RU2694320C2 - Non-lethal garnet with spatial effect - Google Patents

Abstract

FIELD: weapons.

SUBSTANCE: invention relates to non-lethal weapons with sound, light irritant and other means of action on target. Grenade includes housing filled with liquefied, compressed or adsorbed fuel and oxidizer, valve or tap, timer, ejector, or mixer, or nozzles of fuel and oxidizer, one or several unfolding sleeves from polymer or elastic material and one or several devices for initiation of explosive gas mixture of fuel and oxidant. Inner volume of the sleeves may contain a chemical irritant or a smoke-forming agent, or mixtures thereof, or a finely dispersed metal fuel, or a liquid or fine colouring agent.

EFFECT: technical result consists in creation of manual non-lethal grenade with increased area of action for deterrence and dispersion of aggressive crowd with low traumatic danger.

17 cl, 5 dwg

Description

The technical field to which the invention relates.

The invention relates to non-lethal weapons with sound, light, irritant (irritant) means of hitting the target and is intended for use as a means of limiting targeted aggressive physical actions, deterring and dispersing an aggressive crowd in the police technique of suppressing mass disturbances of public order.

The level of technology

Known devices for deterring and dispersing an aggressive crowd, which are hand-held light-sound grenades and light-sound grenades with irritants and traumatic elastic ready-hit elements, such as Zarya, Torch, Flame, GSZ, Vyushka, Drofa and others [1-3].

At present, light-sounding ammunition abroad is practically not patented, probably because the creation of devices whose effect is provided by the energy of explosives (explosives), pyrotechnic compositions, gunpowder no longer carries new technical solutions, and the development of such devices goes in the direction of creating compact (referring to the device in the overall dimensions of classic grenades and projectiles to hand-held grenade launchers) for new innovative technologies developed in the United States and known as "Compact N on-Lethal Non-Pyrotechnic Flash-Bang Technologies.

The disadvantage of light and sound grenades is their increased invasiveness for people who are in an aggressive crowd, primarily because of possible mechanical injuries if a grenade is hurled into the head or injured areas of the body, since a hand and grenade grenade is always a hard and heavy object. large relative lateral load.

The main disadvantage of the majority of well-known light and sound grenades is their high injury risk for casual or non-aggressive participants in an aggressive crowd. The recommended distance from the above grenades at their rupture (not to cause serious injuries to people) is 2 ... 5 m. The explosion of a grenade in a crowd is very traumatic, since the high explosive-crushing effect of the 88-40 pyrotechnic light-sound compositions in the shell (case) of a grenade is from 40 ... 70% of the high explosive-crushing effect of the explosion of a military explosive (BB) of TNT, and may also surpass TNT in terms of the draft. Most of the structures of light-sound grenades also form solid fragments of non-metallic bodies and metal parts of garnet fuses during an explosion. Practice shows that a sound-acoustic grenade exploding close to biological objects, as a rule, causes severe mechanical injuries, including with crushing and tearing of limbs, or serious damage to the organs of vision up to the smallest fragments of the grenade body, including subsequent blindness. Despite the absence of splinters declared in the descriptions of grenades at rupture, in reality lesions are also inflicted by fragments of non-metallic bodies of grenades and, moreover, high-speed particles of metal fuel, condensed oxidizer, and solid heated metal oxides of the explosion products. Due to the great injury risk, as practice shows, law enforcement officers use sound and sound guarantors extremely rarely and only in exceptional cases, being aware of their high injury risk and the risks of subsequent administrative and even (in the case of fatal injuries) criminal liability. The effect of an explosion of a sound-acoustic grenade in the immediate vicinity of a material object is given, for example, in [4]. Fragment wounds from the explosion of sound-acoustic grenades are given, for example, in [5].

