LT6958B - Warhead - Google Patents

Abstract

A shaped charge warhead or a shaped charge with fragmentation warhead of caliber from 75 mm to 85 mm can be used in rockets, grenade launchers, and artillery systems. The warhead comprises a body, a safety and arming mechanism, an explosive charge, a waveshaper, a fairing, and a liner, wherein the outer surface of the liner, adjoining to the explosive, and the inner surface of the liner are made in the form of rotation surfaces. The generatrix of the inner surface is made in the form of a line without breaking points, located inside the figure formed by small arcs of two circles passing through the ends of the line segment connecting the base of the liner with the top, having radii equal to two and a half lengths of the specified segment. To increase the armour penetration, the liner thickness and the opening angle of the outer surface (for the special case of a cone) are correlated with the opening angle of the inner surface and the properties of the explosive used, which are determined by its composition and density.

Description

TECHNICAL FIELD

The invention relates to cumulative or cumulative fragmentation munitions, in particular 75-85 mm caliber, cumulative warheads or cumulative fragmentation warheads for the destruction of armored targets using a cumulative action and for the destruction of unarmored targets using a fragmentation action if there is a fragmentation component.

STATE OF THE ART

Unguided 80 mm anti-aircraft missiles, abbreviated NOR, are the most common anti-aircraft missiles. The NOR consists of two parts: a 78 mm caliber warhead and an 80 mm caliber rocket engine. The following modifications of the 80 mm caliber NOR with a cumulative fragmentation action are known: S-8, S-8A, S-8M, S-8KO and S-8KOM.

On the basis of NOR, guided aircraft missiles are being developed, in which the missile is directed at the target with the help of a laser control device. In addition, the NOR S-8 can be used from ground launch units. Thus, the historically established name "unguided aircraft missile" does not reflect all the possibilities of using this type of missile.

Tandem warhead S-8T with two charges - a main charge and a precursor to remove reactive armor, was designed to destroy armored vehicles with reactive armor.

There is a known technical solution for a warhead, which also has a main and secondary charges ("Unguided aircraft missile with a tandem cumulative charge". Patent RU2371667C1. Ashurkov A.A. etc., published 200910-27).

This invention relates to a main and secondary charge in warheads with a tandem scheme.

There is the NOR Medusa with an 81 mm caliber cumulative warhead, based on the Swiss and Italian SNORA and SURA families of missiles.

Also known is the Chinese Norinco PF-89 disposable grenade launcher. A rocket-propelled grenade with an 80 mm anti-tank HEAT warhead is fired from the launch container.

The RPG-7 hand-held anti-tank grenade launcher is widely used, mainly used to fire grenades with a caliber larger than the caliber of grenade launchers and, among other things, can be loaded with warheads of 75-85 mm caliber.

There are also other grenade launchers and artillery systems designed to fire 75-85 mm warheads.

There is an S-8KOM unguided anti-aircraft missile warhead 9-GZh-4421 (Sychev A.I., Martirosyan V.G., Pereskokov V.A. "Unguided anti-aircraft missiles of 80 mm caliber", 2019, p. 19-21, prototype). It consists of the following parts: a body closed on one side by a protective partition plate, an explosive charge, an inert wave shaper, a copper insert and a fairing.

The warhead is equipped with a V-5KP1 warhead, which consists of a safety and loading mechanism, abbreviated as SUM, and a piezoelectric generator. The electrical connection between them is provided by a conductor inserted into the wave shaper, a conductive cone and an insulating compression ring. The piezoelectric generator converts the mechanical energy of the missile impact on the target into the electrical energy needed to launch the SUM.

The body is a thin-walled aluminum tube that flares out at the front and has threads at both ends to connect the body to the fairing and the rocket part with the help of a body seal. A groove is made inside the front part of the body, into which an insulating polyethylene ring is inserted in the place where the base of the insert approaches the wall of the body.

The fairing ensures good aerodynamic properties of the missile and the necessary gap (distance) between the target and the base of the insert at the moment of impact on the target, and also plays the role of an external electrical circuit connection.

In addition to the detonator, which consists of the piezoelectric generator of the head and the SUM, bottom detonators are also used, activated by inertial breakers, springs or other means. There is a known small bottom detonator ("Bottom detonator". Patent RU2125706C1. Andrejkin P.V. et al., published on 01/27/1999), which, when in contact with the target, is characterized by high sensitivity and high speed of operation. The detonator consists of a body, a trigger in the form of a tip, a safety spring, a spherical inert body in the lower part of a cone-shaped part and a cylindrical part, a protection system and a firing circuit.

In addition, the detonator can be equipped with a remote detonation mechanism and a self-destruct mechanism that activates the charge if, after contact with the target, the detonator does not detonate or malfunctions for some reason.

Typically, the fragmentation portion of a NOR warhead is preceded by fragmentation elements such as rings, bushings, or spirals on the outside of the casing. These elements are placed on the smaller diameter of the housing and fixed with a compression nut. In the 9GZh-4421 warhead, anti-fragmentation elements are made of a spiral of steel profile tape with notches that ensure their fragmentation into fragments weighing about 3 g.

Cumulative fragmentation warheads for NOR S-8 preferably use explosive A-IX-10 (composition 93.5-95% explosive RDX (cyclotrimethylenetrinitramine, C3H6N6O6) with 6.5-5% phlegmatizer (can be paraffin, stearin, ceresin, petrolatum, wax, synthetic polymers and their mixtures)) or A-IX-1 (composition 95% explosive RDX (cyclotrimethylenetrinitramine, C3H6N6O6) with 5% phlegmatizer (may contain paraffin, stearin, ceresin, petrolatum, wax, synthetic polymers and their mixtures)) with a detonation speed of 8.3 km/s to 8.45 km/s.

With the help of the wave shaper inside the explosive charge, the detonation wave spreads to the walls of the case. In the 9-GZh-4421 warhead, which was selected as a prototype, the waveguide is made of compressed fiberglass resin material AG-4V. For her, the values included in the Rankine-Hugoniot relation for mass: p/po = D/(D - U) and moments: P- Po = po UD have the following values: po = 1.79 g/cm ³ , p = 3.19 g/cm ³ , D = 5.95 km/s, U = 2.61 km/s, where p is the density (with the index "0" - before the front of the shock wave), D - the speed of the shock wave, U - material mass velocity; the pressure is P = 27.8 GPa (Trunin RF, Gudarenko LF et al. "Experimental data on shock wave compression and adiabatic expansion of condensed materials", 2006, page 207).

The mass of the 9-GZh-4421 warhead is 3.6 kg, the mass of the explosive material is 1 kg, the number of fragments formed during the explosion, each weighing 3 g, is at least 400 pieces (Sychev A.I., Martirosyan V.G., Pereskokov V.A. "Uncontrolled 80 mm caliber aircraft missiles", 2019, page 17).

The 9-GZh-4421 warhead liner is made of copper and has the shape of a hollow cone with an internal opening angle of 60° and a variable wall thickness. After widening the top of the insert, a brass tube is soldered, which transmits an electric impulse from the piezoelectric generator to the bottom part of the detonator.

In the technical solution of the prototype, the possibilities of increasing the effectiveness of the warhead by correlating (linking) the design and parameters of the warhead with the properties of explosive materials are not sufficiently used.

In a traditional cumulative charge, under the influence of the pressure of the detonation wave, the liner is compressed towards the axis of the charge, a thin metal nozzle is squeezed out in front, and the slow-moving core remains behind it (Bazhin V.E., Dankov V.S. et al. "Detonation, explosives, their use", 2008, 31 , page 34). Most of the energy of the explosion is spent compressing the liner rather than increasing the rate at which the liner material is pushed forward.

The main areas of increasing the effectiveness of cumulative ammunition:

- development of explosives,

- development of devices influencing the propagation of detonation waves,

- development of more reliable explosives with better properties,

- improving the physical and mechanical properties and structure of the liner material,

- modernization of the geometric shapes of the inserts,

- increasing production accuracy.

Inserts are usually made of copper. Modern methods of metallurgy, including powder metallurgy, the use of bimetals and metal polymers, allow to improve the properties and structure of the liner material in order to increase the efficiency of cumulative charges.

