DE102011001809A1 - Protective element and method for accelerating Wirkelelementen - Google Patents

Abstract

Protective element, in particular for arrangement on the outer contour of military vehicles, with active elements (2) that can be accelerated in the direction of a threat and with an overpressure gas reservoir (3) that can be discharged to accelerate the active elements (2). Method for accelerating active elements (2) arranged on a protective element (1) in the direction of a threat, wherein an overpressure gas reservoir (3) is discharged to accelerate the active elements (2).

Description

The invention relates to a protective element, in particular for the arrangement on the outer contour of military vehicles, with acceleration in the direction of a threat active elements. Furthermore, the invention relates to a method for accelerating arranged on a protective element active elements in the direction of a threat.

On the outer contour of various objects, such as on the outer contour of military vehicles are used to protect against various threats, such. B. ballistic projectiles, shaped charges, etc., usually protective elements of various types provided.

From the DE 36 08 959 B3 For example, a protective element for protection against shaped charge projectiles is known which has acceleratable active elements in the direction of the shaped charge projectile. Upon impact of the shaped charge projectile on the protective element, a shock-sensitive explosive layer is initiated, whereby the active elements are blasted off the protective element and accelerated in the direction of the shaped charge projectile to disturb or render harmless.

In this protective element, however, it has proven to be disadvantageous that the explosive layer can be initiated only passively in the event of impact and not active, for example by pressing a button, for example, to combat located near the protective element aggressors on demand on the active elements. Due to the high impact sensitivity may also cause unwanted initiation of the protective element z. B. come by accidental impact or enemy fire, which may be associated with an increased risk to life and limb in the closer vehicle environment residing crew members.

The object of the invention is to provide a protective element and a method for accelerating active elements, which allow an active initiation, at the same time the risk of unwanted initiation is reduced.

A protective element of the type mentioned has to solve this problem on a dischargeable to accelerate the active elements overpressure gas reservoir.

By releasing the gas pressure overpressure gas reservoir, the active elements can be accelerated in the direction of the threat. It is not necessary to provide impact-sensitive explosive for accelerating the active elements on the protective element, whereby the risk of unwanted initiation of the protective element is reduced. It is also possible to actively initiate the protective element, for example, from the protected interior of a vehicle in order to specifically accelerate the active elements in the vicinity of the vehicle closer to the aggressors as needed.

An advantageous embodiment provides a pressure generator for establishing an overpressure in the overpressure gas reservoir. The overpressure gas reservoir can be kept depressurized in a quiescent state and the pressure used to accelerate the active elements can be deliberately built up only upon initiation or actuation of the protective element, thus further reducing the risk of unwanted initiations. As a pressure generator, a gas generator, in particular a cold gas generator, are used, which allows a rapid pressure build-up in the overpressure gas reservoir and thus a rapid initiation of the protective element.

In this context, it is particularly advantageous if the pressure generator is arranged in the interior of the overpressure gas reservoir, so that the pressure can build up directly in the overpressure gas reservoir. In this case, it is not necessary to supply the pressure from the outside to the overpressure gas reservoir. In a gas generator arranged in the interior of the overpressure gas reservoir, the gas can be built up directly in the overpressure gas reservoir. Pressure losses, as occur for example in longer lines, are avoided.

In a further embodiment, it is proposed that the protective element has a discharge element for discharging the overpressure gas reservoir, which is designed such that it automatically opens the overpressure gas reservoir when a threshold pressure is reached. The discharge element can release the overpressure gas reservoir in the manner of a pressure relief valve, so that a jerky escape of the gas from the overpressure gas reservoir is made possible. In order to enable a jerky acceleration of the active elements, the discharge element may have a rupture disk, which is destroyed at a predetermined threshold pressure within the overpressure gas reservoir and thereby releases a flow path in the direction of the active elements.

Of constructive advantage is an embodiment in which the discharge element is arranged on a side opposite the pressure generator side of the overpressure gas reservoir.

A further advantageous embodiment provides that the overpressure gas reservoir is in Direction of the discharge is designed to taper, whereby a large outflow velocity of the gas during discharge of the overpressure gas reservoir can be achieved.

