DE3543714C1 - Warhead - Google Patents

Abstract

In the case of a warhead, a thin-walled lining (3) is provided between the casing (1) and the explosive charge (2) in order to break the casing (1) up into fragments of specific mass. The lining (3) consists of a multiplicity of webs (6) which have a cross-section shaped like a house. When the explosive charge (2) detonates, a cutting jet (13) which breaks up the casing (1) is formed from the ridged roof (9) of the webs (6). The detonation wave (12) thus no longer runs into any cohesive casing (1) but into separate plates which it accelerates individually as fragments of the desired size. <IMAGE>

Description

The invention relates to a warhead according to the Preamble of claim 1.

With old ammunition (grenades, warheads) with metallic shell, the shell becomes by the detonation exploded the explosive charge in a way that is very many very small fragments to a few very few large splinters is enough. This mass or size distribution lung is called natural decomposition. Will the ammunition used against certain targets, such as airplanes or ships, but is only a certain fragment size optimized according to mass and number desired. This optimism tion takes place according to the requirements of breakthrough management stung, which of the splinter mass and the splinterge speed is determined and the frequency of hits depends on the number of splinters, by the splinters one Ammunition instead.

The dismantling of the shell into fragments of certain mass or Size is also known as controlled splintering net. There are several methods for controlled splinters education known. One of these methods is the Inner surface of the shell through notches in a variety of to divide small fields. Another, the Oberbe handle of claim 1 corresponding method is from the US-PS 30 00 309 known. The webs run below Formation of a grid in the longitudinal and circumferential directions warhead.  

The webs, which have a gable roof cross-section detonation of the explosive charge lead to a linear focusing of the detonation wave on the Envelope and thus to a corresponding weakening the same.

The notch grooves in the casing have the disadvantage that the Shell is weakened accordingly. This is particularly true weight of such ammunition, the casing of which is mechanical must be particularly resistant, for example "Semi-Amor-Piercing", ie half-armor-piercing ammunition. With this ammunition, the one caused by the notch grooves Weakening of the envelope with regard to the target intrusion can be compensated for by thickening the casing wall. That means relative to a certain total weight a considerable loss of explosive charge and thus again Loss of effectiveness that increases the splinter effectiveness at least compensates for, if not nullifies. The ratio of the shell weight to the explosive charge weight is typically around 2: 1 for SAP ammunition Envelope about 20% thicker to reduce the weakening caused by the To compensate for notch grooves, the load is reduced by 40%, almost half, which is completely unacceptable is.

The inlay with a roof-like arrangement arranged in a grid Webbing according to US-PS 30 00 309 is problematic because the detonation shock wave focused on the shell in the Casing very quickly dispersed laterally. The linear Additional stress on the casing is therefore relatively low. Leading to the fact that the upper limit of the flat size of the provided controlled splitter limited accordingly to a k value of about 4, the k-value the ratio of the imaginary length of the cube edge  Splinter indicates the wall thickness of the shell. At a larger wall thickness of the shell, as in modern SAP warheads is required is the required Weakening of the shell by the focused detonation Shock wave only get when the roof-shaped cross cut the webs is chosen larger. However, this leads again to much less explosive charge in direct Contact with the cover is at the expense of the splinter leg acceleration. Furthermore, with the known warhead no small splinters are generated, since they affect the Sheathed lines of focused detonation waves at too short distance between the lines from each other influence and thus weaken.

A warhead emerges from DE-OS 28 35 557, whose an embodiment of US-PS 30 00 309 ent speaks, so a shell with a smooth inner wall and one thin-walled insert between the case and the explosive charge lattice-shaped arranged webs of roof-shaped Has cross-section. According to a further embodiment DE-OS 28 35 557 are on the inner surface of the shell Notched grooves are provided, which exactly against the webs overlap. In this embodiment, a Schneidla effect can be brought about because the Notch grooves the cutting beam can form. This kerbnu However, ten again have those discussed above Disadvantage. It is claimed in DE-OS 28 35 557 that also in the embodiment with a smooth inner wall a "cutting charge defect" occurs. However, this is demonstrably not the case, at least if not with it the linear focus of the detonation wave but the formation of a cutting beam is meant.

The invention as characterized in the claims the underlying task is the effectiveness of a To increase fragmentation warhead.

