RU2790259C1 - Method for non-lethal impact on a biological target and a device for its implementation - Google Patents

Abstract

FIELD: non-lethal impact on biological targets.

SUBSTANCE: inventions group relates to methods and means of non-lethal impact on biological targets. To implement the method for non-lethal impact on a biological target, a means for remote non-lethal impact is directed towards the target, made in the form of an irritant substance, or a low-dosage substance, or a light-sound charge, or a non-lethal charge, and equipped with a functional projectile made with the possibility of placing it in the launcher or attaching to a launcher. From the launcher, a control projectile is thrown towards the target and at least one said functional projectile is informationally connected to it via a communication channel. Operation of a functional projectile near the target is produced by an initiating signal generated in the control projectile when the control projectile hits the target. On the flight path, the functional projectile lags behind the control projectile by a distance that ensures that, when the functional projectile fires, there is no possibility of causing mechanical injuries or burns to the target. The device for non-lethal impact on a biological target is made with the possibility of placing it in the launcher or attaching it to the launcher and includes at least one functional projectile, made with the possibility of throwing it from the launcher, equipped with an electric igniter electrically interacting with the projectile initiation signal receiver, equipped with means of remote non-lethal impact and made with the possibility of throwing this tool at the target. The control projectile is made with the possibility of throwing it from the launcher and contains a signal source for initiating a functional projectile, equipped with a trigger that is triggered when the control projectile hits the target. The projectiles are informationally linked via a communication channel.

EFFECT: increasing the range of destruction and eliminating the dependence of the effect of exposure on the distance from the launcher to the target.

10 cl, 10 dwg

Description

Application area

The invention relates to methods and means of non-lethal effects on biological targets, that is, on aggressive animals and offenders, and in particular to methods and means of delivering active substances that affect the target, for example, irritants (irritants), low-odorants (disgusting-smelling substances), light and sound charges, etc.

State of the art

A non-lethal weapon is a modern type of weapon designed to provide a short-term impact on a target in self-defense or protection against attack by third parties without causing severe or fatal injuries.

Known methods of non-lethal effects, consisting in the delivery of active substances to the target by initiating a cartridge placed in the launcher (pistol, revolver, barrelless tool, etc.) containing the appropriate active substance, for example, an irritant, a low-odorant or a light-sound charge [1-3 ], or a charge that marks (colors) the target [4], and the release of this substance towards the target when the cartridge is fired. In some cases, the stopping effect on the offender is ensured by the supply of a combination of substances, the supply of a light or sound signal to law enforcement officers located near the site of the offense, the creation of a smoke screen, etc., for which appropriate cartridges, grenades or shells are also used [5-6] . Blank cartridges are also used.

The basic principle of operation of such funds is as follows.

After the primer or electric igniter is initiated and the cartridge fires, the powder (or other propellant) charge inside the cartridge is ignited. Under the influence of high temperature, crystals (the active substance in the cartridge is usually in crystalline form, representing a dry fine-grained powder weighing from 20 to 220 mg (depending on the type, caliber and manufacturer of the cartridge) sublime (turn into a gaseous state) and under the pressure of powder gases they tear a wad (usually it is plastic, but there are also wads made of paraffin or simply seaming is done with an “asterisk”, as in blank cartridges for military weapons) and break out of the cartridge at high speed, forming a gas-smoke cloud or liquid stream at the outlet, consisting of the smallest particles of the active substance.When fired, the plastic plugs do not fly out with the active substance, but are divided into 4 petals and remain inside the barrel of the cartridge case.A directed cloud of the active substance reaches the target and produces a corresponding effect on it.

As irritants in cartridges, various substances are used that are approved for use as non-lethal weapons, for example:

CS (orthochlorobenzalmalonodinitrile) is the most common type of cartridge for gas weapons. The action is characterized by severe pain in the eyes, shortness of breath, lacrimation, burning in the nasopharynx, nasal discharge. At high concentrations - nausea, dizziness, weakness.

CN (chloroacetophenone). The action is expressed in lacrimation and coughing fits, nasal discharge.

PV is a synthetic analogue of red pepper extract. The action is expressed in eye irritation and coughing. The strength of the action is approximately the same as CS.

Some manufacturers also produce cartridges containing a mixture of two active components (the use of more than two compounds in civilian weapons is prohibited by law).

Light and sound cartridges instead of an irritant are equipped with a pyrotechnic composition designed to signal, stun and scare the enemy.

Low-odorant cartridges instead of an irritant are equipped with a special substance, for example, from the mercaptan family, which emits a persistent, disgusting odor that causes nausea, vomiting, and instantly reduces aggression.

Pyro-liquid (otherwise marking or coloring) cartridges instead of an irritant are equipped with liquid paint or other coloring substances, including covert action (solutions of rivanol, phenolphthalein, tetracycline, etc.).

