RU2764318C1 - Method for affecting a target and apparatus for implementation thereof - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: method for affecting a target, wherein, jointly with an electrical effect, the target is affected by a bright flash of light or a loud sound, or simultaneous or consecutive impact thereof occurring near the target. The apparatus for implementation of the method for affecting a target with a remote-action electric shock apparatus comprises an output electrode made in the form of a probe thrown in the direction of the target using a propellant charge, compressed air, a spring, or by another method, connected by a flexible electrical conductor with the corresponding input electrical contact of the apparatus, electrically communicating with the working electrodes of the electric shock apparatus. The apparatus comprises light and sound charges thrown in the direction of the target simultaneously with said probe or in advance thereof, or lagging behind said probe, or in a combination of advance, simultaneity, and lagging. Light and sound charges are placed in the cavity of the thrown probe or on the surface thereof, or partially in the cavity and partially on the surface of the probe. An element for protecting the target from flying products of sound or light charge, made in the form of a cap (umbrella), is placed on the body of the probe.

EFFECT: increase in the effectiveness of the impact of electric shock apparatuses.

10 cl, 18 dwg

Description

The invention relates to methods and devices for electrical impact on the target with the help of remote-action electroshock devices.

Known and widespread are various methods and devices for electrical impact on aggressive wild animals or offenders (target) using electroshock devices (ESD). The main idea of their implementation is the formation of high-voltage current pulses that act on the target, providing this effect with temporary immobilization of the target [1, 2].

For remote impact on the target, the so-called electric discharge transport units (BTR) of remote-action EShU (DESHU), otherwise called electric cartridges, are used [3, 4]. The design of the BTE usually contains a body equipped with elements of removable fastening in / on the DESHU, with cavities made in it for accommodating thrown flexible electrical conductors (FEC) and accelerating channels with projectiles (probe electrodes) placed in them and means for throwing them at a given distance . The GEP of a given length is attached to the corresponding probe in its rear part, and to the front part of each of the probes there is a fixation element on the target - the clothes or skin of the offender, made mainly in the form of a needle with a hook. The maximum distance of influence on the target is determined by the length of the projectiles. The second end of the HEA is in electrical contact with the corresponding input contact of the cartridge, connected, in turn, to one of the output (working) electrodes of the DESHU. When a shot is fired from the DESH and the probe moves, the HEP is pulled out of the said cavity of the cartridge towards the target. Cartridges are also known, characterized in that the HEC is placed in a cavity made in the probe electrode itself, respectively, when the probe is thrown from the cartridge, the HEC is pulled out of the probe towards the user of the DESHU.

Thus, in all considered technical solutions, a conductive channel in the form of a GEP is used.

The effectiveness of the impact of EShU is determined both by their output parameters (output voltage, repetition frequency of electrical current pulses, etc.), and by the electrical characteristics of the human body, in particular, by its electrical resistance. The lower this resistance, the higher the efficiency of the EShU impact on the target, all other things being equal. The mentioned resistance is a variable value, depending on many factors (skin condition, magnitude of applied voltage, psychophysical state of a person, etc.). The higher the power of the EShU, the higher the efficiency of its impact on the target, however, the increase in the output power of the EShU in the Russian Federation has legal restrictions.

It is known that in some cases the electrical resistance of the human body can be significantly reduced, for example, with a sudden exposure to a strong sound [5]. The intermittent sound enhances the drag reduction effect. A similar effect is produced by a sudden flash of light [6]. The combination of a flash of light and a loud sound signal amplifies the effect of electrical exposure many times over.

Direct analogues and prototype of the proposed invention were not found during the patent search.

The aim of the present invention is to improve the efficiency of the ESA. This goal is achieved by the fact that in the method of influencing the target, which consists in exposing the target with an electric current generated by a remote-action electroshock device, along with the electric impact, at least a single impact on the target is made with a bright flash of light or a loud sound, or their simultaneous or sequential impact that occurs near the target.

The technical result consists in increasing the effectiveness of the impact due to a decrease in the resistance of the target's body when exposed to flashes of light or loud sound, or a combination of them.

An additional feature of the proposed method is that the moment of occurrence of the mentioned effect on the target by a bright flash of light or a loud sound, or their simultaneous or sequential effect, is ahead of the moment of occurrence of the electric effect.

