RU2728016C2 - Method of biological objects immobilization and device for its implementation - Google Patents

Abstract

FIELD: weapons and ammunition.SUBSTANCE: group of inventions relates to non-lethal weapons with thermo-physical minimally invasive means of target destruction and can be used as a means of limiting targeted aggressive physical actions of biological objects—humans and animals, in police equipment for preventing offenses, as well as for self-defense of citizens. Method consists in minimally invasive exposure of a biological object using a throwing weapon and a needle with at least one needle. For this purpose, projectile is used with source of electric power or pyrotechnic composition. Using them form electric circuit with conductor in needle or fire circuit with pyrotechnic initiator of pyrotechnic composition respectively, which are closed or initiated during firing. This is carried out mainly due to a given acceleration force acting on the projectile or its part, or ignition of said pyrotechnic initiator. At that, the needle is heated for a limited time to temperatures causing pain in the object, sufficient for temporary limitation of its physical actions or reduction of degree of aggression.EFFECT: technical result is higher efficiency of temporary immobilisation of biological objects.18 cl, 6 dwg

Description

The technical field to which the invention relates

The invention relates to a so-called non-lethal weapon with a thermo-traumatic minimally invasive means of hitting a target and can be used as a means of limiting targeted aggressive physical actions of biological objects (people and animals), in police techniques for preventing offenses, as well as for the self-defense of citizens.

State of the art

There is a method of mechanical traumatic impact on the offender with the aim of immobilizing him and limiting targeted physical actions by exerting influence on the offender with kinetic projectiles made of elastic materials, theoretically inflicting predominantly non-invasive or minimally invasive mechanical trauma, accompanied by a stunning pain effect in the offender, which limits his mobility and the ability to perform physical actions.

However, all known samples of devices for implementing this method have kinetic projectiles, which, even with the distances prescribed by the developers for use on targets and with clothing typical for a given area, inflict mechanical injuries on targets with varying degrees of invasiveness with consequences in the form of bruises, hematomas with hemorrhages or ruptures of the surface layers of the epidermis and dermis.

The main disadvantage of the above method of non-lethal traumatic impact on biological targets (hereinafter referred to as bio-targets) is that it is fundamentally impossible to control the degree of impact when using traumatic kinetic weapons (at short distances. The degree of impact may be too large, but at the same time instantaneous "stopping effect "Not guaranteed. The use of plastic or rubber bullets and other kinetic soft or elastic projectiles from short distances on bio-targets is often the cause of penetrating wounds, contusions, rib fractures, concussions, significant superficial

damage to various organs and skin, damage to the skull, rupture of the heart, kidney, liver, internal hemorrhage and a high probability of death of the object of application.

In all the designs of traumatic kinetic weapons that have been implemented to date, it is not possible to implement diametrically opposite requirements: ensuring the complete “non-lethality” of hitting the object in the case of using the weapon in a normal mode, on the one hand, and ensuring the effectiveness of the impact, i.e. sufficient "stopping" action, on the other hand. The search for the optimal balance between the requirements of non-lethality and the effectiveness of the impact is still an urgent and unsolved problem.

There are numerous examples of traumatic kinetic weapons using elastic kinetic projectiles, for example, according to RF patents No. 2240490, 2179700, 2230285. The projectiles consist of an elastic body or an elastic body with a metal core, or an elastic body filled with metal balls or powder, or other materials with a high specific gravity. All projectiles are fired from barrels or barrelless samples of traumatic firearms with a certain initial velocity at a muzzle energy of up to 90 ... 120 J. When hitting a target at a certain (pre-calculated, minimum allowable) distance from the weapon and with a certain thickness of clothing on the target, all types of traumatic shells are deformed due to the elasticity of their bodies, increase their diameter on the target and distribute the accumulated kinetic energy on the largest possible surface of the target, thereby reducing the lateral load of the shell and bringing the specific kinetic energy; projectile to an energy not exceeding 0.5 J / mm ² (0.05 kg * m / mm ² ), permitted by the relevant current standards.

However, with a decrease in the distance to the target (less than the minimum permissible), the speed of such projectiles at the moment of impact on the target remains too high, and these projectiles, acting as projectiles with a low specific kinetic energy, inflict already invasive injuries of a large severity due to the bioceles of large inlet openings and, accordingly, inflicting serious injuries to the bioceli, up to penetrating cavities.