To control the degree of non-lethal impact of light-sound grenades is basically impossible When a person is close to a person, the degree of exposure may be too large and causes penetrating shrapnel wounds, contusions, rib fractures, brain concussion, significant superficial damage to various organs and skin, skull damage, heart failure, kidney, liver, internal hemorrhages, fracturing and separation of limbs, in the limit - a high probability of death or disability of the object of use. In all constructions of light-sound grenades implemented in today's time, diametrically opposite requirements cannot be fulfilled: ensuring complete “non-lethal” damage to the object (s) used in the case of use, on the one hand, and ensuring effective impact, sufficient restraining and dispersing aggressive mob action, on the other hand. The search for the optimal ratio of non-lethal requirements and the effectiveness of the impact is still an urgent and not fully solved task.

The lack of light-sound grenades of all types also lies in the fact that all types of such grenades contain condensed pyrotechnic compositions, which are also blasting explosives of reduced power when detonated using detonators. The explosion of one grenade during the storage of light-acoustic grenades at the warehouse causes an inevitable explosion of all grenades and corresponding disastrous consequences. The storage and use of light-sound grenades is equivalent to the storage and use of explosives with the corresponding necessary measures for the security of accounting, storage, preservation, which inevitably complicates the possibility of their use. Getting light and sound grenades into the hands of offenders as a result of weaning them from law enforcement is even more dangerous due to the possibility of individual use of taken away (stolen) grenades to commit crimes, for example, using homemade fragmentation shirts for grenades.

In addition to these drawbacks, it should be noted the very high price of hand-held light-sound grenades, which does not allow using them in the quantities necessary for solving various operational tasks. For example, the cost of the Zarya-2 manual light-sound grenade, the most widespread in the power services of the Russian Federation, amounts to 1,959.49 rubles per unit ([6]). The cost of the hand-borne light-sounding irritating grenade “Drofa-PM” in 2014 amounted to 13,472.09 rubles per unit ([7]).

Also known are "thermobaric" hand grenades, for example, RG-60TB grenade. Such grenades with single-ended thermobaric mixtures contain a charge of a spraying-initiating condensed explosive (IV), and a condensed charge of a mixture of fuel, in some cases, with the addition of a certain amount of oxidant (for example, isopropyl nitrate and fine aluminum or aluminum-aluminum alloy powder (fuel) and nitrate or ammonium perchlorate, RDX or HMX (oxidant)). Such mixed fuel compositions are described, for example, in [8], as well as in [9]. With the explosion of a grenade, an explosive-initiating explosive explodes, which disperses the fuel charge (or oxidation fuel charge) at the same time initiating its combustion. The charge of fuel burns partly due to an internal oxidizer (explosive burning or detonation) and partly due to oxidation by atmospheric air. The increase in the explosive effect contributes to the closed or not fully open volume, where the grenade explodes. Such grenades are combat munitions that have multifactorial and probable lethal damage: high-explosive, fragmentation and incendiary. At the same time, the spatial effect of single-pressure thermobaric ammunition in the open space outside the premises is insignificant and incomparable with the action of two-stroke volume-detonating ammunition.

The prototypes of the claimed device from the prior art and as a result of a patent search were not found.

DISCLOSURE OF INVENTION

The aim of the invention is to create a hand-held non-lethal grenade with a high impact area for deterring and dispersing an aggressive crowd with reduced traumatic risk, not containing condensed explosives or explosive pyrotechnic compositions and not dangerous in case of attempts to use it by offenders to commit serious crimes.

The essence of the invention lies in the fact that a non-lethal grenade comprises a housing with a combustible or combustible and separately contained oxidizing agent, a depressurization device made in the form of at least one valve or tap, at least one timer, ejector, or mixer, or openings of fuel inlet and an oxidizer, at least one unfolding sleeve made of a polymer or elastic material, at least one device for initiating an explosive gas mixture of a combustible and an oxidizer.

An additional feature is that the said depressurization device is launched from a mechanical impact on the controls, similar to the controls of combat hand grenades.

An additional feature is that the mentioned timer is launched from mechanical effects on the controls, similar to combat hand grenades.

