DE19917144A1 - Combination warhead for e.g. guided missile or sub-munition with penetrative and explosive effects satisfying logistic and economic requirements - Google Patents

Abstract

In the penetrator (1), in addition to the main explosive charge (2) a cavity (3) separated by a hollow charge lining (4) is formed.

Description

The invention relates to a combination active system with a penetrator structure-shaped shell warhead with the ignition sensors, an ignition logic and a security device and one of the explosives by means a hollow charge lining has a separate cavity.

In use as active systems for guided missiles or for other carrier devices such as for example, drones, torpedoes or dispensers are in the majority today special active systems optimized only for the main application. Under active system the combination of the warhead and its ignition system is understood here. For example, in anti-tank defense, which has a high penetration rate compared to armored steel (possibly with additional reactive armor) known shaped charge systems (short: HL systems) used. An ignition system with Sensors and an ignition logic for evaluating the sensor signals determine the optimal firing interval.

For a greater control distance, i.e. H. when the active system flies by Target, z. B. used as search fuse ammunition rather projectile-forming charges (in short: P-loading systems) with lower penetration rates than with shaped charges, but an effect from a greater distance. Even intermediate forms between HL systems and P-charge systems are known (e.g. "Hemispheres").

In addition to these axially directed charge types, there are radial ones Splinter charges for use. In flight target control, these are usually pressure / Splinter charges. To combat spatially distributed semi-hard targets (e.g. Radar positions, trucks, etc.) are not only pure fragmentary loads, but also combinations with the HL or P-charge systems as so-called multi-purpose warheads used. The fight against hard armor from the hollow or projectile-forming charge and the simultaneous control of surrounding semi-hard targets accomplished by the additionally applied splinter coat. Both Mechanisms of action are common in this type of multi-purpose systems  ignited at the same time. The effect occurs at the same time. The application of only one of the neither type of action (splinter or shaped charge) is provided.

To fight another target class, the hard concrete targets like bunkers, Airplane shelters, runways etc. as well as from other destinations where the main effect of the explosive charge can only be achieved after penetrating a first hard layer should, such as B. in ships, attack helicopters or in the fight against all above specified goals "in cover", d. H. behind walls or inside buildings the penetrator active systems. These are filled with explosives and by high Penetration performance excellent metal body that only after entering or Penetrate the first hard layer and then ignite its pressure or Develop a splintering effect. Their ignition only takes place inside the target by means of measurement and evaluation of the shock signals during target impact and during the penetration phase through a penetrator detonator.

From DE 38 00 975 A1 an armored projectile has become known in which one Hollow charge is arranged. After breaking through a first hard layer, the Detonator detonates the shaped charge oriented in the direction of flight. A hint for no other possible effects are specified.

With new missile programs, we are increasingly doing more than just fighting one of the target classes mentioned above. The corresponding active systems should be effective against a mixture of different goals at the same time. You are supposed to be a broad Cover spectrum of possible applications. In contrast, the variety of types should logistical and cost reasons be low. This requirement is familiar with the not to meet specially optimized active systems.

It is therefore an object of the invention to design an active system which has the disadvantages of known systems avoids and that with regard to the effect and the ignition timing can be adjusted to suit the target.

This object is achieved by the features of claim 1. Developments of the invention are specified in the subclaims.  

The particular advantages of the invention are that the combination active system is universally designed for all three required operating modes at the same time. The A special feature of the application is the different use of the various ignition system components. In the first case, the ignition takes place by a detonator at the optimal distance, in the second case by an intelligent one Penetrator ignition system and in the third case either by an additional own Ground clearance or proximity detonator or by a commanded ignition signal the parent on-board computer of the carrier device, the z. B. from the laser altimeter a guided missile is obtained.

An exemplary embodiment of the invention is explained in more detail with reference to the drawing.

