DE19707160C1 - Reactive armor unit - Google Patents

Description

The invention relates to a reactive armor unit according to the Oberbe handle of claim 1.

In DE 195 05 629 A1 such armor is described in which the Ge mass from being thrown away by the detonation of the explosive layer th counter plate is formed. This has the advantage that the structure of the armored Vehicle does not have to be designed so stable that it has all reaction forces takes, which arise when accelerating the collision plate. The disadvantage is however, that the plate flung away from the vehicle at high speed flies aimlessly over a long distance and thereby threatens the own team can represent.

A shaped charge spike or a balancing projectile are provided by a protective arrangement tion with a detonatively implementable layer material according to DE 28 31 415 C1 rendered harmless. A composite of an active layer and two metal When detonation of the active layer stratifies for chopping and sideways Deflecting the shaped charge spike. Larger metal layer parts are also used here eliminated, which can lead to a hazard.

The dampening of an explosion shock to prevent a sympathetic Detonation takes place according to US 51 57 223 by a passive metal layer and Foam structure. There is no activatable explosive layer.

According to US 49 81 067, reactive armor consists of an explosive layer between two perforated metal plates. Through the perforation is the same  permanent performance a significant weight saving in explosives and me tall mass possible.

The object of the invention is to armor of the type mentioned vorzu in which the plate flung away from the vehicle is not on your flight Threat forms.

According to the invention, the above object is achieved by the features of claim 1.

Further developments of the invention can be found in the subclaims.

The counterplate dampens the explosive occupancy of the  Collision plate for pulse amplification during detonation of the explosives. When detonating the explosives the counter plate initially acts as a counter mass for the Inclusion of the reaction forces in the trajectory of the attacking projectile accelerated collision plate, the one hitting the collision plate Projectile due to disruption or destruction of the original Punch is taken. The counter plate then disintegrates into particles that are flung away during flight be slowed down in the air. By the decay of the Counterplate and the degradation of their kinetic energy make the flying particles no essential Threat.

The counter plate is preferably made of metal powder or Made of metal beads. The particles can pass through Sintering or bonding or cementing. The binding is chosen so strong that the Counter plate for assembly, transport and under the Operating conditions of the vehicle are adequate Has firmness; on the other hand, it is chosen so weakly that the counter plate in the detonation of the explosive disintegrates into their particles or particle clumps, which in the Flight after a comparatively short flight distance, for example 30 m, on a harmless Speed has slowed down. To increase the Efficiency during the acceleration phase is preferably between the explosive layer and the Countermass a film or a thin plate from one ductile material arranged.

This film or thin plate has because of its low basis weight only a short flight distance. she prevents premature disassembly of the counter mass through the swath flow.

Another solution to the problem is through the features of Claim 6 characterized.  

Embodiments of the invention result from the Subclaims and the following description. In the Show drawing:

Fig. 1 shows an armor cassette,

Fig. 2, the armor cassette upon detonation,

Fig. 3 is a group of armor cassette at the front of a combat vehicle,

Fig. 4 shows a group of armored cartridges with attacking projectile and

Fig. 5 shows an alternative armor.

An armored cassette ( 1 ) has a frame box ( 2 ) which is to be attached to a basic armor ( 3 ) of a combat vehicle. Adjacent to the basic armor ( 3 ), the frame box ( 2 ) carries a floor ( 4 ) on which a flat damping plate ( 5 ) made of energy-absorbing material is arranged. The bottom ( 4 ) can also be an integral part of the damping plate ( 5 ).

A collision plate ( 6 ) is installed in the frame box ( 2 ) at a distance (A) from the damping plate ( 5 ). This consists of high-strength aluminum, steel, titanium or heavy metals or their alloys. The distance (A) offers a free flight path for the collision plate ( 6 ). It is approximately 30 mm to 1000 mm, preferably 200 mm to 400 mm.

On the side of the collision plate ( 6 ) facing away from the damping plate ( 5 ), an explosive layer ( 7 ) is provided, in which an ignition element (not shown in FIG. 1) is integrated. To increase safety, an EFI ignition element known per se is used, which contains no primary explosive and works with an electrically accelerated film.

A counterplate ( 8 ) is arranged on the surface of the explosive layer ( 7 ) facing away from the collision plate ( 6 ). This has a structure consisting of bound particles. The particles are made of a material with a high specific weight, for example tungsten or its alloys, iron or steel or heavy metals. The particle size is between 0.001 mm and 1 mm, preferably between 0.1 mm and 0.3 mm. Particles of the same grain size are preferably used.

