EP2407746A2 - Protection system for protecting an object against military threats - Google Patents

Abstract

The equipment has a coupling element (6) provided between two supports (3, 4). Ballistic protection bars (2) are pressure-decoupled or train-coupled connected with one another over an outer surface (5) of the equipment. The protection bars are pulled by back springs over the coupling element at the outer surface. LED ends of the coupling element are provided with a behind grip and inserted into an aperture of the protection bars. A damping element is placed opposite to a protection element.

Description

The invention relates to a protective equipment for protecting an object against military threats with ballistic protective elements, which are arranged on supports with a predetermined distance on an outer surface of the object to be protected.

Many types of objects, such as containers, bunkers and vehicles, are exposed to military threats worldwide, especially in crisis areas. To protect such objects or those located in these objects Persons are provided with the endangered objects with protective equipment intended to protect the object against military threats.

Ballistic threats are widespread, which have a more selective effect on the object to be protected, for example ballistic projectiles. In addition, especially threats due to explosions are widespread. For example, in the case of an explosive attack, high explosion pressures develop, from which gas waves of high kinetic energy, also referred to as blast, are generated, which act more extensively on the object to be protected.

In the case of known protective equipment, the various threats, on the one hand due to areal blast effect and on the other hand due to rather selective ballistic threats, are always regarded as isolated problems which are to be solved by various measures.

For protection against ballistic threats protective equipment with ballistic protective elements, for example, from solid armor steel plates are usually used, which are arranged on supports on the outer surface of the object to be protected and there releasably secured, for example by screwing. The arrangement of the ballistic protective elements can be made adjacent to the outer surface of the object to be protected or at a predetermined distance from the outer surface.

To protect against Blasteinwirkung these flat ballistic protective elements contribute little, since they yield under the influence of a blast pressure and sag in the direction of the object to be protected. In order to protect the endangered objects also from Blasteinwirkung To be able to, therefore, often consuming additional measures are taken, for example, by stiffening the housing structure of a military vehicle by a corresponding ribbing.

Object of the present invention is to provide a protective equipment that allows both a ballistic protection and over conventional protective equipment in a structurally simple way blast protection.

This object is achieved in a protective equipment of the type mentioned in that a coupling element is provided between two supports, via which the protective element and the outer surface against each other pressure-decoupled and coupled to each other zuggekoppelt.

The arrangement of such a coupling element between two supports of the ballistic protective elements results in an improved protection of the object to be protected in the case of a blast effect, without thereby the ballistic protective properties of the protective elements would be adversely affected. It is not necessary to equip the object for protection against Blasteinwirkung in a structurally complex manner with extensible stiffeners, for example in the form of ribbing.

In an advantageous embodiment of the invention it is proposed that the protective element under Blasteinwirkung in the region of the coupling element in the direction of the outer surface to the collision with the outer surface is elastically freely deflectable. Due to the freely deflectable arrangement of the elastic protective element of this can deform elastically due to a Blasteinwirkung in the direction of the underlying outer surface of the object to be protected. Due to the decoupling of pressure, no forces will be present at first the outer surface of the object to be protected is applied, so that it does not initially bend, but deforms only the outside of the object to be protected arranged protective element.

In this context, it is also advantageous if the coupling element is designed such that the protective element pulls on the return spring on the coupling element on the outer surface to counteract a deflection of the outer surface to the inside. After the collision of the elastically deformed protective element with the outer surface of this remains in accordance with the laws of momentum transfer, where it transfers its energy to the outer surface of the object to be protected. The outer surface begins to deform in the direction of the interior of the object to be protected. At the same time, the elastically deformed protective element begins to spring back in a direction opposite to the direction of deformation of the outer surface. In this case, a tensile force is applied to the outer surface of the object to be protected via the coupling of the coupling element, which counteracts the Durchbulung the outer surface of the object to be protected.

An advantage is an embodiment in which the coupling element is fixed to the outer surface and is guided through an opening of the protective element. In this way it is possible to realize the pressure decoupling and traction coupling of the protective element and the outer surface without it being necessary to provide an opening in the outer surface of the object to be protected. This is advantageous, for example, in military vehicles, the interior of which is sealed gas-tight relative to the exterior of the vehicle.

Alternatively, it is possible that the coupling element is fixed to the protective element and the other end is guided loosely through an opening of the outer surface.

