DE20012858U1 - Bulletproof door leaf or wall element - Google Patents

Description

Arm.: RWD Schlatter AG
__ N/BLU-034-EN ·

Bullet-resistant door leaf or wall element

The innovation concerns a bullet-resistant door leaf or wall element with a ballistic textile surface structure.

To create bullet-resistant door panels, it is known to use so-called armored plywood, which is a melamine resin-impregnated plywood with a high density of around 1,400 kg/m ^3. Good ballistic properties or good bullet resistance are offset by a number of disadvantages that reduce the utility of such an armored door. A door with such a door panel is very heavy, which requires appropriate measures on the door frame and hinge side, and the durability, which means the warping of the door under temperature differences, as well as the sound insulation and fire resistance are not optimal.

The use of ballistic textile fabrics is generally known for bullet resistance, for example from AT-373 068 in the form of a flexible light armor plate that combines such fabrics with plastic plates for use in protective clothing or vehicle armor. The use of a ballistic textile fabric in a door leaf is known from the document WO95/20714. The door leaf shown there supplements a door leaf with such armor on one side, which requires a special construction of the frame or edge banding of the door leaf and results in bullet resistance that is not equally effective on both sides.

The innovation is therefore based on the task of creating a door leaf that does not have the disadvantages mentioned and combines good door-technical properties with high bullet resistance. A similar task exists with bullet-resistant wall elements for the formation of lightweight walls, which are structurally -

Slc/db03921DE

like a door - also good sound and fire protection properties with a light and cost-effective construction,
and possibly also climatic protection, with as much
high bullet resistance.
The task is carried out on a door leaf or

Wall element of the type mentioned above with the characterizing features of claim 1.

Due to the construction with a fibreboard core
or foamed core and ballistic textile fabric on both sides as well as rigid outer elements
a door leaf or a wall element is created which
due to the fibreboard core or foamed
core can provide very good sound and fire protection and with the double-sided armouring of the core with the ballistic

static surface structure provides a high level of bullet resistance that is equally effective from both sides. The relatively soft fibreboard material or foamed material provides good energy absorption in addition to sound insulation.
of deformations of the surface structure and thus supports the bullet resistance. The relatively soft core forms
Furthermore, a catch area for projectiles, which
armor and reduces their energy before hitting the second armor. The
The rigid outer element gives the door leaf or the wall element a high level of stability and thus allows the use of the relatively soft core with the textile surface structure, which is also considered soft for the door or wall formation.

It is preferable to provide an air gap inside the core to increase sound insulation
and to allow increased core deformation when shot, which in combination with the textile fabrics increases the bullet resistance. It is also preferred if the fiberboards of the core are made of non-combustible or hardly combustible material, e.g.
Mineral fibres or fire-retardant treated natural fibres,

I · · · 4

e.g. coconut fibers. When using foamed material, e.g. foam glass is preferred.

The ballistic textile fabric adjoining the core is preferably a fabric made of highly tear-resistant fibers, in particular aramid filament yarns, which can be used as such a fabric or as a prepreg coated with a duromer, thermoplastic or elastomer or as a laminate further formed from the prepreg.

The rigid outer element is preferably made of a wood material, whereby hard wood fiber boards are preferred for high durability. To achieve a special climate resistance of the door leaf or wall element (increased climate class), a thin metal insert can be provided, e.g. between the textile fabric and the outer element or in this outer element, whereby this thin metal insert has practically no influence on the bullet resistance and therefore does not mean that metal armor is intended. In the following, preferred embodiments of the innovation are explained in more detail with reference to the drawings.

Figure 1 is a view of a door leaf; Figure 2 is a vertical sectional view through the door leaf of Figure 1 along the line A-A; and

Figure 3 is a horizontal sectional view through the door leaf of Figure 1 along the line B-B.

Figure 1 shows a view of a door leaf 1, in which the edge band 5 and the lock woods 6 are indicated by broken lines. A vertical cross-section along the line A-A through the door leaf 1 is shown in Figure 2, whereby the sectional view shows the individual layers of the door leaf in thicknesses that are not to scale for better graphic representation. The door leaf 1 has a core 2, which is formed from a fiberboard material. In the