The warhead according to the invention leads to a check gelled splinter generation, with a predetermined inside smooth ammunition case can be used i.e. h. the Invention is already in production Ammunition with a smooth inner wall can be used. The The envelope production process can therefore remain unchanged will. At the same time there is no weakening of the envelope at the expense of the explosive charge through a larger shell wall strength must be compensated. Opposite a splinter Ammunition with notches in the casing becomes one considerable increase in effectiveness achieved.

Because the cutting jet also covers thicker walls disassembled and the invention still a large contact area between explosive charge and shell allows splinters large mass and high speed and therefore higher Breakdown power are generated. But also small ones Splinters can, if a high frequency of hits is required will be generated. The battle according to the invention So head is in a wide range of splinter sizes highly effective.

After a preferred especially for SAP ammunition Embodiment of the invention has the shell projectile educational assignments, with the deposit on these Places is recessed accordingly. The projectile form the occupancies, which is a major breakthrough are effective at a greater distance from the target, lead to holes that the splinters find their way into Lighten the inside of the target.

The invention is based on the attached Drawing explained in more detail. In each of them show scheme table:

Figure 1 shows a section of a warhead in cross section in the area of the shell.

Figure 2 is a plan view of the shell inner wall with insert.

FIGS. 3a and b, the formation of a cutting jet from the liner;

Fig. 4a and b, the operation of an insert according to the invention compared to the operation of a conventional insert with gable roof-shaped webs; and

Fig. 5 is a plan view of the inner wall of the shell with projectile-forming coverings in recesses of the insert.

According to FIG. 1, the explosive charge 2 of the warhead bears against the shell 1 . Between the shell 1 and the explosive charge 2 , a thin-walled insert 3 is provided, which consists of a plastic film 4 and a metal covering 5 on the side of the plastic film 4 facing the shell 1 . For example, the metal coating 5 can be copper, which is vapor-deposited on the plastic film 4 .

The insert 3 is manufactured as a plastic injection molding bar. The metal or copper coating 5 need only have a very small thickness, for example of a few 1/10 mm.

The insert 3 is provided with a plurality of webs 6 which have a house-shaped cross section, that is to say two parallel side walls 7 and 8, on which a gable roof 9 is arranged.

The thickness of the metal covering 5 , the height of the side walls 7 and 8 and their distance from one another and the angle of the gable roof 9 depend on the required design of the ammunition, in particular the shell wall thickness.

As shown in FIG. 2, the webs 6 run both in the longitudinal and in the circumferential direction of the casing 1 . The longitudinal and circumferential sections 6 'and 6 ''thus form a grid, the fields of which determine the length and width of the splinters generated. The grid can also be formed only in part, that is, for example, only consist of webs or web sections running in the longitudinal or circumferential direction.

In order to maintain the house-shaped cross section of the webs 6 , transverse walls ( 10 ) are arranged at a distance in the webs 6 , the cross section of which is adapted to the house-shaped cross section of the webs 6 . The transverse walls 10 consist of plastic or thin metal foil. They are provided with cutouts or bores 11 in the webs for pressure compensation.

The operation of the insert 3 is shown schematically in Fig. 3a and b. The detonation wave 12 starting upon detonation of the explosive charge 2 leads to a collapse of the occupancy 5 in the area of the saddle roof 9 ( FIG. 3a). The height of the side walls 7 and 8 ensures the necessary distance to form a cutting beam 13 from the gable roof 9 along the webs 6 ( FIG. 3b).

As can be seen in FIG. 4a, the cutting beam 13 then has a really disintegrating effect on the casing 1 . I.e. the cutting beam 13 penetrates into the shell in a locally concentrated manner. The reference numeral 13 'and 13 ''indicate the different penetration into the shell 1 cutting beam. The simultaneously advanced detonation wave 12 'or 12 ''thus no longer runs into a continuous shell 1 , but into separate plates, which accelerate them individually as fragments of the desired size.

In contrast, in the conventional insert 3 'with webs 15 with a gable roof cross-section according to FIG. 4b, the focused detonation wave 12 hits the inner wall of the shell and then disperses in the shell 1 .

According to the invention, a shell 1 large wall thickness can be disassembled or much larger and heavy re parts of the shell 1 can be accelerated than with a conventional insert 3 'according to Fig. 4b.

