KR100197828B1 - Device to provide protection from high velocity projectiles - Google Patents

Abstract

The invention relates to a container (1) with a cavity filled with explosive material (2). Two walls 3 and 4 of the container 1 facing each other are configured in the form of a protective plate, and the other walls 5 each have a multilayer structure.

The relationship between the acoustic intensities of the materials in adjacent layers 6 and 7, 7 and 8 and 8 and 9 is two or more.

Description

Protection against high speed weapons

In the prior art, protection against high speed weapons in the form of closed containers in which the cavity is filled with explosive materials is known (PCT / SE / 00132). Both walls of the container are provided with protective plates that are movable relative to each other.

When the hollow charge projectile strikes a container-shaped protector, a hollow-charge blast in the hollow charge explodes the explosive material filled in the cavity of the container. The explosion of explosives produces gaseous explosive products, which act to cause the shroud to destroy the explosives across the trajectory of the explosive, reducing the explosive's ability to penetrate.

By this principle, the protection device for the high speed weapon of the prior art was able to protect the object against the hollow-loaded weapon. However, the explosion of explosive material filled in the hollow part of the container can also act on other adjacent containers apart from exploding explosives. The shock waves generated by the explosion of explosive materials propagate in all directions from the center of the explosion. If such shock waves are delivered to explosive materials in adjacent containers, explosive materials in adjacent containers may explode. If this process continues, it is impossible to control the propagation of shock waves to explosive substances in all containers installed on the object to be protected. Thus, the single cost of the hollow charge weapon may destroy all containers installed on the object to be protected. As a result, the object to be protected not only loses protection against the hollow charge weapon, but may also be damaged by a chain explosion of heavy, explosive material on the surface of the object. Likewise, the same result may occur if a rigid cored shell penetrating the barrier is sensitive enough to strike the container or explosive material in the container to be exploded by the projectile.

To prevent this problem, a protective device has been proposed in which a material is provided which can effectively dampen shock waves between adjacent containers.

However, the material for damping shock waves provided in the interior of the device thus complicates the construction of conventional devices as additional structural members. In addition, the use of such materials separates explosive materials in adjacent containers by a certain distance, which is typically larger than the diameter of the explosive, and sometimes larger than the diameter of the hard cored shell that penetrates the barrier. When the explosive material is separated by a certain distance, the explosives penetrate the object to be protected without exploding the explosive material in the container.

The protection of an object implemented by this method has the disadvantage that a selectively vulnerable area is formed depending on the thickness of the material used, which may occupy up to about 30% of the total protected area of the object.

The present invention relates to a protection device for a high speed destruction weapon, and more particularly, to a protection device for a high speed hollow-charge weapon.

The protection device for the high-speed weapon of the present invention is very preferably used for protecting an object against a hollow-loaded weapon or a hard core shell through a barrier.

Hereinafter, some preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a longitudinal sectional view of a protective device for a high-speed weapon according to the present invention.

2 is a longitudinal section similar to that of FIG. 1 showing another embodiment of a closed container according to the invention.

* Explanation of symbols for main parts of the drawings

1: closed container 2: explosive substance

3,4 protector 5: wall

6,7,8,9 (layered) layer 13,14: collar

15 non-metallic material

It is a primary object of the present invention to provide a protection device for a high speed weapon in the form of a closed container with a wall configured to significantly reduce the area of vulnerability and thus increase the level of protection of the object.

The objective is to have two guard plates that face each other and move relative to each other, and the cavity between these shields is a closed container filled with explosive material that can explode when being bombarded by a high speed projectile. In the protection device for a high-speed weapon consisting of, characterized in that between the two sides of the protective plate of the closed vessel, materials having two or more acoustic strength relations adjacent to each other are formed three or more layered walls, respectively.

The thickness of each layer constituting such a wall is 0.0005 to 0.4 times the distance between the guard plates.

The minimum thickness of the wall is determined by the state of manufacture and the necessity of the layers to prevent the propagation of the explosion shock to adjacent containers. The upper limit of the thickness of the wall layer is defined by the reliable explosion conditions of the explosive material.

Such a configuration simplifies the manufacture of the closed container as well as the configuration of the overall device.

