DE102009057052B4 - Bulk material and protective module containing such material for protection against military threats - Google Patents

Abstract

A bulk material consisting of a multitude of shock-absorbing individual elements, characterized by its use in the form of a bulk material as protective material on vehicles and objects for protection against military threats, in particular from shaped charges, mines or impact projectiles. The bulk material (2) can be poured into a housing (1) to form a protective module for protecting vehicles and objects against military threats.

Description

The invention relates to a bulk material consisting of a plurality of shock-absorbing individual elements as well as a protective module containing such a material for protecting vehicles and objects against military threats.

It is known to protect vehicles and objects against military threats, such as shaped charges, mines or impact missiles by protective modules and armor plates.

Such a protection module is for example in DE 10 257 942 A1 described. It consists of a material or contains a material that is designed as a three-dimensional metallic grid structure or open-cell metal foam.

A composite armor plate for the protection of vehicles or buildings from armor-piercing projectiles with high kinetic energy is z. In DE 10 2005 013 660 A1 described. It contains at least one layer of high-hardness, for example made of alumina ceramic elements, which are arranged within a matrix of a potting compound.

All of these protective devices have the disadvantage that their production is relatively complicated and that they are difficult to adapt to more complicated structures on or in vehicles or buildings.

The DE 103 24 273 A1 discloses a Schüttgutpanzerung in which the bulk material particles are spherical. A disadvantage of this configuration is that when filled cavity due to the high packing density of the balls, a high weight of the bulk material armor arises.

The invention has for its object to design a bulk material armor such that it has a lower weight with good protection.

The invention is based on a bulk material which consists of a plurality of shock-absorbing individual elements. The damping properties of bulk material are known in principle and are used, for example, in packaging for the protection of sensitive objects or devices during transport.

A basic idea of the invention is that a material in the form of a bulk material can be used as a protective material on vehicles and objects for protection against military threats, in particular by shaped charges, mines or impact projectiles, since it easily becomes more complicated due to its flexibility as bulk material can be adjusted.

The individual elements of the bulk material may have very different spatial structures according to the invention. Thus, in a first embodiment according to the invention, each individual element has at least two interconnected sub-elements formed essentially as thin, flat plates, wherein at least two of these plates lie in different planes intersecting in the region of the junction of the plates.

In a second embodiment of the invention, the individual elements are formed so that each individual element is formed as a thin at least in some areas curved strip.

It is possible that each individual element has at least one partial element which is connected to other partial elements and is designed as a thin, curved strip. In this case, the sub-elements are preferably integrally and materially connected to each other. Finally, the individual elements may be chip-shaped in a manner known per se.

The bulk material may also consist of a mixture of individual elements with different spatial structure.

It is particularly advantageous if the individual elements are so asymmetrically constructed that they are not stackable. This effect can also be achieved by widely spread tolerances (tolerance overlaps) of identical individual elements. In this way, settling phenomena caused by vibration are avoided in the bed, and the material retains a high proportion of air volume with low overall weight.

In order to achieve a high shock absorption, it is advantageous if the individual elements or at least a subset of the individual elements in the bulk material has at least one resiliently formed part element.

The individual elements may consist of a metallic material, for example of spring steel. But it is also possible to form the individual elements of a ceramic material or a plastic material. Furthermore, the individual elements can also consist of an irreversibly deformable material or of a material with a defined brittleness. In brittle materials, the damping effect is due to the energy-consuming "Breaking work" achieved in the destruction of the individual elements.

The aim of all these training is that the bulk material in the poured state between the individual elements has a high intermediate volume and has good overall shock-absorbing properties.

Furthermore, it may be advantageous if the individual elements of the bulk material are coated on its surface with a material having a predetermined adhesive effect, so that after the bed, the resulting overall structure of the material is fixed.

For particular applications, it is also advantageous if, in at least a subset of the bulk material, the elements each consist of at least two identically shaped individual elements, which are sandwiched with the interposition of an adhesive layer and interconnected. For example, each element may be composed of two individual elements made of a KTL-coated spring steel sheet with an adhesive layer of polyurethane disposed therebetween. Of course, the bond can also be made with other inorganic or organic adhesives, so for example epoxy resins, polyesters or silicones. Furthermore, it is also possible to use elastomers by means of which the elements can be connected to one another by vulcanization.

The application of the bulk material as a protective material against military threat can be done in such a way that it is poured directly into cavities or depressions on the outside of a vehicle or other object. In practical applications, it may be advantageous to provide a protection module having a housing into which the bulk material can be poured. This housing can be closed with a cover. In the housing, the bulk material may also be arranged in a plurality of separate layers by gaps. If the bulk material consists of resiliently formed individual elements, it may also be advantageous if it is set in the housing, for example by placing a cover under a predetermined bias.

Another advantage of the bulk material according to the invention is that it can be incorporated not only in cavities on the outside of a vehicle or object, but also in cavities located inside a vehicle or object. Thus, for example, it can be introduced into a liquid tank of a vehicle, for example into a niche tank of a battle tank, as a result of which the tank acquires greater stability and at the same time acts as a protection module. Since these cavities in tanks usually made of elastomers (rubber), the bed also acts as a support body with emptied or teilentleertem tank. Furthermore, the introduced elements in vehicle tanks counteract rapid fluid movements (anti-swirling) while driving. Again, it may be advantageous if the individual elements of the bulk material are connected to each other in the tank by point bonding and thus form a stable matrix. The bulk material is therefore also suitable as a retrofit solution to increase the protection.

