DE10018285C2 - Splinter warhead to combat technical objectives - Google Patents

Description

The invention relates to a fragmentation warhead to combat technical Targets with an explosive charge surrounded by a fragment-forming shell, which counteracts the initiation of detonative initiation with the help of a or several low power detonative agents controlled in their Effect can be reduced or destroyed.

The field of application of today's warheads is changing increasingly. It will more and more targets in an urban environment were selected to the opposing Inf weaken the structure. These goals are extremely close civilian and other entities that are not or little damaged should be. Since the preferred direction of action is determined by the design, remains as an opportunity to reduce damage in the target environment next, just influencing the warhead's performance. A splinterge fencing head usually acts radially to its main axis, the achievable Effect depends on the type of splinters produced.

A splinter warhead has become known from DE 199 17 144 A1, at to the outside with the help of the warhead orderly means can be removed based on the intensity of exposure Reduce goals. However, it remains open how the fragment-forming shell, which radially surrounds the explosive charge, even with in a controlled reduction in performance can be included.

It is an object of the invention, in addition to detonative or deflagrative Initiation of the explosive charge is an equally effective method of control th performance reduction of the splinter-forming shell of a warhead specify.  

The object is achieved in a simple manner by the in claims 1 and 9 reproduced characteristics solved. Advantageous embodiments of the invention are described in the respective subordinate claims.

The particular advantage of the invention is that after the diff Exercise or twist at least a portion of the splinter-forming shell of the Warhead there is no splintering effect. They also disassemble uninsulated areas of explosive charges as reaction begins due to the gases and pressures that form and can therefore close at least no longer go into a detonation there.

A developing deflagration is supported in that a lack of damming the likelihood of transition to egg ner detonation is reduced. Deflagrating charges also generate Blast waves that can disassemble shards. The speed that The size and the ballistic performance of these fragments is much lower than with a detonation, but there is still a kind of undesirable debris throw. By means of the displacement / twisting of the splinters the envelope is advantageously prevented from throwing debris and the un deliberate charge of the explosive charge further reduced.

By shifting at least one sector of the splinter-forming The shell and the targeted ignition of individual explosive sections can Splinter power increased in the target direction and at the same time the remaining Blast performance can be reduced in the lateral direction.

Embodiments of the invention are schematically ver in the drawing simply represented and are described in more detail below. Show it:

Fig. 1 shows a section through an explosive charge with a displaceable fragment-forming casing with detonative (2) and deflagrativer tiierung (3) Ini,

Fig. 2 alternative embodiments movable sectors of the splittable sheath and erbil Denden detonative initiation with (2),

Fig. 3 shows a variant of Fig. 2 with individually controllable ignition of explosive charge sectors.

Fig. 1 shows a greatly simplified section through the explosive charge 1 egg nes warhead. The explosive charge consists homogeneously or ge layers of a known explosive and is detonatively initiated via a conventional ignition chain 2 , which is designed in two stages in the exemplary embodiment and is arranged in the drawing on the right front side. The explosive charge 1 is surrounded by a thin jacket 6 made of metal or plastic. On the outside of the casing a circumferential splinter-forming cover 4 is provided, which can be slid or rotated on the casing 6 by means of a drive, not shown.

Depending on its design, the shell breaks down into small, medium or large fragments when the explosive charge detonates, which fragments radially accelerate the who. In the case of the sole initiation of the explosive charge 1 by the ignition chain 2 and without the introduction of further measures for influencing the performance, the entire charge is implemented detonatively and the entire shell 4 will become effective as a radially spreading fragment cloud. Already in this application, the effect of the controlled power control according to the invention of splinter formation can be used. According to FIG. 1, the splinter-forming shell 4 is shifted in whole or in part before initiation by the ignition chain 2. As a result, the quantity of splinters that can be produced is limited to that part of the shell 4 which immediately surrounds the explosive charge 1 . In order to achieve a directional effect, as shown in FIG. 2, only part of the splinter-forming shell 4 is shifted. Similar effects can be achieved within the scope of the invention by rotating the splinter-forming shell. If the ignition is initiated off-center (shown in FIG. 3), the directional effect can be increased in the target direction and the blast effect can be reduced in the opposite direction.

In the exemplary embodiment, the ignition chain 2 is a further deflagrative Zündket te 3 on the opposite end face of the explosive charge 1 is directed. Alternatively, a splinter- or projectile-forming charge that acts in the axial direction (e.g. one or more small hollow charges) can also be used, which then mechanically removes the part of the charge 1 that is not covered by the casing 4 , The example of the sting of Hohlla 3 dung influenced proportion of the explosive charge 1 is only to the extent mechanically broken or worn down that he tion unresponsive detonatively even with subsequent detonative Initiie by the firing chain. 2 With, for example, approximately simultaneous initiation of the ignition chain 2 and the additional charge 3 , the detonation or action fronts produced run towards one another and meet approximately in the middle of the explosive charge 1 at the line 5 shown in dashed lines. The right part of the explosive charge 1 is implemented detonatively. The left part is detonatively ineffective due to the effect of the shaped charge 3 . By timing between the detonative initiation by ignition chain 2 and the deflagrative initiation or mechanical disassembly by the ignition chain / charge 3 , a freely selectable performance of the warhead can be set from 0 to 100%.