According to a preferred embodiment, the protective element has a transmission element arranged between the overpressure gas reservoir and the active elements for the areal transmission of the gas pressure to the active elements. By the transmission element, a uniform pressure transmission to the active elements connected to a uniform application of the active elements can be achieved from the protective element. The active elements can be arranged in their rest position in an active element receptacle. Furthermore, the transmission element can abut against the side of the active element receptacle facing the overpressure gas reservoir, so that the transmission element can deploy the active elements in the manner of a piston out of the active element receptacle.

In a structurally advantageous embodiment, the transmission element is disk-shaped, resulting in a simple construction of the transmission element. In an alternative embodiment, the transmission element may be cup-shaped with a view to easy mounting. The active elements can be preassembled in the cup-shaped transmission element, so that the transmission element can be used together with the active elements in a simple manner as a mounting unit in the protective element. Further, by means of the cup-shaped transmission element on the basis of the angle of the cup wall, the scattering of the active elements can be adjusted during their application.

With regard to a favorable output of the active elements is proposed in a further constructive configuration that the overpressure gas reservoir side facing the transmission element is concave. The released during discharge of the overpressure gas reservoir gas pressure can be transmitted through the concave surface of the transmission element to the active elements, resulting in a possibly larger opening angle of accelerated out of the protective elements active elements.

Furthermore, it is proposed that a cover for covering the active elements is provided. Through the cover, the view of the active elements can be covered, which makes it difficult for any aggressors to recognize the function of the protective element and adjust to it. With regard to a particularly resistant overlap of the active elements, it has proven to be advantageous to form them from glass fiber reinforced plastic (GRP). In a further advantageous embodiment, it is proposed that the cover is made of a paintable material. The cover may be painted in the same way as the rest of the vehicle, which further impedes any aggressors from recognizing the protective element as such.

In this context, it is also advantageous if the cover is held on a pierced lid on the housing of the protective element. The lid may be bolted to a thread provided on the outer circumference of the housing. The perforation or central opening of the cover can be dimensioned such that it holds the cover in the manner of a circumferential collar on the housing.

In order to enable a simple, few handles requiring installation of the cover, the cover can be held in accordance with a further advantageous embodiment by a clamping ring on the housing of the protective element. Also can be achieved by the clamping ring attachment a flush termination of the cover with the housing. Due to the flush configuration of the termination between the cover and the housing, a particularly inconspicuous outer contour of the protective element can be produced without edges.

In addition, it is proposed to solve the problem in relation to a method of the type mentioned that an overpressure gas reservoir is discharged to accelerate the active elements.

By releasing the gas pressure overpressure gas reservoir, the active elements can be accelerated in the direction of the threat. It is not necessary to provide impact-sensitive explosive for accelerating the active elements on the protective element, whereby the risk of unwanted initiation of the protective element is reduced. It is also possible to actively initiate the protective elements, for example, from the protected interior of a vehicle, in order to specifically accelerate the active elements in the vicinity of the vehicle closer to the aggressors as needed.

In addition, the advantageous embodiments described in connection with the protective element according to the invention may also be used in the method according to the invention.

Further advantages and details of the protective element and of the method are described below with the aid of the attached Drawings of an embodiment explained. In these shows:

1 a protective element in a sectional, schematic representation,

2 a protection device with three protective elements in frontal view.

In the 1 is a protective element 1 represented, which can be arranged on the outer contour of an object to be protected, such as a military vehicle, to a threat located in the vicinity of the object by a plurality in the direction of the threat acceleratable active elements 2 to fight.

The protective element 1 is of a total cylindrical geometry and has several active elements 2 on which can be accelerated in the direction of the threat. The active elements 2 are loose in several layers in an active element receptacle 10 on the threat facing side of the protective element 1 arranged. In their rest position are the active elements 2 in a cylindrical area concentric with the longitudinal axis A of the protective element 1 arranged. The active elements 2 are of spherical geometry, alternatively, the active elements 2 but also a different shape, for example, those of a cube, a cylinder or a truncated cone, have.

The active elements 2 according to 1 are formed as separate elements, which as loose bulk material in the active element recording 10 were introduced. Alternatively, the active elements 2 also be embedded in a matrix material, which is the individual active elements 2 locked in their rest position with each other and which at initiation of the protective element 1 from the active elements 2 solves. It would also be conceivable, one the active elements 2 Provide splitter body to provide, in which the individual active elements 2 are connected by predetermined breaking points in such a way that the splitter body as a result of triggering of the protective element 1 in a variety of individual active elements 2 decomposed, which are accelerated in the direction of the threat.