There is a known liner ("Cumulative charge coating". Patent RU2337307C2. Kachalin NI et al., published 2008-10-27) made of pseudo-alloy by powder metallurgy. In the presented case, the material used is a Mo-Cu-Ni pseudoalloy with a density of 9.30-9.85 g/cm ³ , and the content of Cu is 25-60% by mass, Ni - no more than 0.8% by mass, the rest - Mo. The material proposed for the manufacture of inserts helps to increase the depth of penetration.

The insert ("Cumulative Cartridge Insert with Integrated Initiating Mechanism." Patent No. US6026750. Carl A. Nelson, published 02/22/2000), consisting of a front thin-walled portion and a rear tail portion, represents the technical level of design of cumulative charge warheads. The content of the patent is for a detailed investigation of the rear tail section. The thin-walled front part can be of various shapes. Specifically, a cone, hemispherical, bell, trumpet or tulip shaped surface can be used.

This patent does not take advantage of the possibility to control the operating parameters of the cumulative charge by optimizing the shape and thickness of the insert.

Conical inserts are the most common. This is due to their ease of manufacture and sufficient efficiency in their use in most cases. However, efforts are being made to modernize the insert forms.

There is a known form of insert ("Cumulative Charge Insert." Patent No. US6840178B2. William R. Collins et al., published 01-11-2005) which consists of at least three axially arranged, substantially frustoconical sections with different opening angles and a combination of transitions into each other.

The disadvantage of this form is the presence of parallels with a surface discontinuity, where a conical surface with one opening angle passes into a conical surface with a different angle. During an explosion, compression of such a liner causes the material in the liner to accumulate and form thickenings, or it expands and creates a crack in the liner. As thickening occurs, liner velocity decreases; in case of damage to the liner, the products of detonation flow to the front of the j, slowing the liner and reducing the kinetic energy used to penetrate the target.

After choosing the shape of the insert, the question arises as to the distribution of the thickness of the insert. Very little scientific research has been done on this issue. There are such inaccurate estimates as in the textbook (Bazhin V.E., Dankov V.S. et al. "Detonation, explosives, their use", 2008, page 38), which states that: the penetration of a cumulative charge depends on the material of the liner and its thickness; both too much and too little thickness of the insert is unfavorable; depending on the material, size and construction of the insert, the thickness varies from 0.5 mm to 3 mm.

Penetration also depends on the explosive material used. Explosives of the highest possible density and detonation velocity must be used.

However, in order to create effective cumulative warheads, it is necessary to have more accurate values of the liner thickness for specific conditions: the geometric shape and material of the liner, with or without a wave shaper, the composition and density of the explosive used, which depend on the detonation speed and blast pressure, etc.

It can be said that the thickness of almost all existing cumulative charge liners has been determined empirically through numerous experiments. This path is not only expensive, but also imprecise, as it is empirically impossible to examine all theoretically possible options.

New results of explosion theory show that the distribution of the thickness of the cartridge is of great importance for the operation of the cumulative charge, and the explosive material in the corresponding case serves only to create the pressure field necessary for the ejection (push) of the cartridge. At the same time, even in the case of the simplest cone-shaped insert and a linear thickness distribution, it is difficult to find acceptable recommendations for determining the thickness, as well as the coefficient of linear dependence.

ESSENCE OF THE INVENTION

The technical purpose of the invention is to increase the armor penetration of 75-85 mm caliber cumulative warheads or cumulative fragmentation warheads.

The shape and thickness of the liner are decisive for the performance of the warhead. In the present invention, the shape and thickness of the insert are selected so that the trajectories of the insert particles are curved and stretched forward to form an elongating cumulant rod. The high kinetic energy of the rod is due to the decrease of the velocity components towards the axis of the insert and the lengthening of the path of the particles of the insert before they stick to the rod.

The problem is solved by choosing the optimal geometric shape of the insert and correlating (linking) the thickness of the insert and its angles with other parameters of the warhead. Due to this, the ejection (push) of the cartridge caused by the explosion forms an elongating cumulative rod of high kinetic energy and small diameter, thanks to which the energy of the explosion is more usefully used, and as a result, the depth of penetration into the armored target is increased.

This effect was theorized by long-term scientific research and confirmed by several hundred experimental warhead detonations. The obtained result is applicable to various opening angles of liners, as well as to both currently widely used and experimental explosives of different densities. The explosive used must contain at least 70% RDX (cyclotrimethylenetrinitramine, CsHeNeOe), or HMX (cyclotetramethylene-tetranitramine, ΟΑΗδΝβΟδ), or HNIW (CL-20, hexanitrohexaazaisowurtzitane, C6H6N12O12).

The technical solution to the problem is as follows. A cluster warhead or cluster fragmentation warhead includes a body with an outer front diameter of 75 mm to 85 mm, a safety and loading mechanism, an explosive charge with a hollow cavity in the front part, a wave shaper and a fairing. An insert with a density of 8-10 g/cm ³ is located in a hollow charge cavity. Fig. 1-8 show different implementation examples (variants), in which the same elements are denoted by the same numbers.

The safety and loading mechanism can be an independent bottom detonator or a top-bottom detonator working together with a piezoelectric generator. In the second case, to ensure the electrical circuit between the SUM and the piezoelectric generator, a conductor inserted into the wave shaper, a wire cone, or an electrical cable, or other elements of the electrical circuit can be used; the wire cone is pressed against the insert by an insulating compression ring.

The outer surface of the liner adjacent to the explosive and the inner surface of the liner are made as surfaces of rotation with a common axis, with a wide open edge, which is called the base, and a narrow part on the other side, which is called the top (Figure 18-20).

The opening angle a at the base of the insert, required for correlation (matching) with the parameters of the insert, is determined between two opposite tangents of the inner surface meridians at the base.

The inner diameter D of the insert base is between 60 mm and 75 mm. Along the parallel of the outer surface / at a distance from the base along the axis of the insert, the thickness of the insert δι is determined. The value of I is in the following range (interval): 2 mm < / < 8 mm (Fig. 21-23).

The necessary characteristics of a technical solution are the following:

- the component of the inner surface of the insert is a line inside the figure (Fig. 22, Fig. 24) formed by small arcs of two circles passing through the ends of the line segment connecting the base of the insert from the inside with the apex, the beginning of the rounding of the apex, the beginning of the cylindrical part or another vertex at its upper part, with centers on opposite sides of this segment,

- the radii of these circles are equal to two and a half lengths of this section (Figure 24),

- the double angle between this section and the axis of the insert is greater than 23° and less than 125°,

- the composite has no breakpoints (Figures 25a-25c),

- the thickness δι is in the range from 1.2 mm to 3 mm (Figures 21-23),

- when the charge density is p < 1.7 g/cm ³ , the indicated thickness is less than 2.6 mm.

If there is a bevel on the outside at the base of the insert, the thickness is measured along the normal of the inner surface so that the normal reaches the outer surface without the bevel.

In a particular embodiment, the insert may have outer and inner surfaces, which are the side surfaces of a right circular cone with different opening angles, β and a, respectively (Figure 23).

In order to increase the penetration of the warhead j armor, the thickness of the insert at a distance δ / from the base and the angle difference (β - a) (in the special case of a cone, Fig. 23) are related to the angle a of the inner surface and the properties of the explosive material used, which are mainly determined by its density Mr.

The insert must be thin enough that the trajectories of the particles in the insert are bent and stretched forward. However, at the same time, the liner must be thick enough not to break under the pressure of the detonation products, and to prevent the formation of back pressure from the gas penetrating the liner.

For this purpose, the range of angles a is divided into 10° intervals.

The explosive density range is divided into 4 ranges. The first interval, with a density between 1.6 g/cm ³ and 1.7 g/cm ³ , mainly includes materials based on RDX (cyclotrimethylenetrinitramine, CaHeNeOe). The second interval, with a density between 1.7 g/cm ³ and 1.8 g/cm ³ , includes materials based on ΗΜΧ (cyclotetramethylene-tetranitramine, C^eNsOe) with various additives. In the third interval, with a density between 1.8 g/cm ³ and 1.9 g/cm ³ , there are materials based on ΗΜΧ (cyclotetramethylene-tetranitramine, C4H8N8O8) with increased detonation speed and explosion pressure. The fourth interval, in which the density is from 1.9 g/cm ³ to 2 g/cm ³ - materials based on HNIW (CL-20, hexanitrohexaazaisowurtzitane, C6H6N12O12) (Table 1).