An additional feature of the proposed method is that the moment of occurrence of the said effect on the target by a bright flash of light or a loud sound, or their simultaneous or sequential effect, lags behind the moment of occurrence of the electrical effect on the target.

An additional feature of the proposed method is that the moment of occurrence of the first mentioned impact on the target by a bright flash of light or a loud sound, or their simultaneous or sequential impact, is ahead of the moment of occurrence of the electrical impact, and the moment of occurrence of the repeated impact on the target by a bright flash of light or a loud sound, or their simultaneous or sequential impact, lags behind the moment of occurrence of the electrical impact on the target.

The essence of the invention also lies in the fact that in order to implement the proposed method, a device for transmitting an electrical effect on a target by a remote-action electroshock device, containing at least one output electrode made in the form of a probe, thrown in the direction of the target using a propellant charge, compressed air, a spring or otherwise connected by a flexible electrical conductor to the corresponding input electrical contact of the device, electrically interacting with one of the working electrodes of the electroshock device, contains at least one sound or light charge, or light and sound charges, or light and sound charges, which or which are thrown in the direction of the target simultaneously with the mentioned probe, or ahead of it, or behind it, or in a combination of advance, simultaneity and lag, while the initiation of the operation of the mentioned charges is carried out using a mechanical, or pyrotechnic, or electrical sky, or other means of initiation, or a combination of them.

An additional feature of the proposed device is that the moment of operation of said at least one sonic or light charge, or light and sound charges, is ahead of the moment of occurrence of the electrical action of said probes on the target.

An additional feature of the proposed device is that the moment of operation of said at least one sound or light charge, or light and sound charges, lags behind the moment of occurrence of the electrical action of said probes on the target.

An additional feature of the proposed device is that the moment of the first actuation of the mentioned sound or light charge, or light and sound charges, is ahead of the moment of occurrence of the electrical action of the mentioned probes on the target, and the moment of occurrence of the second actuation of the sound or light charge, or light and sound charges, lags behind. from the moment of occurrence of the electrical impact of the mentioned probes on the target.

An additional feature of the proposed device is that part of the mentioned light or sound charges is placed inside, and the other part is outside, mainly on the surface of the said probe.

An additional feature of the proposed device is that on the body of the mentioned probe there is an element for protecting the target from flying products of a sound or light charge and the traumatic action of the probe body, made in the form of a cap (umbrella), mainly directed forward with its deaf part, which may initially have a folded state. , and when approaching the target, or at the moment of hitting the target, or after hitting the target, or at the moment of triggering a light or sound charge, it opens.

The essence of the proposed method is illustrated by drawings, which show:

Fig. 1. The principle of electric impact on the target using a remote-action electroshock device.

Fig. 2. The principle of combined impact on the target according to the proposed method.

Fig. 3. An example of a timing diagram of signals that affect the target according to the proposed method.

The description and design of the device proposed for the implementation of the claimed method is illustrated by drawings, which show:

Fig. 4. A block diagram of a single-channel device in which the means of combined action on the target are structurally combined in one cartridge, with each means of action placed in its own projectile.

Fig. 5. Block diagram of a single-channel device, in which the means of combined action on the target are structurally combined in one projectile.

Fig. 6. Block diagram of a two-channel device, in which the means of combined action on the target of each channel are structurally combined in one projectile.

Fig. 7. An example of the design of a projectile, in which light or sound charges or a combination of them are placed in a cavity made in the body of the probe electrode.

Fig.8. An example of a projectile design in which light or sound charges or a combination of them are placed on the surface of the probe electrode.

Fig. 1. The currently existing methods of influencing the electroshock device 1 on the target 2 with the help of consist in the electrical action of current pulses generated by the remote-action electroshock device (DESHU) 1 and transmitted to the target with the help of projectile flexible electrical conductors (HEP) 3. The figure shows one channel of current transmission, usually two such channels are used to close the electrical circuit DESHU - target - DESHU. The current pulses 4 are usually a burst of pulses having a duration of 50 to 100 μs and following with a repetition rate of 20 to 200 Hz. The length of the pack depends on the time of impact on the target, which, according to the standards established in the Russian Federation, should not exceed 3 s. The amplitude of the voltage pulses at a load of 1000 Ohms is usually 1.2 ... 2.0 kV. A load of 1000 ohms is the average value of the electrical resistance of the human body, adopted in the Russian Federation as a standard for the development of electroshock devices. Under normal conditions, the load resistance varies within very small limits.