The active element recording 10 is as a cylindrical bore in a housing 5 of the protective element 1 trained, which opens in the direction of the threat. To the effective range in which the active elements 2 when triggering the protective element 1 can be accelerated to set, a cross-sectional shape can be selected that of the in the 1 differs shown cylindrical shape. For example, the active element receptacle 10 open in a funnel shape toward the outside, to the scattering of the active elements 2 or to increase the opening angle of the resulting fragment cone.

Alternatively it can be used to adjust the opening angle, not shown in the figures adapter element, which prior to the introduction of the active elements 2 in a on the inner wall of the active element recording 10 arranged thread is screwed in, so that with one and the same protective element 1 by using different adapters to set different opening angle threat-specific. By means of the adapter element, the cross-sectional profile of the active element receiving 10 be adjusted by a few handles, without making changes to the case 5 to be made.

On the side facing away from the threat side of the active element recording 10 shows the case 5 an overpressure gas reservoir 3 on, which with the active element recording 10 via a connecting channel extending along the longitudinal axis A. 7 smaller diameter is connected.

In the overpressure gas reservoir 3 is at initiation or actuation of the protective element 1 generates an overpressure. To build up an overpressure in the overpressure gas reservoir 3 is a pressure generator 4 intended. In the embodiment, the pressure generator 4 designed as a gas generator, which can release a large volume of gas within a very short time. Such gas generators are known for example from vehicle airbags.

For mounting the pressure generator 4 within the overpressure gas reservoir 3 is at the back of the case facing away from the threat 5 an opening is arranged over which the pressure generator 4 in the gas reservoir 3 can be set. The pressure generator 4 at the same time forms a kind of lid, which is the overpressure gas reservoir 3 gas-tight on the back. The pressure generator 4 is as well as the active element recording 10 , the connection channel 7 and the overpressure gas reservoir 3 arranged coaxially with the axis A.

The overpressure gas reservoir 3 is one of a kind in the direction of the active elements 2 tapered nozzle formed. From the pressure generator 4 opposite side of the overpressure gas reservoir 3 extends the connection channel 7 in the direction of the active element recording 10 , wherein the connection channel as shown in FIG 1 via a discharge element 8th is closed. The discharge element 8th is of disk-shaped geometry and designed to be the overpressure gas reservoir 3 upon reaching a predetermined threshold pressure automatically opens and a flow path in the direction of the active elements 2 releases.

In the embodiment, the discharge element 8th is formed as a rupture disc which ruptures upon reaching the threshold pressure and thereby in the overpressure gas reservoir 3 adjoining gas pressure jerkily releases. The unloading element preferably exists 8th from a peripheral frame, which via an external thread in one in the connecting channel 7 provided internal thread is screwed and centrally has the actual bursting element, which may be formed, for example, as a metal plate or as a sheet-like element.

The discharge element 8th is in the transition between the connection channel 7 and the overpressure gas reservoir 3 arranged and represents until reaching the threshold pressure is a gas-tight closure.

With rupture of the discharge 8th this flows out of the overpressure gas reservoir 3 escaping gas following the pressure gradient through the connecting channel 7 in the direction of the active elements 2 , Because the overpressure gas reservoir 3 a significantly larger diameter than the connecting channel 7 has, results in a large flow velocity of the connecting channel 7 flowing gas. By going in the direction of the discharge element 8th tapered cross-section of the overpressure gas reservoir 3 turbulence of the gas stream are kept low.

For a uniform application of the active elements 2 to allow is a transmission element 6 provided on which the gas after flowing through the connecting channel 7 meets. The transmission element 6 lies on a trained in the manner of a circumferential collar shoulder of the active element recording 10 , which at the overpressure gas reservoir 3 facing side of the active element recording 10 is arranged. When unloading the overpressure gas reservoir 3 becomes the transmission element 6 over that from the connection channel 7 escaping gas in the manner of a plunger jerky against the in the active element recording 10 arranged active elements 2 pressed. To reduce the mass to be accelerated is the transmission element 6 made of plastic.