Analogs and prototypes of the method for minimally invasive immobilization of a person by local intradermal thermal exposure, causing short-term severe pain, as well as a projectile for the implementation of the method, which allows limiting physical actions without the likelihood of inflicting severe injuries on a person at any range of use of weapons using the claimed projectile from the prior art and no patent search was found.

Disclosure of invention

The aim of the invention is to create a fundamentally new way of organizing the limitation of targeted aggressive physical actions of biological objects and a device for implementing this method, devoid of the disadvantages of the known methods of traumatic effects on biological objects.

The essence of the invention lies in the fact that the method of limiting the purposeful, predominantly aggressive, physical actions of biological objects consists in minimally invasive action on a biological object using a throwing weapon and a projectile with a needle, at least one, to temporarily restrict the physical actions of the object or reduce the degree of aggression, in this case, a projectile is used with a source of electrical energy or a pyrotechnic composition, with the help of which an electric circuit with a conductor in a needle or a fire circuit with a pyrotechnic initiator of a pyrotechnic composition is formed, respectively, which close or initiate during a shot mainly due to a given acceleration force acting on a projectile or part of it, or the ignition of the said pyrotechnic initiator, while the needle is heated for a limited time to temperatures that cause pain in the target, sufficient to temporarily restrict its physical actions or and reducing the degree of aggression.

An additional feature of the method is that the said needle is inserted to a depth not exceeding the usual depth of needle insertion for medical injections or reflexology.

An additional feature of the method lies in the fact that several of the mentioned needles are inserted simultaneously or within a short period of time at different points of the body of the target.

An additional feature of the method is that at least some of the aforementioned needles are heated at different, preferably sequential, time intervals.

The essence of the invention also lies in the fact that the device for limiting the targeted, mainly aggressive, physical actions of biological objects contains a throwing weapon and a projectile with a needle, at least one located in the front of the projectile, the projectile is hollow, and the needle is provided with the possibility of heating from located in the cavity of the projectile, forming an electric or fire circuit with the needle, through an electric conductor in the needle or a pyrotechnic initiator of a pyrotechnic "composition, respectively, provided with the possibility of closing or triggering during a shot, mainly due to a given acceleration force acting on the projectile or part of it ...

An additional feature of the device for implementing the method is that inside said projectile there is a power supply, made mainly in the form of a chemical current source, for electrically heating said needle, as well as an electric current switch.

An additional feature of the device for implementing the method is that a pyrotechnic initiator of a pyrotechnic device for heating said needle is located inside said projectile.

An additional feature of the device for implementing the method is that said switch or said pyrotechnic initiator is triggered by the acceleration of the projectile or the impact of the acceleration force on a part of the projectile.

An additional feature of the device for implementing the method is that the body of the said needle is made of a hard metal, mainly a steel alloy, with an inner hollow channel in which an electrical conductor is placed, made mainly in the form of a copper, brass or silver single-core or stranded wire in a heat-resistant electrical insulation, and one end of the wire is electrically connected to the front end of the needle, mainly by crimping, soldering or welding, and the other end of the wire comes out of

the rear end of the needle and connected in series with the above-mentioned source of electrical energy, an electrical switch and the body of the needle.

An additional feature of the device for implementing the method is that said needle has a barb or other device in its front part that prevents the needle from being pulled out.

An additional feature of the device for implementing the method is that the said needle is made of a pair of metals for highly exothermic synthesis of the intermetallic compound and may have an inactive outer shell made of other metals.

An additional feature of the device for implementing the method is that the said needle is made of palladium and aluminum, and may have an outer shell of other metals.

An additional feature of the device for implementing the method is that the said needle is made of nickel or its alloy and aluminum and may have an outer shell of other metals.

An additional feature of the device for implementing the method is that the said needle is made of platinum and aluminum and may have an outer shell made of other metals.

An additional feature of the device for implementing the method is that at least a part of the said needle is made flattened.

An additional feature of the device for implementing the method consists in the fact that it has a leading belt or; ready grooves.

An additional feature of the device for implementing the method is that it has aerodynamic stabilizers.

An additional feature of the device for implementing the method is that it has on the said body or a component part of the body of the projectile an additional heated element, which is driven by an electric current or pyrotechnically.

An additional feature of the device for implementing the method is that it also contains additional electronic devices for remote communication with the said weapon or remote control of the device.

An additional feature of the device for implementing the method is that it contains a device for retarding the start of heating.

An additional feature of the device for implementing the method consists in the fact that in said deceleration device the deceleration time can be adjusted.