The essence of the proposed method is shown in Fig. 2. The figure shows one set for the transmission of current and other types of influence, two such sets are usually used for the transmission of current, and additional charges can be in one or both sets.

On FIG. 2a shows a diagram of the transmission of an impact on a target, in which, along with the electric impact, at least a single impact on the target is made by a bright flash of light 5 or a loud sound 6 that occurs when the corresponding charge is triggered, or their simultaneous or sequential impact that occurs near the target, moreover all types of impact are transmitted through their means (channels) of transportation of the corresponding charges. Such means of transport may be, for example, individual projectiles containing appropriate charges. These projectiles can be placed in the BTE.

On FIG. 2b shows a scheme for transmitting an impact on a target, in which, along with the electric impact, at least a single impact on the target is made by a bright flash of light 5 or a loud sound 6 that occurs when the corresponding charge is triggered, or their simultaneous or sequential impact that occurs near the target, moreover all types of influence are transmitted through one transmission channel. In other words, technically, the same electric probe is used for transporting sound and light charges as for transmitting electrical impact.

With a noticeable decrease in the resistance of the body of a person or animal due to stress caused by a sudden flash of light or a loud sound, the effectiveness of the impact of the DESH current pulses increases, since the target receives an increased energy dose compared to the usual one, which determines the degree of temporary immobilization of the target. On the other hand, this effect makes it possible to use DESH with lower output characteristics, nevertheless, providing the impact inherent in conventional DESH, which, in turn, makes it possible to simplify the design of DESH and, accordingly, reduce its production cost.

A sudden loud sound (mainly with an acoustic pressure of more than 95 dBa), generated by a sound charge near the target or when the BTER probe hits the target, causes a noticeable decrease in the human electrical resistance, which, as indicated, enhances the effect of the DESH.

A similar effect is produced by a sudden flash of light near the target or when the BTE probe hits the target.

The combination of a light flash and a loud sound signal when the BTER probe hits the target intensifies the effect of the electric impact of the DESH many times over.

The important point is that the loud sound and/or flash of light must occur unexpectedly and in close proximity to the target. For example, a typical flash and loud sound when fired from a firearm or traumatic weapon that occurs at the muzzle of a weapon is much less effective (inversely proportional to the square of the distance to the target), especially at a higher shot distance, in addition, they can partially blind and stun the user himself, or distract him from re-aiming. This means that the sound and light charges should be triggered when the probe approaches the target.

It should be noted that sudden light and sound signals in themselves produce a stopping effect on the target, which is used, for example, in flash-noise cartridges, but in this case their effect on the electrical resistance of a person is considered, and not on his psychosomatics.

On FIG. 3 shows the timing diagram of the signals.

Fig. 3a illustrates the situation in which the moments of occurrence of light 5 or sound 6 signals, or their combination, are ahead of the moment of the beginning of the electrical impact 4 on the target. Such advance will be useful if it provides the effect of stress reduction in the electrical resistance of the target before or at the beginning of the electrical impact. Since the stress response of the target has its own time constant (usually 200...250 ms), the lead time of the start of the electrical action must be at least 250 ms. The duration of the light flash 5 and sound signal 6 in FIG. 3a are indicated conditionally, as well as the duration of the signal 4 of the electrical action. Usually, the electrical action signal is a pack of current pulses, and the duration of the pack should not exceed 3 s.

Fig. 3b illustrates the situation in which the moments of occurrence of light 5 or sound 6 signals, or a combination thereof, lag behind the moment of the beginning of the electrical impact 4 on the target. In this case, the target is initially affected by an electrical signal, followed by a flash of light and a loud sound, while the electrical signal continues to affect the target. In view of the foregoing, the total duration of a burst of electric impact pulses must be greater than the sum of the lag time and the target's reaction time to sound and light, which is obviously performed in the DESH.

It should be noted that the human body has the property of restoring its electrical resistance after a stress reduction. The recovery time constant is at least 0.5…1.0 s.

Fig. 3c illustrates a situation in which the moment of occurrence of the first mentioned impact on the target by a bright flash of light or a loud sound, or their simultaneous or sequential impact, is ahead of the moment of occurrence of an electrical impact, and the moment of occurrence of the repeated impact on the target by a bright flash of light or a loud sound, or their simultaneous or sequential impact lags behind the moment of occurrence of the electrical impact on the target. The physical meaning of such an impact is that a stress decrease in resistance occurs after the first exposure to light and / or sound, but the restoration to its usual value does not have time to occur, since the target is repeatedly exposed to a bright flash of light or a loud sound.

