RU2726761C1 - High-explosive anti-tank warhead - Google Patents

Abstract

FIELD: military equipment.SUBSTANCE: invention relates to military equipment, namely to high-explosive anti-tank warhead, and can be used for hitting armored targets. High-explosive anti-tank warhead consists of housing, in which there is an explosive charge with copper cumulative facing, detonating fuse consisting of piezogenerator and safety-actuating mechanism, between cumulative facing and safety-actuating mechanism there is a tube made of material having speed of sound exceeding speed of detonation of explosive charge.EFFECT: technical result is higher efficiency of striking armored targets equipped with dynamic protection.1 cl, 4 dwg

Description

The proposed invention relates to military equipment, namely to cumulative ammunition, and can be used to destroy armored targets (tanks, infantry fighting vehicles and armored personnel carriers).

Known cumulative ammunition type PG-29V (http://militaryrussia.ru/blog/topic-439.html). It consists of two cumulative warheads located one after the other. The front warhead (precharge) fires first and breaks through protective screens and removes reactive armor. The main warhead is triggered second and directly hits the armor of the combat vehicle. The front and main warheads are spatially separated from each other.

However, this design has disadvantages. The main disadvantage is the need for spatial separation of the charges of the first and second stages and ensuring the protection of the main charge from the action of the precharge of the first stage.

Known cumulative ammunition (RF Patent No. 2218546 F42B 12/18 dated 10.12.13), containing a tandem warhead having a leading cumulative charge (LKZ) and a main warhead (warhead), located between them a steering drive unit (BRP) and a device protection of the main warhead, characterized in that the protection device is made in the form of a closed volume separate from the body of the controlled projectile, formed by a cylindrical glass with a bottom in the form of a truncated cone directed towards the main warhead, and a front wall made in the form of a massive cylindrical disk, on which installed LKZ, while the glass and disk are made of plastic material, and the PDU is placed in a closed volume.

However, this design has disadvantages. The main disadvantage is the need for spatial separation of the charges of the first and second stages and ensuring the protection of the main charge from the action of the precharge of the first stage.

In addition, known ammunition (warhead for an unguided aircraft missile S8 KOM, drawing 9-GZh-4421 (see Fig. 1)), which is a prototype, and consisting of a body (1), an explosive charge (BB) (2) with a cumulative copper lining (3), a fuse consisting of a piezoelectric generator (4) and a safety-actuator (5).

The disadvantage is that the prototype has insufficient effectiveness against armor equipped with reactive armor.

The task (technical result) of the proposed invention is to increase the efficiency when hitting targets equipped with dynamic protection.

The task is solved due to the fact that in the cumulative ammunition, consisting of a body in which an explosive charge with a copper cumulative lining is located, a fuse consisting of a piezoelectric generator and a safety-actuating mechanism, a tube made made of a material having a speed of sound exceeding the detonation speed of the explosive charge. The tube can be made, for example, of an alumina-based ceramic.

Also, the tube can be made of two layers, with the inner layer made of a material with a high melting and evaporation temperature, for example, niobium. The melting and evaporation points of niobium are 2477 ° C and 4744 ° C, respectively. The inner layer should ensure the formation of a continuous metal high-speed cumulative jet.

In FIG. 2 shows a general view and section of the proposed cumulative ammunition: 1 - body; 2 - explosive charge; 3 - shaped copper cladding; 4 - piezoelectric explosive device; 5 - safety-actuating mechanism of the explosive device; 6 - tube made of material with the speed of sound exceeding the detonation speed of the explosive charge.

To substantiate the performance of the proposed cumulative ammunition, experiments were performed on the explosive compression of ceramic tubes made of ceramics based on aluminum oxide.

In FIG. 3 shows a diagram of the experimental assembly: 7 - electric detonator; 8 - initiating charge; 9 - main charge; 10 - ceramic tube; 11 - target; 12 - base.

In FIG. 4. the front sides of the witness specimens exposed to cumulative jets formed from ceramic tubes of various thicknesses are shown: 13-δ = 0.5 mm; 14-δ = 1.0 mm, 15-δ = 1.5 mm.

The device operates as follows (see Fig. 2). When the piezoelectric generator of the explosive device (4) hits the target obstacle (tank, BMP, armored personnel carrier), a high voltage pulse is transmitted to the safety-actuating mechanism of the explosive device (5) and initiates detonation in the explosive charge (2). The detonation front, propagating along the explosive charge, squeezes the tube (6) made of material at a high speed of sound onto the axis of the ammunition, which leads to the formation of a hyperspeed cumulative jet. Since the speed of sound in the tube material exceeds the detonation speed of the explosive charge, the conditions for jet formation are met in accordance with the theory of cumulation. In particular, in the work [Generation of hyperspeed flows of particles during explosive compression of ceramic tubes / I.А. Balagansky, L.A. Merzhievsky, V.Yu. Ulyanitsky, I.A. Bataev, A.A. Bataev, A.V. Vinogradov [et al.] // Physics of Combustion and Explosion. - 2018. - T. 54, No. 1. - pp. 132-138.] Describes experiments on the formation of hyperspeed jets of ceramic particles from corundum tubes and their effect on targets made of high-carbon steel. The experimental setup is shown in Fig. 3, the effects on the targets are shown in FIG. 4. The maximum speed of the leading part of the jet is ~ 23 km / s, the speed of the main jet is 14 km / s. Such a jet penetrates the screens and neutralizes the dynamic protection of the armored vehicle. Then the detonation process reaches the main cumulative lining (3) and compresses it with the formation of a copper cumulative jet, which penetrates the main armor protection. At the same time, due to the ultra-high speed of the leading jet from the tube, the timing of the action of the first and second stages of the tandem is coordinated.

It is possible to manufacture two-layer tube (6). In this case, the outer part of the tube is made of a material with a high speed of sound, and the inner part is made of a plastic material with a high melting and evaporation temperature. Numerical modeling showed that in this case a continuous cumulative jet is formed from the material of the inner layer. In this case, it is necessary to ensure a high melting and evaporation temperature of the material of the inner layer of the tube [Balagansky I.A. Modeling of fast jet formation under explosion collision of two-layer alumina / copper tubes / I.A. Balagansky, A.V. Vinogradov, L.A. Merzhievsky // The International Journal of Multiphysics. - 2017. - Vol. 11, no. 3. - P. 265-275. - DOI: 10.21152 / 1750-9548.11.3.265.].

The technical result consists in increasing the effectiveness of destruction of armored targets equipped with dynamic protection.

Claims (2)

1. Shaped ammunition, consisting of a body in which an explosive charge with a cumulative lining is placed, a fuse consisting of a piezoelectric generator with a safety-actuating mechanism, characterized in that between the shaped-charge lining and the safety-actuating mechanism there is a tube made of a material having the speed of sound exceeding the speed of detonation of the explosive charge. 2. The shaped charge ammunition according to claim 1, characterized in that the tube is made of two layers, while the inner layer is made of a material with a high melting and evaporation temperature.

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