The explosive material filling the cavity of the container consists of an explosive component (ie RDX) and an inert binder (non-explosive component). The uncertainty binder is a mechanical mixture of high molecular polymers (ie polyisobutylene) and inert materials such as industrial oils. It serves to reduce the sensitivity of these inert materials to the desired level.

The relationship between the weight of explosive components in explosives and the weight of inert binders must be at least 4: 1 in order to reliably explode when high-speed weapons strike a protective device.

The protection device for a high-speed weapon according to the present invention consists of a closed container 1 as shown in FIG. 1, wherein the cavity of this container 1 is filled with explosive material 2.

The container 1 may consist of parallelograms, prisms, cylinders or the like comprising two guard plates 3, 4 which are opposed to each other and move relative to one another. In the container 1 a wall 5 consisting of four layers 6, 7, 8, 9 is formed between both sides of the protective plates 3, 4, respectively. This wall 5 is usually formed of three or more layers of materials having two or more acoustic intensity relations adjacent to each other. That is, adjacent layers 6 and 7, 7 and 8, and 8 and 9 are composed of materials having a relationship of two or more acoustic intensities. In addition, the thickness of each layer 6, 7, 8, 9 constituting the wall 5 is 0.0005 to 0.4 times the distance between the two protective plates 3, 4 facing each other.

The operation of the device according to the invention is described below.

As the explosives of the hard core shells penetrating the hollow-load projectile or the barrier strike the protective device, the explosives of the hollow-load projectiles or core shells penetrate the shield plate 3 and come into contact with the explosive material 2 Explode.

Due to the action of the gaseous explosion product formed by such an explosion, the protective plates 3, 4 start to move in a direction perpendicular to the surface thereof. The shrouds 3 and 4 move across the trajectory of the high-speed weapon, combine with the explosive product in the gaseous state by the explosion of the explosive material (2) to disperse the explosive into individual fragments and disperse the dispersed fragments in the initial direction of movement. Depart from As a result, the individual debris of the explosive cannot enter the bottom of the cavity formed inside the object (not shown) to be protected by the explosive advancement. Therefore, the depth of the cavity does not increase because the penetration force of the explosive is reduced. The impact of the protective plates 3, 4 by the protective plate through core shells causes large and small defects in the protective plates 3,4. The shell has an angular speed that adversely affects its penetration.

With the movement of the guard plates 3, 4, a shock wave propagating through the explosive substance 2 reaches the wall 5 of the container 1. Shock waves that develop in the inner layer 9 of the wall 5 propagate towards the outer surface 10 of the wall 5. These shock waves travel continuously across the boundary area between layers 9 and 8, 8 and 7, and 7 and 6 of materials of different acoustic intensities. For example, when the shock wave travels from the layer 9 of material with high acoustic strength to the layer 8 of material with small acoustic strength, the so-called disintegration of explosion on the interface between adjacent layers. This occurs, i.e., a relief shock wave is formed in the layer 9 of the material having a large intensity, while a passing shock wave is formed in the layer 8 of the material having a small acoustic intensity. The mitigated shock wave travels from the interface of adjacent layers 8 and 9 toward the inner surface 11 of the wall 5 and restores the material of the layer 9 compressed by the laminar wave to its initial state. The front part of the shock wave passing through the layer 8 has a smaller variable (pressure, mass, velocity) than the front part of the shock wave passing through the layer 9. The difference between the value of the variable in the front of the shock wave transmitted from this acoustically high intensity medium to the medium of low intensity is proportional to the relationship between the acoustic intensities of each medium. Experimentally, the relationship of acoustic intensity between these materials is at least two. In addition, the reduction of the variables in the front of the shock wave passing through the layer 8 provides the irreversible energy loss of the shock wave generated during the compression of the layer 9 due to the shock wave.

As the shock wave continues to move across the interface between the other layers (8 and 7, and 7 and 6), the splitting of the explosion as described above is repeated, and likewise the values of the variables at the front of the shock wave are continuous. Is reduced.