In the following, embodiments of the bulk material in its application according to the invention will be explained in more detail with reference to the accompanying drawings.

In the drawings show:

1 in plan view and schematic representation of an open housing with introduced bulk material;

2 to 5 each in a perspective view possible forms of the individual elements of the bulk material;

6 in perspective partial representation of a battle tank with niche tanks;

7 in a schematic representation in longitudinal section a niche tank after 6 with incorporated bulk material;

8th the closed niche tank after 6 in a supervision;

9 in enlarged partial section a part of the niche tank after 7 ; and

10 one of two individual elements according to 2 sandwiched element.

1 shows an open case 1 in the a bulk material 2 is introduced, which consists of individual elements of different spatial structure. The individual elements of the bulk material 2 are preferably formed and the mixture is made so that as possible no stacking effects occur. The housing 1 can be closed in a manner not shown by a cover and the resulting protection module can also be arranged in a manner not shown on a vehicle or building. The 2 to 5 show possible single elements 2.1 . 2.2 . 2.3 and 2.4 the bulk material, which may be formed of spring steel, for example. However, other metallic or non-metallic materials are also conceivable here.

These in the 2 to 5 shown structures of the individual elements are only examples, there are also other structures possible, in particular structures in which the individual elements contain curved formed sub-elements or are constructed in total of curved sub-elements. They can for example also be chip-shaped.

6 shows a part of a main battle tank KP with a vehicle body 4 that on a tracked chassis 3 is built over the chains are in the chain guard 5 American tank 6.1 and 6.2 arranged to receive a liquid fuel. The in 7 to 9 illustrated niche tank 6.1 with a filling opening 6.11 and connecting pieces 6.12 and 6.13 is with a bulk material 7 filled in the 7 and 9 schematically indicated as crosshatching. This way is through the niche tanks 6.1 and 6.2 achieved an increase in ballistic protection.

10 shows the structure of an element sandwiched from two individual elements according to FIG 2 is constructed. The two individual elements 2.11 and 2.12 are stacked and over an adhesive layer 2.13 made of polyurethane. There are the individual elements 2.11 and 2.12 made of KTL-coated spring steel sheet. The thickness of the individual elements may be, for example, 1 mm, while the thickness of the polyurethane adhesive layer may be 3 mm, for example.

Claims (22)

From a variety of shock absorbing individual elements existing bulk material for use in the form of bulk material as a protective material on vehicles and objects for protection against military threats, in particular by shaped charges, mines or impact missiles, characterized in that at least a subset of the individual elements each individual element at least has two interconnected, substantially thin, planar sub-elements, wherein in each case at least two of these sub-elements lie in different, intersecting in the region of their junction planes. From a variety of shock-absorbing individual elements existing bulk material for use in the form of bulk material as a protective material on vehicles and objects for protection against military threats, in particular by shaped charges, mines or impact projectiles, characterized in that at least a subset of the individual elements each element as thinner, at least in partial areas of curved strip is formed. Bulk material according to claim 2, characterized in that at least a subset of the individual elements each individual element has at least one sub-element which is connected to other sub-elements and is formed as a curved strip. Bulk material according to claim 2 or 3, characterized in that at least a subset of the individual elements each individual element is chip-shaped. Bulk material according to claim 1, 3 or 4, characterized in that the sub-elements are integrally connected to each other and of the same material. Bulk material according to one of claims 1 to 5, characterized in that in at least a subset of the individual elements each individual element is constructed asymmetrically such that the individual elements of this structure are not stackable. Bulk material according to one of claims 1 to 5, characterized in that in at least a subset of the individual elements, the individual elements in a structure having the same geometry such tolerance overlaps that individual elements of this structure are not stackable. Bulk material according to one of claims 1 to 7, characterized in that at least a subset of the individual elements each individual element has at least one resiliently formed part element. Bulk material according to one of claims 1 to 8, characterized in that the individual elements consist of a metallic material. Bulk material according to one of the claims 2 to 8, characterized in that the individual elements consist of a ceramic material. Bulk material according to one of claims 1 to 7, characterized in that the individual elements consist of a plastic material. Bulk material according to one of claims 1 to 8, characterized in that the Individual elements consist of an irreversibly deformable material. Bulk material according to one of claims 1 to 7, characterized in that the individual elements consist of a material with a defined brittleness. Bulk material according to one of claims 1 to 13, characterized in that the individual elements are coated on their surface with a material having a predetermined adhesive effect. Bulk material according to one of the preceding claims, characterized in that at least one subset of the elements each consist of at least two identically shaped individual elements, which are sandwiched with the interposition of an adhesive layer and connected to each other. Bulk material according to claim 15, characterized in that each element is constructed of two individual elements of KTL-coated spring steel sheet with a layer of polyurethane disposed therebetween. Protection module for the protection of vehicles and objects against military threats, in particular by shaped charges, mines or impact projectiles, characterized in that it comprises a housing in which a bulk material according to any one of claims 1 to 16 is poured. Protection module according to claim 17, characterized in that the material in the form of a bulk material is arranged in the housing in a plurality of layers separated from one another by intermediate spaces. Protection module according to claim 17 or 18, characterized in that the bulk material in the housing is set under a predetermined bias. Use of a bulk material according to any one of claims 1 to 16, characterized in that it is introduced on or in the vehicle or object existing cavities. Use of a bulk material according to any one of claims 1 to 16, characterized in that it is introduced into a liquid tank of a vehicle. Use of a bulk material according to claim 21, characterized in that the individual elements of the bulk material in the liquid tank ( 6.1 ) are connected to each other by spot bonding.

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