DE4122876C2 - Floor or wall covering to avoid floor ricochets - Google Patents

Description

The invention relates to a floor or wall covering to avoid projectile ricochets, behind one The outer covering absorbs the projectile energy Foam layer is provided.

Such a covering is known from US 4,856,791. Of the The outer surface is formed by a rubber miplate. To the DE-GM 81 03 770 is absorbed as projectile energy Layer a rubber granulate mixture proposed and as Outside covering a rubber layer. Furthermore, DE 34 18 626 A1 known a crash protection, in which on a Steel plate a rubber layer and a foam layer are arranged.

As experiments have shown, a projectile collides with one Rubber sheet with high energy when it comes with a Impact angle of less than about 20 °. The well-known Coverings are therefore not for effective impact safety suitable.

DE 39 37 087 describes the establishment of armored rooms Component known, which has an armor plate and behind it gives a honeycomb structure and rigidity. The The component can be patterned on the outside, such as a wallpaper pattern.

DE 34 09 768 A1 shows a shooting range in which the floor, which alternates from rubber layers and  Steel plates are made with a non-slip rubber covering is provided.

From EP 0 432 031 A1 armor is known, the outside with a ceramic auxiliary plate with a variety of Blind holes is provided, an armor plate inside has and between the auxiliary plate and the armor plate has a honeycomb structure as a spacer. At the The projectile should pass through the auxiliary plate from the side be slit so when it is on the at the distance arranged armored plate hits, burst.

US 4,111,097 shows lightweight armor, which penetrated one with a tungsten wire mesh on the outside Has foam layer and behind it a steel plate, a honeycomb structure and a fiberglass panel. The Steel plate, the honeycomb structure and the fiberglass plate should be the energy of the fragments of the floor record, which disassembled through the tungsten wire mesh becomes.

A vehicle armor is known from US 4,404,889 has a steel plate on the outside and inside and in between a honeycomb structure.

The object of the invention is a floor or wall covering to provide high surface load capacity with which Bullets even with a very small impact angle can be braked safely.

This is the invention with that in the claim marked covering reached.

The floor or wall covering according to the invention can be anywhere there be used where expected to use firearms must become. These are not just shooting ranges, but also  Airports, banks, high security wings and the like public and industrial buildings and facilities.

An embodiment of the invention is shown below the drawing explained in more detail. In it shows

Fig. 1 shows a cross section through a lining; and

Fig. 2 shows a section along the line II-II of FIG. 1.

The covering essentially consists of three layers, namely an outer covering 1 , a honeycomb structure 2 and a layer 3 absorbing the projectile energy, and rests on a floor 4 or a wall.

In particular, if the covering is used as a floor covering, the outer covering 1 is designed as a carpet, for example as a pile carpet with a dense pile 5 and a thin back 6 , to which the pile 5 is attached.

However, the outer covering 1 can also consist of another material, for example a plastic layer or of a wallpaper, a film or the like, if the covering according to the invention is used as a wall covering.

However, the outer covering 1 must not show any rubber-elastic behavior, since, as mentioned above, rubber coverings can cause the projectile to bounce off with high residual energy. Accordingly, the outer covering 1 must consist of a relatively hard, brittle material, and be relatively thin, so that it can be safely penetrated by a projectile even at a relatively small impact angle. For this reason, the back 6 of the pile carpet is also formed by a thin, primer that is as brittle as possible.

The honeycomb structure 2 is provided on both sides with a cover layer 7 , 8 .

The lamellae 9 to 12 of the honeycomb structure 2 which extend between the cover layers 7 , 8 can be formed from plastic, paper, cardboard, aluminum or the like. The honeycomb structure 2 gives the covering in the vertical direction the high surface load capacity of at least 450 t / m ² required in the construction industry for floor coverings, which is necessary so that it can e.g. B. withstands women's shoe heels, luggage trolleys, chair casters and the like.

The cover layers 7 and 8 take over the load distribution on the slats 9 to 12 .