Brief Description of Drawings

FIG. 1. General view of the device for implementing the method in the form of a projectile with ready-made grooves and electric heating of the needle.

FIG. 2a, 2b, 2c. Section of the device for implementing the method in the form of a projectile in an idle position (storage of the projectile and the position of parts before firing) and enlarged parts of the projectile for clarity.

FIG. 3. Section of the device for implementing the method in the form of a projectile in the operating position (the position of the parts after the shot).

FIG. 4. General view of the device for implementing the method in the form of a projectile with aerodynamic stabilization and pyrotechnic heating of the needle.

FIG. 5. Section of a device for implementing the method in the form of a projectile with aerodynamic stabilization and pyrotechnic heating of the needle.

Detailed description of drawings

FIG. 1. One of the variants of the device for implementing the method of minimally invasive immobilization of biological objects in the form of a projectile with a needle having an electric current heating device consists of a housing 1, a leading part 2 with ready-made grooves 3 and a needle 4 with a hollow body (analog of a medical needle). In a different design, the leading part 2 may not have ready-made rifling and be carried out along the rifling of the weapon barrel only by cutting it into the rifling of the barrel due to plastic deformation of the main material of the leading part or by covering the {leading part with a plastically deformable material of one thickness or another. In a different design, the projectile may not have a leading part with a diameter larger than body 1, and body 1 itself plays the role of the leading part with shallow shallow grooves

the barrel of the weapon, or body 1 with a partial or complete covering of it with a plastically deformable material.

FIG. 2. In the electrically conductive body 1, made, for example, of metal, there is a power source, mainly made in the form of a chemical current source, for example, an electric accumulator (in another version, an electric battery) 5, having electrical leads 6 and 7. Below the lead 6 is located elastic element 8, and lead 7 is electrically connected to one end of the inner core of heat-resistant insulated conductor 9 passing inside the channel of the hollow needle 4. The other end of the inner core of the conductor 9 is electrically connected to the front end of the needle 4, preferably by crimping, soldering or welding. The front end of the housing 1 is filled with an electrically insulating material 10, such as an epoxy or silicone compound. The needle 1 is electrically connected to the body 1. The connection of the body of the needle 4 to the body can be achieved by soldering, welding, press fit and other methods that provide an electrical connection and, at the same time, mechanical strength of the connection, preventing the needle from falling through (punching) into the body when the needle is inserted into the target. On the electrically conductive body 1 there is a leading part 2, which can be made of an electrically conductive material, for example, a metal or a dielectric, for example, a polymer material with an inner metal coating or a metal foil coating. The leading part 2 is fixed on the body 1 with a given force of longitudinal movement relative to the body 1 with tight electrical contact. The provision of a given force of movement of the driving part 2 along the body 1 is carried out by tight fitting of part 2 on the body 1, additional fixing of part 2 on the body 1 with glue, etc. The heating of the needle body 4 is started by closing the electrical circuit "terminal 7 of the power supply - conductor 9 passing inside the channel of the needle body, - needle body 4 - electrically conductive body 1 - leading part 2 - terminal 6 of the power supply". FIG. 2 shows the position of the projectile parts in the storage position and before firing. An air gap is formed between the terminal 6 of the power source and the electrically conductive leading part 2, which prevents electrical contact of the terminal 7 of the leading part 2 in the initial state of the projectile. The electrical circuit "terminal 7 of the power supply - conductor 9 passing inside the channel of the needle body, - the body of the needle 4 - electrically conductive body 1 - leading part 2 - terminal 6 of the power supply" is open.

FIG. 3. The leading part 2 is pushed onto the body 1 until its end comes into contact with the terminal 6 of the power supply. The electrical circuit "output 7 of the power supply - conductor 9 passing inside the channel of the needle body - the body of the needle 4 - electrically conductive body 1 - leading part 2 - output of the power supply 6" is closed. Pushing the leading part 2 onto the body 1 until the air gap between terminal 6 and the leading part 2 is pulled out with the closure of the electric heating circuit of the needle is carried out during the firing of a projectile from a weapon, due to the impact on the end of the leading part 2 of the force of acceleration of the projectile and the rest mass of the main mass of the projectile ( and mainly the mass of the power supply). When a projectile is fired from a weapon, the leading part 2, fixed on the body 1 with a predetermined shearing force relative to the body 1, with a tight electrical contact between the generatrix of the outer diameter of the body 1 and the inner diameter of the forming part 2, moves in the direction of the accelerating force and is tightly connected by the surface of its inner end with terminal 6 of the power supply. In this case, the elastic element 8 acts as an automatic alignment of the output 7 along the surface of the inner end of the driving part 2, which ensures tight contact of the entire surface of the output 6 with the surface of the inner end of the driving part 2.