In a further embodiment of the invention it is proposed that a guided through the opening end of the coupling element is provided with a rear handle. The rear grip acts on the elastic springback of the protective element as a kind of driver, via which the tensile force is applied to the outer surface of the object to be protected. Advantageously, the rear grip of planar geometry and has a larger diameter than the opening. In order to avoid ballistic weak points, the driver preferably covers the opening over the whole area.

A development of the invention provides that the rear grip is supported via a damping element with respect to the protective element or the outer surface. The provision of a damping element has the advantage that jerky overloads on the coupling element, which could lead to a tearing, are damped. As damping elements, for example, damping elements made of elastomers, plastics or wire mesh can be used. It is also possible to construct the damping elements from Beulelementen, which are preferably formed by one or more stationary metal rings or metal spirals. The buckling elements can be dimensioned such that they yield only when an admissible maximum tensile stress on the coupling element is exceeded.

A further embodiment of the invention provides that one end of the coupling element is formed by a threaded sleeve, in which a bolt carrying the other end is screwed, resulting in a simple way to mount the coupling element.

Another advantage is an embodiment, according to which the diameter of the threaded sleeve is smaller than the diameter of the opening. In this way, the threaded sleeve can occur in the deformation of the protective element in the direction of the outer surface in the opening. Collisions with the protective element and thus premature transmission of compressive forces on the outer surface are avoided.

Furthermore, it is proposed that the supports are arranged in the edge regions of the protective element, resulting in a long bending distance.

Advantageously, the supports are arranged in the region of stiffness jumps of the object to be protected. Such stiffness jumps of the object to be protected may be present, for example, in the region of partitions or structures welded to the inside of the outer surface. By providing the supports in these areas, deflections in the area of the supports, as they can occur as a result of blowing effects, are reduced to a minimum.

Fig. 1

in stark schematisierter Darstellung eine Ansicht eines militärischen Fahrzeugs, welches mit der erfindungsgemäßen Schutzausstattung versehen ist,

Fig. 2

eine vergrößerte Detailansicht der Schutzausstattung im Bereich eines Kopplungselements,

Fig. 3

eine perspektivische Darstellung eines mit einer Schutzausstattung versehenen Objekts und

Fig. 4

eine perspektivische Ansicht eines Auflagers.

Further details and advantages of the protective equipment according to the invention are explained below with the aid of the accompanying drawings of an embodiment. Show:

Fig. 1

in a highly schematic representation of a view of a military vehicle, which is provided with the protective equipment according to the invention,

Fig. 2

an enlarged detail view of the protective equipment in the region of a coupling element,

Fig. 3

a perspective view of an object provided with a protective equipment and

Fig. 4

a perspective view of a support.

The schematically held Fig. 1 shows a side of an object 1 to be protected, which is a military vehicle. However, the present invention is not limited to military vehicles, but can be applied to many types of objects, such as bunkers, ships, containers, and the like.

The object 1 to be protected has a designed as a vehicle pan housing 8, which is designed to avoid bulging due to Blasteinwirkungen B in certain areas stiffened, for example in its corner areas. In the corner regions of the housing 1, there are stiffness jumps which barely give way under the effect of blast B.

The situation is different in the central regions of the outer surfaces of the housing 8, for example the outer surface 5. In the case of a Blasteinwirkung B in the direction of a large outer surface 5 of the housing 8, it may due to the significant pressures to Durchbulungen D of the respective outer surface 5 in the interior of the Object 1 come. By means of these bulges D, for example, the crew of the military vehicle located inside the housing 8 can be seriously damaged.

In order to minimize such bulging D, the protective equipment according to the invention is provided with a coupling element 6, which is described below with reference to the side surface 5 arranged in the side region of the object 1 becomes. However, the present invention is not limited to sidewalls, but is also suitable for use in the area of roofs or for example as underbody protection for military vehicles.

Like the illustration in Fig. 1 can recognize, the protective equipment on a ballistic protection element 2. The ballistic protective element 2 is designed as a protective plate and forms the outer contour of the object 1. The protective element 2 consists of a metallic material, for example armored steel, titanium or similar materials.

The protective element 2 is fixed at a position spaced apart from the outer surface 5 by a distance A via two supports 3, 4. Between the outer surface 5 and the protective element 2, the supports 3, 4 are provided, which form a kind of spacer, whereby between the supports 3, 4, a deformation space 9 is formed. Preferably, the distance A and thus the height of the deformation space 9 is in a range of 10 to 50 mm. In the exemplary embodiment, the supports 3, 4 are arranged in two opposite edge regions of the plate-shaped protective element 2. It is also possible that a total of four supports 3, 4 are provided in the region of the edges of the protective element 2, which form a frame-shaped spacer.

