UA105913U - BORONBEAN THERMOBARIC BATTLE - Google Patents

Abstract

The armor-piercing thermobaric warhead comprises a housing, a fuze, an additional detonator and a thermobaric charge having a detonation velocity of at least 6000 m / s and consisting of metallic fuel in the amount of 25-50% by weight, explosives and decomposing components. In the main part of the warhead between its body and the surface of thermobaric composition there is a cavity. An additional detonator is located in a glass with a height of 100-500% of its diameter and a wall thickness of 0.5-10% of its diameter and is immersed in a thermobaric charge to a depth of at least 150% of its diameter.

Description

The useful model belongs to the field of military equipment and weapons, in particular to the armor-piercing thermobaric warhead (BU) of shells.

Thermobaric charges contain an explosive substance (BP), which ensures the detonation of the charge, fuel, which ensures an increase in the temperature of the products of the explosion and the heat of the explosion, as well as components that, under the action of a high-intensity shock wave (with a pressure in the front of the shock wave above a certain value), are able decompose into reactive products.

A detonation wave is a complex of a shock wave and a chemical reaction zone. When a shock wave passes through a shock wave, it causes its decomposition with the release of energy, while part of the energy of the shock front is consumed. The energy released in the chemical reaction zone of BP causes the formation of compression waves that catch up with the shock wave and compensate for energy losses. In the stationary mode of detonation, the amount of energy spent by the shock wave is equal to the amount of energy entering it. The amount of energy expended is proportional to the square of the detonation rate (pressure), and the amount of energy supplied is simply proportional to the detonation rate. Therefore, if the detonation rate is less than steady state, then the amount of energy input is higher than the expenditure, and then the pressure, and hence the detonation rate, increase until equilibrium is reached. However, with insufficient initiation, the so-called low-speed detonation may occur, when the stationary mode is achieved due to the energy of one of the components of the composition, which has a high decomposition rate and a low critical initiation pressure.

In this case, all other components do not have time to react within the chemical reaction zone. Therefore, insufficient initiation for such compositions (which include the used thermobaric compositions) qualitatively changes the mechanism of detonation and the characteristics of the charge.

Aluminum, magnesium, silicon, boron or their combinations are most often used as fuel - because they give the best burning temperature in combination with availability and reasonable cost.

Liquid, for example, nitro-organic substances (isopropyl nitrate, ethyl nitrate, nitromethane, etc.) can be used as components that decompose in the detonation wave, which, among other things, are themselves a weak BP and thus contribute to a faster start of chemical reactions in the cloud, which increases the reliability of cloud initiation and the completeness of fuel combustion in the detonation mode, as well as solids, including ammonium or potassium nitrates, ammonium or potassium perchlorates,

From fluoroplastic, etc.

In the components decomposing in the detonation wave, chemical bonds are broken under the action of the shock wave, which causes the formation of reactive radicals (active decay products). At the same time, the thermal effect of the decomposition reaction of these components at the first stage can be very insignificant or even the reaction can be endothermic, i.e. go with energy consumption. Decomposition of these materials in the detonation wave leads to the appearance of reactive components in the detonation products, which interact in the chemical reaction zone with the fuel and with each other and with the release of additional energy, and the formation of new active radicals due to secondary reactions of the diffuse type. At this stage, due to secondary reactions, such products as hydrogen, carbon monoxide, carbon and hydrocarbon radicals are formed.

During the expansion of the explosion products and access to the air detonation products, further oxidation of this hydrogen, carbon monoxide, carbon and hydrocarbon radicals, as well as the remaining unreacted fuel occurs.

To start the decomposition of a substance in a shock wave, the molecules of the substance need to obtain a certain minimum (critical) energy from it. The amount of thermal energy received by a substance from a shock wave is proportional to the detonation pressure or proportional to the square of the detonation speed. The higher the value of the energy received by the substance (the higher the detonation rate), the higher the rate of decomposition of the substance in the detonation wave.