To eliminate the displacement of the power supply due to the inertia of rest when fired relative to the housing 1 and the corresponding breakage of the conductor 9, the power supply can be fixed in the housing 1, for example, by gluing over the entire diametrical surface of the power supply.

In other versions of the device, including in the form of a projectile, the electrical heating circuit can be closed in other ways, for example, by an exhaust leash, an inertially displaceable load, which can be the power source itself, by a centrifugal method, etc.

In a different version of the projectile, the projectile body itself may often be the leading one, while the body may have ready-made rifling. In another version of the projectile, the body can work as a jacket of a shell bullet, which is plastically deformable by the rifling of the weapon barrel, or have a full or partial coating of the body with a plastically deformable material of a certain thickness.

After the shot, the projectile flies to the target (for example, to the offender), while the needle 4 begins to warm up and, due to the small

the inertia of heating the body of the needle, which has an insignificant mass and heat capacity, when it is introduced into the biological tissue of the target, the needle is practically already heated to the operating temperature. The authors (based on their experiments) suggest that, according to future safety standards for this type of weapon, the maximum operating temperature of an electrically heated needle when inserted into biological tissue (taking into account heat dissipation into biological tissue) can be no more than 100 ° C, since at a higher temperature On the surface of the needle, the liquid in the biological tissue adjacent directly to the body of the needle quickly boils, which complicates the further efficient transfer of energy from the body of the needle to the biological tissue. The achievement of the required temperature is determined by the electrical resistance of the said electrical circuit (in particular, the resistance of the needle body), the voltage of the electrical current, the electrical capacity of the applied power supply and the value of the maximum current delivered by the applied power supply during the required operation of the projectile on the target. The optimal length of the needle is selected on the basis of the conditions for the reliable fixation of the needle in the body of the biocele, on the one hand, and the conditions for the non-penetration of the needle into the large blood vessels of the biocele, on the other hand. In the proposed method, the needle is preferably inserted to a depth not exceeding the usual depth of insertion of a needle for medical injections or acupuncture. For example, a sedation needle for acupuncture (acupuncture) is inserted into the skin and subcutaneous tissue to a depth of at least 15 mm.

The diameter of the non-flattened needle in the device for the implementation of the method, reasonable in terms of safety conditions, should not exceed the diameters of widespread medical needles for injection (0.5 ... 1 mm). A heated needle, embedded in the biological tissue of the target, due to mainly thermal effects, causes a painful effect in the offender or an immobilized animal, which limits his mobility and the ability to perform meaningful (primarily aggressive) physical actions. The time the needle is in the heated state depends on the capacity of the power source used. The authors (on the basis of their experiments) assume that, according to future safety standards for a given type of weapon, this time will be mostly no more than 30 ... 60 s.

In any case, the specific permissible values for the heating temperature of the needle, the time of its exposure and the permissible traumatic consequences must be determined in the relevant safety standards.

the use of this type of weapon, developed and approved by competent departments, for example, the Ministry of Health and Social Development (Ministry of Health of the Russian Federation) or the Federal Medical and Biological Agency (FMBA of the Russian Federation).

To prevent premature extraction of the device for the implementation of the method, including in the form of a projectile, from the biological tissue of the target by the hands of the offender (or by the paws or teeth of an animal), in a different version of the projectile on the body 1 of the projectile or part of the body (for example, the leading part 2) there is an additional heated an element driven by electric current or pyrotechnic means.

Another way to prevent premature extraction of the projectile from the biological tissues of the target can be to supply the needle in its front part with a barb or other device that prevents the extraction of the needle.

In another version of the device in the form of a projectile, the projectile body may contain additional electronic devices, for example, target hit sensors and a radio or infrared transmitter designed to communicate with the said weapon and inform the user of the weapon with the proposed projectile about the mode of its use.

FIG. 4. A device for implementing the method of minimally invasive immobilization of biological objects, in the form of a projectile with a pyrotechnic heating device, consists of a body 11, stabilizers 12 and a needle 13. The design of the device with stabilizers 12 is used in the case of throwing or firing a device from a remote-action smooth-bore weapon to ensure aerodynamic stabilization.

