RU207648U1 - Extended Range Cartridge for Remote Electric Shock Device - Google Patents

Abstract

A cartridge for an electroshock device of remote action comprises a housing in which at least one electrical contact is placed with the possibility of its electrical interaction with the corresponding output electrode of the electroshock device, at least one working channel and at least one accelerating channel, means for throwing an electrode is placed in the working channel - the probe to the target, and the probe electrode is placed in the accelerating channel, the cartridge is equipped with at least one flexible electrical conductor, the front end of which is electrically connected to the probe electrode, and the rear end is electrically connected to the said electrical contact, while the flexible electrical conductor is partially placed in the cavity of the electrode-probe, and partially in the cavity made in the housing, thereby forming two series-connected stacks. The stretching of the flexible electrical conductor can initially be carried out from the stack in the cavity of the electrode-probe, and then from the cavity made in The stretching of the flexible electrical conductor can be carried out partly from laying in the cavity made in the housing and partly from laying in the cavity of the electrode-probe alternately. The order of pulling the flexible electrical conductor can be determined by different pulling forces from the corresponding packing. At least partly flexible electrical conductor can be made with a high-voltage insulating coating.

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.

Known means of delivery of electric current from a remote-action electric shock device (DESHU) to the target, also called cartridges for DESHU [1]. As a rule, such a device contains a housing in which at least one electrical contact is placed with the possibility of its electrical interaction with the corresponding output electrode of the electroshock device, at least one working channel and at least one accelerating channel, mainly coaxial with the working channel, in the working channel contains means for throwing the probe electrode at the target (for example, a pyrotechnic propellant charge, a compressed gas cylinder, a spring, etc.), and the accelerating channel contains a probe electrode, the cartridge is equipped with at least one flexible electrical conductor, the front the end of which is electrically connected to the electrode-probe, and the rear end is electrically connected to the electrical contact.

The flexible electrical conductor can be coated with or without high voltage insulation. A conductor without an insulating coating (or with a thin enamel coating) has a small diameter (usually 0.1 ... 0.3 mm), which makes it possible to place a long stack in the cartridge, but at the same time, mutual high-voltage breakdowns of a pair of such conductors are possible during operation of the DES. The insulating coating protects a pair of conductors from possible mutual high-voltage breakdowns during operation of the DES, but noticeably increases the diameter of the conductor (usually 0.3 ... 0.6 mm), respectively, its maximum length that can be packed into a cartridge is noticeably less than that of a conductor without cover. Therefore, the choice of the type of flexible electrical conductor depends on the permissible (specified) dimensions of the cartridge and the expected operating conditions of the DES.

Flexible electrical conductor can be placed in a cavity made in the body of the electrode-probe [2-4]. The disadvantage of such devices is the limited range of action, determined by the maximum length of a flexible electrical conductor, which can be placed in a probe electrode of specified dimensions. For currently existing cartridges of this type, produced in the Russian Federation, the maximum length of a conductor with an insulating coating is 3 m [5].

Flexible electrical conductor can be placed in a cavity made in the body [6]. The disadvantage of such devices is the limited range of action, determined by the maximum length of the flexible electrical conductor, which can be placed in the cavity of the cartridge of specified dimensions. For currently existing cartridges produced in the Russian Federation, the maximum conductor length is usually 4.5 ... 6 m [7, 8].

Of the known devices, the closest to the proposed one is a cartridge for an electroshock device of remote action, containing a housing with a mechanism for removable installation on an electroshock device, equipped with electrical contacts located with the possibility of electrical connection with the electroshock device, placed in the working channels made in the housing, two propelling charges placed in made in the housing of the accelerating channels, two electrode-probes, as well as two ejected flexible electrical conductors, placed in the cavities made in the housing [9]. The cartridge is realized as a product "BTER" manufactured by the Russian company "MART GROUP". The disadvantage of such devices is the limited range of action, determined by the maximum length of the flexible electrical conductor, which can be placed in the cavity of the cartridge of specified dimensions.

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 distance of destruction of a remote-acting electric shock device by increasing the length of a flexible electrical conductor placed in a cartridge of the same dimensions as in the prototype.