An additional feature is that the said timer is a time delay device of a mechanical, chemical, pyrotechnic or electrical type.

An additional feature is that the fuel and oxidant mentioned are gas-liquids, or compressed gases, or adsorbed gases.

An additional feature is that said liquid fuel is a liquefied combustible gas.

An additional feature is that in the internal volume or on the inner surface of the said sleeve there is a chemical irritant, or smoke agent, or mixtures thereof.

An additional feature is that fine metal fuel is contained in the internal volume or on the internal surface of the said sleeve.

An additional feature is that a liquid or fine dye is contained in the internal volume or on the inner surface of the said sleeve.

An additional feature is that said housing is at the same time a container for storing said liquid fuel or liquefied, compressed or adsorbed oxidant.

An additional feature is that said sleeve is laid in a collapsed state on top of said housing.

An additional feature is that the said sleeve is elastic or has built-in elastic elements.

An additional feature is that the said sleeve has a cover or other protection device from premature deployment and destruction.

An additional feature is that the said device for initiating a mixture of fuel and oxidant is a fuse or fuse of a mechanical, chemical, pyrotechnic or electrical type.

An additional feature is that the said device for initiating a mixture of a fuel and an oxidizer of an electric type has a power supply.

An additional feature is that the said device for initiating a mixture of fuel and oxidizer is capable of producing a thermal, spark or detonation initiating impulse.

An additional feature is that several mentioned devices for initiating a mixture of fuel and an oxidizer are capable of issuing initiating pulses sequentially or according to another program set by said timer.

Brief Description of the Drawings

FIG. 1. A schematic depiction of the main parts and assemblies of the grenade with an “atmospheric oxidizer”.

FIG. 2. Schematic representation of the main parts and components of the grenade with the “internal oxidizer”.

FIG. 3. Possible forms of deployment of grenade hoses.

The implementation of the invention

FIG. 1. A garnet in an embodiment with an “atmospheric oxidant” (atmospheric air serves as a fuel oxidizer) consists of a housing 1 in which a reservoir 2 is located containing liquid fuel, mainly in the form of easily liquefied liquefied combustible gases or mixtures thereof (see below). The tank 2 has a valve or valve 3, opened with the help of a folding safety lever 4 grenades, or pulled out safety grenade checks, or a folding safety lever 4 grenades after pulling the checks.

When opening the valve or valve 3, the liquefied combustible gas enters the evaporator 5, where gasification of the liquid into gas occurs, and then into the ejector device 6. At the ejector device 6, atmospheric air leaks from the atmosphere and the air is mixed with combustible gas Atmosphere of air should not be less than the amount necessary for the formation of a mixture of gas - air with the highest explosive limit for the type of combustible gas used. Ejector device 6 is hydraulically adjacent at least one unfolding sleeve 7 made of polymeric or elastic material (for example, from different types of rubber), and said sleeve may be a ready-made industrial form, for example, the shape of inflatable balls - balloon modeling)). In the state before using the grenades, the sleeves are laid (folded), mainly around the body 1. In FIG. 1 shows only one sleeve 7 in the already deployed state. The thickness of the polymer (for example, made of polyethylene) or elastic material can be very small (no more than 10 microns). The sleeves begin to unfold (swell) due to the overpressure of the gas-air mixture flowing into them. The rate at which the gas-air mixture enters the sleeve (sleeves) is chosen so that the full deployment (swelling) of these forms takes place in a time not exceeding a few seconds so that the aggressive crowd does not have time to damage them (pierce, pierce, cut through or damage in another way). To improve the conditions of filling the sleeves, the latter can be made of an elastic material that supports the unfolded form even without filling the form with gas. Elastic elements, such as elastic string (s) or elastic tape, can be embedded in the sleeve (for example, glued or welded). To prevent defective filling of all sleeves in case of damage to one sleeve or volumetric shape, it is advisable to use a check valve 8 in each sleeve. Valves 8 can be made soft adjacent to the sleeve (sleeves) that do not occupy additional volume in the garnet. After full unfolding of the inflated sleeve and, accordingly, the exhaustion of the stock of liquefied gas, the gas-air mixture is initiated in the unfolded sleeves using a thermal or detonation impulse carried out with the help of initiator 9 (igniter or detonator) with starting from retarder 10 retarding time started by folding safety lever 4 grenades, or pulling out safety checks grenades, or folding safety lever 4 grenades (after pulling out eki). In various technical versions of the grenade, the crane 3 (or the valve) can be opened immediately after affecting the check or lever tilting or with a time delay using an additional timer (not shown in Fig. 1), so that the sleeves begin to swell not in flight, but after the fall of the grenade to the ground.