4 illustrates an example block diagram of a device for implementing the proposed method of FIG. 2a.

On FIG. 4a is a block diagram of a device containing one set for transmitting current and other effects, usually two such sets are used, and additional charges can be in one or both sets. Each signal (4, 5, 6) of the impact on the target 2 is transmitted through its channel for transmitting the impact. The device contains a transportation unit connected to the DESH 1, in which the BTE 7 is placed, containing the projectile 8. The projectile 8 contains a probe electrode 9. The BTE 7 and the probe 9 are connected by a flexible electrical conductor 3, which can be placed in the cavity of the BTE 7 or in the cavity of the probe 9. The transportation unit also contains a sonic cartridge 10, in which a projectile 11 is placed, equipped with a sound charge 12. The transportation unit also contains a light cartridge 13, in which a projectile 14 is placed, equipped with a light charge 15. It should be noted that all the mentioned nodes that are part of the BTE form one chain of action, for effective action on the target, as a rule, two chains of action are required, forming a completely closed circuit. An exception is the so-called single-wire action circuit, when the closing wire is "ground". At present, such schemes are practically not used (they are technically very complex), but in the future, as technology develops, they can be used quite widely.

The device works as follows.

The scenario of Fig. 3a.

When firing from a DESH cartridge, all three projectiles 8, 11 and 14 fly out towards the target, having reached the target (or near it), light 15 or sound 12 charges, or a combination of them, are triggered, while light 5 or sound 6 impact, or their combination, occur earlier than the electrical impact 4, while the delay in the start of the electrical impact 4 may exceed the reaction time of the target (reducing its electrical resistance) to the light/sound impact. Throwing in the direction of the target is carried out using a propellant charge (powder or pyrotechnic), compressed air, a pre-compressed spring, or in another way, for example (but not limited to), electromagnetic (Gauss gun or railgun) or high-voltage electrochemical explosion. The technically required delay can be provided by the software settings of the DESH output voltage turn-on timer, which is widely used in electronic engineering. The initiation of the operation of the mentioned charges is carried out using means of initiation widely known in pyrotechnics, for example (but not limited to) mechanical (impact of the striker - ignition), pyrotechnic (chemical ignition), electrical (instant heating by current - ignition) or other means of initiation, or a combination thereof. . The moments of actuation of light and sound charges can be provided, for example, by slowers (relative to the moment of the shot) of the corresponding initiators of the charges actuation - by well-known means used, for example, in pyrotechnics, or occur directly upon impact on the target due to the mechanical impact of the impact on the corresponding initiator of the charge actuation (not shown in Fig. 4). In addition, the shot of the projectile 8 can simply occur a little later than the shots of the projectiles 11 and 14, which is easily achieved by the technical means of the DESHU, which provide the shot and are widely used in technology.

The scenario of Fig. 3b.

When firing from a DESH cartridge, all three projectiles 8, 11 and 14 fly out towards the target, having reached the target (or near it), light 15 or sound 12 charges, or a combination of them, are triggered, while light 5 or sound 6 impact, or their combination, occur later than the electric impact 4, while the duration of the electric impact 4 must exceed the time of the target's reaction (reduction of its electrical resistance) to the light/sound impact. The moments of operation of light and sound charges can be provided, for example, by slowers (relative to the moment of the shot) of the corresponding charge actuation initiators - widely known means used, for example, in pyrotechnics, after hitting the target due to the mechanical impact of the impact on the corresponding charge actuation initiator (in Fig. .4 not shown). In addition, the shot of the projectile 8 can simply occur a little earlier than the shots of the projectiles 11 and 14, which is easily achieved by the technical means of the DESH, which provide a shot and are widely used in technology.

The scenario of Fig. 3c.

The scenario of Fig. 3c is essentially a combination of the scenarios of FIG. 3a and 3b and requires a double set of propellant charges 11 and 14, while the operation of the first set is ahead of the start of the electric action, and the operation of the second set lags behind it.