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In the example shown, the core 2 is formed by the fiberboards 2' and 2", which form an air gap 10 between them. The air gap 10 can be ensured by spacers (not shown), e.g. cardboard strips. Instead of the core 2 shown as an example of two fiberboards, the core 2 could also consist of a single piece made of a correspondingly thicker fiberboard or of more than two fiberboards. Accordingly, there may be no air gap 10 or, if there are several boards, more than one air gap 10 may be provided. The fiber core 2 is formed from a fiberboard material with a relatively low density. The resulting relatively soft core forms good sound insulation on the one hand, which is further increased by the preferred air gap 10, and on the other hand forms a catch area for projectiles, which interacts with the actual armor in a manner to be described below. The fiber material core 2 preferably has mineral fiberboards. These can, for example, have a density in the range of 250 kg/m ³ - 320 kg/m ³ and preferably a density of approx. 280 kg/m ³ and, for example, have a thickness of 16 mm each or, in another example, a thickness of 21 mm each. The preferred use of non-combustible mineral fiber boards gives the door leaf a high fire resistance, whereby, for example, in the case of a door leaf with 16 mm thick mineral fiber boards, this can be a fire resistance T3 0 according to the Swiss fire protection regulations of the Association of Cantonal Fire Insurers (VKF) or the corresponding CEN standard. Instead of mineral fiber boards (which term also includes glass fiber boards in this case), other relatively light fiber board materials can also be used, e.g. fiber boards made of natural fibers, such as coconut fibers. These fibers also provide good sound insulation, especially with an air gap 10, and work together with the armoring to be explained later to provide bullet resistance. In such cases

It is preferred for fiberboards if they are made fire-retardant by a known treatment. Instead of or in combination with the preferred fiberboards, boards made of foamed materials can also be used, which preferably have a similar density and are non-flammable or only slightly flammable. The foamed material is preferably foam glass, but the term also includes all other foamed or foamable materials.

A textile fabric 3 is provided on the outside of the core 2 and is used as armor against bullets. Such textile fabrics, which can be in the form of a woven, knitted or braided fabric, for example, are known.

Highly tear-resistant plastic or carbon fibers are processed into the corresponding textile fabric. By coating the fabric or knitted fabric or braid with a plastic material, a so-called prepreg material is created from the fabric or knitted fabric or braid, which can be easier to handle during use. Such prepregs can be further processed into a laminate, which is known. For the present use of such textile fabrics, which can be called ballistic textile fabrics due to their bullet-resistant properties, all three of the above-mentioned forms are possible. Preferably, however, a coated fabric 3, i.e. a so-called prepreg, is used in each case, with the preferred example being the material Ultrax® WO 9116 from Verseidag-Indutex GmbH, Krefeld, Germany, which is an elastomer-coated fabric made of various highly tear-resistant fibers. This fabric has a thickness of approximately 5.15 mm and is used in the example shown as a single layer textile fabric 3 on both sides of the core. Of course, a two- or multi-layer arrangement on both sides of the core 2 would also be possible. However, it has been shown that

by combining the material mentioned with the soft core 2, a high level of bullet resistance can be achieved with just one layer 3 on each side of the core 2. This results in an interaction between the ballistic textile fabric 3 and the soft core, which absorbs deformation of the textile fabric 3 and distributes it over a relatively large area, or which core forms a catch area for the projectile when it passes through the fabric 3 in front of it and also slows it down before it reaches the fabric 3 behind it in the direction of fire, so that this fabric can prevent the door leaf from being shot through. Tests have shown that with a core made of 16 mm thick mineral fiber boards and a single layer of the ballistic textile fabric mentioned made of the material Ultrax®, bullet resistance in class FB4 according to the draft of the CEN standard prEN 1522-1 for security doors can be achieved.

Since the textile fabric 3 is arranged on both sides of the door in the direction of fire before and after the core 2, symmetrical conditions generally result for the fire, i.e. the door leaf has the same bullet resistance on both sides; however, it is of course also possible to achieve different bullet resistances for the firing directions by asymmetrical arrangement or thickness of layers, e.g. one layer 3 of the core on the one hand and two layers 3 of the core on the other. The textile fabric 3 is inserted on both sides of the core, preferably beyond the core and into the edge band 5, as can be seen from Figure 2 and also from Figure 3. This results in protection of the edge band 5, which consists of hardwood, for example, on the one hand, and on the other hand, an option for fastening the fabric to the edge band 5, e.g. by gluing. The fabric 3 is further preferably

attached to the core 2 by gluing, whereby this gluing may be only partial or substantially full-surface.

To form the door leaf, a rigid flat element 4 is now provided on each side, which gives the door leaf the necessary stability, which is not provided by the relatively soft core and the armoring with the textile surface structure 3. In order to maintain the light and narrow structure made possible by the core 2 and the armoring 3, the rigid flat element 4 is preferably made of a material containing wood, preferably hardboard. According to DIN 68753, hardboard or hard wood fiberboard (HDF/high density fiberboard) is understood to mean wood fiberboard with a gross density of more than 800 kg/m ^3. Medium-hard wood fiberboard (MDF/medium density fiberboard) with a gross density between 350 kg/m ³ - 800 kg/m ³ can also be used for the rigid flat outer element 4. Such wood fiber boards give the door leaf a very high level of stability and form a hard and smooth surface. This can be further treated in a known manner with decorative panels or with paint. In the embodiment shown, the rigid flat element 4 is made up of two wood fiber boards 4' and 4" on both sides of the core. These wood fiber boards are in turn glued to one another, whereby this can be done partially or essentially over the entire surface, and the element 4 thus formed is also glued to the textile surface structure 3, whereby this can also be done partially or essentially over the entire surface. Instead of the element 4 being made up of two wood fiber boards, only one board can of course be provided. This board or the boards are guided in a known manner up to the front side of the edge banding and are also attached to it by gluing or possibly by fastening elements. The thickness of the wood fiber boards is e.g. 8 mm when using one board on each side of the door leaf or e.g.

two times 4 mm or two times 3.2 mm when using two plates each.