The values of δι for each interval are given; the angle difference (β - a) of the conical insert is also given (Fig. 23).

Metals (including bimetals), metal alloys (including powders and pseudoalloys) and metal polymers can be used as liner material.

Anti-corrosion coating is allowed.

Preferably, the insert is made of copper with a total impurity content of less than 0.1%.

The thickness of the liner along any internal or external surface parallel is determined by the normal to the internal surface.

The tolerance of the thickness of the insert along any parallel of the inner or outer surface should preferably be less than ±0.05 mm.

the insert may contain elements for installation and/or initialization.

In addition to the described cumulative part, the warhead may also have a fragmentation part. Seven possible variants of the fragmentation part are presented and illustrated below as examples of implementation (Figures 9-16).

Other features and advantages of this invention will become clear to specialists in this field from the drawings in which the same numbers denote the same elements, the description, the examples of the invention, the theoretical justification, the evaluation of the effectiveness of the technical solution proposed by the experiment, and the definition points.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. shows an external view of a typical cumulative fragmentation warhead of an 80 mm unguided anti-aircraft missile.

- Figure 5 shows partial cross-sections of some embodiments of the present invention. Figure 4 shows a warhead with a top-bottom detonator operating in conjunction with a piezoelectric generator, Figure 5. a warhead with a self-contained depth charge is shown.

, Figure 7 shows the appearance and partial section of the fragmentation-free part of the cumulative warhead and the piezoelectric generator of the warhead; it is designed for 81 mm caliber rockets such as the NOR Medusa.

Fig. shows a cumulative warhead that may be a rocket-propelled anti-tank grenade warhead for an anti-tank grenade launcher.

Fig. shows a diagram of a warhead, in which pre-fragmentation elements are made in the form of rings, sleeves or spirals and are attached to the body in a place where its diameter is smaller.

Fig. similar pre-fragmentation elements inside the case are depicted.

Fig. shows the ready destruction elements inside the case.

Fig. shows a part of the shell with thickened walls in the form of pre-fragmentation transverse or diagonal grooves and notches on the inner side of the shell.

Fig. shows a section of the shell with thickened walls with similar pre-fragmentation on the outside of the shell.

Fig. shows a part of the body with a flexible sleeve filled with ready-made elements of destruction.

Fig. shows part of the case with indentations all over the inner surface made in a certain repeating pattern.

Fig. a combination of the two variants of the pre-fragmentation elements mentioned above is shown. In addition, Fig. 16 the symbol Dstandoff indicates the standoff (distance) between the target and the base of the insert.

Fig. shows the basic shapes of wave shapers used in cluster munitions.

- Fig. 20 illustrates inserts of various shapes made in accordance with the present invention.

Figure 21-23 diagrams of the insert are shown, indicating the opening angle of the inner surface a, the opening angle of the outer surface β (in the case of the conical insert, Fig. 23), the inner diameter of the insert base D; the thickness of the insert is 5/is specified at / distance from the base of the insert.

Fig. a diagram of the construction of the inner surface is shown; a section of length L along which the insert is drawn is shown, and the angle γ/2 between the section and the axis of the insert, whose y value can vary from 23° to 125°.

Figure 25a-25c. several examples of the inner surface are given.

DETAILED DESCRIPTION OF THE INVENTION

The body of the cumulative warhead (1) is made of a thin-walled shell with a cylindrical-conical surface (Fig. 2). The internal volume of the case must be such that it accommodates the safety and loading mechanism (2), the explosive charge (3), the wave shaper (4) and the liner (5). Based on this, the geometric design of the body is selected. There are usually threads at both ends of the housing that connect the housing to the fairing and various means for accelerating and stabilizing the warhead in flight. Often, in order to facilitate the warhead, the body is made of aluminum and its alloys. Cumulative warhead versions (variants) (Figure 6-8) do not have a fragmentation part.

The design of the cumulative fragmentation warhead (Fig. 1-5) depends on the selected version (variant) of the fragmentation part. The most common version (variant) of the NOR body is a thin-walled hollow cylinder of two diameters (11), in which one diameter smoothly passes into the other, and there are threads at both ends (Fig. 9). The fragmentation part can be made of 17 steel rings placed on a smaller diameter body, each of which has 24 notches inside, ensuring the production of 408 fragments (17 x 24 = 408) weighing approximately 3 g each. A similar effect can be achieved using a steel helix (12) or bushings with notches on the inner surface. These elements are placed on the body and fixed with a compression nut (13).

In addition, other variants of the fragmentation part can be used (Figures 10-15):

- body (14) and anti-fragmentation elements (15) in the form of rings, sleeves or spirals inside the body,

- a case with prepared destruction elements (16) - balls, rods, cubes, prisms and 1.1., inside the case; a binder such as epoxy glue can be used to attach them,

- body (17) with thicker walls with anti-fragmentation, the inner side of which has grooves and notches dividing the walls of the body into fragments of the required mass; grooves and notches can be made along the axis of the warhead, across or at an angle,

- a body (18) with thicker walls with anti-fragmentation, having similar grooves and notches on the outside,

- flexible fragmentation sleeve (19) with prepared destruction elements (20) outside the body,

- the body (21), the entire inner surface of which has recesses made according to a certain pattern.

Another version of the fragmentation part or a combination of different versions can be used (Figure 16).

In terms of warhead performance, neither of these casing options is preferred. Any or a combination of these can be used. In this way, it is possible to increase the number of fragments of the required mass. In general, the choice of housing implementation is determined by technological and manufacturing factors.

Inside the casing (1) there is an explosive charge (3), consisting of several explosive briquettes or one solid element. Compositions based on RDX (cyclotrimethylenetrinitramine, CsHeNeOe) are commonly used as explosives in NOR warheads. A complex (joined) version is preferred, where a more powerful composition based on HMX (cyclotetramethylene-tetranitramine, CaHsNsOs) is used for the part of the cumulative charge, and a composition based on RDX (cyclotrimethylenetrinitramine, CaHeNeOe) is used for the fragmentation part. In all cases, the explosive must provide the necessary electrical insulation.

table shows the parameters of some explosives ("Military Explosives". Technical Manual No. 9-1300-214, as amended 1-4. Headquarters of the Department of the Army). The explosives listed in the table, like other high explosives, have one characteristic - they contain at least 70% RDX (cyclotrimethylenetrinitramine, CaHeNeOe), or HMX (cyclotetramethylene-tetranitramine, C^sNeOs), or HNIW (CL-20, hexanitrohexaazaisowurtzitane, C6H6N12O12) ("Pirospravka. Textbook of Explosives, Gunpowder and Pyrotechnic Compositions", 6th edition, 2012, pages 182-188).

The authors of this invention have carried out theoretical studies, numerical calculations and experimental studies with these materials. The liner parameters in the definition clauses were determined for explosives containing at least 70% RDX (cyclotrimethylenetrinitramine, CsHeNeOe), or HMX (cyclotetramethylene-tetranitramine, CaHsNsOs), or HNIW (CL-20, hexanitrohexaazaisowurtzitane, C6H6N12O12).

The front part of the explosive (3) has a hollow cavity into which the insert (5) is pressed. In the lower part there is a recess in which the safety and loading mechanism (2) is installed. The bottom of the missile warhead housing is usually closed by a protective partition. Between the SUM and the liner is a wave shaper (4), which expands the detonation wave emanating from the SUM to the walls of the case. This creates a more favorable detonation wave pattern inside the charge.

The location of the wave shaper inside the explosive device is determined by the condition that the distance from the cross section of the wave shaper in the widest part to the top of the insert does not exceed the diameter of the wave shaper in the wide part. If the largest diameter remains in any part of the wave shaper, then the cut closest to the liner with the largest diameter is selected and the distance to the top of the liner is measured from it - it should not be greater than the maximum diameter of the wave shaper.