Fig. 1 shows the principle of a combination of the active system,

Fig. 2 shows the passive detonation wave guidance for the optimization of the shaped charge performance,

Fig. 3 shows the Zündortanpassung for the optimization of the shaped charge performance,

Fig. 4 shows the allocation of the overall warhead in different compartments with their own ignition,

Fig. 5 shows the adaptation of the shaped charge liner to optimize the shaped charge performance,

Fig. 6 shows the expression of the liner generally as a hollow charge, EFP charge, or intermediate form thereof,

Fig. 7 shows the adjustment of the Penetratorspitze for the optimization of the shaped charge performance,

Fig. 8 shows the pre-shaped charge for opening the Penetratorspitze,

Fig. 9 shows the ejectable Penetratorspitze when used as a shaped charge,

Fig. 10 shows the filled with an incompressible medium cavity to increase the strength of the penetrator,

Fig. 11 shows an embossed Penetratorhülle to optimize the fragment formation,

Fig. 12 shows in the form and size optimizable, internal, pre-formed chips,

Fig. 13 shows an additive fragmentation casing of preformed fragments, which is optional absprengbar.

The basic structure of the combination active system according to the invention is shown in FIG. 1. A conventional penetrator 1 with an optimized tip and an optimized length to diameter ratio (L / D) is not completely filled with explosive 2 , but contains an additional space 3 at its tip which is suitable for ensuring the formation of a shaped charge spike. For this purpose, this space 3 is separated from the explosive 2 behind it with a shaped charge lining 4 . The shock-resistant design of this lining, as well as its support on the penetrator casing 5 and the explosive insulation, are structurally matched to the warhead.

The warhead securing device 6 contains the ignition stage for the explosive charge 2 and, as the first pyrotechnic elements of the ignition chain, the detonator and, if appropriate, transmitter or amplifier charges.

The penetrator according to the invention can be further accelerated to increase its kinetic energy by expelling it from the expulsion unit 20 . For this purpose, the propellant charge 25 is ignited. The expulsion unit securing device 21 serves to secure this propellant charge.

The switchable control of the combination active system is carried out by the ignition logic 26 . Furthermore, the system contains a distance sensor 22 , an intelligent penetrator fuse 24 and optionally an additional ground clearance or proximity fuse 23 . The function of this sensor can also be used by other carrier device components such. B. a laser altimeter. The signal line 28 (“commanded ignition”) serves this purpose. As a further input signal for the firing logic signal, the operating mode selector 27 is used. It attaches e.g. B. defined by the protection of the ammunition, one of the selectable operating modes (shaped charge, penetrator or fragment charge) and passes this information to the ignition logic ( 26 ). This then controls the required ignition sensors in accordance with the sequence described further below and forwards the corresponding ignition signals to the warhead safety device 24 or the drive unit safety device 21 and the ignition stages contained therein.

The combination warhead, which is carried to the target by a guided missile, for example, is triggered as follows:
In the hollow charge mode when fighting armored targets, the warhead is fired at a suitable distance ("stand off") by the distance detonator 22 . A shaped charge spike is formed, which only has the penetrator tip 1 and components located in the guided missile, e.g. B. the seeker head must penetrate. Then he can act unhindered on the target and deliver his high penetration in armored steel.

In the penetrator mode when fighting hard layer targets, the warhead is not ignited at a suitable distance, but the propellant charge 25 of the expulsion unit is initiated. This accelerates the penetrator and hits the target with great force. After penetration (penetration) of at least the first hard layer, the (possibly intelligent) penetrator fuse 24 determines the suitable ignition timing and ignites the explosive charge 2 of the warhead. As a side effect, this can still have a forward shaped charge effect which, due to possible shock-related deformations of the lining, can be restricted compared to a non-penetrating, pure shaped charge warhead. The main effect in this case is achieved by pressure and splinter effects of the penetrator sleeve 5 .

In the splinter mode to combat semi-hard targets that cannot be directly combated also at a suitable distance z. B. from the ground, which by the ground clearance or Proximity detonator is specified or by the on-board computer of the guided missile is transferred, the propellant charge ignited. From the ejection of the warhead the guided missile with subsequent delayed ignition of the cargo before Guided missile ensures that the splinters do not act in the Guided missile components located in the vicinity can be weakened. The The warhead can optionally be fired without a previous emission of the warhead.