To increase the efficiency during the acceleration phase, a metal foil ( 19 ) or a thin plate ( 20 ) made of a ductile material, preferably metal, is preferably arranged between the explosive layer ( 7 ) and the counterweight ( 8 ). It prevents premature disassembly of the counter mass ( 8 ) during the acceleration process.

The particles are bound to the counterplate ( 8 ) in a sintering process or adhesive or cementing process. The bond is selected so that the bond bridges between the particles are destroyed when the detonation wave detonates the explosive ( 7 ) and the counterplate ( 8 ) disintegrates into as many parts as possible, preferably into the particles.

The counterplate ( 8 ) is protected by a cover plate ( 9 ) of the armor cassette ( 1 ). The cover plate ( 9 ) consists, for example, of comparatively thin aluminum or sheet metal. It can also extend over several armored cassettes.

The function of the armored cassette ( 1 ) described is approximately as follows (see FIG. 2):

When the explosive layer ( 7 ) is ignited, the resulting pressure pulse is transferred to the collision plate ( 6 ). Due to pressure reflections at the counter plate (8), the pressure acting on the collision plate (6) is greatly increased, so that the collision plate (6) is flying at high speed in the direction (B) on the damping plate (5). The ignition is controlled so that the collision plate ( 6 ) meets on its trajectory with a projectile or penetrator penetrating the cassette, preferably in the front third to the front half thereof. The penetrator loses its original penetration, so that it can no longer penetrate the basic armor. The kinetic energy of the collision plate ( 6 ) is absorbed on the damping plate ( 5 ).

When the explosive layer ( 7 ), which forms explosive plumes ( 7 '), detonates, the counterplate ( 8 ) breaks down into a particle cloud ( 8 '), the cover plate ( 9 ) bursting open. The particles fly outwards in the direction of the arrows (C) and are slowed down in the air so that they are safe from the vehicle in a few meters. The metal foil ( 19 ) has only a short flight distance due to the low basis weight.

The ignition of the respective armor cassette (1 a to 1 k) is carried out via a selection computer (10) (see. Fig. 3), which is connected to the ignition elements of the armor cassette via lines (10 ') and the means of a sensor (11) with Antenna detects the trajectory of an approaching projectile by distance, azimuth and elevation angle and uses a suitable algorithm to calculate the point of impact and the cassette to be ignited. Suitable sensors ( 11 ) are radar sensors, UV or IR sensors, which lead to the desired detection through appropriate antenna arrangements, for example phased array radar antennas or imaging sensor surfaces (focal plane arrays). The type of projectile approaching can also be recognized during the detection.

Ignition with the aid of an externally controlled ignition element has the advantage over the previously known solutions that an explosive ( 7 ) with low sensitivity can be used which has a high level of security against unintended triggering.

The interaction of the active armor with the sensor and the evaluation algorithm of the selection computer ( 10 ) makes it possible to align the cassette that is suitable for rendering the incoming projectile harmless. As a result, compared to today's arrangements in which the initiation of the explosive ( 7 ) takes place by the impulse of the projectile, it is avoided that in the event of an unfavorable impact point, e.g. B. in the upper region of the cassette ( 1 ), the collision plate ( 6 ) has no protective effect. The evaluation algorithm can control the ignition point in such a way that an optimal encounter situation for the disturbance or destruction of the approaching projectile is achieved between the projectile and the collision plate ( 6 ).

A radar sensor is preferably used, which is located below Taking advantage of the Doppler effect the speed of the approaching projectile, through the swiveling Beam of a phased array antenna array Projectile angular direction in elevation and azimuth determined and at runtime or phase measurements different frequencies the distance of the projectile detected. By the information about speed, The reflective cross section and reflective signature can do that approaching projectile are classified, creating a unnecessary triggering of armor cartridges avoided  can be.

Fig. 4 shows an example of use. For an attacking penetrator (P) in the flight direction (F) shown, a point of impact (T) is calculated, which is located on the edge of the armor cassette ( 1 c). In this case, the armored cassette ( 1 c) is ignited at the appropriate time, but the armored cassette ( 1 b) lying next to it, the penetrator (P) penetrating the armored cassette ( 1 c) in the corner area and then onto the one in the armored cassette ( 1 b ) Accelerated collision plate ( 6 ) hits, where its penetration is consumed.