Blank cartridges do not have a striking element, the muzzle of the sleeve is rolled (compressed) with an “asterisk” to prevent powder from spilling out. However, they pose some danger when fired at close range due to the possible harm to the target's health, for example, mechanical injury, burns, etc.

The contents of such cartridges, certified as ammunition for civilian self-defense weapons and permitted for sale to the public, when fired at the manufacturer's recommended distances (no closer than 1 m from the muzzle of the launcher to the enemy when using an irritant or low-dose charge, no closer than 1.5 m when using a light and sound charge), as a rule, does not cause serious harm to human health in the form of unwanted injuries, mainly mechanical injuries or burns. In this case, the action of the irritant in most cases provides temporary damage to the organs of vision and breathing of the enemy. Combinations of several cartridges of different action increase the impact on the target many times over.

The effective range of use of such weapons varies depending on the specific model of the weapon, the type of cartridges used, weather conditions, etc., but in any case does not exceed 2.5 ... 3.0 meters. In addition, the farther the user of the weapon is from the target, the lower the effectiveness of its impact on the target, in other words, the maximum impact occurs at a minimum distance (1.0 ... 1.5 m) to the target.

Thus, the range of use of such weapons is not less than 1 m and not more than 3 m, which significantly limits the operational and tactical properties of these weapons. The factors of limited range and a decrease in the effectiveness of impact with each meter of distance from the target are serious drawbacks that limit the use of non-lethal weapons of this type.

Disclosure of invention

The problem solved by the proposed method and device for its implementation is to create a tool devoid of the shortcomings of the prototype. The technical result provided by the proposed method and device is to significantly increase the range of destruction and eliminate the dependence of the impact effect on the distance from the launcher to the target.

The problem is solved by the fact that, in accordance with the proposed method of non-lethal impact on a biological target, a means for remote non-lethal impact, made in the form of an irritant substance, or a low-dose substance, or a light-sound charge, or another substance or charge of non-lethal action, which is equipped with a functional projectile, made with the possibility of placing it in the launcher or attaching it to the launcher, a control projectile and at least one mentioned functional projectile are thrown from the launcher towards the target, which is triggered near the target by an initiating signal generated in the control projectile when the control projectile hits the target, at the same time, on the flight path, the functional projectile lags behind the control projectile by a distance that ensures that, when the functional projectile fires, there is no possibility of causing harm to the target, mainly mechanical injuries or burns.

An additional feature of the method is that the flight speed of the functional projectile or projectiles corresponds to the flight speed of the control projectile, while the functional projectile or projectiles are thrown towards the target after the control projectile is thrown after a period of time that creates a lag of the functional projectile or projectiles from the control projectile at a distance determined by type of means for non-lethal impact, which ensures that when the functional projectile fires, there is no possibility of causing harm to the target, mainly mechanical injuries or burns.

An additional feature of the method is that at least one part of the functional projectile is equipped with a means of remote action of one type, and other parts are equipped with means of remote action of another type or other types, while the lag of each functional projectile from the control projectile corresponds to the type of remote effect that equipped with an appropriate functional projectile.

The problem is also solved by the fact that the device for non-lethal impact on a biological target is made with the possibility of placing it in the launcher or attaching it to the launcher and includes at least one functional projectile, made with the possibility of throwing it from the launcher, with an electric igniter, electrically interacting with a projectile initiation signal receiver, equipped with a means of remote non-lethal impact and made with the possibility of throwing this tool at a target, a control projectile made with the possibility of throwing it from a launcher, containing a source of a functional projectile initiation signal, equipped with a starter that is triggered when the control projectile hits the target .

An additional feature of the device is that said starter is made in the form of a normally open trigger button, the movable contact of which is configured to close with its fixed contact when the control projectile hits the target.

An additional feature of the device is that the mentioned start button is made with the possibility of its closing due to the action of inertia force at the moment of impact of the control projectile on the target.

An additional feature of the device is that said trigger button is placed in the head part of the control projectile, made with the possibility of its partial deformation at the moment the control projectile hits the target, leading to the activation of this button.

An additional feature of the device is that said start button is made in the form of a relay that closes the electrical circuit for turning on the initiation signal source, driven by a piezoelectric generator that is triggered when the control projectile hits the target due to mechanical action on the piezoelectric element.

An additional feature of the device is that the initiation signal source is made in the form of a predominantly single-acting power supply, the control and functional projectiles are mechanically connected by a flexible electrical conductor, the first end of which electrically interacts with the said power supply source, and the second end electrically interacts with the initiation signal receiver, which can be functionally and structurally combined with the mentioned electric igniter.

An additional feature of the device is that the length of the flexible electrical conductor is determined by the minimum allowable distance from the functional projectile when it fires to the target and is mainly 0.5 ... 1.5 m.

An additional feature of the device is that the functional projectile is equipped with irritants, or low-dosage substances, or a light and sound charge, or a marking charge, or a smoke charge, or another, for example, a blank charge.