As an example, consider a grenade with unfolding arms in the form of a flat N-ray star (N> 1), with a tank inside the grenade case located in the center of a star filled with liquefied propane with a volume of 125 cm ³ . The volume of gasified propane will be about 32 liters. The volume of the mixture of 32 liters of propane with air, obtained in the ejector, should be about 789 liters, while the content of propane in the mixture is close to stoichiometric (4.03%). However, to increase the explosion pressure and the rate of increase of this pressure, it is advisable to reduce the amount of air in the mixture to a value less than the stoichiometric composition, i.e. until the content of propane in the mixture is more than 4%, namely, up to 6 ... 7%.

With a diameter of a cylindrical unfolded hose with a diameter of, for example, 100 mm to accommodate 789 liters of propane - air mixture at atmospheric pressure, the sleeve should be 101 m. Given the length of one sleeve, for example, 4 m, we get the maximum number of sleeves stars), which will be 101 m / 4 m = 25 pcs. Since the sleeves are deployed under excessive pressure and under excessive pressure, they must keep their shape until the gas mixture is initiated in them, the maximum volume of the sleeves under a slight excess pressure will be less than 789 liters, and, accordingly, the number of sleeves will be less than 25 pieces. Nevertheless, a grenade, even with 15 ... 20 rays - with sleeves during blasting, will be largely equivalent to affecting sound pressure on an area of at least 50 m ² . In this case, however, due to the greater density of rays in the center of the star, the sound effect will be more intense near the center of the star. In the case of giving a developable sleeve a different shape, for example, a circle with a single beam coming out of the center (grenade body), at least theoretically the total area affected by sound pressure can reach values of the order of 100 ... 300 m ² , however, due to the fact that the sound wave will converge to the center of the circle of the blasted sleeve, in which case the sound effect near the center of the sleeve’s circumference may be greater than at the periphery of the sleeve’s circumference.

FIG. 2. In an embodiment with an “internal oxidizer” (the fuel oxidizer is compressed, liquefied or adsorbed gas contained in the tank inside the grenade) the grenade consists of a housing 11 that houses a tank 12 containing liquid fuel, mainly in the form of the above liquefied gases or mixtures thereof, and a reservoir 13 containing a gas oxidant, for example, nitrous oxide, or oxygen, or nitrogen tetroxide, located in the reservoir (depending on the properties of a particular gas) in a compressed, liquefied, or adsorbed form . The tanks 12 and 13 have a crane 14 (or valve) or a valve 15 (or valve), respectively, opened with the help of a folding safety lever 4 grenades, or pulled out safety grenade checks, or opened after pulling out checks of the safety lever 4 grenades. Valves (or valves) can be combined into one multi-port valve. In different versions of grenades, the taps 14 and 15 (or valves) can be opened either immediately after the impact on the check or lever tilting, or with a time delay using an additional timer (not shown in Fig. 2).