Document Sh5Z4074628A discloses a cylindrical container in the form of a truncated cone for obtaining an explosive cloud aerosol, having a ruptured upper wall that collapses first, forming a pancake-shaped cloud, and a thickened control ring surrounding the lower part of the wall, which collapses last. The container belongs to the two-stroke munitions of volumetric explosion. It has no armor-piercing and fragmentation effect.

From patent OO56293201, a warhead containing a complex energy composition is known: cyclodextrin nitrate, plasticizer ether nitrate, bismuth subsalicylate and a stabilizer, in the form of individual small balls that disperse in the form of a cloud before impact on the target. Upon impact with the target, the balls explode without the use of a detonator due to the high sensitivity of the composition to impact. Such composition is not thermobaric and does not have a noticeable armor-piercing effect, as well as an oskCoOolkovy effect.

From document 052014182473A1, a thermobaric ammunition is known, which consists of a thick-walled case in which a combined charge is located. The combined charge consists of a central charge made of explosive BP and a pressed peripheral charge made of a mixture of aluminum powder (9095) and polytetrafluoroethylene (1095), which is located between the body and the central charge. The peripheral charge is dispersed during the explosion of the central charge and due to the combustion of aluminum in air provides a thermobaric effect. The best variant of the implementation of this invention includes a system with a thick-walled warhead, which contains a container and a cylinder of metal-enriched charge, located in the container, so that the specified cylinder is in contact with the inner wall of the container. In addition, the explosive substance is located in the cylinder with the detonator in direct contact with the high explosive substance, so that the detonator detonates the high explosive substance. This thermobaric ammunition does not have an armor-piercing effect and has a weak fragmentation effect (shredding the case and throwing fragments is provided by a central charge, the effect of which is greatly weakened by a non-detonating peripheral charge).

From patent B2917O1, a mine with a main detonator and feathering is known, has a body filled with a thermobaric charge, a pressure compensator (protection against thermal expansion of the liquid composition) and a sleeve with an additional detonator. The mine has neither an armor-piercing nor an anti-tank effect.

From the utility model patent of Bulgaria ВЕ125501, a thermobaric ammunition is known, which includes a case filled with a thermobaric charge and a pressure compensator, and an additional detonator is placed along the axis of the charge, the mass of which is from 595 to 20 95 of the mass of the thermobaric charge (for reliable initiation). Like the previous solution, it does not have an armor-piercing and fragmentation effect.

From patent Ba63552, a two-section warhead containing a chamber divided into two parts, separated from each other by a metal partition, is known. A liquid thermobaric composition (suspension) is located in the main part, and a standard explosive composition is located in the rear part. Blocks with ready-made striking elements can be placed in the back of the ammunition to increase the striking effect.

The charge is initiated by the main detonator, so the thermobaric charge is initiated first, and the explosive charge is initiated from it. This technical solution, in comparison with ammunition equipped only with a thermobaric composition, has a reduced

From the thermobaric effect, since the thermobaric effect is inherent only to part of the composition. Compared to ammunition equipped only with high-explosive fragmentation, the proposed ammunition also has a lower fragmentation effect, since the main part of the ammunition has a reduced fragmentation effect due to the characteristics of the liquid thermobaric mixture used. In addition, the low detonation speed of the thermobaric composition (detonation pressure) when initiated through the partition of the explosive composition causes the formation of a transient low detonation area (with a low detonation speed and, accordingly, with a lower fragment speed), the length of which, with insufficient initiation, is up to 10 charge diameters. Therefore, this design does not provide sufficient fragmentation effect not only of fragments formed from the main part of the case, but also fragments from the bottom part of the case and ready striking elements.

