RU2669907C2 - Method for elimination of painful sensations in case of capacitive breakdown in electric shock devices and device for implementation of such method - Google Patents

Abstract

FIELD: instrument engineering.SUBSTANCE: method for eliminating painful sensations of users of electric shock devices in the case of capacitive breakdown involves selection of high-voltage potential from the electric circuit of the electric shock device and application of the said potential to the human body through a special lead-in electrode. In the method, the device for implementing such method for eliminating painful sensations of an electric shock device user in case of capacitive breakdown contains an electrically conductive layer on the holding or controlling elements of the electro-shock device, connected to the electric circuit of the electric shock device by direct electrical contact or connection through the air gap.EFFECT: technical result is the possibility of producing miniature electro-shock devices or remote electro-shock devices.4 cl, 1 dwg

Description

FIELD OF THE INVENTION

The invention relates to police and civilian electroshock devices (ESD), remote electroshock devices (ESD) with an electric means of influencing the target.

State of the art

Known contact and remote stun devices (ESA), affecting the offender (public order violator) by high voltage electric current discharges that are transmitted to the body of the offender by direct contact of the working electrodes of the ESA with the body of the offender, or using electrical conductors fired from the ESA and secured on the body of the offender in various ways. The disadvantage of most samples of modern ECS is their large dimensions, which are, inter alia, a consequence of the fight against the phenomenon called “capacitive discharge” or, in other words, “capacitive breakdown”. This phenomenon is as follows. With the electrical contact of only one of the working electrodes of the EShU or DEShU with an electric capacity of 50 ... 100 pF (a natural capacitor, the surface of the offender’s body serves as one capacitor) with an electric potential on the said electrode, which is 50 ... 120 kV for standard ESHs, between the internal electrically conductive parts ESH and the hand of the user holding the ESH or DESH, an electric discharge (spark) appears, which occurs during the charge of the second lining of the mentioned natural capacitor, and in ETS this second electrode is the surface of the user's body.

The spatial extent of the spark discharge during capacitive breakdown in dry air is up to 8 ... 12 mm for current values per pulse of several microamps at a resistance of 1000 Ohms, equivalent to the electrical resistance of the human body accepted for determining the characteristics of EShU or DEShU (GOSTR50940-96). Therefore, a spark discharge during the occurrence of capacitive breakdown (due to the low current strength) is not hazardous to the user of an ESH or TES, i.e. it does not have damaging properties, but it can turn out to be very painful, and is often the cause of a “fear of one’s own device” for a user of an ESH or DESh.

When using contact ECGs, capacitive breakdowns are very rare, since the user presses the working electrodes against the body of the offender almost simultaneously, so that contact of only one working electrode of the ESH with the body of the offender (including through the air gap formed by the clothes of the latter) is unlikely, although in practice ESU such cases are known. However, when using DESHO, the occurrence of contact of only one working electrode with the body of the offender and, accordingly, the occurrence of capacitive breakdown, can occur quite often, for example, when only one electrical conductor is connected to the body of the offender, connected, respectively, with one working electrode, due to a break one of the electrical conductors when fired.

In this case, a capacitive breakdown inevitably occurs, as a result of which the user of the ESD or DESU receives a series of painful electric discharges from his own device, which can cause a conditioned reflex “device use is pain”, i.e. fear of one’s own device and, consequently, a psychological attitude to refuse to use the device even in situations in which its use is necessary.

To combat the phenomenon of capacitive breakdown on the body of the ESA user, spatial diversity (distance) of any internal electrically conductive part of the ESA, regardless of whether it is a low-voltage or high-voltage part of the ESA (including indication and control elements, batteries), from places in ESH housing with access to the surface of the device (gaps in the places of the connector of the housing parts, the outputs of the indication and control elements, contact elements of the built-in battery, etc.). The distance at which the electrically conductive parts are removed from the above locations of the ESH enclosure should be no less than 1.5 ... 2 times the length of the spark discharge of capacitive breakdown, which is 8 ... 12 mm in dry air, to prevent the development of a surface discharge along adjacent parts of the control cabinet, even if made of an insulating material. The need for such a distance of the electrically conductive parts from the indicated places in the ESH enclosure, in turn, requires an increase in the dimensions of the ESH.