According to the execution in the 1 is the transmission element 6 disc-shaped. Alternatively, the transmission element 6 be designed in the manner of a cup, which the active elements 2 receives. About the geometry of the transmission element 6 can the effective range of the active elements 2 to be influenced. It is also conceivable that the transmission element 6 at its overpressure gas reservoir 3 facing side is concave. Also in this way, the opening angle of the protection element 1 accelerated out active elements 2 to be influenced.

To the operation of the protection element 1 is not immediately apparent to any attacker is at the threat facing side of the protective element 1 a made of a glass fiber reinforced plastic cover 9 to cover the active elements 2 intended. The cover 9 is so in the housing 5 let in that they are flush with the case 5 completes and thus a particularly inconspicuous since transition and edge-free coverage of the active elements 2 allows.

Also, at the threat facing area of the housing 5 an external thread to be formed, on which a the cover 9 position-securing, pierced lid is screwed on.

To the cover 9 to the appearance of the protective element 1 or the outer contour of the object to be protected, the cover 9 be paintable. Moreover, the cover is 9 preferably formed resistant to weathering, so that weather-related impairments of the active elements 2 be avoided over long periods of time.

The cover 9 is designed as a thin disk, so that the active elements 2 upon initiation of the protective element can pass through the cover to the outside. The cover 9 may also be designed such that they are at initiation of the protective element 1 ruptures or dissolves in the manner of a lid on predetermined breaking points and together with the active elements 2 accelerated in the direction of the threat.

In a particularly easy to install design, the cover 9 via a clamping ring, not shown in the figures, on the housing 5 of the protective element 1 be attached.

The active energy, which the active elements 2 when triggering the protective element 1 can record by suitable choice of the thickness of the cover used in the assembly 9 and the swelling pressure of the discharge element 8th be set.

Due to the open design of the housing on both sides 5 can be the components of the protective element 1 easy to assemble. First of all, the discharge element will be from one of the two sides 8th in the connection channel 7 used and fixed there. The transmission element 6 is over the outer opening of the housing 5 brought in. Subsequently, the active elements 2 as well as the cover 9 also inserted over the outer opening. To simplify the workflow or to reduce the assembly steps, the transmission element 6 be designed as a cup and together with the active elements 2 as a mounting unit in the housing 5 be used. In the back opening of the housing 5 becomes the pressure generator 4 attached, which is the overpressure gas reservoir 3 Closes gastight to the rear. Subsequently, several protective elements 1 in a common protection device 20 be arranged as such in 2 is shown.

About the protection device 20 can have multiple protection elements 1 side by side and possibly also in rows one above the other are arranged on the outer contour of the vehicle. The protection device 20 can be used as a basic body a ballistic armor plate 21 For example, from armored steel, in which the protective elements 1 are admitted. Optionally, the protection device 20 be arranged outside the base armor of the vehicle or integrated into the base armor of the vehicle. The protective elements 1 the protection device 20 can with different active elements 2 be equipped to protect against various threats. So z. B. be provided that the protective elements 1 alternating with lethal and non-lethal active elements 2 are equipped.

The detailed procedures for initiating the protective element will be described below 1 described.

For vehicles with a z. B. arranged on the roof of the vehicle weapon, there are often shot dead areas near the vehicle, which are not accessible with the weapon. Now approaches an attacker the vehicle, so this is first z. B. detected by optical vision devices of the vehicle crew. If a potential danger to the vehicle or the crew is recognized in the attacker and the attacker is in the shot dead room of the weapon, one or more protective elements can 1 actively triggered by the vehicle crew and the attacker be fought in this way.

At the initiation of the protection element 1 First, the pressure generator 4 triggered by an electronic detonator. Within the pressure generator designed as a gas generator 4 is released by a chemical reaction, a large volume of gas, which radially from the pressure generator 4 in the overpressure gas reservoir 3 flows, including the outflow of the pressure generator 4 a predetermined distance from the inner surface of the overpressure gas reservoir 3 having. The radial gas outlet is when the pressure generator 4 generates a comparatively low repulsion force in the direction of the vehicle.