The supports 3, 4 may be formed as adapted to the outer contour of the object to be protected metallic rails, for example, made of aluminum extruded profiles. In the area of the supports 3, 4, the protective element 2 is pressure-tight against the outer surface 5 of the object 1. According to the execution in Fig. 3 is the support 4 of a substantially rectangular cross-section, ie, both the protective element 2 facing, as well as the outer surface 5 facing side of the support 4 are of planar geometry. The situation is different with that in the upper part of the object to be protected 3. In this, the protective element 2 facing side 3.1 of substantially planar geometry, whereas the outer surface 5 facing side 3.2 is adapted to a provided there curvature of the outer surface 5, see. also the representation in Fig. 4 , Such an adaptation of the sides 3.1, 3.2 of the support 3 allows a pressure-resistant support between the protective element 2 and the outer surface 5. For attachment of the protective element 2 on the outer surface 5, the support 3 has a plurality of distributed over its length arranged eyelets 3.3. These are of lug-like geometry and each have an opening 3.4, through which a coupling element 6 is passed. The coupling elements 6 provided in this area serve primarily for fixing the protective element 2 to the outer surface 5, but in contrast to the coupling elements 6 provided in the middle region between the supports 3, 4 do not contribute significantly due to the significantly lower deflection of the protective element 2 in this region Improvement of the blast protection at.

The outer surface 5 has a stiffness jump in the region of the supports 3, 4 with respect to the remaining surface 5, since in these regions further sections of the housing 8 extend angled relative to the outer surface 5. These areas can be provided inside the housing with stiffeners, for example in the form of ribs. These areas yield only slightly as a result of a blowing effect B resulting, for example, from a mine detonation, i. E. H. the Durchbulung D the outer surface 5 is low in these areas.

As in Fig. 1 can be seen further, in the area between two supports 3, 4, a coupling element 6 is provided, the details of which below with the aid of the enlarged view in Fig. 2 to be discribed.

The coupling element 6 is provided centrally between the supports 3, 4. For longer surfaces 5, it is possible to arrange a plurality of such coupling elements 6 one behind the other, cf. also Fig. 3 ,

The coupling element 6 is connected in the region of its one end 6.1 to the outer surface 5 of the object 1. This end 6.1 is formed in the embodiment 1 as a welded to the outer surface 5 threaded sleeve. In the threaded sleeve 6.1, a screw bolt 6.5 is screwed from high-hardness material, which penetrates an opening 7 of the protective element 2. The other end 6.2 of the coupling element 6 is formed by a one-piece with the bolt 6.5 radial expansion, for example in the form of a screw head. Furthermore, a rear grip 6.3 is provided in the region of the end 6.2, whose diameter is greater than that of the opening 7 of the protective element 2, through which the bolt 6.5 is passed. The rear grip 6.3 covers the opening 7 to avoid ballistic weaknesses over the entire surface. The rear handle 6.3 is formed by an armored steel disc, which rests against the trained as a screw head end 6.2 of the coupling element in the axial direction. As an alternative to the embodiment shown in the figures, it is possible to form the end 6.2 as a conical screw head, which engages in a correspondingly designed conical depression of the rear handle 6.3, resulting in a reduced overall height in the region of the coupling element 6.

Between the rear handle 6.3 and the protective element 2, a damping element 6.4 is provided. This damping element 6.4 may for example consist of a plastic or elastomeric material. It is also conceivable to form this as Beulelement of metallic elements.

The protective equipment according to the invention can be mounted in a simple manner and can be retrofitted with little effort even with existing protective equipment as a retrofit solution. For this purpose, the end 6.1 of the coupling element 6 is first arranged at the corresponding positions of the outer surface 5. Subsequently, the protective element 2 is fixed on the supports 3, 4 on the object to be protected 1, wherein the opening 7 and the end 6.1 are aligned. Finally, the screw bolt 6.5 is screwed from the outside into the end 6.1 and stretched over this the rear handle 6.3 and the damping element 6.4 against the outer surface of the protective element 2.

The mode of operation of the protective equipment or the processes occurring when a blast B acts are described below on the basis of both the illustration in FIG Fig. 1 as well as the representation in Fig. 2 be explained.