To avoid collateral damage or to adjust the effect of the splinters of the warhead produced, the splinter-generating shell 4 can be moved or rotated in relation to the explosive charge in such a way that a portion of the splinter-forming shell which can be selected between 0 and 100% becomes effective. In general, the splinter-forming shell 4 is shifted so far that only the part of the splinter-forming shell 4 located above the detonatively converted portion of the explosive charge (to the right of the dashed line 5 ) remains effective. The deflagratively degrading or mechanically separable part of the explosive charge is supported here, since it is easier to remove mechanically and it does not tend to go into a detonative implementation.

The displacement of the splinter-forming shell 4 in the exemplary embodiment can take place at different times and with the aid of different drive means. It is conceivable, for example, to carry out a corresponding presetting manually before the start of the warhead carrying the aircraft. During the flight to the destination, the displacement can be carried out, for example, with the aid of a prestressed spring device up to the desired degree of displacement. If the shift is only to be carried out in the vicinity of the target, it is possible to use a motorized drive, in particular an electric motor or stepper motor. Pyrotechnic drives such as gas generators, propellant charges or explosive charges that can be detonated are suitable for very rapid movement of the splinter-forming shell.

It makes sense for a number of applications to move the entire shell 4 over the explosive charge or to twist it with a helical movement and to reposition it at the same time. Just as well, only an annular part of the shell 4 can be moved or rotated. Finally, according to FIGS. 2 and 3, it is advantageous to shift one or more sectors 4 a dividing the envelope. The effect of the splinters produced can thus be metered in azimuthal direction. In this application, the homogeneous charge 1 is only equipped with a detonative ignition chain 2 . In extreme cases, only one sector of the shell is left above the explosive charge, which limits the splintering effect to a narrow Winkelbe. This can also be used to advantageously initiate a targeted initiation of the sub-areas of the explosive charge 1 assigned to the sheath 4 according to FIG. 3. Here, the detonative ignition chain 2 is replaced by a safety device 2 a. Starting approximately device of this common Siche 2 a are each the sub-regions of the explosive charge 1 associated ignition cables 2 b each with their own Zündketten 2 c, consisting of a detonator and a booster is used. In this way, the splinter power increases in the target direction and the remaining blast power in the colateral direction decreases at the same time.

Claims (10)

1. fragmentation warhead to combat technical objectives with a surrounding the explosive charge splinter-forming shell, which can be removed with the aid of the warhead arranged means, characterized in that the entire splinter-forming shell ( 4 ) or at least an annular or a sector-shaped part thereof on the surface of the Explosive charge ( 1 ) can be repositioned to change the effect. 2. fragmentation warhead according to claim 1, characterized in that the repositioning ( 7 ) of at least part of the splinter-forming shell ( 4 ) takes place before the start or release of the warhead carrying aircraft. 3. splinter warhead according to claim 1 or 2, characterized in that the repositioning ( 7 ) of at least part of the splinter-forming shell ( 4 ) takes place during the approach phase to a target. 4. fragmentation warhead according to at least one of claims 1 to 3, characterized in that the drive of the repositioning part of the fragment-forming shell ( 4 , 4 a) takes place via a pre-stressed system. 5. splinter warhead according to one of claims 1 to 3, characterized in that the drive of the repositioning part of the splinter-forming shell ( 4 , 4 a) via at least one motor, in particular via an electric motor, takes place. 6. fragmentation warhead according to pure one of claims 1 to 3, characterized in that the drive of the repositioning part of the fragment-forming shell ( 4 , 4 a) is carried out with the aid of pyrotechnic means. 7. fragmentation warhead according to claim 1, characterized in that the explosive charge ( 1 ) with the aid of several selectively controllable Zündein devices ( 2 b, 2 c) can be initiated. 8. fragmentation warhead according to claim 7, characterized in that the ignition devices ( 2 b, 2 c) can be controlled via a common Sicherheitsvor direction ( 2 a). 9. fragmentation warhead to combat technical targets with a surrounding the explosive charge splinter-forming shell, which can be removed with the aid of a warhead arranged means, characterized in that the explosive charge ( 1 ) counter to the initiation of the detonative initiation ( 2 ) with the help of one or more detonative means ( 3 ) with lower power can be reduced or destroyed in their controlled effect and that the entire splinter-forming shell ( 4 ) or at least an annular or a sector-shaped part thereof can be repositioned on the surface of the explosive charge ( 1 ) in a manner that changes its action. 10. fragmentation warhead according to claim 9, characterized in that by repositioning at least part of the splinter-forming shell ( 4 ) exposed portion ( 1 a) of the explosive charge surface matches the portion of the explosive charge ( 1 ) converted by deflagration.