On FIG. 4b shows a block diagram of the proposed device containing BTER7 with a double set of projectiles 8 for transmitting electrical impact and one set of cartridges containing sound 10 and light 13 cartridges. BTER 7 with a double set of projectiles 8 for transmitting electrical impact provides a fully closed circuit DESHU - target - DESHU.

Each signal (4, 5, 6) of the impact on the target 2 is transmitted through its own impact transmission channel. The device contains a transportation unit connected to the DESHU 1, in which the BTE 7 is placed, containing two projectiles 8. Each projectile 8 contains an electrode-probe 9. The BTE 7 and probes 9 are connected by flexible electrical conductors 3, which can be placed in the cavity of the BTE 7 or in the cavity of the probes 9. The transportation unit also contains a sonic cartridge 10, in which a projectile 11 is placed, equipped with a sound charge 12. The transportation unit also contains a light cartridge 13, in which a projectile 14 is placed, equipped with a light charge 15.

The device operates similarly to the device shown in Fig. 4a.

Fig. 5 illustrates an example of block diagrams of a device for implementing the proposed method according to Fig.2b, for effective impact on the target, as a rule, two impact circuits are required, forming a completely closed circuit. All means of influencing the target are transmitted through one transportation channel, which is a projectile, including a probe electrode. On FIG. 5a shows a block diagram of a device containing a DESHU 1, a target 2, a BTER 7, in which a projectile 8 is placed. The projectile 8 contains a probe electrode 9 and a sound charge 12. FIG. 5b shows a block diagram of a device in which the projectile 8 comprises a probe electrode 9 and a light charge 15. FIG. 5c shows a block diagram of the device, in which the projectile 8 contains a probe electrode 9, a sonic projectile 12 and a light charge 15. All shown options form one part of the electric circuit for affecting the target. When a DESH is fired from a BTE, a projectile 8 flies towards the target, consisting of a probe electrode 9 and a sound charge 12 or a light charge 15, or a combination of both. When the probe hits the target or when approaching the target (depending on the algorithm embedded in the device), the charges are triggered, providing a stress reduction in the electrical resistance of the target. The advance or delay in the operation of the mentioned charges by the moment of occurrence of the electric effect on the target, shown in Fig. 3 may be provided by the same means as previously described. In addition, the control of the moment of actuation of sound or light charges, or a combination thereof, can be carried out using other technical means, for example, by transmitting a control signal over the GEP 3, using a separate electrical conductor, including structurally integrated with the GEP, or wireless way. The difference shown in Fig. 5 block diagrams from the block diagrams shown in FIG. 4 lies in the fact that the mentioned charges are placed not in separate projectiles, but directly in the probe electrode. This is how the use of one channel for the transfer of charges and electrical effects on the target is ensured.

Fig. 6 illustrates an example of block diagrams of a device for implementing the proposed method according to Fig.2b, but with the organization of a complete closed electrical circuit formed by two probe electrodes. Throwing projectiles 8 and 16 contain probe electrodes 9 and 17, equipped with sound charges 12 and 18 (Fig. 6a), or light charges 15 and 19 (Fig. 6b), or their combination (Fig. 6c). Equipment with light or sound charges, or a combination of them, can have both probe electrodes or one of them (the last option is not shown in Fig. 6). The device operates similarly to the device shown in Fig. 5.

Fig. 7a illustrates one of the possible implementations of the design of the electrode-probe 9, in which the sound 12 or light charge 15, or their combination, is placed in the cavity made in the probe 9. A flexible electrical conductor 3 is fixed in the rear part of the probe. In the front part of the probe 9 a needle 20 is installed, designed to pierce the clothes or the upper layer of the target's skin, facilitating the penetration of the probe electrode 9 into the target, equipped with a fixation element on the body or clothes of the target, usually made in the form of a beard or a hook. Perforations 21 can be made in the body of the electrode-probe 9 for the output of light or sound signals. In flight, the probe electrode is in a folded state, and when probe 9 hits the target, it opens (Fig. 7b), protecting the target from possible direct contact with the face and eyes of the products of combustion of sound or light charges arising in the immediate vicinity of the target. that said combustion products are generally safe for humans or animals.

The opening of the protective cap (umbrella) can be provided by well-known technical means, for example, by mechanical action on the opening mechanism when the probe 9 hits the target.