An additional feature of the device is that at least part of the functional shells is equipped with means of remote action of one type, mainly irritant substances, the other part or other parts are equipped with means of non-lethal action of another type or other types, mainly low-dosage substances, or light-sound, or smoke charges, or blank charges, or may contain a combination of them, while the lag of each functional projectile from the control projectile corresponds to the type of means of remote action with which the corresponding functional projectile is equipped.

An additional feature of the device is that the control projectile is made with initiation by a baric discharger or an electric igniter.

An additional feature of the device is that the control projectile is made with initiation by a shock initiation capsule.

An additional feature of the device is that irritant, marking or low dose charges are mainly initiated at a distance to the target in the range of 1.0 ... 1.3 m, light and sound charges are mainly initiated at a distance to the target in the range of 1.3 ... 1, 5 m, and smoke charges are initiated at a distance to the target, which is in the range of 0.5 ... 1.0 m.

An additional feature of the device is that the control projectile and each functional projectile are placed in their individual housing, mechanically interacting with the launcher.

An additional feature of the device is that the control projectile and the functional projectile or projectiles are placed in a single housing that mechanically interacts with the launcher.

An additional feature of the device is that the control projectile and functional projectile or projectiles are placed in the respective seats of the launcher.

An additional feature of the device is that the front part of the control projectile can be configured to provide a mechanical (traumatic) non-lethal effect on the target.

Brief description of the drawings

The proposed method and the design of the device that implements the method is illustrated by drawings, which show:

Fig. 1. Scheme of the proposed method. Departure of the control and functional projectiles to the target.

Fig. 2. Scheme of the proposed method. The approach of the control and functional projectiles to the target.

Fig. 3. Scheme of the proposed method. Operation of functional projectiles.

Fig. 4. Timing diagram of the proposed method.

Fig. 5. One of the examples of the design of a device that implements a method in which the communication channel is organized using flexible electrical conductors.

Fig. 6. An example of the design of a device in a single housing in the form of a cartridge using a baric discharge.

Fig. 7. An example of the design of the device in a single housing in the form of a cartridge with the use of a percussion capsule.

Fig. 8. Examples of the design of the control projectile.

Fig. 9. Examples of the design of a functional projectile.

Fig. 10. An example of the design of a cartridge with one control and many functional projectiles.

Detailed description of the invention

On FIG. 1 shows the first phase of the proposed method. The launcher 1 throws a control projectile 3 towards the target 2 and, for example, two functional projectiles 4 and 5, respectively. The control projectile 3 is informationally connected to the functional projectiles 4 and 5 by means of a communication channel 6 used for signaling the initiation of functional projectiles. The control projectile contains a body 7, an initiation signal source 8 and a trigger 9, and can also be equipped with means of throwing it (not shown in Fig. 1). Functional projectiles include a body 10, a non-lethal charge 11 or 12, an initiation signal receiver 13 and a propelling charge 14, while the propelling charge and the non-lethal charge can be separated by a wad (not shown in Fig. 1), and can also be equipped with means for its throwing (not shown in Fig. 1). Functional projectiles can be equipped with irritants, or low-risk substances, or a light and sound charge, or a marking charge, or a smoke charge, or another charge, such as a blank charge, which are thrown towards the target with the help of a propellant charge 14 when it is initiated. Functional projectiles are thrown at approximately the same initial speed as the control projectile, but later (generally not simultaneously) than the control projectile, so from the moment of throwing from the launcher to hitting the target at any moment of flight along the trajectory (for example, as shown in Fig. 1, at a distance L of the control projectile to the target) functional projectiles 4 and 5 lag behind the control projectile at distances L01 and L02, respectively, which depend on the type of non-lethal charge and represent distances equal to or exceeding the minimum allowable distances to the target , which are allowed to be exposed to one or another type of non-lethal charge. If functional projectiles are equipped with the same non-lethal charges, then L01=L02.

In the general case, part of the functional shells can be equipped with means of remote action of one type, mainly irritant substances, the other part or other parts can be equipped with means of remote action of another type or other types, mainly low-dosage substances, or light and sound, or smoke charges, or blank charges , or may contain a combination of them, while the lag of each functional projectile from the control projectile corresponds to the type of means of non-lethal impact with which the corresponding functional projectile is equipped.

For each type of non-lethal charge, the minimum distance at which its impact on the target is allowed is determined, for example, for an irritant or low-dosage charge, this minimum distance is usually 1.0 ... 1.3 m, for a light and sound charge - 1.3 ... 1.5 m, for a smoke charge - 0.5 ... 1.0 m, etc. The mentioned minimum allowable distance is determined by ensuring that, when the functional projectile fires, there is no possibility of causing harm to the target, mainly mechanical injuries or burns, or causing other harm to health, for example, temporary blindness or respiratory dysfunction for an unacceptably long period.