FIG. 5. A pyrotechnic igniting composition 14 and a low-gas or gas-free pyrotechnic composition 15, for example, of the thermite type, are pressed into the housing 11, made, for example, of metal. The needle 13 is secured to the body 11 by soldering, welding, press fit or other suitable means. The rear end 14 of the needle 13 is inserted into the pyrotechnic composition 14, and the rear end may be flattened or in the form of a spiral to provide better heat transfer from the pyrotechnic composition 14 to the body of the needle. For better heat transfer of heat to the bio target, the anterior end of the needle or the entire body of the needle can also be flattened.

The needle 13 can be made of bimetallic wire of the "Pyrofuse" type (reactive material), in particular, of wire with an aluminum core and a sheath of nickel or palladium (or their alloys). FIG. 5 shows a sectional view of a "Pyrofuse" bimetallic wire needle. On top of the bimetallic "Pyrofuse" wire, there can be: also a protective sheath, eg stainless steel.

The needle 13 can also be made of a homogeneous metal with high thermal conductivity, for example, cold-worked copper or silver. When using a wire of the "Pyrofuse" type, the powder charge of the cartridge with the proposed projectile through an obturator with a flame force transmission hole ignites the pyrotechnic igniting composition 14, which, in turn, starts the exothermic reaction of the low-gas or gas-free pyrotechnic composition 15, which in turn starts the exothermic synthesis reaction intermetallic compound "Pyrofuse" wire (another name - self-propagating high-temperature synthesis - SHS). The time of starting the reaction of the synthesis of the intermetallic compound must correspond to the moment when the projectile hits the biological tissue of the target, or it should be carried out with a minimum or predetermined (configured) time delay after the projectile hits the target. A needle made of "Pyrofuse" wire can have a protective sheath that repeats the shape of the needle and serves to prevent explosive evaporation of water in biological tissues during the synthesis reaction and subsequent extraction of the projectile needle from biological tissues. The action of projectiles with needles made of Pyrofuse wire is short-lived, but the overall dimensions and cost of such projectiles can be minimal, which means that projectiles can be used to organize multiple hits on the target.

When using a needle 13 made of a homogeneous metal material, the needle is heated due to heat transfer from an exothermic reaction in a low-gas or gas-free pyrotechnic composition 15 to the body of the needle. In this case, the rear end of the needle, made flattened or in the form of a spiral and located in the pyrocomposition 15, increases the surface of heat transfer. The front end of the needle can also be flattened, or the entire needle can be made flattened to increase the surface of heat transfer from the body of the needle to biological tissues.

In addition to heating by electric current or pyrotechnic method, other technical solutions for heating the needle that implement the proposed method are also possible.

A device using the proposed method for immobilizing biological objects (bio-targets) can have a different design, for example, as the above-described projectiles for remote use, fired from a remote-action weapon with muzzle energy, which excludes penetrating mechanical injury to the body of the bio-target by the projectile body even at the smallest possible distance of use.

When devices are implemented in the form of projectiles, when the target hits the target, the needle 4 or the needle 13 is introduced into the tissue of the bio target to its full length, minus the thickness of the clothing (or animal skin) pressed against the target's body. The depth of penetration of the needle into biological tissues is ensured with a minimum muzzle energy of the projectile due to the high specific kinetic energy of the needle penetrating into biological tissues. Due to the high penetrating ability of the needle, the throwing of devices for implementing the method in the form of projectiles can be carried out not only with the help of fire or pneumatic throwing, but also neuroballistic throwing, for example, by using a mechanical or gas spring compressed before the shot with a minimum muzzle energy of the projectile, excluding penetrating wounds of the bio target. In this case, the distance of the shot ensures the inaccessibility of the user of the weapon for aggressive actions of the target.

To enhance the effect of temporary damage, several needles can be inserted into different points of the body of the target simultaneously or within a short period of time, which can be located both in different devices for implementing the method, and in one device in its other design. In this case, at least some part of the needles located in one device is exposed to heat, and the other part improves the fixing on the target.

It is useful to note that at least some of the aforementioned needles can be heated at different, preferably sequential, periods of time, for which retarders of the beginning of heating of the needles can be used.

As a retarder for the onset of needle heating when implementing a circuit for heating the needle with an electric current, for example, an electronic switch with an RC circuit at the control input, which is widely known in the art, and connected in series with a power supply, can be used. The selection of the time constant of the RC-chain allows you to control the delay time for turning on the electronic switch, i.e. deceleration time

start of heating. Other technical solutions of the deceleration device are also possible, which implement the proposed method.

