CZ270694A3 - Device for protection from high-velocity armour piercing means - Google Patents

Abstract

The proposed device comprises a capsule (1) whose cavity is packed with an explosive charge (2). Two capsule walls (3, 4) which face each other are constructed as protective plates, and each of the other walls (5) is multi-layered; the ratio of the acoustic impedances of the materials in contiguous layers (6 and 7, 7 and 8, 8 and 9) is not less than 2.

Description

Apparatus for protection against high-speed abrasive means

Technical field

The invention is. concerns the area of protection of objects against high-speed armor-piercing means, in particular the Dro facility for the protection of objects against cumulative combat ammunition and anti-armored subcaliber bullets.

BACKGROUND OF THE INVENTION

There is known a device for protection against high-speed armaments, representing a closed box in which the cavity is filled with an explosive (PCT SE 00132). Two opposing walls of said box are designed as cover plates movable relative to each other.

Upon the impact of an anti-armored cumulative projectile into the box, the cumulative beam causes detonation of the explosive charge filling the box cavity. The gaseous fumes of the explosion will set the two reversing plates in motion, which intersect the trajectory of the cumulative beam, disrupting it, reducing its armor-piercing ability. However, an explosion of an explosive charge that fills the cavity of the box also affects adjacent boxes. The shock wave produced by the explosion propagates from the point of explosion in all directions. The impact on the explosive charge filling the cavity of an adjacent box is a shock wave capable of initiating an explosion of the charge. Further development of this process can lead to an uncontrolled explosion of explosive charges of all boxes arranged on the protected object. In this way, all the boxes arranged on the protected object can be destroyed in one impact of the cumulative armor. The object not only loses its anti-cumulative protection _; but it can also suffer damage by the simultaneous explosion of a large explosive mass on its surface. Analogous effects can also occur with the impact of armored subcaliber missiles, if the explosive charge in the box shows sufficient sensitivity to initiate explosions in it due to such missiles.

In order to eliminate these undesirable effects in the known apparatus, it is proposed to deposit a material that effectively suppresses the shock wave parameters between adjacent boxes. However, the mentioned mate ·? The material incorporated in the construction of the device is an additional structural element, which complicates the construction of the known device. In addition, when using a given material, the charges of explosives of adjacent boxes are separated from each other at a distance generally substantially exceeding the diameter of the cumulative beam and often the diameter of the armored subcaliber bullet. Upon impact on the recess of this material, a cumulative beam or an armored subcaliber bullet can penetrate in the direction of the protected object and do not cause an explosion of the explosives in the boxes.

The object protection * performed in the above manner is of a discrete nature; Well-protected parts alternate with thinner bands, the area of which, depending on the material used and its thickness, can be up to 30 percent of the protected area of the object.

SUMMARY OF THE INVENTION

The object of the present invention was to provide a device for. protection against high-speed armor-piercing means with such a construction of closed box walls that would allow to significantly reduce the area of the weakened bands and thereby increase the degree of protection of the object.

The given task is solved by the _fact: that the apparatus for protection against high speed penetrating means constituting in itself a closed box jejeíž two opposite walls are designed as cover plates relative to each other movable, and the cavity is filled with explosive, capable detonate on impact broadband průhojného means. According to the invention, each of the remaining walls of the box is multilayered and consists of at least three layers, wherein the acoustic strength of the adjacent layer materials is at least 2.

Desirably, the thickness of each layer of said walls should be between 0.0005 and 0.4 of the distance between the cover plates.

The choice of the thickness of the layers of said walls at the lower limit is determined by the technological expediency of the production of these layers as well as by the necessity to ensure that the explosion cannot be transferred to the adjacent box. The upper limit of the wall thickness of said walls is selected from the condition of reliably initiating the explosion of the explosive.

Such a construction considerably simplifies both the construction of the device according to the invention as a whole and the technology of manufacturing the box.

In order to ensure reliable initiation of the explosive upon impact of the high-velocity armor device on the inventive platform, it is necessary that the ratio of explosive mass to inert binder in the charge material be at least 4: 1.