The foam energy-absorbing layer 3 is preferably a plastic foam layer, preferably made of a small and closed-cell foam with a relatively high density of more than 0.3 g / cm ³ , preferably more than 0.4 g / cm ³ to have sufficient load capacity. Extruded polystyrene, but also extruded polyethylene foam have proven to be particularly suitable.

The layer 3 which absorbs the projectile energy also serves for sound insulation and impact sound insulation.

The floor 4 or wall can be concrete or any other building material, including steel.

The carpet 1 is bonded to its back 6 with the covering layer 7 and the projectile energy-absorbing foam layer 3 with the layer 8 of the disc layer. 2

These adhesive layers and the cover layers 7 , 8 may in turn not exhibit rubber-elastic behavior, ie they should be as brittle and thin as possible. Thus, all glass-hard curing two-component synthetic resin systems are suitable as adhesives, while the cover layers 7 , 8 are preferably formed by fiber-reinforced, in particular glass or carbon fiber reinforced, plastics. Examples of suitable plastics are epoxy resin or, in view of the lower risk of fire, phenolic resin.

With regard to fire protection, the other components of the covering are also made of flame retardant materials. Likewise, the outer covering 1 is preferably designed to be electrically conductive in order to prevent electrostatic charges.

When a projectile 13 hits the covering at a flat angle of, for example, 7 °, it penetrates the thin, brittle layer sequence from the back 6 , the cover layer 7 and the intermediate adhesive layer and then penetrates into the honeycomb structure 2 .

It penetrates the lamellae 9 to 12 arranged one after the other in its trajectory ( FIG. 2). Since the slats 9 to 12 are arranged at a distance from one another which is smaller than the length 1 of the projectile 13 , it is guided through the slats 9 to 12 to a certain extent. This means that the projectile 13 is prevented from escaping through an uncontrolled flight behavior. At the same time, the projectile energy is reduced when penetrating the slats 9 to 12 .

As tests have shown, the projectile 13 then runs along the cover layer 8 at an impact angle of 7 ° until its energy is completely used up.

The path length of the projectile in the honeycomb structure 2 can be influenced by the type, thickness and spacing of the slats 9 to 12 .

At a steeper angle of 20 ° or more, for example, the projectile 13 penetrates the honeycomb structure 2 , including the cover layer 8 , and then penetrates into the energy-absorbing foam layer 3 . Depending on how thick the energy-absorbing layer 3 and how large the angle of incidence is, the projectile 13 can then either get stuck in the energy-absorbing layer 3 or penetrate it.

If the energy-absorbing layer 3 is penetrated by the projectile 13 , it either runs along the surface of the floor 4 or it is retouched, ie it bounces off the floor 4 and penetrates again into the energy-absorbing layer 3, as a result of which its residual energy is destroyed.

At a very steep angle, in particular an angle of incidence of 90 °, the projectile 13 penetrates through the covering undeformed, its energy being destroyed by impact on the floor 4 by deformation. If it is dismantled, the residual energy of the projectile parts in the energy-absorbing layer 3 is destroyed.

Dismantling of the projectile 13 when it hits the surface is prevented in any case, since the energy shock which the projectile experiences upon impact is too small to disassemble it.

The described mode of operation of the described covering could be proven by experiments.  

Since the usable space is reduced by the covering, a minimum covering thickness is generally sought. This means that the thickness of the honeycomb structure 2 and the energy-absorbing layer 3 should be as small as possible. The required thickness of the honeycomb structure 2 depends primarily on the material, the thickness, the spacing of the lamellae 9 to 12 and the floor diameter. It is generally between 0.5 and 5 cm. Apart from the thickness of the honeycomb structure 2 , the required thickness of the energy-absorbing layer 3 depends in particular on the material density. It is generally between 2 and 10 cm.

Claims (1)

Floor and wall covering in order to avoid Geschoßabprallern, a the projectile energy-absorbing foam layer is provided at the rear an outer covering, characterized in that between the outer covering (1) and the foam layer (2) provided with covering layers (7, 8) honeycomb structure (2 ) is arranged.