Let, for example, a functional projectile 4 be equipped with an irritant charge 11, and a functional projectile 5 with a light and sound charge 12. In this case, L01={ 1.0…1.3} m, and L02={1.3…1.5} m.

On FIG. 2 shows the second phase of the proposed method. When the control projectile 3 hits the target 2, the trigger 9 is activated, including the source of the initiation signal 8, which transmits the initiation signal 15 to the functional projectiles 4 and 5 via the communication channel 6. The signal 15 is fed to the receivers 12 and initiates the propellant charges 13 directly or using a means preliminary impact on the propellant charge, for example, an electric igniter (not shown in Fig. 2). Propelling charges may differ from each other in composition and mass (volume) depending on the non-lethal charge used in a given projectile.

It should be noted that when fired, functional projectiles stop and fall, or their flight speeds, respectively, their trajectories, are significantly reduced, primarily due to the action of the recoil force from the operation of the propellant charge. The flight speed of active substances significantly exceeds the flight speed of the control projectile (respectively, the flight speed of functional projectiles), which is usually 40 ... actions.

On FIG. 3 shows the third phase of the proposed method. Propelling charges 13 ignite and act on non-lethal charges, namely (in this example) an irritant charge 11 and a light-sound charge 12, which, under the influence of high temperature, break out of the cartridge at high speed, forming gas-smoke (aerosol) clouds and / or liquid jets at the exit (in the case of using pyro-liquid projectiles) 16 and 17, consisting of the smallest particles of the corresponding active substance. Active substances, if intended to affect the target directly (e.g., irritants, markers, or malodorants, or combinations thereof) are applied to the clothing or body of the target, and provide a non-lethal effect on the target by inducing appropriate biological responses of the target, such as temporary immobilization or at least least, a significant reduction or complete suppression of the aggression of the target. Other active substances that are not intended to directly affect the target, for example, a light and sound or smoke charge, provide a non-lethal effect on the target, causing temporary blinding and / or stunning of the target (light and sound charge) or provide covert movement of law enforcement officers towards the target to neutralize it (smoke charge). The recoil force of 18 when the propellant charge is triggered stops functional projectiles or at least significantly reduces their speed and flight path. At the same time, correctly performed balancing and placement of the center of mass of a functional projectile does not allow it to significantly change the position of its axis at the moment the active substance is ejected towards the target. Moreover, such a balancing of the functional projectile is possible, in which, at the moment of operation, it will turn through an acute angle outward from its longitudinal axis, increasing the area of destruction of the target.

On FIG. 4 shows the timing diagram of the proposed method. At the moment t ₀ a control projectile is thrown from the launcher, at the moments t ₁ , t ₂ and t ₃ - functional projectiles (in this example there are three of them, which contain, for example, smoke, irritant and light-sound charges, respectively). At the moment t ₀₁ , the control projectile hits the target, while a signal is generated to initiate functional projectiles that are triggered by this signal at times t ₁₁ , t ₂₁ and t ₃₁ , respectively, being at the same time at distances from the target L ₀₁ that are acceptable for these types of active substances , L ₀₂ and L ₀₃ , subject to the correspondence of the average speeds of the control and functional projectiles:

v ₁ =L ₀₁ /(t ₁₁ -t ₁ );

v ₂ =L ₀₂ /(t ₂₁ -t ₂ );

v ₃ =L ₀₃ /(t ₃₁ -t ₃ );

v ₁ \u003d v ₂ \u003d v ₃ \u003d v ₀ ,

Where

v ₁ - speed of functional projectile 1,

v ₂ - speed of the functional projectile 2,

v ₃ - functional projectile speed 3,

v ₀ - the speed of the control projectile.

The general scheme of the device that implements the proposed method coincides with Fig. 1, however, the physical medium of the communication channel may be different, for example, a radio channel or an electrical conductor. The components of the device, namely the control and functional projectiles, can also be made using various technical means and will be discussed below.

The control projectile and each functional projectile can be placed in individual housings that interact with the launcher.

The control projectile and functional projectile or projectiles can be placed in a single housing that interacts with the launcher.

The control projectile and functional projectile or projectiles can be placed directly in the respective seats of the launcher.

On FIG. 5 shows one of the examples of the design of the device that implements the method, in which the communication channel 6 with each functional projectile is organized using electrical conductors.