DETAILED DESCRIPTION OF THE INVENTION

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is explained in detail below by way of example of a specific embodiment with reference to the accompanying drawings, in which Fig. 1 is a longitudinal sectional view of a device for protection against high-speed armor-piercing means of the invention;

Fig. 2 is the same as in Fig. 1, but using a second variant of the closed box construction according to the invention, in longitudinal section.

The device for protection against high velocity penetration means provided in accordance with the invention is a closed box 1 / FIG. Whose cavity is filled with an explosive charge.

The box 1 may be in the form of a parallelepiped, prism or cylinder whose two opposing walls are in the form of cover plates 3 and 4 movable relative to each other. The other walls 5 of the bead 1 are multilayered and consist of four layers 6, 7, 8 and 9. The minimum number is three. The ratio of the acoustic Deviations of the materials of the adjacent layers 6 and 7, 7 and 8, 8 and 9 is at least 2. The thickness of each layer 7, 7, 8 and 9 of said walls 5 is 0.005 to 0.4 of the distance between the cover plates 3 and 4.

The operation of the device according to the invention takes place as follows:

Upon impact of the cumulative armor-piercing missile or armor-subcaliber missile on the device according to the invention, the high-velocity armor pierces the cover plate 3 and penetrates the explosive charge 2 and initiates its explosion. Under the action of the gaseous fumes, the cover plates 3 and 4 move in a direction perpendicular to the surface of the cover plates 3 and 4. During the displacement of the cover plates 3 and 4, they intersect the trajectory of the movement of the high-speed armor. Simultaneously with the gaseous fumes of the explosive explosive charge 2, the cover plates 3 and 4 disperse the cumulative beam into individual fragments and divert them from the original direction of movement. As a result of such action, the individual fragments of the cumulative beam do not fall on the cavern floor formed in the protected box (not shown) by the preceding parts of the cumulative beam. In this way, the depth of this cavern does not increase, and as a result, the armor-piercing cumulative beam decreases. Impact of the cover plates 3 and 4 on the surface of the body of the armored subcaliber bullet leads to the formation of micro- and macrodefects. In doing so, the bullet acquires an angular speed of rotation, as a result of which its anti-armor action decreases.

Simultaneously with the movement of the cover plates 3 and 4, the detonation wave propagating from the explosive charge 2 reaches the walls 5 of the box 1. The shock wave formed in the inner layer 9 of the wall 5 propagates in the direction of the outer surfaces of the wall 5. 9 and 8, 8 and 7, 7 and 6 formed from materials of different acoustic strength. The so-called explosion decomposes at the boundary of the layer transition when, for example, from a material with a higher acoustic strength (layer 9) into a material with a lower sound strength (layer 8), a so-called explosion decay. 9 with higher acoustic strength, a decomposition wave is produced. This proceeds from the boundary of the interface of the layers 8 and 9 to the inner surface 11 of the wall 5, relieving the impact compressed material of the layer 9 to its original state. The passing shock wave in the layer 8 material has a lower parameter value at its front (pressure, mass velocity) than the shock wave front in layer 9. The difference between

- The 5 parameter values at the front of the shock wave, falling from a more acoustically strong environment into a less acoustically strong environment, are proportional to the ratio of the acoustic strengths of both environments. Experimentally it has been found that this ratio must not be less than 2. In addition, the reduction of the parameters at the front of the passing shock wave in layer 8 is accompanied by irreversible energy losses of the incident shock wave resulting from the shock-wave compression process. by cutting its boundary at the boundary of layers 8 and 7, 7 and 6, where the above-mentioned explosion decay process repeats, and the parameters at the front of the shock wave further decrease in the manner described. To the detriment of lateral decomposition propagation from wall surfaces 5 adjacent to The cover plates 3 and 4 also undergo a reduction in the dimensions of the shock wave front.

It is known that in the multilayer walls the lateral decomposition waves propagate at an angle of the order of 40 ... 50 degrees, which is more than in the monolayer walls. In this way, in the shock wave propagation process in the layers 9, 8, 7 and 6 of the wall 5, both the parameters at the front of the shock wave and the magnitude of the shock wave itself are reduced. Upon reaching the outer surface 10 of the wall 5 with a shockwave, this passes into; the same wall of the adjacent box 12 (in its existence) in which the shock wave propagation process is analogous.