When opening taps or valves, the liquefied gas enters the evaporator (not shown in Fig. 2), and then into the mixer 16, or directly into the mixer 16 or the fuel injector nozzle. At the same time, a gas oxidizer enters the evaporator, the mixer 16, or the oxidizer nozzle of the mixer. In the mixer 16 or directly next to the fuel and oxidizer nozzles, the fuel and oxidizer are mixed, the resulting mixture enters the unrolling sleeve 7 made of polymer or elastic material hydraulically adjacent to the mixer or injectors. A sleeve or several sleeves begin to unfold (swell) due to the excess pressure of the fuel and oxidant entering them. The rate of receipt of fuel and oxidizer in the gasified state into the sleeve (s) is chosen so that the full deployment (swelling) of the sleeve (s) takes place in a time not exceeding a few seconds. To improve the conditions of filling the sleeves, the latter can be made of an elastic material that supports the unfolded form even without filling the form with gas. Elastic elements, for example, elastic string (s) or elastic tape can be embedded in the sleeve (for example, glued or welded). After full unfolding of the inflated sleeves and, accordingly, the fuel and oxidizer are exhausted, in tanks 12 and 13, the gas mixture is initiated — the oxidant in the expanded sleeves or other forms — with a thermal or detonation impulse carried out with the help of initiator 9 started from a timer - a retarder 10 activated with a folding safety lever 4 of a grenade, or pulled out a protective grenade check, or pushed back after pulling out a safety lock Foot lever 4 grenades.

The use of liquefied propane or propane-butane, propylene, ethylene oxide, MARP-gas (Mappgas), dimethyl ether (DMO) or their mixtures is most appropriate as a liquefied combustible gas. The tank for their storage in a grenade must withstand a pressure of no more than 5 ... 10 atm, i.e. may be thin-walled and lightweight.

Liquefied nitrous oxide or nitrogen tetraoxide can be used as a gaseous oxidizing agent. The use of nitrogen tetroxide is less advisable due to its toxicity (i.e. the need to use special measures during storage in pomegranate) and a high boiling point, which excludes the use of garnet at low temperatures. Due to the relatively high pressure in the tank containing nitrous oxide in the garnet and, accordingly, a considerable thickness of the tank walls, and hence its weight, it is possible to use a thin-walled tank with nitrous oxide adsorbed on the absorber (for example, activated carbon). In adsorbed form, it is also advisable to store oxygen in an oxidizer garnet. Approximately we can assume that in a unit volume of the selected adsorbent it is possible to store approximately 100% by volume more gas than in the same volume with the same pressure of compressed gas. Oxygen as an oxidizing agent can be stored in a grenade tank and in compressed form, although in this case the thickness of the walls of the storage tank the amount of oxygen necessary to produce an explosive gas mixture, and, accordingly, the weight of the tank may be excessive. At the same time, mixtures of combustible substances with nitrous oxide and oxygen have increased (as compared with mixtures of combustible substances with air) the lower and upper explosive limits (LEL and ERW). For example, a mixture of propane - butane with oxygen has 100% larger LEL and ERW, than a mixture of propane - butane with atmospheric air. This allows grenades with an "internal oxidant" to introduce a smaller amount of gaseous oxidant into the gas mixture filling the sleeve or another volumetric form than the amount of atmospheric air to effect an explosion with the same fuel in garnets with an "atmospheric oxidant."

In garnets with an “internal oxidizing agent”, it is possible to use a liquid combustible substance with a higher boiling point than the above-mentioned combustible substances, for example, diethyl ether. In this case, to form a gas mixture, the liquid fuel must be sprayed into a unrolling sleeve or other volumetric form by the pressure of a gas - propellant, for which it is advisable to use an oxidant gas.

The proposed grenade can have two modes of rupture. Soft impact mode and hard impact mode. Changing the mode of exposure is achieved by changing the method of initiating a gas mixture of fuel - an oxidizing agent in an unfolding sleeve or other bulk form. The initiation of a gas mixture by a thermal impulse from a flame source or heated electrospiral, initiation from an electric spark discharge with some energy in the impulse or initiation using a detonator causes explosive effects of different nature: from laminar deflagration to deflagration explosion and detonation. At the same time, regardless of the method of initiating the gas mixture, the effect of sound exposure will increase when the gas mixture is initiated along with the oxidizing agents: atmospheric air; nitrous oxide; nitrogen tetroxide; oxygen.