The problem is solved in that a cartridge for an electric shock device of remote action, containing a housing in which at least one electrical contact is placed with the possibility of its electrical interaction with the corresponding output electrode of the electric shock device, at least one working channel and at least one accelerating channel , in the working channel there is a means for throwing the electrode-probe at the target, and in the acceleration channel there is an electrode-probe, the cartridge is equipped with at least one flexible electrical conductor, the front end of which is electrically connected to the electrode-probe, and the rear end is electrically connected to the said electrical contact , a flexible electrical conductor is placed partially in the cavity of the electrode-probe, and partially in the cavity made in the housing, thereby forming two series-connected stacks.

An additional feature of the device is that the stretching of the flexible electrical conductor is initially performed from the placement in the cavity of the electrode-probe, and then from the cavity made in the housing.

An additional feature of the device is that the stretching of the flexible electrical conductor is initially carried out from laying in a cavity made in the body, and then from laying in the cavity of the electrode-probe.

An additional feature of the device is that the stretching of the flexible electrical conductor is carried out partly from laying in a cavity made in the housing, and partly from laying in a cavity of the electrode-probe alternately.

An additional feature of the device is that the order of pulling the flexible electrical conductor is determined by different pulling forces from the corresponding stack.

An additional feature of the device is that at least part of the flexible electrical conductor can be made with a high-voltage insulating coating.

The design of the device is illustrated by drawings, which depict: FIG. 1. Variants of typical designs of single-wire cartridges.

FIG. 2. Typical design of two-wire cartridges.

FIG. 3. An example of the design of the proposed device. Channel design.

FIG. 4. An example of the design of the proposed device. Probe electrode design.

A typical design of a single-wire cartridge contains a housing, one cavity for placing a flexible electrical conductor, one accelerating channel for placing the projectile electrode-probe, one working channel, mainly coaxial with the accelerating channel, in which the means for throwing the electrode-probe into the target is located (for example, pyrotechnic propellant charge, miniature compressed gas cylinder, spring, etc.). As a rule, for the production of a shot from the DESHU at the target and the impact on the target with a high voltage current, two such cartridges are required to ensure complete closure of the electrical circuit DESHU-target-DESHU.

FIG. 1a shows a typical design of a single-wire cartridge housing, which contains a housing 1, a cavity 2 for accommodating a flexible electrical conductor, made in a housing 1, and an accelerating channel 3 for accommodating a projectile electrode-probe (a working channel with throwing means, a flexible electric conductor and an electrode probe not shown).

FIG. 1b shows another typical design of the housing of a single-wire cartridge, containing a housing 1 and an accelerating channel 3 for accommodating a projectile electrode-probe, in which a flexible electrical conductor is placed in a cavity made in the body of the probe, usually in its rear part (working channel with throwing means, flexible electrical conductor and probe electrode not shown). The advantage of such a device is its miniature size, however, the maximum length of laying an insulated flexible electrical conductor in the electrode-probe with the typical dimensions of the cartridge does not exceed 3 m (while the length of the laying with an uninsulated conductor can reach 10 m).

FIG. 2 shows a typical design of a two-wire cartridge housing, comprising a housing 1, two cavities 2 for accommodating flexible electrical conductors and two accelerating channels 3 for accommodating projectile electrodes (working channels with throwing means, flexible electrical conductors and probe electrodes are not shown). For the production of a shot from the DESHU at the target and the impact on the target with a high voltage current, one such cartridge is required, which ensures complete closure of the electrical circuit DESHU-target-DESHU. Stacking of flexible, predominantly insulated electrical conductors makes it possible to provide a range of operation of the DESHU of 4.5 ... 6 m (while the length of stacking with an uninsulated conductor can reach 10 m, but insulated conductors are usually used for two-wire cartridges).

The design of the proposed device is shown in Fig. 3 and FIG. 4, and the housing for the implementation of the device is selected similar to the housing shown in FIG. 2.

FIG. 3 shows a cross-section of the housing 1 along the line A-A (see Fig. 2). The device contains two identical channels, each of which contains an accelerating channel 3 and a working channel 4. Some part 5 of the flexible electrical conductor is placed in a cavity made in the body 6 of the electrode-probe, the front part 7 of which is equipped with a needle 8, electrically in contact with the front end of the flexible electrical conductor 5. In the working channel 4, there is a throwing means, for example, made in the form of a pyrotechnic propellant charge 9, upon ignition of a high-pressure gas generating, mechanically acting on the electrode probe using a pusher wad 11. From the rear end of the housing 1, the working channel is protected cover 12.