In addition to this in Fig. 1 gezeigtem basic principle 13 possible embodiments of this concept are shown in Figure 2. To FIGS. That facilitate or enable implementation of the optimization of shaped charge or Penetratorleistung depending on the destination request. They can be seen as exemplary in that other combinations of the various constructive measures than the ones just shown result in a sensible warhead design.

In FIG. 2, the possibility of a passive detonation wave guidance 7 is shown for the formation of an optimum hollow charge spike. Such measures may be important because on the one hand for the penetrator 1 a large length / diameter ratio (L / D) of about 4. .8 is cheap, on the other hand an L / D of approx. 1 is the optimum for the pure shaped charge. The passive detonation wave steering 7 can compensate for these opposing demands within certain limits. If this passive measure is not sufficient, the choice of one or more detonation sites closer to the lining, e.g. B. with additional detonator 8 , for the "hollow charge" mode, the power in the sense of "active detonation wave guidance" can be increased; see Fig. 3.

Fig. 4 shows a further measure to improve the HL-performance. The warhead is divided into different compartments 9 and 10 , which are fired differently depending on the operating mode.

In Fig. 5 it is shown as an example that the shaped charge lining 4 is optimized for the specific application in the combination warhead compared to a pure, non-penetrating shaped charge with regard to position, material, wall thickness, opening angle etc. It also takes into account the special L / D situation in the combination warhead as well as the greater insulation of the load by the penetrator shell 5 .

In principle, a high penetration rate against armored steel can be achieved not only by a shaped charge, but in a weakened form also by EFP loads or by intermediate forms between the two types of charge. In FIG. 6, the liner is shown by way of example a 11-EFP charge.

A main obstacle to the formation of a stable shaped charge spike is the penetrator tip itself. Appropriate measures on the one hand facilitate penetration through the HL spike and on the other hand ensure the mechanical stability of the tip in order to achieve the penetration performance. FIG. 7 shows an embodiment of the pentrator tip which is suitable for solving this problem and which has an inner cavity 12 in the tip.

If the measure according to Fig. 7 is not sufficient to keep an impairment of the shaped charge spike by the penetrator tip sufficiently low, can be taken by a further measure, such as. B. the ignition of a pre-shaped charge 13 , shortly before reaching the target an opening in the penetrator can be blasted. This charge also clears other components of the guided missile arranged in front of the penetrator, such as. B. the seeker electronics, out of the way and ensures the formation of an undisturbed HL spike. This possibility is shown in FIG .

FIG. 9 shows a further development of the invention with a detachable penetrator tip, the detachment means 14 becoming effective before the target is approached in order to achieve an unhindered shaped charge effect with the warhead.

FIG. 10 represents a possibility of increasing the stability of the penetrator by filling the cavity 3 in front of the shaped charge lining with an incompressible medium 15 . In the "penetrator" operating mode, this material gives the penetrator increased strength, in the "hollow charge" operating mode it can be released or removed by separating the penetrator tip. This medium can with a suitable design. U. also a secondary effect such. B. cause fire or similar.

A pretreated penetrator sleeve 16 can be used to increase the splintering effect, which is pre-embossed or otherwise pretreated in such a way that the natural splinters of the sleeve have predefined geometries. This is shown in Fig. 11. Here, too, it is possible to adjust the optimum in terms of penetrator performance (smooth casing) or splinter performance (embossed casing).

Fig. 12 shows that internal, pre-shaped splinters 17 can also be used in the warhead according to the invention in order to optimize the splintering effect. The deliberately broken lines of fragments are intended to symbolize that "patterns" between preformed and natural shell fragments can also be used to optimize the effect in the target.