Fig. 5a. The device includes a control projectile 3, which contains a housing 7, an initiation signal source 8, a trigger 9, as well as projectile throwing means (not shown in Fig. 5). The control projectile 3 interacts with functional projectiles 4 and 5 using communication channels 6, which are organized in the form of pairs of flexible electrical conductors, made mainly in the form of thin flexible cables with two insulated cores and a common outer sheath. Each functional projectile contains an initiation signal receiver 13, a non-lethal charge 11 and a propelling charge (not shown in Fig. 5) housed in the body 10. There may be one functional projectile or there may be several. In this example, two functional projectiles are shown, equipped with non-lethal charges of the same type, therefore, flexible electrical conductors 6, containing two opposite-pole wires each, are made of the same length, corresponding to the minimum allowable distance L ₀₁ to the target at the time of operation of the functional projectile. Flexible electrical conductors can be made resistant to stretching and tearing, so that simultaneously with the function of transmitting initiation signals, they can perform the function of a mechanical connection between the control projectile and functional projectiles. In this case, the use of own projectile throwing means in functional projectiles is not required, and functional projectiles will fly after the control projectile, which performs the function of the carrier projectile, at a speed exactly equal to the speed of the control projectile. The energy of the means of throwing the control projectile should ensure the throwing of several (in this example, three) projectiles, and not just one, which is quite achievable with standard throwing means, for example, powder charges with very high energy, or sufficiently powerful electric igniters or capsules.

If special measures are not taken, then functional projectiles will fly in the fairway of the control projectile (near its longitudinal axis), which is not always convenient, for example, if functional projectiles, as in this example, are equipped with the same active substance in order to increase the area of destruction targets (the affected areas will in this case completely or partially intersect). A remedy for eliminating this feature can be the use of a more rigid additional conductor, the so-called “leash” (not shown in Fig. 5a), as it is implemented, for example, in [7]. When throwing a control projectile, the leash, due to its rigidity, lines up behind the projectile at a noticeable angle, and not on the axis of the projectile, so the functional projectiles will fly behind the control projectile at a distance from the longitudinal axis of the control projectile, as shown in Fig. 5a.

The flexible electrical conductor 6 can be placed in the form of a compact stack in the body of the functional projectile, or in the body of the control projectile, or in the device (if the control and functional projectiles are located in the common supporting body of the device), or outside the device (for example, if the control and functional projectiles placed directly in the launcher). When throwing a control projectile from the launcher, flexible electrical conductors are gradually pulled out of the stack, straightening to their full length and thereby forcing the functional projectiles driven by the control projectile to fly to the target.

It should be noted that the distance of throwing projectiles from the launcher to the target must always exceed the minimum allowable distance from the functional projectile to the target, i.e. in this example, L ₀₁ , otherwise the flexible conductors will not stretch to their full length and functional cartridges will not fly to the target. However, since the purpose of the proposed method and device for its implementation is precisely to increase the firing range, this condition is almost always met.

Fig. 5 B. The design of the device differs in that the functional projectiles 4 and 5 are equipped with non-lethal charges 11 and 12 of different types, therefore, flexible electrical conductors 6 can have different lengths L ₀₁ and L ₀₂ determined by the minimum target destruction distances defined for this type of non-lethal charge.

An example of the design of a device in the form of a cartridge that combines the control and functional charges in one housing, attached to the launcher or installed in the launcher, is shown in Fig. 6.

Fig. 6a. The cartridge 19, attached to the launcher 1 or installed in the launcher, includes a common housing 20 for accommodating the control projectile 3 and at least one functional projectile, and in this example, two functional projectiles 4 and 5. The cartridge contains three guide channels made in the form of predominantly cylindrical cavities, in one of which, for example, in the middle or central, a control projectile 3 is installed, and in the other - functional projectiles. Means for throwing a control projectile 3, including a baric arrester 21 and a pusher 22, are located in the rear part of the corresponding guide channel.

In the present design example, the guide channel of the control projectile 3 is made with the locking of the gases generated during the ignition of the baric discharge 21 from the initiation signal in the form of a current pulse. The locking of the guide channel is ensured by the fact that the part of the guide channel, in which the baric discharger 21 and the pusher 22 are located, is made with a diameter larger than its part, in which the control projectile 3 is placed. moves forward and pushes the control projectile 3 towards the target, at the same time blocking the entrance of the guide channel of smaller diameter with its head part, cutting off gases from the surrounding atmosphere.

A baric discharger differs from a conventional electric igniter in that it can be initiated by high-voltage current pulses that create an electric spark that ignites the working substance of the arrester, and when setting a not very high initial velocity of the control projectile, it usually does not require a separate propellant (usually powder) charge. An example of the use of baric dischargers in cartridges of electroshock devices (in which the speed of launch of the projectile elements of the cartridge is also relatively low and amounts to 40 ... 50 m/s) is given in [8]. It should be noted that the industry produces electric igniters with the appropriate energy, which also do not require a separate propellant charge, initiated by a low voltage current. In both cases, it can be considered that the electric igniter and the propelling charge are structurally and functionally combined. When using a baric discharger as a launcher, it is possible to use electric shock devices of remote (EShU DD) or contact-remote (EShU KDD) action, adapted for their intended purpose for attaching cartridges to them, and output high voltage current signals of ESHU DD are used as an initiating signal or ESHU KDD. When using an electric igniter, those types of EShU DD or EShU KDD can also be used, in which low-voltage signals for initiating electric cartridges of electroshock devices are formed.