From patents B21707O and VSs17080, respectively, a thermobaric grenade with a main charge made of a solid composition and an additional detonator made of explosive composition, the ratio of the mass of which to the mass of the charge is from 1/12 to 1/20, and a thermobaric warhead in a thin-walled case with a main charge of of solid composition and an additional detonator of explosive composition. All these munitions do not have a fragmentation shell, and the composition contains metal fuel, salts of inorganic acids, high-explosive BP and binder made of rubber with a plasticizer (this composition has a low detonation rate due to the content of a large amount of binder and salts of inorganic acids and does not provide high armor-piercing or fragmentation action). These solutions do not have an armor-piercing or anti-tank effect.

From the patent NI2402741, an ammunition with a cylindrical body with a liquid filling in the form of a detonable suspension of metal powder in a combustible liquid is known, and a central shell with a detonator fixed on a transverse diaphragm, which carries an axial check of an incendiary pyrotechnic composition, while the central shell is made with a bell on the edges, which forms annular gaps relative to the adjacent detonator, and the checker of the incendiary pyrotechnic composition with a mass of 2-4 95 from the mass of the liquid filling is divided into two autonomous charges, displaced from the middle of the detonator. This ammunition has a thermobaric effect, but it does not have an armor-piercing effect (there is no data on the effectiveness of the fragmentation effect).

From the patent NO2291376, a missile is known, which contains an elongated warhead with a main detonator, which includes a body filled with a liquid-flowable detonating mixture with a spherical head and a transverse diaphragm fixed on it, an axial detonator and a solid-fuel jet engine, while it is equipped with bearing shells and a disk membrane , made of a set of plate springs, centered on the shielding cap of the projection of the axial detonator, equipped with a projectile charge, inside which the ignition pyrotechnic composition is placed axially, while on one of the rods an elongated warhead with the main detonator is mounted, and on the other a spherical head is fixed, which rests on the disk membrane, the spherical head is made of thick wall and filled with condensed explosive substance, and the body is made of corrugated inside. The missile does not have an armor-piercing effect.

From the patent NO2401978, a high-explosive warhead part of the missile is known, which contains two consecutive sections separated by a common line, while the invigorating body of the high-explosive section is filled with a condensed weapon, adjacent to the main igniter and to the central detonator of the high-explosive section, placed inside the detonating liquid filling of the cylindrical shell and mounted in the transverse diaphragm, while the separator is made in the form of a damping device, which includes a plate shock absorber and an air buffer, in the axial hole of which the central detonator of the high-explosive section is fixed, and the mass of the condensed weapon of the main fragment section is 4-5 times greater than the mass of the liquid filling of the high-explosive section . The proposed solution does not have an armor-piercing effect.

From the patent VO2291377, a high-explosive warhead part of a rocket is known, containing a main detonator, a case, a detonating charge, a central detonator and a transverse diaphragm, which performs the function of a shock wave reflector, and the case consists of the main high-explosive fragment section and a high-explosive section mounted on carrier, while the fragmentation section is filled with condensed explosive and has semi-finished striking elements inside, and the high-explosive section consists of a tubular shell with a bottom filling unit, filled with a detonating filling, which is liquid. The proposed solution is also not armor-piercing.

From the patent NO2357197, a volume-detonating warhead of a rocket is known, which contains a body, a shell, a combustible composition, a detonator and a propellant charge, the shell is made of inner and outer tubes connected by annular end bottoms, and the inner tube of the shell is made with a variable length with a diameter that increases in the direction

From the detonator. Such a warhead allows you to control the size and shape of the fuel cloud, has a thermobaric, high-explosive, but not armor-piercing effect.

From the patent NO2291378, a projectile is known, which contains a rigidly connected engine and an elongated warhead, the body of which is filled with a detonating liquid mixture, where the central shell with a dispersive explosive charge connected to the main detonator and a transverse shock wave reflector are located. The dispersive charge by means of a calibrated dose in the reflector, made in the form of a concave truncated cone, is connected through an axial fire transmission tube with a pyrotechnic initiating composition of a metal charge of ready striking elements packed in a cylindrical cassette mounted in the bottom part of the warhead, while the shock wave reflector, functionally separating thin-walled the case for the main high-explosive and bottom fragmentation section, fixed on the supporting frame. The striking effect of the projectile is increased due to the proposed two-section design. The projectile has thermobaric, high-explosive fragmentation, but not armor-piercing action.