Due to the multiple passage of the boundary at the stated ratio of acoustic strength as well as the loss of compression of the wall layer material 5 by the shock wave and the reduction of the shock wave front value, it loses the ability to initiate an explosion of the explosive when it reaches the explosive. the mass of the explosive and the inert binder in the charge material exceeds 4: 1.

It has been experimentally found that for charges 2 filling the cavity of a box 1 containing an explosive and an inert binder in a ratio of at least 4: 1, a reliable initiation upon impact of the high-velocity armor is guaranteed while impossibility to initiate the shock wave from the explosion of the adjacent box 12.

When selecting the thickness of the layers 6, 7, 8 and 9 of the wall 5 of the box 1, it is necessary to take into account the following factors:

- 6 side, the minimum thickness of each of layers 6, 7, 8 and 9 must be sufficient Dro needed to reduce the shock wave parameters resulting from the explosion of explosive 2 filling the cavity of the box 1.

Consequently, the minimum thickness of said layers is determined by the dimensions of the cavity of the box 1 as well as the characteristics of the explosive 2 (detonation rate, specific explosion temperature) filling the cavity. Moreover, the minimum thickness of said layers is determined according to the conditions of technological expediency in their manufacture. On the other hand, the maximum thickness of these layers must be such that at least one of them is reacted upon impact of the cumulative beam or armor projectile. Consequently, the maximum thickness of each of these layers is determined by the cumulative beam diameter, taking into account the actual cumulative beam scattering in the area bounded by a cone with a spatial apex angle of 1 to 1.5 degrees / dimension of this scattering area. 1 /. These considerations also determine the need for the explosive 2 to contact the inner surface 11 of the wall 5.

Taking into account all of the above, the thickness of the layers 6, 7, 8 and 9 is chosen in the range of 0.0005 to 0.4 of the distance between the cover plates 3, 4.

In those cases where a box with said multilayer walls 5, as shown in Fig. 2, is used in the high-speed armor protection device according to the invention, these walls are made by flanges 13 and 14 of the cover plates 3 and 4, the gap between them is completely or partially filled with a non-metallic, e.g. lacquer, material 15, wherein one flashing, preferably the flashing 13, touches the explosive. Such a design considerably simplifies the technology of manufacturing the box 1.

The operation of the device according to the invention in such a construction of the box 1 takes place analogously to that described above.

Industrial applicability

The most efficient use of the device according to the invention is in the form of a set of said devices as reactive armor, which

- 7 is installed on armored ground objects: tanks,

Director

V.I. Šaškin s p

PATENT CLAIMS

Claims (12)

PATENT CLAIMS I. A device for protection against high-speed armaments, constituting a closed box 1 _{K of} which two opposing walls 3, 4 are in the form of cover plates movable relative to each other and whose cavity is filled with a charge 2 of explosives, characterized in that each of the other walls 5 of the box 1 is multilayered and consists of at least three layers 6, 7, 8 and 9, respectively. wherein the ratio of the sound strengths of the materials of adjacent layers 6 and 7, 7 and 8, 8 and 9 is at least 2. Device according to claim 1, characterized in that the thickness of each layer 6, 7, 8 and 9 of said walls 5 is 0.0005 to 0.4 of the distance between the cover plates 3, 4. Device according to claim 1, characterized in that the three-layered embodiment of said walls 5 is each formed by flanges 13, 14 of the cover plates 3,4 and the gap between them comprises non-metallic material 15 and one of the flanges 13 is in contact with the explosive charge 2. . 4. The apparatus of claim 1 wherein the ratio of explosive mass to inert binder in the charge material is at least 4: 1. A set of devices according to any one of claims 1 to 4. A set according to claim 5, suitable for armored ground objects. An armored ground object according to claim 6, representing a tank itself. The armored ground object of claim 6, representing About you> 3h'eSÍ ~. An armored ground object according to claim 6, representing ABOUT YAy 6ofr / o, The assembly of claim 5 adapted to Dro building objects. An assembly according to claim 5, adapted for river or sea vessels. Assembly according to claim 5, adapted for transport containers.