Flexible electrical conductors 6, which mechanically and electrically connect functional projectiles 4 and 5 with the control projectile 3, including with the help of leads 23, made with higher mechanical rigidity and elasticity compared to conductors 6, can be packed in a compact form, for example spiral, laying and placed together with functional projectiles in the corresponding guide channels. To provide the said mechanical connection, the leads 23 can be placed in the longitudinal grooves 24 made in the body of the control projectile 3, and enter the corresponding side guide channels through the slots 25 made in the body 20 in the front part of the central guide channel.

On FIG. 6b shows the cartridge 19 at the moment of its operation. The gases 26 formed during the ignition of the baric discharge or electric igniter 21 press on the pusher, which forces the control projectile 3 to fly out of the cartridge 19. The projectile 3 pulls the leads 23 and then the flexible electrical conductors 6, which then pull the functional projectiles 4 and 5 A system of control and functional projectiles, mechanically connected by flexible electrical conductors, flies towards the target.

Another example of the design of the device in the form of a cartridge 19, which combines the control and functional charges in one housing, attached to the launcher or installed in the launcher, is shown in Fig. 7. The cartridge design shown in FIG. 7a is almost identical in design to the cartridge shown in FIG. 6a, but differs in the means of throwing a control projectile, which include a primer 27 of shock initiation, driven by a striker 28 of the launcher, a propelling (usually powder) charge 29 and a wad 30.

On FIG. 7b shows the cartridge 19 at the moment of its operation. The gases 31 formed during the ignition of the propellant charge 27 put pressure on the wad 30, which forces the control projectile 3 to fly out of the cartridge 19. The projectile 3 pulls the leashes 23 and then the flexible electrical conductors 6, which then pull the functional projectiles 4 and 5 behind them. A system of control and functional projectiles, mechanically connected by flexible electrical conductors, flies towards the target. The central guide channel is made with a constant diameter, so the wad 30 can fly out of the channel when the cartridge is triggered.

Examples of the design of the control projectile for different types (physical environments) of the communication channel 6 are shown in Fig. 8.

On FIG. 8a shows the design of the control projectile 3 associated with the control projectiles using a radio channel. The projectile 3 contains a body 7, a source 8 of the initiation signal 15, made in the form of a radio transmitter, which can be equipped with an antenna 33, a starter 9, a power source electrically connected to the starter 9 and the radio transmitter 8, as well as the head part 34 of the body 7, which can be made with the possibility of mechanical deformation when the projectile 3 hits (impacts) the target. Since the projectile 3 is a disposable device, the power supply 32 may be in the form of a miniature non-rechargeable cell or battery or accumulator. The starter 9 can be made in the form of a normally open start button that closes the electrical circuit for starting the radio transmitter 8, the movable contact of which is made with the possibility of closing with its fixed contact when the control projectile 3 hits the target due to the action of inertia (if the starter 9 is made with limited mobility inside the housing 7) or the corresponding deformation of the head part 34 of the control projectile 3 (if the starter 9 is made stationary). Other design options for the starter 9 are also possible, for example, it can be made in the form of a relay that closes the electrical circuit for starting the radio transmitter 8, while the relay is activated by a piezoelectric generator that is triggered by mechanical action on the piezoelectric element when the control projectile hits the target.

When the control projectile 3 hits the target 2, the trigger 9 is activated, which starts the radio transmitter 8, which transmits the initiation signal 15 to the functional projectiles via the radio channel 6.

On FIG. 8b shows the design of the control projectile 3 connected to the control projectiles with the help of leashes and flexible electrical conductors. In this design, the introduction of leashes and flexible electrical conductors can be compensated by a significant simplification of the projectile. The projectile 3 contains a body 7, a source 8 of the initiation signal 15, functionally and structurally integrated with a power source 32, a starter 9, as well as leashes 23 connected to flexible electrical conductors 6, and a head part 34 of the body 7, which can be made with the possibility of mechanical deformation upon hit (impact) of the projectile 3 on the target. As in the previous design shown in Fig. 8a, the starter 9 can be made in the form of a normally open start button that closes the electrical circuit for turning on the radio transmitter 8, the movable contact of which is made with the possibility of closing with its fixed contact when the control projectile 3 hits the target due to the action of inertia (if the starter 9 is made with limited mobility inside the housing 7) or the corresponding deformation of the head part 34 of the control projectile 3 (if the starter 9 is made stationary). Other design options for the starter 9 are also possible, for example, it can be made in the form of a relay that closes the electrical circuit for turning on the transmitter 8, driven by a piezoelectric generator that is triggered by mechanical action on the piezoelectric element when the control projectile hits the target.

When the control projectile 3 hits the target 2, the starter 9 is activated, connecting the power source 32, which transmits the initiation signal 15 in the form of a current pulse to the functional projectiles along the leashes 23, and then through the flexible electrical conductors 6.