The shape of the waveguide is chosen so that the detonation wave surrounding it reaches the opposite side before the shock wave passing through the waveguide material. Figure 17 shows the basic shapes of wave shapers used in cluster munitions.

For the wave shaper, inert materials can be used, the speed of which shock waves at a pressure equal to the explosion pressure is lower than the detonation speed of the explosive material used. Cluster munitions typically use high explosives with detonation velocities ranging from 8 km/s to 9.5 km/s (Table 1). Waveformers can be made not only from inert materials, but also from explosive materials with a low detonation speed.

table. Parameters of some explosives

No. Title Material, % Detonation speed RDX HMX HNIW (CL-20) at density, g/cm ³ speed, m/s 1 Composition A3 91 — — 1.60 8180 2 Composition A5 98.5-99 — — 1.64 8200 3 A-IX-10 93.5-95 — — 1.64 8310 4 A-IX-1 95 — — 1.68 8450

5 PBXN-110 — 88 — 1.68 8390 6 Cyclotol type II 70 — — 1.73 8060 7 Cyclotol type I 75 — — 1.74 8250 8 Okfol-3.5 — 96.5 — 1.76 8700 9 Octonyl — 90 — 1.77 8850 10 PAX-2A — 85 — 1.78 8520 11 Octol type II — 70 — 1.80 8300 12 ERDCO-301 —- 82 — 1.80 8510 13 Octol 77/23 — 77 — 1.80 8540 14 PBXW-11 — 96 — 1.80 8820 15 Octol type I — 75 — 1.81 8400 16 LX-14 — 95.5 — 1.82 8830 17 PBX-P31 — 96 — 1.83 8560 18 Rowanex-3000 — 95 — 1.83 8860 19 OMA — 97.5 — 1.84 8850 20 Octol 85/15 — 85 — 1.86 8740 21 PBXN-5 — 95 — 1.86 8800 22 OKF — 98 — 1.86 9000 23 PATHX-2 — — 95 1.92 9120 24 LX-19 — — 95.2 1.96 9440 25 HNIW-98 — — 98 2.00 9350

The fairing (6) is conical or vault-shaped with thin walls. A conductive cone (8) connects the piezoelectric detonator of the head to the base of the insert.

When using a detonator without a head piezoelectric generator, the conductive cone is not used, and the thickness of the smooth walls is increased (Figures 5, 7).

The length of the overhang determines the gap (distance) between the target and the base of the insert (Fig. 16) at the moment of hitting the target. In order to ensure the effectiveness of the warhead, it is very important to ensure the correct gap (distance) between the target and the base of the insert.

Usually, the speed of action of bottom explosives is high. In this case, this said gap (distance) between the target and the base of the insert is equal to the distance from the base of the insert to the top of the piezoelectric generator of the head.

Detonators with a piezoelectric generator have a delay time (Markovsky V., Prikhodchenko I. "Unguided rockets of the S-8 type". M-Hobby, 2013, No. 9 (148), page 46). Although it is very small (20-30 microseconds), this delay reduces the gap (distance) between the target and the base of the liner at the time the explosive charge is detonated.

The flight speed of a rocket launched from a launcher is equal to the sum of the speed of the device from which the rocket is launched and the speed at which the rocket itself can accelerate. The maximum speed of modern attack helicopters is about 300 km/h, and the sustained flight speed of fighters only starts from this value. The cruising speed of fighters is much higher. For example, MiG-29 - about 850 km/h.

In addition, if we take into account the speed of the missile itself (about 600 m/s) and the conversion factor from km/h to m/s (1 km/h = 0.278 m/s), then the gap (distance) between the target and the impact of the base of the insert moment can decrease by 16-24 mm (for fighters), 13-20 mm (helicopters) or 12-18 mm if the missile is launched from a ground launcher.

Calculations and experimental studies by the authors of this invention showed that the gap (distance) between the target and the base of the liner at the moment of explosion of the explosive device should be about 0.5L _pe n, where L _pen is the average penetration depth of the armored target. This rule applies to warheads with different explosives and liners of different shapes and thicknesses. Tests of the proposed warheads showed that using explosives of the type A IX-1 (95% RDX (cyclotrimethylenetrinitramine, CsHeNeOe) with 5% phlegmatizer) the warhead penetrates about 450 mm when the cone opening angle a = 70° and about 470 mm - when the opening angle σ = 40° (tables 3 and 4). Therefore, for a warhead with an insert, when the opening angle a = 70°, the gap (distance) between the target and the base of the insert should be approximately 225 mm. When designing warheads, it is necessary to add 16-24 mm (for fighters) to compensate for the delay in the action of the bottom detonator, and another 10 mm when the opening angle is approximately a = 40°.

Thus, the distance from the base of the insert to the top of the piezoelectric generator of the head should be 240-250 mm, and for small opening angles of the insert - 250-260 mm. In order to ensure the required dimensions of the missile, deviations from these distances are allowed, usually in the direction of decrease, but not more than 10%.

As shown by numerous tests of ammunition with various cumulative charges, the aforementioned dependence of the optimal gap (distance) between the target and the base of the cartridge on the penetration of armor is quite accurate. More precisely, it can be written as follows: 0.45L _pen Dstandoff < 0.5·L _P en, where Dstandoff is the gap (distance) between the target and the base of the insert (Fig. 16).

Another important issue is the dependence of the depth of penetration on the opening angle of the insert a. Calculations and experiments have shown that when the opening angles of the conical insert are between 50° and 70°, the average penetration depth of the cumulative charge with the wave shaper practically does not change. If the angle is less than 50°, the depth of penetration increases with one type of explosive. When the opening angle, which is in the range of 30°<a<50°, decreases by one degree, the penetration of the warhead of the 78 mm caliber rocket into the armor increases by about 2 mm. In addition, when designing a warhead, when the opening angle is reduced by 1°, the gap (distance) between the target and the base of the insert must be increased by 1 mm.

In many cases, the use of liners with small opening angles of the cone-shaped liner presents practical difficulties due to the dimensions of the ammunition. However, for a missile warhead with a long body, such inserts are undoubtedly useful.

In order to create an internal electrical circuit between the piezoelectric generator and the bottom part of the detonator, a conductive cone (8) is installed between the piezoelectric generator and the liner. The insulating compression ring (9) is installed to press the cone flange against the liner base. The conductor (7), after widening, is soldered to the top of the insert and inserted into the hole of the wave shaper, the detonator contact is inserted at the other end of the conductor.

To ensure electrical insulation, an annular groove is made in the housing wall in front of the base of the insert, into which an insulating ring made of polypropylene, for example, is inserted.

When installing the bottom detonator, positions (7)-(10) are not used and the annular groove for the insulating ring is not made.

The outer surface of the liner adjacent to the explosive and the inner surface of the liner are made in the form of rotating surfaces with a common axis, having a wide open edge (the base of the liner) and a narrow part at the other end (the top of the liner) (Figures 18-20).

A surface of revolution is a surface formed by rotating a curve around a straight line called the axis of the surface. When rotating around an axis, a curve that has formed a new figure is called a composite curve. Meridians are the lines of intersection of the surface of rotation with planes passing through the axis of rotation. Parallels are lines of intersection of a surface with planes perpendicular to the axis of the surface.

At the distance / from the base along the axis of the insert along the parallel of the outer surface, the thickness δι is determined. / value is in the following range: 2 mm < / < 8 mm (Fig. 21-23).

the thickness of the insert along any parallel of the inner or outer surface is determined along the normal of the inner surface and the deviation is less than ±0.05 mm.

In this invention, the inner diameter D of the insert base meets the following condition:

mm < D < 75 mm (Fig. 21-23).

The component of the inner surface of the insert is a line obtained in the following way:

- the line segment is obtained from the inside by connecting the base of the insert with its top, the beginning of the upper rounding, the beginning of the cylindrical part or another peak in its upper part, it depends on the method of manufacturing the top,

- through the ends of the formed section, small arcs of two circles are drawn, the centers of which are on opposite sides of the section (Fig. 24),

- the radii of these circles are equal to two and a half lengths of the specified segment,

- the double angle between the section and the insert axis is between 23° and 125°,

- the desired line is drawn from the top to the base, it is inside the figure formed by the specified arcs (Fig. 24, item 22),

- the desired line should not have break points (Figures 25a-25c).