In variants of grenades with the initiation of a gas mixture by a thermal impulse from a heated electric helix or electric spark discharge, it is necessary to use an electric power source, for example, an electrochemical current source (EChIT) for long-term storage in a charged state (in particular, a lithium battery), or a piezoelectric generator, or magnetic pulse electric generator (MIG). When used in EHIT versions of the EHIT, the retarding timer can be made as an electronic unit and use power from the EHIT, and electrical safety devices can be used to prevent abnormal start-up (without a mechanically pull-out safety check, a folding safety lever, etc.), for example , pushbutton fuse, easily reprogrammable for different deceleration times. It is also possible to equip grenades with an electronic fuse with a radio control, for the remote initiation of grenades, used, for example, as stationary special means for the protection of objects, etc.

In garnets with an “internal oxidizing agent,” a regime of “hard” exposure (detonation) can be achieved even without the use of special detonators. In “atmospheric oxidant” garnets, the detonation mode without using detonators can be achieved by increasing the length of the pre-detonation area in longer and larger-diameter sleeves (sleeve), because with the same weight as the “internal oxidizer” grenade in “atmospheric oxidant” grenades the volume (length, diameter) of the inflatable arms may be greater due to the larger volume of gasified fuel and the work of the ejector of atmospheric air suction for mixing.

FIG. H. Forms of deployment of sleeves or other volumetric forms of the proposed grenade can be very diverse. The optimal deployment of the sleeves so that the resulting body has such an arrangement of the blown elements that evenly covers the maximum area from the extreme elements of the deployable forms to the body of the grenade. For example, in FIG. 3a shows a star shape, FIG. 3b is a spiral shape, in FIG. 3c - kolovrata form (17 - grenade, 18 - unfolded sleeve or sleeves).

The position of the grenade after its fall to the ground near the target does not matter, since the sleeves at any position of the hull, starting to unfold, set the hull of the grenade to a position convenient for the further deployment of the sleeves on the ground plane.

Deploying grenade sleeves with their chaotic straightening and throwing sleeves resembling the monster's tentacles to the sides should give the aggressive mob an additional synergistic effect of grenade fear and a desire to leave the grenade deployment place as quickly as possible before they are detonated.

The initiation of a gas mixture can be performed simultaneously in all deployed sleeves (other volumetric forms), or, for example, sequentially (pulsed mode of detonation), or according to another program defined by timers. For example, for the above-considered grenade in the form of a flat multi-rayed star, the blasting program may suggest the simultaneous blasting of all the sleeves — the star’s rays, or the successive blasting of all the sleeves — the star’s rays one after the other in a circle, or consecutive (or in a different order) opposite the center of the star formed by the grenade body. The impulse mode of action of a grenade is most preferable for exerting a psychophysical effect on offenders.

Unlike light-sound grenades containing condensed light-sound pyrotechnic mixtures, the proposed garnet has a much milder traumatic effect when it is detonated, while it is distributed over a much larger area. When an elastic shell of an unrolled sleeve (s) breaks, the pressure of explosion products (even in the immediate vicinity of the shell in deflagrating and even detonating gas mixtures is oxidizer) is much less than the pressure of the explosion near the surface of the grenades with light-sound pyrotechnical condensed mixtures when they explode or detonation at low speeds, which occurs in light-sound grenades - analogues. Therefore, the traumatic risk for people, even when the sleeve (sleeves) or other volumetric form is undermined close to the human body, is orders of magnitude lower than from the close break of well-known light-sound charges of grenades analogues. At the same time, the acoustic effect when a sleeve or other volumetric shape is blown extends to a much larger affected area due to the spatial deployment of the sleeve or another volumetric shape, reflection and partial focusing of sound waves with divergence on surrounding targets, for example, when deploying sleeves in star-shaped with the body of the proposed grenade in the center.

