RU2668147C9 - Method for elimination of capacitive breakdown pain feelings in electric shock and protection device for implementation thereof - Google Patents

Abstract

FIELD: electricity.SUBSTANCE: method of pain feeling elimination of the electric shock user in case of capacitive breakdown consists in selecting the high voltage potential signal from the electric circuit of the electric shock device through a control electrode connected to the user's body and with a high-speed device for disconnecting the high-voltage electric current generator of the high-voltage ES or RCES. Device for implementing a method for eliminating the pain sensations of a user of an electric shock in the case of a capacitive breakdown comprises a reference electrode, a divider-limiter, a comparator, a single-oscillator or a trigger connected to a generator of high-voltage electrical impulses of an electric shock.EFFECT: technical result is the possibility of producing miniature ES or RCES.9 cl, 2 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 (in accordance with GOST R 50940-96). 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 be painful, and is often the cause of a “fear of one’s own device” for a user of an ESH or a DES.

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 or a partial miss (one of the two conductors flies past the target).

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 “use of the device = 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 for laying in the body of the internal electrical insulating cover, which is packaged in the electrical circuit ESA. The said cover must have a material thickness of at least 1 ... 2 mm, which inevitably leads to 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 complex 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 prototype of a 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 were 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 in a method for eliminating the painful sensations of a user of an electroshock device during capacitive breakdown, the generator of an electroshock device that generates high-voltage pulses of electric current is automatically turned off at the moment it begins to generate a high-voltage potential charging the electric capacitance of the user's body, with a signal turning off the aforementioned electrical circuit serves as the first pulse of the high voltage potential, taken from e of the conductive parts of the electric circuit of the stun device and passing to the user’s body through a special contact place, namely, through a control electrode connected to the electronic circuit breaker.

The essence of the invention also lies in the fact that the subsequent inclusion of the aforementioned generator is carried out manually by re-enabling the stun device.

The essence of the invention also lies in the fact that the subsequent inclusion of the said generator is carried out automatically after a programmed time after it is turned off.

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 a control electrode, a divider-limiter, a comparator, a one-shot oscillator or a trigger connected to a generator of an electroshock device generating high voltage electric current pulses.

The essence of the invention also lies in the fact that an additional signaling device connected to the one-shot or trigger is introduced into the device for implementing the method.

The invention also lies in the fact that the aforementioned additional signaling device is made in the form of an audio indicator.

The essence of the invention lies in the fact that the aforementioned additional alarm device is made in the form of a light indicator.

The essence of the invention lies in the fact that the aforementioned additional alarm device is made in the form of a vibration indicator.

The invention also lies in the fact that the aforementioned additional signaling device is made in the form of any combination of sound, light and vibration indicators.

Description of drawings

FIG. 1. A block diagram of a protection device for implementing the inventive method in an ESH with a generator for generating high-voltage pulses of electric current in an ESH without controlling a microcontroller.

FIG. 2. The block diagram of the protection device for implementing the proposed method in an ESA with the formation of a high voltage generator of high-voltage pulses of electric current ESA controlled by a microcontroller.

FIG. 1. When conditions are created for the occurrence of capacitive breakdown (C> 10 ... 20 pF), a capacitive breakdown current flows through the divider-limiter 1 and the control electrode 2 connected to the owner of the electronic control system (user), and an increasing voltage appears at the input of the comparator 3. When it reaches the threshold of operation of the comparator 3, the one-shot 4 starts (or the trigger fires), which generates a control signal to block the operation of the generator of the stun device that generates high-voltage pulses of electric current.

When using the trigger, the formation of high voltage current pulses is blocked until the ESH button “START” is pressed again. When using a single-shot, the duration of the pulse generated by it determines the time during which the aforementioned high-voltage current pulse generator is blocked, and can be selected for a specific task. The choice of the division ratio of the divider-limiter 1 and the response threshold of the comparator 4 determines the critical value of the capacitance C at which the protection circuit operates.

The condition for the occurrence of capacitive breakdown is the absence of contact of one of the electrodes of the object of influence (target), or the failure of one of the DESHU probes to fall into the object of influence (target), or the breakage of one of the DESHU current leads, in the general case, the abnormal (ineffective) use of an ESA or a DESA.