FIG. 4 shows a cross-section of the housing 1 along the line B-B (see Fig. 2). The device contains two identical cavities 2, each of which contains a second part 13 of a flexible electrical conductor. The front end of each flexible electrical conductor 13 is connected to the rear end of the corresponding portion 5 of the flexible electrical conductor, which is located in a cavity formed in the body of the probe electrode. More precisely, it is essentially a continuation of a flexible electrical conductor placed in a cavity made in the body of the probe electrode. The rear end of the flexible electrical conductor electrically interacts with the electrical contact 14 located on the housing 1, and the electrical contact 14 itself is made with the possibility of electrical interaction with the corresponding output electrode of the DEGU.

Thus, the total length of the parts of the flexible electrical conductor can be significantly increased in comparison with the existing designs of cartridges, which means a corresponding increase in the distance of destruction of the DES.

Some part of the flexible electrical conductor (for example, that part that is located in the cavity of the electrode-probe) can be made without insulation, and its second part (for example, that part that is located in the cavity of the cartridge body) can be insulated, which can further increase the maximum distance of defeat.

In some cases, the part of the flexible electrical conductor adjacent to the needle 8 (for example, the first 50 ... 100 cm) can be made with insulation, and the rest of the flexible electrical conductor, located in the electrode-probe, without insulation. This design option makes it impossible for the offender, who was shot from the DES, to close two flexible electrical conductors without insulation with his hands and thus protect himself from the effects of the high voltage current generated by the DES (in this case, the electric current will not go through the target's body).

For the implementation of the proposed design, it is important to draw out the parts of the flexible electrical conductor located respectively in the cavity of the electrode-probe and the cavity made in the housing, and the means ensuring this order. The following three main variants of this order are possible:

the first is the complete stretching of the flexible electrical conductor located in the cavity of the electrode-probe, and only then - the stretching of the flexible electrical conductor located in the cavity made in the housing;

the first is the complete stretching of the flexible electrical conductor located in the cavity made in the housing, and only then - the stretching of the flexible electrical conductor located in the cavity of the electrode-probe;

some, relatively small parts of the flexible electrical conductor are pulled out alternately from the cavity of the electrode-probe and the cavity made in the housing.

The choice of the desired pulling order remains with the cartridge designer, since each of them has its own advantages and disadvantages.

One of the effective means of ensuring the desired order of pulling a flexible electrical conductor is to create different pulling forces: it is obvious that the first part of the flexible electrical conductor will always be pulled with a lower pulling force. Different pulling forces can be provided, for example, by different winding densities of the turns of a flexible electrical conductor (turns with a lower winding density will have a lower pulling force). Another way to provide different pulling forces is to glue the turns of different parts of a flexible electrical conductor with weak adhesives with different bonding properties: a weaker adhesive gives a lower pulling force on the turns of a flexible electrical conductor. Finally, a design option is possible with temporary mechanical locking of that part of the flexible electrical conductor, which should be pulled out by the second, with its subsequent unlocking after pulling out the primary part of the flexible electrical conductor. The mentioned mechanical locking, in fact, is a special case of control of the pulling force (when locking, the pulling force tends to infinity).

It should be noted that the energy of the propellant charge, which, during ignition, provides the required gas pressure for throwing the probe electrodes, in the proposed device should provide the required initial velocity of the electrode-probe departure from the cartridge, taking into account the mass of the flexible electrical conductor placed in its cavity and the increased total length flexible electrical conductor. Increased initial take-off speed is also necessary to improve the flight path of the probe electrode over a long distance. At a typical exit speed (40 ... 45 m / s), the decrease in the trajectory due to the gravitational influence of the Earth is very noticeable and reaches 20 cm at a hitting distance of 8 m, which reduces aiming accuracy and, accordingly, increases the probability of a miss for the DES operator. This follows from the relation

where:

h - decrease in the trajectory of the probe electrode relative to the horizontal line of sight,

ρ is the linear mass of a flexible electrical conductor,

m is the mass of the probe electrode,

g - acceleration of gravity,

L - distance of defeat,

v ₀ - initial speed of the probe electrode (when leaving the cartridge, or at a distance of 1 m from it).