For any opening angle a at the base, the following properties are ensured:

- the range of thickness δi is from 1.2 mm to 3 mm (Fig. 21-23),

- when the charge density is p < 1.7 g/cm ³ , the indicated thickness is less than 2.6 mm.

The outer and inner surfaces of the insert can be constructed as the side surfaces of a right circular cone with different opening angles (Figure 23). A right circular cone is a cone whose base is a circle, and the perpendicular projection of the apex to the plane of the base coincides with the center of the circle. The lateral surface of a right circular cone is a special case of a surface of revolution.

The opening angle a of the inner surface at the base (Fig. 21, 22), the opening angle β of the outer surface (in the special case of the cone, Fig. 23) and the thickness of the insert must be related to other parameters of the cumulative charge.

Since the double angle y can vary from 23° to 125° and the radii of the circles are equal to two and a half lengths of the segment, the angle a can vary from 0° to 148°, the angle β is slightly larger than a, and its range is about 0° to 150°.

There may be a bevel on the outside of the insert at the base of the insert. In this case, the thickness δι is measured along the normal of the inner surface at the point where the normal reaches the outer surface without a slope.

The average density p of the explosive material can be determined by standard laboratory methods.

The thickness of the insert at a distance δι / must be such that, in the specified ranges of the angle a and density p of the explosive material used, the δι values correspond to the conditions specified in the corresponding clauses of the definition of the invention.

In the case of a conical insert (Fig. 23), the thickness δι and the difference in the opening angles of the outer and inner surfaces (β - a) must meet the relevant requirements.

For example, it is necessary to create a warhead loaded with Α-ΙΧ-10 (composition 93.5-95% explosive RDX (cyclotrimethylenetrinitramine, CsHeNeOe) with 6.5-5% phlegmatizer) with a density of 1.64 g/cm ³ , with insert with an inner diameter of 68 mm and an opening angle of the inner surface a = 42°. In this case, at a distance from the base / = 5 mm, the thickness of the insert δι should be from 1.41 mm to 2.14 mm, and the angle difference (β - a) - from 1° to 1°30' (clauses 12, 13 of the definition) . Therefore, the angle β must be between 43° and 43°30'.

Under these conditions, an elongated cumulant rod is produced with the highest possible mass, high head section velocity, uniform tension and small cross-sectional diameter. As a result, the energy of the explosion is effectively transferred to the kinetic energy of the optimally shaped cumulative rod, which increases the depth of penetration into the target.

In addition, this can be achieved with different opening angles of the liner and by using explosives of different densities. Only when designing, it is necessary to select the insert parameters according to the definition points of this invention.

When choosing a parameter value from an interval that depends on another parameter, in addition to being set in a given interval, a common mathematical rule must be followed: if the range boundary of the domain of definitions is included in the range, then the corresponding range boundary of the function domain is also included in the range of j if the range limit is not included in the scope of definitions, the limit is not included in the scope of the function.

For example, if the domain of definitions is 1.6 g/cm ³ < p < 1.7 g/cm ³ , and the range of the function domain is 1.31 mm to 2.01 mm, then the limit of 1.31 mm falls within the range, and the limit of 2.01 mm is not included in the range (clause 2 of the definition).

Theoretical calculations and control experiments showed that when choosing the liner material, it is necessary that its density is higher than the density of steel, which ranges from 7.7 g/cm ³ to 8 g/cm ³ , and it is enough that its density exceeds the density of steel not more than 25%.

The insert can be made of copper with a density of about 8.9 g/cm ³ .

When creating the geometric shape of the insert, it is logical to apply the Lagrangian description, which determines the state and movement parameters (coordinates, velocity and 1.1.) of each material particle at any time. When the liner is in the form of a surface of revolution, the mass and velocity of the cumulative rod element formed by the Lagrangian ring of a given liner is determined by three factors:

- the diameter of the considered Lagrangian ring,

- the angle between two opposite tangents of the meridians of the inner surface of the ring,

- the thickness of the insert at this point.

Their influence is as follows:

- increasing the diameter and keeping the other two parameters unchanged increases the speed of the elongating cumulant rod, as the Lagrangian particle path length of the liner increases,

- increasing the specified angle works in the same way as increasing the diameter,

- on the contrary, as the thickness increases, the insert slows down.

At the same time, due to the high acceleration that is observed during the ejection of the explosion-induced liner, even a small change in these parameters leads to large changes in the ejection dynamics. There is a paradox that small deviations have a big impact.

In view of this paradox, it is necessary to avoid breaking points of the turning surface and large deviations of the shape of the insert from the basic conical shape.

A turning point is a special point on a curve where the branches of the curve, which this point divides the original curve, have different one-sided tangents. If the curve has no break points, then the tangents of one side and the other coincide at all points of the curve.

Extensive (extensive) mathematical research, numerical calculations and numerous experiments have led to the development of a principle to which the inserts of cumulative charges must best comply. In this case, the contour of the surface of the inner insert should be formed as a line without breakpoints, located inside the figure (Fig. 24, item 22), formed by two small arcs of circles passing through the ends of the line segment connecting the base of the insert with the top from the inside ( the beginning of the rounding of the top, the beginning of the cylindrical part, or another vertex), whose radii are equal to two and a half lengths of the specified segment and whose centers are on opposite sides of this segment.

After choosing the geometric shape of the insert, the thickness and opening angle of the insert must be related to the dynamic parameters of the ejection of the insert caused by the explosion, which are determined by the composition and density of the explosive material. Tuning was done by calculating the ejection of the liner caused by the detonation of explosives of different densities at various opening angles. The calculation results were verified by experiments.

The optimal parameters of the liners were determined; the selected parameters are specified in the corresponding definition clauses.

Cone-shaped inserts do not lose their importance; they are a special case of the liners of this invention. By correlating (associating) the thickness of the inner and outer surface and the opening angle with the composition and density of the explosive material, the effectiveness of cumulative charges with cone-shaped inserts increases.

By correctly setting these parameters, the parameters of the elongating cumulus rod can be controlled to increase its kinetic energy and optimize the velocity gradient and rod diameter in different zones. As a result, it is possible to increase the main parameter of the warhead - the depth of penetration.

A comparison of the effectiveness of the proposed warhead with the prototype was made. Warheads were produced with copper liners with an internal opening angle of 60° and a wall of the usual variable thickness; phlegmatized hexogen was used. Warheads of the same design, but loaded with the more powerful Okfol-3.5 explosive (96.5% HMX (cyclotetramethylene-tetranitramine, C^sNsOs) with 3.5% phlegmatizer) were also produced (Table 2).

The effectiveness of the proposed technical solution was evaluated. Warheads with parameters specified in the invention and parameters differing from them were produced.

In order to compare the proposed warheads with the prototype, new warheads with conical copper inserts were made, the outer diameter of the body - 78 mm, the inner diameter of the insert - 68 mm, with different opening angles and the parameters specified in the invention. In tables 3-6, the thickness of the insert δι is given when / = 5 mm, and the indicator "7 - is not indicated.

Composition A ΙΧ-1 (95% RDX (cyclotrimethylenetrinitramine, CsHeNeOe) with 5% phlegmatizer) was used as an explosive with a density of 1.6 g/cm ³ < p < 1.7 g/cm ³ ; whose density is 1.7 g/cm ³ < p < 1.8 g/cm ³ - phlegmatized octogen Okfol-3.5. A set of side by side armor plates were used as a target. The head's piezoelectric detonator was not used. The warheads were mounted perpendicular to the upper armor plate, with a gap of approximately 20 mm between the plate and the tip of the gun. Such a gap simulates the actual position of the warhead at the moment of detonation, taking into account the delay time of the action of the bottom part of the warhead, which is applied to a warhead with a top-bottom detonator operating in conjunction with a piezoelectric generator.