As a retarder for the onset of needle heating when implementing a pyrotechnic needle heating scheme, it is possible, for example, to use special retarding pyrotechnic compositions, also known in pyrotechnics. The selection of the retardant composition allows you to control the deceleration time.

The device using the proposed method of immobilization can be implemented in the form of a projectile of a contact weapon. In this version, a projectile with a needle is contained in the weapon, when pressed against the target, the needle is exposed, extending from the guiding parts of the weapon, is fixed to the target, for example, with the help of a beard, after which the weapon is removed from the target, and the projectile, remaining fixed on the target, begins act. Structurally, a device in the form of a projectile for a contact weapon may not differ from a projectile for remote use fired from a remote weapon.

Claims (18)

1. A method of limiting targeted, predominantly aggressive, physical actions of biological objects, which consists in minimally invasive impact on a biological object using a throwing weapon and a projectile with a needle, at least one, temporarily limiting the physical actions of the object or reducing the degree of aggression, characterized in that they use a projectile with a source of electrical energy or a pyrotechnic composition, with the help of which an electric circuit with a conductor in a needle is formed or a fire circuit with a pyrotechnic initiator of a pyrotechnic composition, respectively, which close or initiate during a shot mainly due to a given acceleration force acting on the projectile or part of it , or ignition of the said pyrotechnic initiator, while the needle is heated for a limited time to temperatures that cause pain in the target, sufficient to temporarily restrict its physical actions or reduce the degree of aggression these. 2. A method according to claim 1, characterized in that said needle is inserted to a depth not exceeding the usual insertion depth of a needle for medical injections or acupuncture. 3. The method according to claim 1, characterized in that several of said needles are inserted simultaneously or within a short period of time into different points of the body of the target. 4. A method according to claim 3, characterized in that at least some of said needles are heated at different, preferably sequential, time intervals. 5. A device for limiting targeted, predominantly aggressive, physical actions of biological objects, including a throwing weapon and a projectile with a needle, at least one, located in the front part of the projectile, characterized in that the projectile is hollow, and the needle is provided with the possibility of heating from that located in the cavity of the projectile of the energy source forming with the needle an electric or firing circuit through an electric conductor in the needle or a pyrotechnic initiator of the pyrotechnic composition, respectively, provided with the possibility of closing or triggering during a shot, mainly due to a given acceleration force acting on the projectile or part of it. 6. The device according to claim. 5, characterized in that the body of said needle is made of hard metal, mainly steel alloy, with an internal hollow channel in which an electrical conductor is placed, made mainly in the form of copper, brass or silver single-core or stranded wire in heat-resistant electrical insulation, where one end of the wire is electrically connected to the front end of the needle, mainly by crimping, soldering or welding, and the second end of the wire leaves the rear end of the needle and is connected in series with the above-mentioned source of electrical energy, an electric switch and the body of the needle. 7. A device according to claim 5, characterized in that said needle has a barb or other device in its front part that prevents the needle from being pulled out. 8. The device according to claim 5, characterized in that said needle is made of a pair of metals for highly exothermic synthesis of an intermetallic compound and may have an inactive outer shell made of other metals. 9. A device according to claim 8, characterized in that said needle is made of palladium and aluminum and may have an outer sheath of other metals. 10. A device according to claim 8, characterized in that said needle is made of nickel or its alloy and aluminum and may have an outer shell of other metals. 11. The device according to claim 8, characterized in that said needle is made of platinum and aluminum and may have an outer shell of other metals. 12. The device according to claim 5, characterized in that at least part of said needle is made flattened. 13. The device according to claim 5, characterized in that it has a leading belt or ready grooves. 14. The device according to claim 5, characterized in that it has aerodynamic stabilizers. 15. A device according to claim 5, characterized in that it has on said body or a component part of the body an additional heated element, driven by an electric current or by a pyrotechnic method. 16. The device according to claim 5, characterized in that it also contains additional electronic devices for remote communication with the said weapon or remote control of the operation of the device. 17. The device according to claim 5, characterized in that it also contains a device-retarder for turning on an electric switch of an electric power source or a pyrotechnic initiator of a pyrotechnic power source included in the electric or fire circuit of the device, respectively. 18. The device according to claim 17, characterized in that said retarder device provides the ability to adjust the deceleration time.

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