The proposed grenades are distinguished by lower injury risk in comparison with light-sound grenades by analogs also because they do not form solid fragments of even a hard polymer case when they break, like grenades are analogs. At the rupture of the proposed grenade, only small safety-proof fragments of the thinnest polymer sleeve can be formed when a gas mixture of fuel and oxidizer is detonated, or larger fragments in the case of turbulent combustion of fuel and oxidizer. Compared to thermobaric hand grenades, the action of the proposed grenade is incomparably less traumatic because the proposed grenade does not contain condensed explosives, fragmentation shirt, does not have an incendiary effect and gives only focal overpressure centers in an explosion, and not a general area of overpressure in the spraying and mixed explosion radius fuel composition thermobaric grenades. Reduced injury risk is also achieved by the fact that, unlike light and sound grenades, which are analogous to an explosion, a gas mixture explosion does not form high-velocity particles of metal fuel scattering from the explosion site, condensed oxidizer and solid heated products of the explosion, the effect of which on people's organs of vision can cause serious ( up to blindness!) eye injuries.

Equipment in the proposed grenades of the sleeve (sleeves), in addition to the equipment itself explosive gas mixture when deploying a grenade, can be very diverse. For example, to obtain additional sound and to obtain intense light exposure, a sleeve or other form can be equipped with fine aluminum, magnesium, or their alloys. During the explosion of a grenade, metal combustible ignite, spray and burn out due to the oxygen of the air. To obtain an additional smoke-generating effect, a sleeve or other form can be equipped with liquid smoke-generators sprayed with an explosion of a sleeve or another form. To obtain additional irritant, for example, tear and spasmodic effects, a sleeve or other volumetric form can be filled with capsaicin liquid solutions or chloroacetophenone powders, chlorobenzalmalondinitrile powders, or their mixtures.

To obtain an additional offender-marking effect, a sleeve or other form can be equipped with a liquid, indelible or solid powder-like dye.

Combined equipment is also possible, for example, with indelible dyes with capsaicin.

These additional active substances are introduced into the sleeve or another form in the manufacture of grenades, for example, in the form of easily shake-off coating (for example, dusting) the inner surface of the sleeve, or coating the inside of the sleeve with additional active substances on the film former with increased brittleness, destroyed by the explosion of the sleeve with the transformation into powder and aerosol containing the destroyed film former and said additional active substances.

Due to the fact that in the proposed grenades an explosive gas mixture is formed and acquires volume only when filling and unfolding sleeves or another volumetric shape, grenades can be stored with an initiating device attached to them, which is unacceptable when storing grenades - analogues (storing light-grenades with fuses and / or fuses are unacceptable). The impossibility of unwrapping the sleeves, as well as protection from the integrity (punctures and other damage) of the sleeves during storage and transportation, is provided by a cover worn over the folded sleeves, or other unfolding protection devices, such as strapping a grenade with a cord or tape, easily removed before use .

Laying the unfolding sleeves on top of the grenade body makes its outer surface soft, which ensures a lower risk of injury when the grenade that we offer is hit, for example, in a person’s head in an aggressive crowd.

Reduced injury risk is also achieved by the fact that, in contrast to the explosion of light-sound grenades - analogues, the explosion of the gas mixture does not form high-velocity particles (unburned particles of metallic fuel, condensed oxidizer, solid heated metal oxides of the explosion, etc.) scattering from the explosion site, the impact of which on the organs of vision of people can cause serious injuries, including blindness.

In the event that the proposed grenade falls into the hands of offenders (for example, as a result of theft or weaning from law enforcement officers), their alteration into grenades that can be used to commit serious crimes (for example, using homemade fragmentation shirts) is completely impossible for the proposed grenades.