Patent 57571680 discloses a collapsible fuel-containing ammunition container for military aircraft drop, which has an accordion-like structure, does not explode on impact, and after being dropped, forcibly disperses the fuel up, around, and beyond the impact zone.

The fuel is then ignited with a lighter or other source of fire. This is an incendiary solution, not a thermobaric ammunition.

From patent 2482428083, a method of controlling the speed and direction of detonation of a warhead in a warhead by using two detonators, detonation cords and a charge of different types is known

BP (or the same type of BP with different densities) with different detonation speeds to control the direction of detonation and fragmentation action. There are two cavities in the warhead - one is located in the main part, intended for one of the detonators, the other is located in the center of the charge.

The central axial cavity is used to control the force and direction of the explosion. In one embodiment, the warhead contains liquid BP. Such a warhead has a fragmentation but not a thermobaric effect.

Patent 482442382 discloses a method of controlling the speed and direction of detonation of a warhead in a warhead using detonation cords and various types of warheads, including liquid (with different detonation speeds) and a cavity into which a liquid warhead can be quickly pumped through a valve, which contains a central axial cavity , and the space between the shell and the cavity is divided into sectors filled with liquid BP, and each sector has a passage to the cavity. This solution is a development of the previous one, described in patent 82428083, and also does not have a thermobaric effect.

From the patent HO2427785, a high-explosive munition of directional action is known, which contains a case, an initiation system, an external hollow cylindrical explosive charge with a high detonation speed and an internal explosive charge with a lower detonation speed, the detonation speeds of which are given as 1:(0.7- . a - the diameter of the internal charge.This ammunition has a thermobaric and high-explosive effect, but not an armor-piercing effect.

A cumulative ammunition is known from patents C272533101 and 5K50021201301, in which the explosive composition is replaced by a thermobaric one. However, such a solution has low armor penetration relative to the thickness of the pierced armor compared to ammunition with high-explosive composition, since for a cumulative jet, armor penetration depends only on the speed of detonation (detonation pressure) and does not depend on the energy characteristics of the composition. In addition, when piercing the armor with this ammunition, the hole is very small in diameter, which does not provide sufficient barrier action of the afterburning products of the thermobaric charge penetrating through it for the armor (since their number is proportional to the diameter of the hole squared). Also, such ammunition does not have a fragmentation effect.

From patent 57418905, a rocket with a collapsible nose tip and a relatively rigid nose cone of penetration to the target is known. The nose cone may have a liquid fuel tank inside and a chemical energetic explosive charge, such as a cumulative charge behind the liquid fuel tank. The nose cone of target penetration provides perforation of certain types of targets before the detonation of the chemical energy of the explosive substance and liquid fuel. The destroyed nose tip is designed to be easily penetrated or otherwise dislodged by the explosive force of the chemical energy of the explosive charge when the missile complex is used to attack solid targets. The payload in the nose can be fragmentation, with means designed to increase fragmentation upon detonation of the explosive and/or liquid propellant.

Zo This rocket with liquid jet fuel has a tandem warhead consisting of an armor-piercing element (armor-piercing projectile) with a ballistic tip (easily destroyed when meeting an obstacle) or a cumulative charge and a second high-explosive fragmentation ammunition. The armor-piercing element pierces the armor and a second projectile penetrates the hole, which provides increased anti-barrier action.

The disadvantages of this solution are that the warhead has only an armor-piercing effect. Also, the filling factor is very low (low mass of the warhead compared to the mass of the entire warhead) and, as a result, the low-explosive effect of the warhead. There is no thermobaric effect. To increase the high-explosive effect of the rocket, detonation of the remaining liquid rocket fuel can be used (this has nothing to do with the design of the warhead and is used on missiles with any warhead).