Another way to eliminate capacitive breakdown on the body of the ESA user is through complete electrical isolation, i.e. separating internal electrically conductive parts from the indicated places in the housing by an electrically strong barrier, mainly made of an electrically insulating elastic material such as rubber. This method also increases the dimensions of the ESA due to the need to put an internal electrical insulating cover into the housing, into which the electrical circuit of the ESA is packed, with a cover material thickness of at least 2 mm, which means an increase in the total internal volume and a corresponding increase in the external dimensions. In addition, the complete electrical isolation of the electric circuit of the ESA, including its control elements (indication elements, fuse, start button or trigger, etc.), as well as the contact elements of the built-in battery, is extremely expensive and represents a very difficult constructive task , which negatively affects the final price of the ESA for the consumer. The increase in the external dimensions of electroshock devices makes their further miniaturization impossible, although the modern elemental base potentially provides such an opportunity. In addition, when using this method, the conditions of heat removal from the loaded elements of the electric circuit of the ESH are significantly worsened, which increases the risk of ESH failure.

An analogue and a prototype of the method for eliminating the painful sensations of capacitive breakdown in electroshock devices from the prior art and as a result of a patent search were not found.

An analogue and prototype device for eliminating the pain of capacitive breakdown in electroshock devices from the prior art and as a result of a patent search is also not found.

Disclosure of invention

The aim of the invention is to provide a method of preventing painful sensations of the user of the ESA or TESA when capacitive breakdown occurs. The aim of the invention is also the creation of a device for implementing the method. The ultimate goal of the invention is the ability to create a miniature ESHU or DESHU.

The essence of the invention lies in the fact that to eliminate the painful sensations of the user of the electroshock device during capacitive breakdown, a high-voltage potential charging the electric capacity of the human body is selected from the electrically conductive parts of the electric circuit of the electroshock device and organizes the application of this potential to the human body through a large area supply electrode.

The essence of the invention also lies in the fact that the device for implementing the method of eliminating the painful sensations of the user of the electroshock device during capacitive breakdown contains an electrically conductive layer, made mainly by metallization or gluing with metal foil, or by coloring the surface of the retention or control organs of the electroshock device with electroconductive paint, or both together, which is electrically connected to the electrically conductive part of the electric shock device circuitry CTBA by direct electrical contact or connection through air gap, wherein the area of said electrically conductive layer is chosen sufficient to eliminate painful sensations at the electroshock device.

Description of drawings

FIG. 1. General view of the electrically conductive layer, made mainly by metallization or pasting with metal foil, placed on the handle part of the stun device.

FIG. 1. On the outer surface of the grip handle 1 of the electroshock device 2, an electrically conductive layer 3 is applied, made in the form of a vacuum, chemical or galvanic metallization, or a glued electrically conductive coating (for example, metal foil) or applied electrically conductive paint.

Said electrically conductive layer 3 is electrically, for example, by means of a conductor, connected to any electrically conductive part of the electric circuit located inside the electroshock device 2. As such, the electrically conductive battery outer shell (or galvanic cell) of the electroshock device can serve, for example, even located inside the power compartment of the stun device 2.

The mechanism of operation of the method and device for eliminating the pain of capacitive breakdown in electroshock devices is most simply described as follows.

When fired from the DESU in the event of a failure (or breakage of the electrical conductor during the firing) of one of the electrical conductors into the body of the offender, an electrical connection occurs between one of the working electrodes of the DESU with an electric capacity of 50 ... 100 pF (a natural capacitor, one of which serves as the surface of the body of the offender) when the electric potential at the said electrode, which is for standard ESH 50 ... 120 kV, between the internal electrically conductive parts of the ESH and the hand of the user holding ES or DESHU, there is an electrical discharge (spark) occurring during charging of said second electrode of said capacitor natural, and as of the second electrode is the surface of the user's body. This discharge usually occurs in the place of the smallest air gap between any element of the electrically conductive part of the electronic control circuit and the palm surface of the user's hand holding the weapon (moreover, neither a fabric nor leather glove worn on the user's hand can serve as an obstacle to a high-voltage discharge). Such a breakdown of the air gap by an electric discharge is actually a point electrical effect on the nerve endings of the palm of the user's hand, located at the breakdown point. Such, even a single, electric discharge can already cause some painful sensations, and before the user’s reaction (the human reaction time to any action is 0.2 ... 0.5 s) allows him to turn off the generator of working electric discharges (for example, by releasing the pressed start-up control element of the ESA), the user will feel the impact of 20 ... 50 discharges at an ESH frequency of 100 Hz (or 60 ... 150 discharges at an ESH frequency of 300 Hz). The calculations were carried out taking into account the factor that at present the typical frequency of working electric discharges of ESW is 100 ... 300 Hz. It should be noted, an increase in the duration of the output high-voltage pulses enhances the effect of pain. Such a significant number of point electric discharges directed to the same place in the user's hand causes (due to the accumulation of the amount of electricity) severe persistent pain and subsequent fear of their own device.