In the exemplary embodiment according to FIG. 5, in addition to the armoring cassettes described, a further armor ( 12 ) is shown on the front of an armored vehicle. This armor ( 12 ), like the armor cassette ( 1 ), has an explosive layer ( 7 ) between a collision plate ( 6 ) and a counter plate ( 8 ), which layer is designed and operates as described above. The collision plate ( 6 ) is arranged in a shaft ( 13 ) open on the underside of the vehicle or to the ground. The damping plate ( 5 ) is not necessary here. Upon ignition, the collision plate ( 6 ) flies through the shaft ( 13 ) and leaves it downwards. The vehicle is hardly burdened by the kinetic energy of the collision plate ( 6 ). The collision plate ( 6 ) flying out downwards does not pose any danger to the team.

In the exemplary embodiments described above, the plate ( 8 ) made up of bound particles forms the counterweight to the collision plate ( 6 ). In another embodiment, the collision plate itself - as described above - consists of bound particles. In this case the base armor ( 3 ) is used as a countermass, the explosive layer ( 7 ) being arranged between the base armor ( 3 ) and the collision plate consisting of bound particles. The binding of the particles of the collision plate is adjusted during production so that the collision plate only disintegrates into its particles when the projectile has penetrated the collision plate or has broken down in such a way that it can no longer penetrate the basic armor. In this case too, a cassette arrangement similar to that in FIG. 3 can be provided, in which the cassettes can be ignited individually.

The mode of operation is in this alternative version about the following:

By igniting the explosive layer, the Collision plate away from the vehicle into the trajectory of the approaching projectile accelerated, the Base armor acts as a countermass. Then if that Projectile hits or hits the collision plate breaks through, the collision plate disintegrates into particles or parts like this when flying in the air be braked so that after only a few meters Flight route no longer pose a serious threat.

Claims (12)

1. reactive armor unit, in particular for a vehicle, which is arranged at a distance from the object to be protected and is activated by external sensors,
consisting of a collision plate on the object side,
an outside counterplate and
an explosive layer arranged between these plates,
characterized by
that the counter plate ( 8 ) has a granular structure consisting of sintering, gluing, cementing or other interconnected particles with a high specific weight structure. 2. Armor unit according to claim 1, characterized in that between the explosive layer ( 7 ) and the counter plate ( 8 ) a metal foil ( 19 ) or a thin plate ( 20 ) made of ductile metallic material is arranged. 3. Armor unit according to claim 1, characterized in that the counter plate ( 8 ) is arranged such that its particles fly away from the vehicle in the detonation of the explosive layer ( 7 ). 4. Armor unit according to claim 3, characterized in that the collision plate ( 6 ) is arranged such that it detonates the explosive layer ( 7 ) over a distance (A) to a base armor ( 3 ) of the vehicle. 5. Armor unit according to claim 4, characterized in that a damping plate ( 5 ) is arranged on the vehicle such that the collision plate ( 6 ) strikes it. 6. Armor unit according to claim 1 or 3, characterized in that the collision plate ( 6 ) is arranged in such a way in a shaft ( 13 ) of the vehicle that it emerges downward from the vehicle upon detonation of the explosive layer ( 7 ). 7. armor unit, in particular for a vehicle, with a collision plate and an explosive layer arranged between this and a countermass layer, the collision plate te being accelerable into the trajectory of an approaching projectile by the detonation of the explosive layer, and the counter mass absorbing reaction forces, characterized that both the collision plate ( 6 ) and the counter mass ( 8 ) has a granular structure consisting of particles with a high specific weight, in which the particles are bound in such a way that the collision plate disassembles after it meets the projectile. 8. Armor unit according to claim 7, characterized in that a base armor ( 3 ) of the vehicle forms the countermass and the collision plate is arranged such that it flies away from the vehicle in the detonation of the explosive layer. 9. armor unit according to one of the preceding claims, characterized, that the particles of tungsten, its alloys, steel or heavy metals consist.   10. armor unit according to one of the preceding claims, characterized, that the particles have a grain size between 1 mm and 0.001 mm, preferably between 03 mm and 01 mm. 11. Armor unit according to one of the preceding claims, characterized in that the plate constructed from the particles and the explosive layer ( 7 ) are each arranged in cassettes ( 1 a to 1 k) which can be fixed on the vehicle, the explosive layers being individually ignitable by means of ignition elements. 12. Armor unit according to claim 11, characterized in that the armor cartridge ( 1 ) lying on the outside, built up from the particles plate ( 8 ) is protected by a cover plate ( 9 ).