Fig. 8a illustrates one of the possible implementations of the design of the probe electrode 9, in which the sound charge 12 or light charge 15, or a combination thereof, is placed on the surface of the probe 9. All elements of the probe electrode 9 correspond to FIG. 7, including a protective cap (umbrella) 22, the opening of which is shown in FIG. 8b.

A variant of the design of the device is also possible, in which sound or light charges are partially placed on the surface of the probe electrode 9, and partially in the cavity made in the probe 9.

Thus, the use in the proposed invention, along with the electrical impact on the target, additional means of impact in the form of a sudden sound, light signals or their combination, which reduce the electrical resistance of the body, increases the effectiveness of the impact on the target, realizing the task.

The device is technically implemented as shown in FIG. 6 and has the following characteristics:

List of sources cited

1. Patent of the Russian Federation No. 2179294 Electroshock device for protection against attack.

2. Patent of the Russian Federation No. 2461785 Universal hand-held multi-shot weapon.

3. Patent of the Russian Federation No. 2351871 Cartridge for an electroshock device with a remote defeat.

4. Patent of the Russian Federation No. 2462678 Cartridge for remote stun weapons and multiply charged remote stun weapons.

5. Katsay V.V. The study of the resistance of the human body. Kurgan State University. Kurgan, 2007

6. The resistance of the human body - what it depends on and how it can change. http:electrik.info/main/fakty/1223-soprotivlenie-tela-cheloveka-ot-chego-zavisit-i-kak-mozhet-izmenyatsya.html

Claims (10)

1. A method of influencing a target, which consists in exposing the target to an electric current generated by a remote-action electroshock device, characterized in that, along with the electric impact, at least a single impact on the target is made with a bright flash of light or a loud sound, or their simultaneous or sequential impact, occurring near the target. 2. The method according to claim. 1, characterized in that the moment of occurrence of the said impact on the target by a bright flash of light or a loud sound, or their simultaneous or sequential impact, is ahead of the moment of occurrence of the electrical impact. 3. The method according to claim 1, characterized in that the moment of occurrence of the said impact on the target by a bright flash of light or a loud sound, or their simultaneous or sequential impact lags behind the moment of occurrence of the electrical impact on the target. 4. The method according to claim 1, characterized in that the moment of occurrence of the first mentioned impact on the target by a bright flash of light or a loud sound, or their simultaneous or sequential impact, is ahead of the moment of occurrence of the electrical impact, and the moment of occurrence of the repeated impact on the target by a bright flash of light or a loud sound or their simultaneous or successive impact lags behind the moment of occurrence of electrical impact on the target. 5. A device for transmitting electrical impact on a target by a remote-action electroshock device, containing at least one output electrode made in the form of a probe thrown in the direction of the target using a propellant charge, compressed air, a spring or otherwise, connected by a flexible electrical conductor to the corresponding input electrical contact of the device, electrically interacting with one of the working electrodes of the electroshock device, characterized in that it contains at least one sound or light charge, or light and sound charges, or light and sound charges, which or which are thrown in the direction of the target simultaneously with mentioned probe, or ahead of it, or behind it, or in a combination of advance, simultaneity and lag, while the initiation of the operation of the said charges is carried out using a mechanical, or pyrotechnic, or electrical, or other means of initiation, or a combination thereof . 6. The device according to claim 5, characterized in that the moment of operation of said at least one sound or light charge or light and sound charges is ahead of the moment of occurrence of the electrical action of said probes on the target. 7. The device according to claim. 5, characterized in that the moment of operation of said at least one sound or light charge or light and sound charges lags behind the moment of occurrence of the electrical action of said probes on the target. 8. The device according to claim 5, characterized in that the moment of the first actuation of the mentioned sound or light charge or light and sound charges is ahead of the moment of occurrence of the electric action of the said probes on the target, and the moment of occurrence of the second actuation of the sound or light charge or light and sound charges lags behind from the moment of occurrence of the electrical impact of the mentioned probes on the target. 9. The device according to claim 5, characterized in that part of the mentioned light or sound charges is placed inside, and the other part is outside, mainly on the surface of the said probe. 10. The device according to claim. 5, characterized in that on the body of the said probe there is an element for protecting the target from flying products of a sound or light charge and the traumatic action of the probe body, made in the form of a cap (umbrella), mainly directed forward with its deaf part, which initially can have a folded state, and when approaching the target, or at the moment of hitting the target, or after hitting the target, or at the moment of triggering a light or sound charge, it opens.

Images