Tables 3-6 show the armor penetration results for each warhead tested. The tables show the effectiveness of various warhead manufacturing options based on the average penetration depth of each option.

table. test results of the normal (with Α-ΙΧ-1) and Okfol-3.5 filled prototype

No. Warhead Penetration depth, mm Average depth, mm 1 Prototype 410 400 2 Prototype 400 3 Prototype 420 4 Prototype 390 5 Prototype 380 6 Improved prototype with Okfol3.5 430 420 7 Improved prototype with Okfol3.5 420 8 Improved prototype with Okfol3.5 410

9 Improved prototype with Okfol 3.5 420 10 Improved prototype with Okfol 3.5 400

table. Test results of warheads with A-IX-1 and inserts with a=40° (clauses 12, 13 of the definition)

No. Insert parameters Penetration depth, mm Average depth, mm Location by average depth 1 a=40°, δ=1.3, (β-α)=0°50' 360 360 7 2 a=40°, δ-1.3, (β-α)=0°50' 350 3 a=40°, δ=1.3, (β - a)=0°50' 370 4 α=40°, δ=1.3, (β-α)=1°15' 410 420 4 5 α=40°, δ=1.3, (β-α)=1°15' 430 6 α=40°, δ=1.3, (β-α)=1°15' 420 7 α=40°, δ=1.3, (β-α)=1°40' 350 357 8 8 α=40°, δ=1.3, (β-α)=1°40' 380 9 α=40°, δ-1.3, (β-α)=Γ40' 340 10 α=40°, δ=1.8, (β-α)=0°50' 460 443 3 11 α=40°, δ=1.8, (β-α)=0°50' 440 12 α=40°, δ=1.8, (β-α)=0°50' 430 13 α=40°, δ=1.8, (β - α)=1°15' 460 470 1 14 α=40°, δ=1.8, (β-α)=1°15' 480 15 α=40°, δ=1.8, (β-α)=1°15· 470 16 α=40°, δ=1.8, (β-α)=1°40· 440 450 2 17 α=40°, δ=1.8, (β-α)=1°40' 450 18 α=40°, δ=1.8, (β-α)=Γ40' 460 19 α=40°, δ-2.2, (β-α)=0°50' 360 350 9 20 α=40°, δ-2.2, (β - α)=0°50' 340 21 α=40°, δ=2.2, (β-α)=0°50' 350 22 α=40°, δ=2.2, (β-α)=1°15' 390 413 5 23 α=40°, δ=2.2, (β-α)=Γ15' 430 24 _α =40°, δ=2.2, (β-α)=1°15' 420 25 α=40°, δ=2.2, (β-α)=1°40' 380 367 6 26 _α =40°, δ=2.2, (β-α)=1°40' 390 27 _α =40°, δ=2.2, (β-α)=1°40' 330

table. Test results for warheads with A-IX-1 and inserts with a =70° (clauses 18, 19 of the specification)

No. Insert parameters Penetration depth, mm Average depth, mm Location by average depth 1 a=70°, δ=1.5, (β-α)=1°40' 350 377 7 2 a=70°, δ=1.5, (β -a)=1°40' 400 3 a=70°, δ=1.5, (β-α)=1°40' 380 4 a=70°, δ=1.5, (β - a)=2° 420 403 5 5 α=70°, δ=1.5, (β-α)=2° 400 6 α=70°, δ=1.5, (β-α)=2° 390 7 α=70°, δ-1.5, (β-α)=2°20' 350 343 8 8 α=70°, δ=1.5, (β-α)=2°20' 320 9 α=70°, δ=1.5, (β-α)=2°20' 360 10 α=70°, δ=1.95, (β-α)=Γ40' 450 433 2 11 α=70°, δ=1.95, (β-α)=1°40' 440 12 α=70°, δ=1.95, (β-α)=1°40' 410 13 α=70°, δ=1.95, (β-α)=2° 430 453 1 14 α=70°, δ=1.95, (β-α)=2° 460 15 α=70°, δ=1.95, (β-α)=2° 470 16 α=70°, δ-1.95, (β-α)=2°20' 420 430 3 17 α=70°, δ-1.95, (β - α)=2°20' 420 18 α=70°, δ=1.95, (β-α)=2°20· 450 19 α=7Ο ⁰ , δ-2.4, (β-α)=1°40' 320 340 9 20 α=70°, δ=2.4, (β-α)=1°40' 380 21 α=70°, δ=2.4, (β-α)=1°40' 320 22 α=70°, δ-2.4, (β-α)=2° 400 407 4 23 α=70°, δ=2.4, (β-α)=2° 390 24 α=70°, δ-2.4, (β - α)=2° 430 25 α=70°, δ-2.4, (β - α)=2°20' 390 390 6 26 α=70°, δ-2.4, (β - α)=2°20' 380 27 α=70°, δ-2.4, (β-α)=2°20' 400

table. Test results of warheads with Okfol-3.5 and inserts with a =45° (clauses 14, 15 of the specification)

No. Insert parameters Penetration depth, mm Average depth, mm Location by average depth 1 a=45°, δ=1.5, (β-α)=1°10' 390 403 7 2 0=45^ δ=1.5, (β-α)=1°10' 390

3 a=45°, δ=1.5, (β-α)=1°10' 430 4 a=45°, δ-1.5, (β-α)=1°30' 420 420 5 5 a=45°, δ=1.5, (β-α)=Γ30' 430 6 α=45°, δ=1.5, (β-α)=1°30' 410 7 α=45°, δ=1.5, (β-α)=1°55' 410 390 8 8 α=45°, δ=1.5, (β-α)=1°55' 370 9 α=45°, δ-1.5, (β-α)=Γ55' 390 10 α=45°, δ=2, (β-α)=1°10' 450 447 3 11 α=45°, δ=2, (β-α)=1°10' 460 12 α=45°, δ=2, (β-α)=1°10' 430 13 α=45°, δ=2, (β-α)=1°30' 500 490 1 14 0=45°, δ=2, (β-α)=1°30' 480 15 α=45°, δ=2, (β-α)=1°30' 490 16 α=45°, δ=2, (β-α)=1°55' 450 463 2 17 α=45°, δ=2, (β-α)=1°55' 480 18 α=45°, δ=2, (β-α)=1°55' 460 19 α=45°, δ=2.4, (β-α)=1°10' 410 387 9 20 α=45°, δ-2.4, (β-α)=1°10' 380 21 α=45°, δ-2.4, (β-α)=1°10' 370 22 α=45°, δ=2.4, (β-α)=1°30' 430 437 4 23 α=45°, δ-2.4, (β-α)=1°30' 460 24 α=45°, δ-2.4, (β-α)=1°30' 420 25 α=45°, δ=2.4, (β-α)=1°55' 410 413 6 26 α=45°, δ-2.4, (β-α)=1°55' 410 27 α=45°, δ-2.4, (β-α)=1°55' 420

table. Test results of warheads with Okfol-3.5 and inserts with σ=70° (clauses 18, 19 of the specification)

No. liner parameters Penetration depth, mm Average depth, mm Location by average depth 1 α=70°, δ=1.6, (β-α)=1°45' 350 377 6 2 α=70°, δ=1.6, (β-α)=1°45' 380 3 α=70°, δ=1.6, (β-α)=1°45' 400 4 α=70°, δ=1.6, (β-α)=2° 420 417 4 5 α=70°, δ=1.6, (β-α)=2° 430 6 α=70°, δ=1.6, (β-α)=2° 400 7 α=70°, δ=1.6, (β-α)=2°25' 350 353 9 8 α=70°, δ=1.6, (β-α)=2°25' 360 9 α=70°, δ=1.6, (β-α)=2°25' 350

10 a=70°, δ=2.1, (β-α)=Γ45' 440 450 2 11 a=70°, δ=2.1, (β-α)=1°45' 470 12 a=70°, δ=2.1, (β-α)=1°45' 440 13 α=70°, δ=2.1, (β-α)=2° 490 470 1 14 α=70°, δ=2.1, (β-α)=2° 470 15 α=70°, δ=2.1, (β-α)=2° 450 16 α=70°, δ=2.1, (β-α)=2°25' 460 440 3 17 α=70°, δ=2.1, (β-α)=2°25' 420 18 α=70°, δ=2.1, (β-α)=2°25' 440 19 α=70°, δ=2.55, (β-α)=1°45' 360 357 8 20 α=70°, δ=2.55, (β-α)=1°45' 360 21 α=70°, δ=2.55, (β-α)=1°45' 350 22 α=70°, δ=2.55, (β - α)=2° 400 413 5 23 α=70°, δ=2.55, (β-α)=2° 410 24 α=70°, δ=2.55, (β - α)=2° 430 25 α=70°, δ=2.55, (β - a)=2°25' 380 373 7 26 α=70°, δ=2.55, (β - α)=2°25' 350 27 α=70°, δ=2.55, (β-α)=2°25' 390

From the analysis of the performed experiments, it can be seen that in the case of all tested liner opening angles and all used explosive materials, the highest penetration was observed in cases where both liner parameters, thickness δι and angle difference (β - a), meet the criteria specified in the definition clauses of the invention.