The propagation of the lateral shock waves from the surface of the wall 5 adjacent the guard plates 3, 4 reduces the magnitude of the front of the shock waves. Typically, the mitigated lateral shock waves within a multi-layer wall travel at an angle greater than the shock wave propagating in the monolayer wall, that is, between about 40 ° and 50 °. Therefore, as the shock wave moves through the layers 9, 8, 7, 6 that make up the wall 5, both the magnitude of the variables at the front of the shock wave and the magnitude of the front of the shock wave are appropriately reduced. When the shock wave reaches the outer surface 10 of the wall 5, the shock wave passes back to the wall of the adjacent container 12 and propagates in the same manner.

As the shock wave is repeatedly moved across the different interfaces having the above-described acoustic intensity relationship, the compressive force of the shock wave on the material layer constituting the wall 5 is reduced and the size of the front portion of the shock wave is reduced. Shock waves that reach explosive materials in adjacent containers 12 lose their ability to ignite explosive materials even when the ratio between the weight of the explosive component in the explosive material and the weight of the inert binder exceeds 4: 1.

According to the experiment, if the ratio of the weight of the explosive component in the explosive material 2 filling the container 1 to the weight of the inert binder is less than 4: 1, the explosive material 2 is reliably exploded at the time of high-speed weaponry. It can be seen that the shock wave generated by the explosion of the explosive substance in the adjacent container 12 does not explode.

When selecting the thickness of each layer 6, 7, 8, 9 that constitutes the wall 5 of the container 1, the following points should be taken into account. In other words, the minimum thickness of the layers 6, 7, 8, 9 constituting the wall 5 should be sufficient to reduce the parameters of the shock wave generated by the explosion of the explosive material 2 in the container 1. . Thus, the minimum thickness of the layers 6, 7, 8, 9 constituting the wall 5 is determined by the properties (explosion rate, heat of explosion) of the explosive material 2 in the container 1.

In addition, the maximum thicknesses of the layers 6, 7, 8, and 9 that make up the wall 5 are such that when the hollow charge projectile or core shell strikes the contact area between two adjacent vessels 1, 12. At least one of the two containers must be destined to explode. Thus, the maximum thickness of each layer is determined by the diameter of the explosive or core shell, taking into account the natural dissipation of the explosive within the area formed by the cone at an angle of 1 to 1.5 ° from the vertex (natural dissipation). The size of the area depends on the distance between the container 1 and the hollow charge projectile). It is also necessary to take into account the essential contact between the explosive material 2 and the inner surface 11 of the wall 5.

Based on this point of view, the thicknesses of the layers 6, 7, 8, 9 constituting the wall 5 are selected in the range of 0.0005 to 0.4 times the distance between the guard plates 3 and 4.

As shown in FIG. 2, a protection device for a high-speed weapon according to another embodiment of the present invention uses a container 1 having a wall 5 composed of a plurality of layers, which wall 5 is a protective plate ( 3, 4, and three layers of non-metallic materials 15, such as paint or varnish, which are partially or wholly filled in the gap between these collars 13,14. One of the collars 13 is in contact with the explosive material 2.

According to this embodiment, there is an advantage that the manufacture of the container 1 is simplified. The protection device for high-speed weapons with such a container 1 preferably works as described above.

The protection device for the high-speed weapon of the present invention can be preferably used in such fields as ground vehicles such as tanks, armored vehicles, personal vehicles, self-propelled launchers, building structures, transport vehicles, and river or marine vessels. .

Claims (4)

Consisting of a closed container (1) having two guard plates (3,4) facing each other and capable of moving relative to one another and having a cavity between the guard plates (3,4) filled with explosive material (2), In the protection device for high-speed weapons, between two sides of the protective plates 3, 4 of the container 1, materials having two or more acoustic strength relations are adjacent to each other and have three or more layers 6, 7, 8, 9. A protection device for a high-speed weapon, characterized in that walls (5) forming 13, 14, and 15 are formed respectively. The weapon according to claim 1, wherein the thickness of each of the layers 6, 7, 8, 9 constituting the wall 5 is 0.0005 to 0.4 times the distance between the guard plates 3, 4. Protection against 3. The wall (5) according to claim 1, wherein the wall (5) consists of three layers of nonmetallic material (15) filled in the gap between the collars (13,14) of the guard plates (3,4) and the collars (13,14). And the collar (13) is connected to the explosive substance (2). The protection device for a high-speed weapon as claimed in claim 1, wherein the relation between the weight of the explosive component in the explosive substance (2) and the weight of the inert binder is at least 4: 1.