It is also possible to provide a further layer between the textile surface structure 3 and the rigid outer element 4, in particular to improve the climatic properties of the door leaf, which allows it to be classified in a higher climate class. In the example shown, such a layer could also be provided between the wood fiber boards 4' and 4", whereby such a layer is, for example, a very thin metal layer, e.g. an aluminum layer, which has no relevant influence on the bullet resistance.

Figure 3 shows the corresponding structure in a horizontal section along the line B-B of Figure 1, whereby in this figure the lock wood 6 is also visible, which in this case forms part of the core 2 and is covered by the textile surface structure 3 on both sides.

A door leaf according to the embodiment of the innovation shown has a density of approx. 680 kg/m ³ , which offers a significant reduction compared to the density of the armored plywood mentioned at the beginning. The door leaf nevertheless has the aforementioned bullet resistance according to FB4 and offers high climatic protection and sound insulation as well as high fire resistance (T3 0) as well as thermal insulation and burglary protection. The same properties can also be achieved by a wall element for lightweight construction, which is constructed in the same way as described using the example of the door leaf, whereby of course the lock wood 6 can be dispensed with in such a case. This results in lightweight wall elements which nevertheless have a high level of bullet resistance on both sides, whereby this is achieved by the shown and preferred symmetrical structure of the wall

element or the door leaf is identical from both firing directions.

Claims (14)

1. Bullet-resistant door leaf ( 1 ) or wall element with ballistic textile surface structure ( 3 ), characterized by a core ( 2 , 2 ', 2 ") made of fiberboard material and/or foamed material, on both sides of which a ballistic textile surface structure ( 3 ) is arranged towards the outside, which is followed in each case towards the outside by a rigid surface element ( 4 , 4 ', 4 "). 2. Bullet-resistant door leaf ( 1 ) or wall element according to claim 1, characterized in that the core ( 2 ) is formed by fiberboards ( 2 ', 2 "), which in particular leave an air gap ( 10 ) between them. 3. Bullet-resistant door leaf ( 1 ) or wall element according to claim 1 or 2, characterized in that the fiberboards ( 2 ', 2 ") comprise mineral fiberboards. 4. Bullet-resistant door leaf ( 1 ) or wall element according to claim 3, characterized in that the mineral fiber panels have a density in the range of 250-320 kg/m ³ , in particular approximately 280 kg/m ³ . 5. Bullet-resistant door leaf ( 1 ) or wall element according to one of claims 1 to 4, characterized in that the fiberboards comprise natural fiberboards, in particular coconut fiberboards. 6. Bullet-resistant door leaf ( 1 ) or wall element according to claim 1, characterized in that the core ( 2 ) is formed by foam glass, in particular by two or more foam glass panels, which optionally enclose one or more air gaps between them. 7. Bullet-resistant door leaf ( 1 ) or wall element according to one of claims 1 to 6, characterized in that the ballistic textile fabric ( 3 ) is a fabric made of aramid filament yarns. 8. Bullet-resistant door leaf ( 1 ) or wall element according to one of claims 1 to 7, characterized in that the ballistic textile fabric ( 3 ) is provided as a fabric or as a prepreg or as a laminate. 9. Bullet-resistant door leaf ( 1 ) or wall element according to one of claims 1 to 8, characterized in that the rigid flat element ( 4 ) is formed from a material containing wood, in particular from wood fiber boards, in particular from hard wood fiber boards or medium-hard wood fiber boards. 10. Bullet-resistant door leaf ( 1 ) or wall element according to claim 9, characterized in that each element ( 4 ) is formed by two or more panels ( 4 ', 4 "). 11. Bullet-resistant door leaf ( 1 ) or wall element according to one of claims 1 to 10, characterized in that a metal insert, in particular an aluminum layer, is provided between the ballistic textile sheet structure and the rigid sheet element or in the latter. 12. Bullet-resistant door leaf ( 1 ) or wall element according to one of claims 1 to 11, characterized in that the core and the ballistic textile fabric ( 3 ) are partially or substantially fully bonded to one another. 13. Bullet-resistant door leaf ( 1 ) or wall element according to one of claims 1 to 12, characterized in that the ballistic textile sheet structure ( 3 ) and the rigid sheet element ( 4 ) are partially or substantially fully bonded to one another, optionally via a metal intermediate layer. 14. Bullet-resistant door leaf ( 1 ) or wall element according to one of claims 1 to 13, characterized in that it is provided with an edge band ( 5 ) made of wood material, in particular hardwood, and optionally with a lock wood ( 6 ) made of wood material, in particular chipboard material, which lie essentially on the inside of the ballistic textile fabrics ( 3 ).