Armor penetration is lower when the thickness δι meets the required criteria, but the angle difference (β - a) does not meet them. At the same time, in these cases, the average penetration is still higher than the average penetration of the prototype (400 mm) and the average penetration of the prototype with a more powerful explosive (420 mm).

The worst results, even worse than the prototype, are obtained in cases where both parameters of the insert, thickness δι and angle difference (β - a), do not meet the required criteria.

The presented examples do not exhaust the possibilities of application of the invention. However, they convincingly confirm the effectiveness of the technical solution, which was proposed on the basis of extensive research, calculations and experiments.

The conducted experiments showed that, compared to the prototype, the proposed variants of the warhead are superior.

The invention is described in sufficient detail to comply with patent provisions and to provide those skilled in the art with the information necessary to apply the new principles. However, it should be understood that the described technical solution may be implemented using other details and components without departing from the true spirit and scope of the present invention.

Links

1. "Unguided anti-aircraft missile with a tandem cumulative charge." Patent RU2371667C1. Ashurkov A.A. etc" published on 10/27/2009.

2. Sychev A.I., Martirosyan V.G., Pereskokov V.A. Unguided 80 mm caliber aircraft missiles, 2019.

3. "Bottom explosive". Patent RU2125706C1. Andrejkin P.V. et al., published on 1/27/1999.

4. Trunin R.F., Gudarenko L.F. etc. "Experimental data on shock wave compression and adiabatic expansion of condensed matter", 2006.

5. Bazhin V.E., Dankov V.S. etc. "Explosion, explosives, their use", 2008.

6. "Cumulative charge cover". Patent RU2337307C2. Kachalin N.I. et al., published on 10/27/2008.

7. "Cumulative charge cartridge with integral initiation mechanism." Patent no. US6026750. Carl A. Nelson Posted 02/22/2000.

8. "Cumulative cartridge insert". Patent no. US6840178B2. William R. Collins et al, published 1/11/2005.

9. "Military Explosives". Technical manual no. 9-1300-214, as amended 1-4. Headquarters of the Department of the Army.

10. "Pirospravka. Textbook of Explosives, Gunpowder and Pyrotechnic Compositions", 6th edition, 2012.

11. Markovsky V., Prikhodchenko I. "Unguided missiles of the S-8 type." M-Hobby, 2013, no. 9(148), pp. 44-50.

Claims (24)