The size of the splinters formed in a controlled manner is essentially limited according to the invention by the centrifugal voltages to which the splinters are subjected along their curved circumference. Accordingly, if the largest possible splinters are required, the longitudinal sections 6 'of the webs 6 longer than the circumferential sections 6 '', the length of the circumferential sections 6 ''being such that it due to the centrifugal tensions mentioned above, there is no natural decomposition of the fragments.

If the insert 3 according to the invention is subsequently inserted into a ready-designed ammunition with a smooth inner wall, preferably with cast loads, a charge loss of approximately 2 to 5% arises. This charge loss in ammunition to be developed can generally be compensated for without loss of charge quantity.

Fig. 5 shows a preferred particularly for SAP ammunition embodiment of the invention, are provided in the projectile-forming assignments 14 in the envelope 1. The projectile-forming coverings 14 have a large breakdown capacity. When penetrating the SAP ammunition into the target, for example in a ship, the projectile-forming assignments 14 are thus also effective at a greater distance, while the splinters formed by the insert 3 act in the middle area and the gas blow is effective in the immediate vicinity .

As mentioned, 10 holes 11 are provided in the transverse walls in order to bring about a pressure compensation in the webs 6 . This pressure compensation is particularly important in the case of "fuel fires", ie if the ammunition is exposed to a fire due to an accident, external influences, etc. before it is fired operationally. Conventional ammunition usually reacts fairly quickly with deflagration or even detonation. The reason for this is the local overheating of the explosive, which usually occurs in the boundary layer between the shell and the explosive charge, which leads to its decomposition with simultaneous high local pressure build-up with subsequent initiation. By using the insert according to the invention, the critical time until the explosion can be extended or the explosion in fuel fire can be prevented entirely. This is achieved in particular by arranging the metal covering 5 on the plastic film 4 on the side facing the casing 1 . As a result, the metal coating 5 leads to a derivation and distribution of the heat energy locally fed in at the exposed locations of the ammunition over a large area, so that local locations of extremely high temperature are avoided.

If the heat lasts longer, this distribution becomes suffice and explosive decomposition will start. However, this no longer happens locally and accordingly violent, but extensive and milder. At the same time, in the large affected area effective derivation of the decomposition products via the webs take place, which corresponding discharge openings z. B. have in the bottom of the ammunition or the projectile. The local pressure rise thereby reaches the initiation pressure no more, at most the escaping decomposition ignition products ignite, so that the ammunition at the same time burns relatively safely instead of exploding.

Claims (8)

1. warhead with an explosive charge resting against the smooth inner wall of the casing, a thin-walled insert being provided for disassembling the casing into fragments of certain mass between the casing and the explosive charge, which insert has a multiplicity of webs with gable-roof-shaped sections, characterized in that that the gable-roof-shaped section ( 9 ) is arranged at a distance from the casing ( 1 ) by two side walls ( 7 , 8 ) running parallel to one another and this distance can be selected to form a cutting beam ( 13 ). 2. warhead according to claim 1, characterized in that between the side walls ( 7 , 8 ) transverse walls ( 10 ) are provided. 3. Warhead according to claim 2, characterized in that the transverse walls ( 10 ) are provided with recesses ( 11 ). 4. warhead ( ', 6' 6 ') form according to any one of the preceding claims, characterized in that the webs (6) cuts through extending in the longitudinal direction and in the circumferential direction from a grid, wherein the length of the longitudinally extending portions (6' ) is greater than the length of the circumferential sections ( 6 ''). 5. Warhead according to one of the preceding claims, characterized in that the thin-walled insert ( 3 ) consists of a plastic film ( 4 ) which is coated with a metal ( 5 ) from which the cutting beam ( 13 ) is formed. 6. warhead according to claim 5, characterized in that the metal ( 5 ) on the sleeve ( 1 ) facing side of the plastic film ( 4 ) is provided. 7. warhead according to claim 5 or 6, characterized in that the metal ( 5 ) from the plastic film ( 4 ) is evaporated copper. 8. warhead according to any one of the preceding claims, characterized in that in the shell ( 1 ) projectile-forming coverings ( 14 ) are provided and the insert ( 3 ) is recessed at these locations accordingly.