In the gastight sealed Überduck gas reservoir 3 As a result of the gas introduction, an increased gas pressure builds up. Once the pressure inside the overpressure gas reservoir 3 exceeds a predetermined threshold pressure, ruptures designed as a rupture disk unloading 8th and suddenly opens the overpressure gas reservoir 3 , That in the overpressure gas reservoir 3 accumulated gas escapes through the connecting channel 7 and hits the transmission element at high speed as a pulsating gas swarm 6 , The diameter of the connection channel 7 is compared with the diameter of the overpressure gas reservoir 3 formed small, resulting in a nozzle-like acceleration of the gas. For example, the diameter of the connecting channel 7 to the diameter of the overpressure gas reservoir 3 in a ratio of less than 1: 5, less than 1:10 and in particular less than 1:15. The comparatively small diameter of the connecting channel also offers the advantage that the protective element 1 after triggering no significant ballistic vulnerability forms.

As a result of after release of the connection channel 7 on the transmission element 6 applied gas pressure, the transmission element moves 6 in the active element recording 10 into and pushes the in the active element recording 10 arranged active elements 2 at high speed from the protective element 1 out. This is the on the outside of the active element recording 10 arranged cover 9 by the active elements coming from inside 2 destroyed. The from the active element recording 10 accelerated out active elements 2 act on the attacker like a variety of ballistic missiles, which achieve a lethal or non-lethal effect depending on the geometry and material.

In the protective element described above 1 and method for accelerating active elements 2 be by the unloading of the overpressure gas reservoir 3 released gas pressure active elements 2 If necessary, it actively accelerates towards the threat. It is not necessary explosives to accelerate the active elements 2 in the protective element 1 provide so that the protective element 1 Insensitive to unwanted external triggering is.

LIST OF REFERENCE NUMBERS

1

protection element

2

active element

3

About pressure gas reservoir

4

pressure generator

5

casing

6

transmission element

7

connecting channel

8th

discharging

9

cover

10

Knitting elements recording

20

guard

21

armor plate

A

axis

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 3608959 B3 [0003]

Claims (14)

Protective element, in particular for arrangement on the outer contour of military vehicles, with accelerating towards a threat active elements ( 2 ), characterized by a for accelerating the active elements ( 2 ) dischargeable overpressure gas reservoir ( 3 ). Protective element according to claim 1, characterized by a pressure generator ( 4 ) to build up the overpressure in the overpressure gas reservoir ( 3 ). Protective element according to claim 2, characterized in that the pressure generator ( 4 ) inside the overpressure gas reservoir ( 3 ) is arranged. Protective element according to one of the preceding claims, characterized by a discharge element ( 8th ) for discharging the overpressure gas reservoir ( 3 ), which is designed such that upon reaching a threshold pressure, the overpressure gas reservoir ( 3 ) opens automatically. Protective element according to one of the preceding claims, characterized in that the discharge element ( 8th ) on a pressure generator ( 4 ) opposite side of the overpressure gas reservoir ( 3 ) is arranged. Protective element according to one of claims 4 or 5, characterized in that the overpressure gas reservoir ( 3 ) in the direction of the discharge element ( 8th ) is tapered. Protective element according to one of the preceding claims, characterized by a between the overpressure gas reservoir ( 3 ) and the active elements ( 2 ) arranged transmission element ( 6 ) for transmitting the gas pressure of the overpressure gas reservoir ( 3 ) on the active elements ( 2 ). Protective element according to claim 7, characterized in that the transmission element ( 6 ) is disc-shaped or cup-shaped. Protective element according to one of claims 7 or 8, characterized in that the overpressure gas reservoir ( 3 ) facing side of the transmission element ( 6 ) is concave. Protective element according to one of the preceding claims, characterized by a cover ( 9 ) for covering the active elements ( 2 ). Protective element according to claim 10, characterized in that the cover ( 9 ) via a pierced lid on the housing ( 5 ) of the protective element ( 1 ) is held. Protective element according to claim 10, characterized in that the cover ( 9 ) by a clamping ring on the housing ( 5 ) of the protective element ( 1 ) is held. Method for accelerating on a protective element ( 1 ) arranged active elements ( 2 ) in the direction of a threat, characterized in that to accelerate the active elements ( 2 ) an overpressure gas reservoir ( 3 ) is unloaded. Method according to claim 13, characterized in that the protective element ( 1 ) is designed according to one of claims 1 to 12.

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