It should be noted that the control projectile can be performed with a traumatic effect.

Examples of the design of a functional projectile for different types (physical media) of the communication channel 6 are shown in Fig. 9.

On FIG. 9a shows the design of a functional projectile 4 associated with a control projectile using a radio channel 6. The projectile 4 includes a body 10, a receiver 13 of the initiation signal 15, made in the form of a radio receiver, which can be equipped with an antenna 35, a power supply 36 electrically connected to the radio receiver 13 and electric igniter 37, as well as the head part 38 of the housing 10, made in the form of a plug. The projectile is equipped with a propellant charge 14 and a non-lethal charge 11, which is the corresponding active substance (irritant, malodorant, light and sound charge, smoke charge, etc.) placed in front of the body 10 in front of the plug 38. The propellant charge and the active substance of non-lethal action can be separated by a wad (not shown in Fig. 9a).

When the control projectile 3 hits the target 2, the initiation signal 15, transmitted over the radio channel 6, is fed to the input of the radio receiver 13, which simultaneously performs the function of a current amplifier. From the output of the radio receiver 13, the amplified and normalized signal 15 initiates the operation of the electric igniter 37, which in turn ignites the propellant charge 14.

Under the influence of the high temperature of the propellant charge 14, the crystals (the active substance 11 in the projectile is usually in crystalline form) sublimate (turn into a gaseous state) and, under the pressure of the gases of the propellant charge 14, squeeze out or destroy the plug 38 and break out of the projectile at high speed, forming at the exit gas-smoke cloud or liquid jet, consisting of the smallest particles of the active substance. A directed cloud of active substance reaches target 2 and produces a corresponding effect on it.

On FIG. 9b shows the design of the functional projectile 4 connected to the control projectile with the help of flexible electrical conductors. The projectile 4 contains a body 10, an electric igniter 37, a propellant charge 14, a plug 38 and an active substance 11. A flexible electrical conductor 6 is attached to the plug 37. Passing through the plug, the conductor 6 is divided into two opposite-pole wires 39 and 40, electrically interacting with the corresponding contacts of the electric igniter 37.

When the control projectile 3 hits the target 2, the initiation signal 15, transmitted through flexible electrical conductors 6, enters the electric igniter 37, which, when fired, in turn causes ignition of the propellant charge 14.

Under the influence of the high temperature of the propellant charge 14, the crystals (the active substance 11 in the projectile is usually in crystalline form) sublimate (turn into a gaseous state) and, under the pressure of the gases of the propellant charge 14, squeeze out or destroy the plug 38 and break out of the projectile at high speed, forming at the exit gas-smoke cloud or liquid jet, consisting of the smallest particles of the active substance. A directed cloud of active substance reaches target 2 and produces a corresponding effect on it.

Control and functional projectiles can be equipped with flight stabilizers, made, for example, in the form of plumage (not shown in Fig. 9), as well as, if necessary, propellant charge retarders (not shown in Fig. 9), for example, when functional the projectiles are made with different non-lethal charges, and the flexible electrical conductors are made of the same length, corresponding to the largest minimum allowable distance to the target, corresponding to the most dangerous active substance in terms of possible harm to the target.

The ejection of the active substance from the head of the functional projectile can be carried out along the longitudinal axis of the projectile and/or to the sides at an angle to said longitudinal axis.

The front part of the control projectile can be configured to provide a mechanical (traumatic) non-lethal effect on the target, similar to traumatic bullets in compliance with the safety requirements for non-lethal traumatic means. This technical solution makes it possible to further enhance the non-lethal effect on the target.

On FIG. 10 shows an example of the proposed device, in which one control projectile 3 and eight functional projectiles 4 are placed in the housing 19. This design allows you to significantly increase the area of destruction, which makes it possible to non-lethally affect an aggressive crowd consisting of several offenders when a control projectile hits one of the offenders, such as their leader, especially if the target is in the center of the crowd. If the control projectile is made with a traumatic action that enhances the effect of the impact, then the defeat of the leader will lead to an additional decrease in the aggressiveness of the rest of the offenders.

The proposed device can significantly increase the distance to hit the target compared to the distance of 3...5 m, typical for modern hand-held non-lethal weapons. For example, the tests of the prototype showed the possibility of successful application of the proposed device at a distance of 10...12 m or more. For longer distances (15 ... 30 m or more), a more complex target designation device on the launcher will be required, as well as a higher energy of the means of throwing (respectively, the flight speed) of the control and functional projectiles, which seems quite possible.

Technical implementation

The device was implemented in pilot production and has the following characteristics:

The purpose and design of the proposed device should be distinguished from a gas, stun or smoke grenade. The grenade is thrown towards the target and is triggered not by the fact of hitting the target, but by the delay time. The distance to the target at the moment of triggering is random and does not depend on the grenade hitting the target.