As can be seen from the analysis of the existing level of technology, thermobaric ammunition does not have an armor-piercing effect. On the other hand, armor-piercing munitions do not have a thermobaric effect, that is, they have a low high-explosive effect (a TNT equivalent of 1 to 1.5) in the absence of an impressive effect on sheltered targets (for example, no damage to manpower in trenches and shelters). So, the combination of armor-piercing, in which a large-diameter hole is formed, and the thermobaric action of the main charge makes it possible to obtain a high and impressive anti-barrier effect.

In cumulative ammunition, the cumulative jet is formed from part of the cumulative funnel (the jet has a high speed and a small diameter). In an ammunition with a striking effect of the "shock core" type, the entire mass of the element is compressed and thrown, due to this, the element has a significantly higher mass and diameter, but also a lower speed compared to a cumulative jet. Conventional munitions with a shock core penetrate armor, but have a low barrier effect (low effectiveness of damage behind pierced armor).

The basis of a useful model is the task of creating an armor-piercing thermobaric warhead or ammunition that combines high armor-piercing, thermobaric, high-explosive, and, if necessary, fragmentation action.

At the same time, armor penetration is carried out due to the blasting (crushing) action of the thermobaric composition, which is in close contact (after crumpling the main part), and the diameter of the hole in the armor is equal to the diameter of the charge. The second option is penetration by a projectile-forming element of the "impact core" type.

The proposed ammunition penetrates the armor with the formation of a large-diameter hole into which the detonation products of the thermobaric charge penetrate. The reaction of these products with air oxygen causes the release of a large amount of energy with the formation of compression waves (shock wave) and secondary (thermobaric) reaction products with the formation of new reaction products with high temperature. At the same time, the TNT equivalent in terms of the heat of explosion (high-explosive action) during the primary reaction with the formation of detonation products of thermobaric composition (heat of explosion during detonation without air access) is from 2.3 to 2.5 and during the secondary reaction with the formation of oxidation products due to the reaction with with air oxygen (heat of explosion with afterburning in air), the TNT equivalent of the composition is from 3.8 to 4.3. Thus, as a result of the joint use of all these factors, a universal ammunition is obtained, which combines the effectiveness of conventional thermobaric ammunition and armor-piercing ammunition (and in the presence of a fragmentation shell, also the effectiveness of high-explosive fragmentation ammunition) with an additional higher efficiency of hitting armored targets at the expense of a significant increasing the anti-barrier effect of the ammunition.

In addition, for the variant with an impressive element of the "shock core" type, due to its greater mass and slower acceleration, the energy characteristics of the composition already significantly affect its speed and formation. Therefore, when using the "impact core" in the design, both an effective armor-piercing effect and a high striking effect behind the armor are obtained.

The task of a useful model is solved by an armor-piercing thermobaric warhead containing a case, a detonator, an additional detonator and a thermobaric charge consisting of a metal fuel in the amount of 25-50 95 by weight, an explosive substance and components that decompose in a detonation wave, while a thermobaric charge has a detonation speed of at least 6000 m/s, there is a cavity in the main part of the ammunition between the body of the warhead and the surface of the thermobaric composition, and the additional detonator is located in a cup with a height of 100-500 95 from its diameter and a wall thickness of 0.5-10 95 from its diameter and immersed in a thermobaric charge to a depth of at least 150 95 from its diameter.

At a detonation speed of a thermobaric charge of more than 6000 m/s, a sufficient depth of the primary stage of decomposition of all active (decomposing in the detonation wave) components is provided, which ensures a sufficiently high temperature of the explosion products and concentration

Of the reactive components that are necessary for the effective course of oxidation of the explosion products in the second stage during their interaction with air oxygen.

In addition, the detonation speed of the thermobaric charge is more than 6,000 m/s, providing a high fragmentation and explosive effect of the thermobaric composition.