FIG. 13 shows an external splinter jacket 18 which increases the splintering effect when the distance is ignited, but can also be separated by a separating means 19 before the charge is detonated, if this should be necessary to avoid collateral damage.

It should be emphasized that all other combinations of those described above Measures than those shown are possible (e.g. detachable penetrator tip with external splinter jacket or similar).

Claims (17)

1. Combination active system with a warhead designed as a penetrator with a structurally stable shell, which is equipped with ignition sensors, an ignition logic and a safety device and which has a cavity separated from the explosive by means of a shaped charge lining, characterized by the following features:

• a. the warhead ( 1 ) is mounted in an expulsion unit ( 20 ), which has a safety device ( 21 ),
• b. the ignition logic ( 26 ) processes an adjustable operating mode selection signal for executing the corresponding operating mode of the combination active system,
• c. the ignition logic ( 26 ) activates the ignition sensors ( 22 , 23 ) required according to the selection,
• d. The ignition logic ( 26 ) controls the respective ignition levels of the safety device ( 6 ) of the warhead ( 1 ) and the safety device ( 21 ) of the expulsion unit ( 20 ) depending on the operating mode and thus triggers the combination active system in the selected operating mode.

2. Combination active system according to claim 1, characterized in that the Warhead optionally in a shaped charge, penetrator or splitter mode can be triggered. 3. Combination active system according to claim 1 or 2, characterized in that the operating mode of the combination active system is selected by the shooter and as a mode selection signal by means of z. B. the on-board computer of a carrier system is transmitted to the ignition logic ( 26 ). 4. Combination active system according to at least one of claims 1 to 3, characterized in that a passive detonation wave guidance ( 7 ) is integrated in the explosive ( 2 ) of the warhead ( 1 ). 5. Combination active system according to at least one of claims 1 to 4, characterized in that in the explosive ( 29 ), spaced apart from the securing device ( 9 ) and closer than this to the shaped charge lining ( 4 ), an additional detonator ( 8 ) for detonation wave guidance is integrated . 6. Combination active system according to at least one of claims 1 to 5, characterized in that the explosive ( 2 ) is filled in two compartments ( 10 ) arranged one behind the other, each having a separate ignition. 7. Combination active system according to at least one of claims 1 to 6, characterized characterized in that the shaped charge lining with regard to position, material, Wall thickness and opening angle to the special L / D and insulation situation the combination warhead is adapted. 8. Combination active system according to at least one of claims 1 to 7, characterized characterized in that to achieve a sufficient breakthrough in Armored steel instead of a pure shaped charge also an EFP load or intermediate forms between two types of charge. 9. Combination active system according to at least one of claims 1 to 8, characterized in that the penetrator tip has an inner cavity ( 12 ). 10. Combination active system according to at least one of claims 1 to 9, characterized in that the warhead has a pre-hollow charge ( 13 ), whereby an opening can be blasted into the penetrator tip and further components are removed in front of the penetrator. 11. Combination active system according to at least one of claims 1 to 10, characterized in that the penetrator ( 1 ) has separating means ( 14 ) with which the penetrator tip can be separated during the approaching target. 12. Combination active system according to at least one of claims 1 to 11, characterized in that the cavity ( 3 ) is filled with an incompressible medium ( 15 ) which, when the warhead is used as a hollow charge, is let down before the target approach or is removed with the penetrator tip. 13. Combination active system according to claim 12, characterized in that the released incompressible medium secondary effects such. B. triggers fire. 14. Combination active system according to at least one of claims 1 to 13, characterized in that the penetrator shell ( 5 ) is pre-embossed or otherwise pretreated to produce a defined splintering effect. 15. Combination active system according to at least one of claims 1 to 14, characterized characterized in that the warhead has internal, pre-shaped splinters. 16. Combination active system according to at least one of claims 1 to 15, characterized characterized in that the warhead has an outer splinter jacket. 17. Combination active system according to claim 16, characterized in that the outer splinter jacket ( 18 ) can be removed with the aid of a separating means ( 19 ) before reaching the goal.