The proposed method and device for its implementation make it possible to hit the target at any distance, depending on the aiming capabilities of the launcher and the energy of the means of throwing control and functional projectiles, while the destruction efficiency will always be maximum, since the operation of functional projectiles always occurs at a distance close to the minimum allowable distance from the target. Thus, the claimed technical result is achieved, which consists in a significant increase in the range of destruction and the elimination of the dependence of the impact effect on the distance from the launcher to the target.

List of sources cited

1. RF patent 2111444 Gas cartridge.

2. RF patent 2585124 Non-lethal weapons.

3. RF patent 2237854 Light and sound cartridge.

4. RF patent 2768532 Method for firing marking cartridges and a marking cartridge that implements it.

5. RF patent 2663421 Non-lethal ammunition.

6. RF patent 2215977 Smoke cartridge with irritant (options).

7. Patent of the Russian Federation 208546 Cartridge for an electroshock device with a remote defeat.

8. Patent of the Russian Federation 2351871 Cartridge for an electroshock device with a remote defeat.

Claims (10)

1. A method of non-lethal impact on a biological target, which consists in directing towards the target a means for remote non-lethal impact, made in the form of an irritant substance, or a low-dosage substance, or a light-sound charge, or a non-lethal charge, which is equipped with a functional projectile, made with the possibility of its placement in the launcher or attached to the launcher, characterized in that a control projectile is thrown from the launcher towards the target and at least one mentioned functional projectile is informationally associated with it via a communication channel, the operation of which near the target is produced by an initiating signal generated in the control projectile when the control projectile hits the target, while on the flight path the functional projectile lags behind the control projectile at a distance that ensures that when the functional projectile fires, there is no possibility of causing mechanical injuries or burns to the target. 2. The method according to claim 1, characterized in that the flight speed of the functional projectile or projectiles corresponds to the flight speed of the control projectile, while the functional projectile or projectiles are thrown towards the target after the control projectile is thrown after a period of time that creates a lag of the functional projectile or projectiles from the control projectile at a distance determined by the type of means for non-lethal impact, ensuring that when the functional projectile is triggered, there is no possibility of causing mechanical injuries or burns to the target. 3. The method according to p. 1, characterized in that at least one part of the functional projectiles is equipped with a means of remote action of one type, and the other parts are equipped with means of remote action of another type or other types, while the lag of each functional projectile from the control projectile corresponds to the type means of remote action with which the corresponding functional projectile is equipped. 4. A device for non-lethal impact on a biological target, characterized in that it is made with the possibility of its placement in the launcher or attachment to the launcher, and includes at least one functional projectile, made with the possibility of throwing it from the launcher, equipped with an electric igniter, electrically interacting with the projectile initiation signal receiver, equipped with a means of remote non-lethal impact and made with the possibility of throwing this tool at a target, a control projectile made with the possibility of throwing it from a launcher, containing a source of a functional projectile initiation signal, equipped with a starter that is triggered upon impact of the control projectile at the target, while the projectiles are informationally linked using a communication channel. 5. The device according to claim 4, characterized in that the source of the initiation signal is made in the form of a predominantly single-acting power supply, the control and functional projectiles are mechanically connected by a flexible electrical conductor, the first end of which electrically interacts with the said power supply source, and the second end electrically interacts with an initiation signal receiver, which can be functionally and structurally combined with the mentioned electric igniter, while the length of the flexible electrical conductor is determined by the minimum allowable distance from the functional projectile to the target when it is fired and is mainly 0.5 ... 1.5 m. 6. The device according to claim. 4, characterized in that the said starter is made in the form of a normally open start button, the movable contact of which is configured to close with its fixed contact when the control projectile hits the target due to the action of inertia or the corresponding deformation of the head of the control projectile. 7. The device according to claim 4, characterized in that the functional projectile is equipped with irritants, or low-dosage substances, or a light and sound charge, or a marking charge, or a smoke charge, or another non-lethal charge. 8. The device according to claim 4, characterized in that at least part of the functional shells is equipped with means of remote action of one type, mainly irritant substances, the other part or other parts are equipped with means of remote action of another type or other types, mainly low-odorant substances, or light and sound , or smoke charges, or blank charges, or may contain a combination of them, while the lag of each functional projectile from the control projectile corresponds to the type of means of remote action with which the corresponding functional projectile is equipped. 9. The device according to claim 4, characterized in that irritant, marking or low dormant charges are predominantly initiated at a distance to the target in the range of 1.0 ... 1.3 m, light and sound charges are predominantly initiated at a distance to the target in the range of 1 .3 ... 1.5 m, and smoke charges are initiated at a distance to the target, which is in the range of 0.5 ... 1.0 m. 10. The device according to claim 4, characterized in that the control projectile and each functional projectile are placed in individual housings that mechanically interact with the launcher, or are placed in a single housing that mechanically interacts with the launcher, or are placed directly in the corresponding seats of the launcher .

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