A similar phenomenon can occur in a contact control ECU in the case of contact of only one working electrode with an electrically conductive body (surface) with dimensions close to or greater than the dimensions of a person with a relatively large (50 ... 100 pF or more) electric capacitance.

In the case of applying an electrically conductive layer, made mainly by metallization or gluing with a metal foil, or by painting an electrically conductive paint on the surface of the retention or control elements of an electroshock device, or both, connected to the electrically conductive parts of the electric circuit of the electronic control system, the user is still connected with parts of the electric circuit of the ESA conducting the charging potential through a large area of contacting surfaces (surfaces electrically conductive layer placed on the ESH containment body, and the surface of the hand in contact with the electrically conductive layer in many places), as a result of which, when charging the electric capacity of the body, the passing charging current is distributed over a large area of the surface of the palm of the hand, and the charge drains off immediately from the user's body air. A significant potential difference between the electrically conductive parts of the electric circuit of the ESA and the human body does not develop, the nerve endings of the palm of the hand do not respond to a weak charging current distributed over the area of the palm of the hand, and accordingly there are no painful sensations.

The minimum required area of the electrically conductive layer, made mainly by metallization or gluing with metal foil, or by staining the surface of the retention or control organs of an electroshock device, or both together, is selected from the condition of the absence of painful sensations in the average person when one of the working electrodes of the ESA is connected to electrically conductive surface with an area equal to or greater than the "normal value" of the surface of the human body (PPT) equal to 1.73 ^2, and is usually 0.005 ... 0.01 m ^2.

The device may further be characterized in that said electrically conductive layer is applied on both sides or on the side and end sides of the retention or control elements of the electroshock device, or both.

The device may further be characterized in that said electrically conductive layer is applied to all surfaces of the retention or control organs of the stun device, or both.

Implementation example

Remote stun device made in the form of a semi-automatic pistol. The output voltage at the working electrodes is 70 ... 90 kV, the distance between the working electrodes is 26 mm, the electric power of the impact is 3 W, the permissible time of exposure to the offender is not more than 3 s.

An electrically conductive layer made in the form of a glued electrically conductive coating (metal foil) is applied to the outer surface of the handle, said electrically conductive layer is electrically connected to the metal surface of the battery housing located in the power compartment of the device. The area of the electrically conductive layer in contact with the palm of the user is about 0.01 m ² . Such an area of the electrically conductive layer is quite sufficient to ensure the absence of painful sensations of the user when a capacitive breakdown of the ESA appears in the previously considered situations.

Claims (4)

1. A method for eliminating the painful sensations of a person who is a user of an electroshock device during capacitive breakdown, consisting in the fact that, to eliminate painful sensations when a person’s electric capacity is charged during the operation of electroshock devices, a high-voltage potential charging an electric capacity of a human body is selected from electrically conductive parts of the electric circuit of the stun device and organize the application of the aforementioned potential to the human body through the supply electrode of a large area di. 2. A device for implementing a method of eliminating pain during capacitive breakdown in electroshock devices, comprising an electrically conductive layer made primarily by metallization or gluing with a metal foil, or by coloring with electroconductive paint the retention or control organs of an electroshock device, or both, which are electrically connected with the electrically conductive part of the electrical circuit of the stun device by direct electrical contact or by connecting through ushny gap, wherein the area of said electrically conductive layer is chosen sufficient to eliminate painful sensations at the electroshock device. 3. The device according to claim 2, characterized in that said electrically conductive layer is applied on both sides or on the side and end sides of the holding or controlling organs of the stun device, or both. 4. The device according to p. 2, characterized in that said electrically conductive layer is applied to all surfaces of the retention or control organs of the stun device, or both.

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