the pusher base is made corresponding to the diameter of the front cylinder. 3. The cartridge according to claim 1, characterized in that said body has a cavity in its front part having flat parallel side walls and convex semicircular tops, an insert is installed in the cavity having flat side walls and concave semicircular vertices of the same size as the convex the tops of the cavity, and the mentioned accelerating channels are formed by the mechanical interaction of the corresponding convex and concave tops of the said cavity and the insert. 4. The cartridge according to claim 1, characterized in that said flexible electrical conductors are placed in cavities made in the body, the pusher base is a rod with an external thread made on its front part, and the plug is made in the form of two teeth connected by a transverse plate, in the center of which a hole with an internal thread is made, the front threaded part of the base is installed in the hole, with the teeth directed towards the projectiles. 5. The cartridge according to claim 1, characterized in that said flexible electrical conductors are placed in cavities made in the rear of the projectiles, the projectiles are made elongated, the pusher base is a rod with an external thread on its front, and the plug is made in the form two teeth connected by a transverse plate, in the center of which a hole with an internal thread is made, a threaded part of the base is installed in the hole, while the teeth of the pusher are directed towards the propellant charge, and their ends are bent at right angles. 6. The cartridge according to claim. 1, characterized in that the body is provided with a mechanism for removable installation on the electroshock device.

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