A warhead that includes a housing (1) with an outer frontal diameter of 75 mm to 85 mm, a safety and loading mechanism (2) located in the bottom (lower) part of the housing, an explosive charge (3) containing at least as 70% RDX, or HMX, or HNIW (CL-20), with a hollow cavity in the charge head, a wave shaper (4), a fairing (6) and a liner (5) in the hollow cavity, where - the liner is made of material, with a density between 8 g/cm3 and 10 g/cm3 , - the outer surface of the liner adjacent to the explosive and the inner surface of the liner are made as surfaces of rotation with a common axis, with a wide open edge called the base and a narrow part on the other side called the top , - the opening angle α at the base of the insert is determined between two opposite tangents of the meridians of the inner surface at the base, - the inner diameter D of the base of the insert is from 60 mm to 75 mm, the safety and loading mechanism can be an independent bottom detonator a rba top-bottom part of the detonator working together with the piezoelectric generator (10) to form an electrical circuit between them, a conductor (7) inserted into the wave shaper, a conductive cone (8), an insulating compression ring (9) or an electrical cable, or other elements used in the electrical circuit, but differing in that the contour of the inner surface of the insert is formed as a line without breaking points, located inside a figure formed by small arcs of two circles passing through the ends of the line segment connecting the base of the insert to the top from the inside, the beginning of the rounding of the apex , the origin of the cylindrical part, or another vertex in its upper part, the radii of the circles equal to two and a half the length of the given segment, and their centers on opposite sides of this segment, the double angle between the segment and the axis of the insert being between 23° and 125°; at the same time, parallel to the outer surface at a distance l from the base along the axis of the insert, the thickness of the insert δl is indicated, determined along the normal to the inner surface, l is from 2 mm to 8 mm, when δl is in the range from 1.2 mm to 3 mm, and δl does not exceed 2.6 mm if an explosive material with a density ρ < 1.7 g/cm3 is used for the charge. The warhead, according to point 1, differs in that its opening angle α at the base of the insert satisfies the condition: 15° ≤ α < 25°, depending on the density ρ of the explosive material used, the value of the thickness δl is selected in the range from 1.31 mm to 2, 01 mm when 1.6 g/cm3 ≤ ρ < 1.7 g/cm3 , the value of δl is chosen in the range from 1.43 mm to 2.16 mm when 1.7 g/cm3 ≤ ρ < 1.8 g/ cm3 , the value of δl is chosen in the range of 1.55 mm to 2.31 mm for 1.8 g/cm3 ≤ ρ < 1.9 g/cm3 , and the value of δl is chosen in the range of 1.66 mm to 2.45 mm, when 1.9 g/cm3 ≤ ρ ≤ 2 g/cm3 . The warhead, according to point 1, differs in that its opening angle α at the base of the insert satisfies the condition: 25° ≤ α < 35°, depending on the density ρ of the explosive material used, the value of the thickness δl is selected in the range from 1.36 mm to 2, 08 mm when 1.6 g/cm3 ≤ ρ < 1.7 g/cm3 , the value of δl is chosen in the range from 1.48 mm to 2.23 mm when 1.7 g/cm3 ≤ ρ < 1.8 g/ cm3 , the value of δl is chosen in the range of 1.60 mm to 2.37 mm for 1.8 g/cm3 ≤ ρ < 1.9 g/cm3 , and the value of δl is chosen in the range of 1.71 mm to 2.52 mm, when 1.9 g/cm3 ≤ ρ ≤ 2 g/cm3 The warhead, according to point 1, differs in that its opening angle α at the base of the insert satisfies the condition: 35° ≤ α < 45°, depending on the density ρ of the explosive material used, the value of the thickness δl is selected in the range from 1.41 mm to 2, 14 mm when 1.6 g/cm3 ≤ ρ < 1.7 g/cm3 , the value of δl is chosen in the range from 1.53 mm to 2.29 mm when 1.7 g/cm3 ≤ ρ < 1.8 g/ cm3 , the value of δl is chosen in the range of 1.65 mm to 2.44 mm for 1.8 g/cm3 ≤ ρ < 1.9 g/cm3 , and the value of δl is chosen in the range of 1.76 mm to 2.59 mm, when 1.9 g/cm3 ≤ ρ ≤ 2 g/cm3 . The warhead, according to point 1, differs in that its opening angle α at the base of the insert satisfies the condition: 45° ≤ α < 55°, depending on the density ρ of the explosive material used, the value of the thickness δl is selected in the range from 1.46 mm to 2, 21 mm when 1.6 g/cm3 ≤ ρ < 1.7 g/cm3, the value of δl is chosen in the range from 1.58 mm to 2.36 mm when 1.7 g/cm3 ≤ ρ < 1.8 g/ cm3 , the value of δl is chosen in the range of 1.70 mm to 2.51 mm for 1.8 g/cm3 ≤ ρ < 1.9 g/cm3 , and the value of δl is chosen in the range of 1.81 mm to 2.65 mm, when 1.9 g/cm3 ≤ ρ ≤ 2 g/cm3 . The warhead, according to point 1, differs in that its opening angle α at the base of the insert satisfies the condition: 55° ≤ α < 65°, depending on the density ρ of the explosive material used, the value of the thickness δl is selected in the range from 1.51 mm to 2, 28 mm when 1.6 g/cm3 ≤ ρ < 1.7 g/cm3 , the value of δl is chosen in the range from 1.63 mm to 2.42 mm when 1.7 g/cm3 ≤ ρ < 1.8 g/ cm3 , the value of δl is chosen in the range of 1.75 mm to 2.57 mm for 1.8 g/cm3 ≤ ρ < 1.9 g/cm3 , and the value of δl is chosen in the range of 1.86 mm to 2.72 mm, when 1.9 g/cm3 ≤ ρ ≤ 2 g/cm3 . The warhead, according to point 1, differs in that its opening angle α at the base of the insert satisfies the condition: 65° ≤ α < 75°, depending on the density ρ of the explosive material used, the value of the thickness δl is selected in the range from 1.56 mm to 2, 34 mm when 1.6 g/cm3 ≤ ρ < 1.7 g/cm3 , the value of δl is chosen in the range from 1.68 mm to 2.49 mm when 1.7 g/cm3 ≤ ρ < 1.8 g/ cm3 , the value of δl is chosen in the range of 1.80 mm to 2.64 mm for 1.8 g/cm3 ≤ ρ < 1.9 g/cm3 , and the value of δl is chosen in the range of 1.91 mm to 2.79 mm, when 1.9 g/cm3 ≤ ρ ≤ 2 g/cm3 . The warhead, according to point 1, differs in that its opening angle α at the base of the insert satisfies the condition: 75° ≤ α < 85°, depending on the density ρ of the explosive material used, the value of the thickness δl is selected in the range from 1.61 mm to 2, 40 mm when 1.6 g/cm3 ≤ ρ < 1.7 g/cm3 , the value of δl is chosen in the range from 1.72 mm to 2.55 mm when 1.7 g/cm3 ≤ ρ < 1.8 g/ cm3 , the value of δl is chosen in the range of 1.84 mm to 2.70 mm for 1.8 g/cm3 ≤ ρ < 1.9 g/cm3 , and the value of δl is chosen in the range of 1.96 mm to 2.85 mm, when 1.9 g/cm3 ≤ ρ ≤ 2 g/cm3 . The warhead, according to point 1, differs in that its opening angle α at the base of the insert satisfies the condition: 85° ≤ α ≤ 125°, depending on the density ρ of the explosive material used, the value of the thickness δl is selected in the range from 1.65 mm to 2, 47 mm when 1.6 g/cm3 ≤ ρ < 1.7 g/cm3 , the value of δl is chosen in the range from 1.77 mm to 2.62 mm when 1.7 g/cm3 ≤ ρ < 1.8 g/ cm3 , the value of δl is chosen in the range of 1.89 mm to 2.77 mm for 1.8 g/cm3 ≤ ρ < 1.9 g/cm3 , and the value of δl is chosen in the range of 2.01 mm to 2.92 mm, when 1.9 g/cm3 ≤ ρ ≤ 2 g/cm3. The warhead, according to point 3, differs in that the insert is made as a side surface of a right circular cone, and the opening angle α, which is the same throughout the insert, meets the condition: 25° ≤ α < 35°. The warhead, according to point 10, differs in that, depending on the density of the explosive material used ρ, the difference in the opening angles of the outer and inner surfaces (β - α) is selected in the range from 0°45' to 1°15', when 1.6 g /cm3 ≤ ρ < 1.7 g/cm3 , (β - α) is chosen in the range from 0°50' to 1°20', when 1.7 g/cm3 ≤ ρ < 1.8 g/cm3 , (β - α) is chosen in the range from 0°55' to 1°25' when 1.8 g/cm3 ≤ ρ < 1.9 g/cm3 , (β - α) is chosen in the range from 1° to 1°30' when 1 .9 g/cm3 ≤ ρ ≤ 2 g/cm3 . The warhead, according to point 4, differs in that the insert is made as a side surface of a right circular cone, and the opening angle α, which is the same throughout the insert, meets the condition: 35° ≤ α < 45°. The warhead, according to item 12, differs in that, depending on the density ρ of the explosive material used, the difference in the opening angles of the outer and inner surfaces (β - α) is selected in the range from 1° to 1°30', when 1.6 g/cm3 ≤ ρ < 1.7 g/cm3 , (β - α) is chosen in the range from 1°5' to 1°35', when 1.7 g/cm3 ≤ ρ < 1.8 g/cm3 , (β - α) is chosen in the range from 1°10' to 1°40' when 1.8 g/cm3 ≤ ρ < 1.9 g/cm3 , (β - α) is chosen in the range from 1°15' to 1°45' when 1 .9 g/cm3 ≤ ρ ≤ 2 g/cm3 . The warhead, according to point 5, differs in that the insert is made as a side surface of a right circular cone, and the opening angle α, uniform throughout the insert, meets the condition: 45° ≤ α < 55° The warhead, according to point 14, differs in that, depending on the density ρ of the explosive material used, the difference in the opening angles of the outer and inner surfaces (β - α) is selected in the range from 1°15' to 1°45', when 1.6 g /cm3 ≤ ρ < 1.7 g/cm3 , (β - α) is chosen in the range from 1°20' to 1°50', when 1.7 g/cm3 ≤ ρ < 1.8 g/cm3 , (β - α) is chosen in the range from 1°25' to 1°55' when 1.8 g/cm3 ≤ ρ < 1.9 g/cm3 , (β - α) is chosen in the range from 1°30' to 2° when 1 .9 g/cm3 ≤ ρ ≤ 2 g/cm3 . The warhead, according to point 6, differs in that the insert is made as a side surface of a right circular cone, and the opening angle α, which is the same throughout the insert, meets the condition: 55° ≤ α < 65°. The warhead, according to point 16, differs in that, depending on the density ρ of the explosive material used, the difference in the opening angles of the outer and inner surfaces (β - α) is selected in the range from 1°30' to 2°, when 1.6 g/cm3 ≤ ρ < 1.7 g/cm3 , (β - α) is chosen in the range from 1°35' to 2°5', when 1.7 g/cm3 ≤ ρ < 1.8 g/cm3 , (β - α) is chosen in the range from 1 °40' to 2°10' when 1.8 g/cm3 ≤ ρ < 1.9 g/cm3 , (β - α) is chosen in the range from 1°45' to 2°15' when 1.9 g/cm3 ≤ ρ ≤ 2 g/cm3. The warhead, according to point 7, differs in that the insert is made as a side surface of a right circular cone, and the opening angle α, which is the same throughout the insert, meets the condition: 65° ≤ α < 75°. The warhead, according to point 18, differs in that, depending on the density ρ of the explosive material used, the difference in the opening angles of the outer and inner surfaces (β - α) is selected in the range from 1°45' to 2°15', when 1.6 g /cm3 ≤ ρ < 1.7 g/cm3 , (β - α) is chosen in the range from 1°50' to 2°20', when 1.7 g/cm3 ≤ ρ < 1.8 g/cm3 , (β - α) is chosen in the range from 1°55' to 2°25' when 1.8 g/cm3 ≤ ρ < 1.9 g/cm3 , (β - α) is chosen in the range from 2° to 2°30' when 1 .9 g/cm3 ≤ ρ ≤ 2 g/cm3 . A warhead according to any of the preceding claims, characterized in that the liner is made of metals, including bimetals, or metal alloys, including powders and pseudoalloys, or metal polymers, preferably with an anti-corrosion coating A warhead according to any of the preceding claims, characterized in that the insert is made of copper with a total impurity content of less than 0.1% by mass. A warhead according to any one of the preceding claims, characterized in that the thickness of the liner along any parallel of the inner or outer surface is determined along the normal of the inner surface and the deviation is less than ±0.05 mm. A warhead according to any of the preceding claims, characterized in that the liner additionally includes mounting and/or actuation elements. A warhead according to any of the preceding claims, characterized in that the warhead additionally includes a fragmentation portion.