Preferably, the ratio of the volume of the cavity to the volume of the thermobaric charge in the range from 1:50 to 1:10 ensures maximum penetration of armor, and for the variant of ammunition with a liquid component of the thermobaric composition, it additionally ensures the preservation of characteristics (stability) during long-term storage of ammunition and at high temperatures.

Preferably, the warhead additionally contains ready-made or semi-finished striking elements located in the cylindrical part of the body to ensure fragmentation action.

Preferably, the warhead additionally contains a formed striking element of the "shock core" type, located in the main part, and an explosive charge for its formation.

Preferably, the thermobaric charge consists of pressed checkers of a thermobaric composition, except for the checker in contact with the molded striking element of the "shock core" type, which consists of an explosive composition containing an explosive BP, such as hexogen or octogen, and a binder.

The body of the warhead is mainly made of aluminum or an aluminum alloy.

Preferably, the main part of the body of the warhead, in which the cavity is located, is made of aluminum or an aluminum alloy.

Making the case and/or the main part of the case from aluminum or its alloys ensures the rapid destruction of the main part of the ammunition and higher armor penetration (thickness of the armor penetrated).

Mostly, all the components decomposing in the shock wave are solid, and the thermobaric charge is made by pressing.

Preferably, one of the components that decomposes in the shock wave is a liquid, and an element made of a polymer with closed porosity, preferably of foamed polyethylene or polypropylene with a density of 5 to 50 kg/m3, is additionally placed in the cavity.

For a thermobaric composition containing a liquid, the presence of a porous polymer in the cavity ensures the preservation of the shape of the charge and prevents the composition from entering the cavity. In addition, the presence of a porous element with closed pores provides compensation for the thermal expansion of the liquid at high temperatures. Foamed polyethylene or polypropylene with a density of 5 to 50 kg/m3 (porosity from 98.5 95 to 99.5 95) can be used as a material for an element with closed porosity. These materials have a structure with closed pores, which excludes the ingress of the liquid component of the thermobaric composition into the pores. When the density of the material is less than 5 kg/m", the thickness of the material bridges between the pores decreases and there is a possibility of breaking the bridges with liquid entering the cavity, which leads to a change in the ratio of components in the thermobaric composition and a decrease in its characteristics. A porous element with a density of 5 to 50 kg/m" practically does not affect armor penetration. When the density of the material of the porous element increases by more than 50 kg/m? there is a noticeable decrease in armor penetration.

The fact that the additional detonator is placed in a cup with a height of 100-500 95 from its diameter and a wall thickness of 0.5-10 95 from its diameter and is immersed in a thermobaric charge to a depth of at least 150 95 from its diameter ensures reliable initiation of a thermobaric charge.

In case of insufficient initiation, low-speed detonation modes occur in the composition, which leads to a significant decrease in the effectiveness of explosive and baric action.

More preferably, the thickness of the walls of the glass is 2-4 95 of its diameter.

Preferably, the glass has a diameter of at least 25 mm and a wall thickness of 0.2-2.0 mm.

More preferably, the glass has a wall thickness of 0.5-1.5 mm.

Preferably, the additional detonator is embedded in the thermobaric charge to a depth of at least 40 mm.

Preferably, the glass, in which the additional detonator is located, is made of aluminum or its alloys.

Making the tumbler from aluminum or its alloys reduces energy losses during detonation transmission and additionally increases the reliability of initiating high-speed detonation.

Below are four examples of the implementation of a useful model.

In fig. 1-4 shows ammunition containing a case 1, a thermobaric charge 2, a detonator 3, an additional detonator 4, a cavity 5 in the main part of the case 6.

In the ammunition presented in fig. 2, cavity 5 is filled with an element of foamed polyethylene or polypropylene with a density of 5-50 kg/m3.

Ammunition presented in fig. C, additionally features a molded striking element

Of the type "shock core" 7, located in the main part, and a charge of high-explosive BP 8 for its formation.