In a first phase, extremely high surface forces act on the ballistic protective element 2 due to the blast pressure B. The edges of the protective element 2 transmit these forces via the supports 3, 4 to the housing 8 of the object. In these areas, there is no significant deformation of the housing 8, since the supports 3, 4 are arranged in the range of stiffness jumps of the housing 8.

In the middle region of the protective element 2, ie that region in which the coupling element 6 is located, this is not supported in the direction of the outer surface 5 of the housing 8 and begins to elastically deform in the direction of the outer surface 5 due to the Blasteinwirkung within the deformation space 9. Initially no forces are transmitted to the outer surface 5 of the housing 8 due to the pressure decoupling. The over the bolt 6.5 against the outside of the protective element 2 braced rear handle 6.3 as well as the damping element 6.4 lift from the bent surface of the protective element 2 from. With sufficiently great deformation, the protective element 2 then strikes the outer surface 5 of the housing 8 in the region of its opening 7, which for this purpose has a larger diameter than the threaded sleeve 6.1 formed as a slug.

According to the laws of momentum transmission, the casing wall and with it also its outer surface 5 are accelerated or deformed towards the vehicle interior by this impact, the outer surface 6.5 entraining the coupling element 6 via its end 6.1. This results in a Durchbulung D.

While the housing wall and with this the outer surface 5 deformed inwards and the bulge D becomes larger, the elastically deformed protective element 2 begins to spring back into its starting position quasi simultaneously. This spring-back movement is directed against the movement of the bulging outer surface 5.

By the traction coupling via the coupling element 6 while a tensile force is exerted on the oppositely moving outer surface 5, which counteracts the Durchbulung the outer surface 5. The traction coupling is achieved via the rear grip 6.3, which serves as a kind of driver for the recoil protective element 2. Overloading of the bolt 6.5 are avoided by a compression of the damping element 6.4.

With the help of the present protective equipment ballistic protective elements can be included in the blast protection. This results in a dual functionality of the ballistic protection elements that effectively support the blast protection. It results in Durchbulungen, which otherwise only with elaborate stiffening by the provision of large-scale ribbing would be possible.

Reference numerals:

1

object

2

protection plate

3

In stock

3.1

page

3.2

page

3.3

flap

3.4

opening

4

In stock

5

outer surface

6

coupling element

6.1

The End

6.2

The End

6.3

rear grip

6.4

damping element

6.5

bolts

7

opening

8th

casing

9

deformation space

A

distance

B

Blast

D

Durchbeulung

Claims (11)

Protective equipment for protecting an object (1) against military threats with ballistic protective elements (2) arranged on supports (3, 4) at a predetermined distance (A) on an outer surface (5) of the object (1) to be protected,
characterized,
in that a coupling element (6) is provided between two supports (3, 4), via which the protective element (2) and the outer surface (5) are pressure-decoupled from one another and connected to each other in a coupled manner. Protective equipment according to claim 1, characterized in that the protective element (2) under the influence of a Blastdrucks in the region of the coupling element (6) in the direction of the outer surface (5) to the collision with the outer surface (5) is elastically freely deflectable. Protective equipment according to claim 2, characterized in that the coupling element (6) is configured such that the protective element (2) pulls on the outer surface (5) during springback over the coupling element (6), in order to counteract bending of the outer surface (5). Protective equipment according to one of claims 1 to 3, characterized in that the coupling element (6) is fixed to the outer surface (5) and is guided through an opening (7) of the protective element (2). Protective equipment according to one of claims 1 to 3, characterized in that the coupling element (6) fixed to the protective element (2) and the other end (6.2) is loosely passed through an opening (7) of the outer surface (5). Protective equipment according to one of the preceding claims, characterized in that an end (6.2) of the coupling element (6) guided through the opening (7) is provided with a rear grip (6.3). Protective equipment according to claim 6, characterized in that the rear handle (6.3) via a damping element (6.4) relative to the protective element (2) or the outer surface (5) is supported. Protective equipment according to one of the preceding claims, characterized in that one end (6.1) of the coupling element (6) is formed by a threaded sleeve into which a bolt (6.5) carrying the other end (6.2) is screwed. Protective equipment according to claim 8, characterized in that the diameter of the threaded sleeve (6.1) is smaller than the diameter of the opening (7). Protective equipment according to one of the preceding claims, characterized in that the supports (3, 4) are arranged in at least one edge region of the protective element (2). Protective equipment according to one of the preceding claims, characterized in that the supports (3, 4) are arranged in the region of stiffness jumps of the object to be protected.

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