When using a single-vibrator, it is possible to implement a mode in which the ESW or DESHU (the aforementioned generator of high-voltage current electric pulses in the EShU or DEShU) will be switched off after a single electrical discharge of capacitive breakdown at the owner of the EShU or DEShU, indicating (by itself, the fact of the unit is not too painful for the user breakdown and subsequent shutdown of the generator, or by generating an additional miss indication signal (in the general form, the emergency mode of the emergency control or emergency control), for example, light, sound owner or user that the EShU or TEShU is used abnormally (inefficiently), and it is necessary either to ensure contact of both electrodes of the EShU with the target (target), or to re-shoot from the TEShU. After the programmed time (for example, after 0.2 ... 1 s), the ESW or DESHO can turn on again. If at the same time the emergency situation is corrected, then the ESHU or DESHU will begin to work in normal mode, affecting the target. If the abnormal situation is not fixed, the device will again indicate to the owner with the next single electrical discharge of capacitive breakdown that the ESH or DEShU is used abnormally (ineffectively), and it is necessary either to ensure contact of both electrodes of the EShU with the target (target), or to re-shoot from the DEShU.

FIG. 2. When using a protection device in ESW circuits in which a microcontroller is used to form high-voltage discharges, the protection unit circuit is simplified, since the comparator is contained in many microcontrollers, and a single-shot or trigger is easily implemented using software methods.

The control electrode 2 is an electrically conductive layer deposited on at least part of the outer surface of the handle or other part of the retention surface of the electroshock device, made in the form of vacuum, chemical or galvanic metallization, or a glued conductive coating (for example, metal foil) or deposited electrically conductive paint, or made in any other suitable way.

Mentioned conductive layer of the control electrode 2 is electrically, for example, using an electrical conductor, connected to the input of the divider-limiter 1.

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

When fired from the electric shock generator, in case of failure (for example, due to the breakage of the electrical conductor during the shooting) of one of the electrical conductors in the body of the offender, an electrical connection occurs between one of the working electrodes of the electronic controller with an electric capacitance of 50 ... 100 pF (a natural capacitor, one surface of which is the body surface delinquent or other object of influence) with an electric potential on the said electrode, which is for standard EShU or DEShU 50 ... 120 kV, between internal electrical conductors The electrical parts (spark) appear during the charge of the second plate of the mentioned natural capacitor, and the surface of the user's body serves as this second plate. 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). In the device under consideration, a high-voltage discharge of capacitive breakdown will occur between the user's hand and the control electrode 2. The breakdown of the air gap by the 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 cause some pain, but, due to the high speed of the electronic circuit of the protection device, the generator of the electroshock device that generates high-voltage pulses of electric current will be turned off in such a short time that the user will experience the effect of only a single discharge of a capacitive breakdown (even with a frequency of operation of an ESH or TES more than 300 Hz). At the same time, at present, the typical frequency of output electric discharges of an ESH or DESh does not exceed 300 Hz. A similar phenomenon of capacitive breakdown can also occur in a contact control ESH 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. And in this case, the protection device will almost instantly turn off the generator of the electroshock device that generates high-voltage pulses of electric current, so that the user will experience only a single discharge.

Implementation example

Remote stun device made in the form factor of the gun. 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.

Claims (9)

1. A method for eliminating the painful sensations of capacitive breakdown in electroshock devices is that to eliminate painful sensations when charging a user’s capacitance during capacitive breakdown, the generator of an electroshock device generating high-voltage pulses of electric current is automatically turned off at the moment it begins to generate a packet of pulses of high-voltage potential, charging the electric capacity of the user's body, and the signal to turn off the aforementioned electrical circuit the first impulse of generating a high-voltage potential, taken from the electrically conductive parts of the electric circuit of the electroshock device and passing to the user’s body through a special contact place, namely through a control electrode connected to an electronic shutdown circuit, lives on. 2. The method according to p. 1, characterized in that the subsequent inclusion of the said generator is carried out manually by re-enabling the stun device. 3. The method according to p. 1, characterized in that the subsequent inclusion of the said generator is carried out automatically after a programmed time after it is turned off. 4. A device for implementing a method of eliminating pain when charging a user’s capacitance of an electroshock device with a capacitive breakdown comprises a control electrode, a divider-limiter, a comparator, a one-shot vibrator or a trigger connected to a generator of an electroshock device that generates high voltage electric current pulses. 5. The device according to p. 4, characterized in that it includes an additional alarm device connected to the aforementioned one-shot or trigger. 6. The device according to p. 5, characterized in that the said additional alarm device is made in the form of an audio indicator. 7. The device according to p. 5, characterized in that the said additional alarm device is made in the form of a light indicator. 8. The device according to p. 5, characterized in that the said additional alarm device is made in the form of a vibration indicator. 9. The device according to p. 5, characterized in that the said additional alarm device is made in the form of any combination of sound, light and vibration indicators.

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