Ammunition presented in fig. 4, additionally contains finished or semi-finished striking elements 9.

In the ammunition presented in fig. 1, fig. 2 and fig. 4, when meeting with armor, the main part of the body 6 is destroyed or crumpled due to the cavity 5 before the main charge is triggered. At the same time, thermobaric charge 2 comes into direct contact with the armor.

The activation of the thermobaric charge 2, which is in contact with the armor, due to the explosive action of the charge causes the destruction of the armor up to 20 mm thick. Detonation products of the thermobaric composition penetrate into the hole in the armor, which react with air and provide a high anti-armor effect of the ammunition.

For the munition with an impact core, presented in fig. Damage to armored vehicles occurs in the following sequence: the formation of a "shock core" 7 under the action of a high-explosive BP 8, then the penetration of the armor by the "shock core", then the pro-barrier action of the thermobaric charge.

Claims (16)

USEFUL MODEL FORMULA 1. An armor-piercing thermobaric warhead containing a case, a detonator, an additional detonator and a thermobaric charge consisting of a metal fuel in the amount of 25-50 95 by weight, an explosive substance and components that decompose in a detonation wave, which differs in that the thermobaric the charge has a detonation speed of at least 6000 m/s, there is a cavity in the main part of the warhead between its body and the surface of the thermobaric composition, and the additional detonator is located in a cup with a height of 100-500 95 from its diameter and a wall thickness of 0.5-10 95 from of its diameter and immersed in a thermobaric charge to a depth of at least 150 95 from its diameter. 2. Warhead according to claim 1, which differs in that the thickness of the walls of the glass is 2-4 95 of its diameter. 3. Warhead according to claim 1, which differs in that the glass has a diameter of at least 25 mm and a wall thickness of 0.2-2.0 mm. 4. Warhead according to claim 3, which differs in that the glass has a wall thickness of 0.5-1.5 mm. 5. Warhead according to any of claims 3-4, which is characterized by the fact that the additional detonator is embedded in the thermobaric charge to a depth of at least 40 mm. b. Warhead according to any of claims 1-5, which differs in that the ratio of the volume of the cavity to the volume of the thermobaric composition is from 1:50 to 1:10. 7. Warhead according to any of claims 1-6, which is characterized by the fact that its body is made of aluminum or an aluminum alloy. 8. Warhead according to any of claims 1-6, which is characterized by the fact that the main part of its body, in which the cavity is located, is made of aluminum or an aluminum alloy. 9. Warhead according to any of claims 1-8, which is characterized by the fact that the cup in which the additional detonator is located is made of aluminum or its alloys. 10. Warhead according to any one of claims 1-9, which is characterized by the fact that it additionally contains finished or semi-finished striking elements located in the cylindrical part of the body. 11. The warhead according to any one of claims 1-9, which is characterized by the fact that it additionally contains a formed striking element of the impact core type, located in the main part, and an explosive charge for its formation. 12. The warhead according to claim 11, which is characterized by the fact that the thermobaric charge consists of pressed warheads of a thermobaric composition, except for a warhead in contact with a shaped striking element of the impact core type, which consists of a high-explosive composition containing a high-explosive substance (BP) , and the binder. 13. Warhead according to claim 12, which differs in that the explosive BP is hexogen or octogen. 14. The warhead according to any of claims 1-13, which is characterized by the fact that all components decomposing in the shock wave are solid, and the thermobaric charge is produced by pressing. 15. Warhead according to any of claims 1-11, which is characterized by the fact that one of the components that decomposes in the shock wave is a liquid, and an element made of a polymer with closed porosity is additionally placed in the cavity. 16. Combat part according to claim 15, which differs in that the element is made of foamed polyethylene or polypropylene with a density of 5-50 kg/m3. ; zhe rshe shn de Deco - KOKO ke MO ot ek SHO Mk PE k Kk Fig. 1 Fig. 2