An increase in the exit speed of the probe electrode to 60 m / s provides half the decrease in the trajectory at a similar distance of destruction. Pyrotechnic propellant charges (for example, based on lead trinitroresorcinate - TNRS) have the property of a significant increase in energy even with a slight increase in the mass of the charge, therefore this increase does not affect the dimensions of the cartridge.

The device works as follows.

At the moment the shot is fired, that is, the cartridge is initiated, the propelling charges 9, if they are made with the use of pyrotechnic substances, ignite, forming a gas with increased pressure, which, acting on the probe electrodes 6 through the pusher wads 11, pushes them in the direction of the target. Another option for pushing out the probe electrodes can be the use of compressed gas (for example, air or CO ₂ ) as a propellant charge, as in pneumatic weapons. There are other options for the means of ensuring the ejection of the probe electrodes, for example, the use of a pre-compressed spring. Next, we will consider one channel of transmission of influence to the target.

After the exit of the probe electrode 6 from the corresponding accelerating channel 3 in the direction of the target, the flexible electrical conductor 5 or 13 (depending on the adopted pulling order in this cartridge) begins to be pulled out of the cavity of the probe electrode 6 or the cavity of the cartridge body 2. If the distance to the target exceeds the length of that part of the flexible electrical conductor, which is initially located in the cavity of the electrode-probe 6 (or the cavity of the cartridge body 2), then its further pulling is performed from another cavity. There is also an option in which the pulling of some parts of the flexible electrical conductor is performed alternately from different cavities. As mentioned earlier, the order of pulling the flexible electrical conductor from different cavities can be provided by different pulling forces from the corresponding cavity, determined, for example, by the different density of winding the turns of the flexible electrical conductor on the mandrel before being placed in the corresponding cavity.

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

Thus, the proposed device has the same dimensions as the prototype, despite the fact that the total length of the flexible electrical conductor is much greater than in the prototype.

List of cited sources

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

2. RF patent №2486451 A projectile of a remote electric shock weapon and a method for its manufacture.

3. RF patent №2477441 Cartridge of remote electric shock weapons.

4. RF patent No. 43350 Probe of an electroshock device for remote destruction of targets by electric current.

5.http: //www.gardsystems.ru/.

6. RF patent No. 2648562 Remote cartridge for an electroshock device with individual initiation of projectiles.

7.https: //marchgroup.ru/products/sartridges-and-nozzles/strelvavucshij-kartridzh-bter.html.

8.https://npp-oberon.ru/magazin/116/223.html.

9. RF patent №2351871 Cartridge for an electric shock device with a remote defeat.

Claims (6)

1. A cartridge for an electroshock device of remote action, containing a housing in which at least one electrical contact is placed with the possibility of its electrical interaction with the corresponding output electrode of the electroshock device, at least one working channel and at least one accelerating channel, is located in the working channel means for throwing a probe electrode at a target, and a probe electrode is placed in the accelerating channel, the cartridge is equipped with at least one flexible electrical conductor, the front end of which is electrically connected to the probe electrode, and the rear end is electrically connected to the said electrical contact, characterized in that Flexible electrical conductor is placed partly in the cavity of the electrode-probe, and partly in the cavity made in the housing, thereby forming two series-connected stacks. 2. The cartridge according to claim 1, characterized in that the stretching of the flexible electrical conductor is initially carried out from laying in the cavity of the electrode-probe, and then from the cavity made in the housing. 3. The cartridge according to claim 1, characterized in that the stretching of the flexible electrical conductor is initially performed from laying in a cavity made in the housing, and then from laying in the cavity of the electrode-probe. 4. The cartridge according to claim. 1, characterized in that the stretching of the flexible electrical conductor is performed partly from laying in a cavity made in the housing, and partly from laying in a cavity of the electrode-probe alternately. 5. The cartridge according to claim 1, characterized in that the pulling order of the flexible electrical conductor is determined by different pulling forces from the respective stack. 6. The cartridge of claim. 1, characterized in that at least part of the flexible electrical conductor can be made with a high-voltage insulating coating.

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