Links used:

1. http://www.dogswar.ru/boepripasy/granaty/7392-rychnye-svetozvykovy.html

2. http://niiph.ru/index.php?dir=special

3. http://pirochem.net/index.php?id1=3&category=azgotov-prim-vv&author=dik-vn&book=2009&page=99

4. https://vk.com/video124116536_167363117?list=3c863af2c54b3a9173

5. http://uargument.com.ua/politika/kak-revolyutsioneryi-bili-soldat-srochnoy-sluzhbyi/

6. Tender of the Ministry of Internal Affairs of 02/15/2016, “Name of the object of purchase: 464-2015АЭ Grenades” http://zakupki.gov.ru/epz/order/notice/ea44/view/common-info.html?regNumber=0173100012515000443

7. Tender of the Ministry of Internal Affairs of August 29, 2014. Name of the object of purchase: “Hand grenade of irritating and light-sound effects of increased power“ Drofa-PM ”https://zakupki.kontur.ru/0342100003114000353

8. RF patent №2209806 “Explosive composition of multifactor action of increased power”

9. Application for the invention of the Russian Federation No. 2009129232 "Energy-intensive explosive composition"

Claims (17)

1. Non-lethal grenade, comprising a housing with combustible or combustible and separately contained oxidant, a depressurization device made in the form of at least one valve or tap, at least one timer, ejector, or mixer, or openings for fuel and oxidant, at least one unfolding sleeve made of polymeric or elastic material, at least one device for initiating an explosive gas mixture of a fuel and an oxidizer. 2. Non-lethal grenade according to Claim. 1, characterized in that said depressurization device is launched from a mechanical effect on the control elements similar to the control elements of combat hand grenades. 3. A non-lethal grenade according to claim 1, characterized in that said timer is started from mechanical effects on controls similar to combat hand grenades. 4. Non-lethal grenade according to Claim. 1, characterized in that said timer is a time delay device of a mechanical, chemical, pyrotechnic or electric type. 5. Non-lethal garnet according to Claim. 1, characterized in that said fuel and oxidant are gasifying liquids, or compressed gases, or adsorbed gases. 6. Non-lethal pomegranate according to claim 1, characterized in that said liquid fuel is a liquefied combustible gas. 7. A non-lethal pomegranate according to Claim. 1, characterized in that a chemical irritant or smoke generator or mixtures thereof is contained in the internal volume or on the inner surface of the said sleeve. 8. Non-lethal pomegranate according to claim 1, characterized in that fine metal fuel is contained in the internal volume or on the inner surface of the said sleeve. 9. Non-lethal pomegranate according to Claim. 1, characterized in that a liquid or fine dye is contained in the internal volume or on the inner surface of said sleeve. 10. Non-lethal pomegranate according to Claim. 1, characterized in that said body is at the same time a container for storing said liquid fuel or liquefied, compressed or adsorbed oxidant. 11. The non-lethal grenade according to Claim. 1, characterized in that said sleeve is laid in the folded state over said housing. 12. Non-lethal grenade according to Claim. 1, characterized in that said sleeve is made elastic or has built-in elastic elements. 13. Non-lethal grenade according to Claim. 1, characterized in that said sleeve has a cover or other protective device against deployment and destruction. 14. Non-lethal garnet according to claim 1, characterized in that said device for initiating a mixture of fuel and oxidant is a fuse or fuse of a mechanical, chemical, pyrotechnic or electric type. 15. Non-lethal garnet according to claim 1, characterized in that said device for initiating a mixture of a fuel and an oxidizer of an electrical type has a power supply. 16. Non-lethal garnet according to claim 1, characterized in that said device for initiating a mixture of fuel and oxidant is capable of producing a thermal, spark, or detonation initiating impulse. 17. Non-lethal garnet according to claim 1, characterized in that several of said devices for initiating a mixture of fuel and oxidizer are capable of issuing initiating pulses sequentially or according to another program specified by said timer.

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