DE4135392A1 - Tandem warhead for use against armoured targets - comprises forward and main hollow charges divided by three component, forward charge blast energy absorbing, shield - Google Patents

Abstract

A tandem warhead comprising a forward (3) and main (7) hollow charge, sepd. by an explosion gas shield (6). The latter is tapered forwards and consists of a forward part (11) and a rear part (12), both parts being held together by a ring-shaped clamping component (13). The explosion gas shield (6) absorbs most of the explosion gas energy (15) on detonation of the forward charge (3), by its plasic deformation. The base outer dia. of the forward part (11) of the shield (6) is one third to one half that of the rear part of the shield. USE/ADVANTAGE - So called tandem warheads are intended for use against armoured target of a twin active component component nature. The forward hollow charge is detonated first inactivating the first armour compound so that the spike of the time delayed main charge works against the main armoured component without its power being reduced. Compared with previous tandem warheads the claimed design has reduced mass and shorter length.

Description

The invention relates to a warhead a pre-charge, a main charge and one tapering towards the front, axially displaceable Swath shield between precharge and Main hollow charge.

Warheads of this type are known and are also known as Designated tandem warheads (cf. EP 01 54 580 B1, DE 36 01 051 C1). You will be particularly against such armored targets, the armor active Have components against shaped charge spikes. Here is the pre-charge in the case of target detection ignited, the sting of the active components the active armor ineffective, so that the Sting of the delayed ignited Main hollow charge on its way to the inside of the destination performance-reducing interactions with the active acting components of the armor are spared.

The swath shield has the purpose before the main hollow charge to create a spike formation room, d. H. one Free space in which the sting of the main hollow charge  can train without swaths or fragments to be adversely affected when the detonation of the Form pre-charge. In the well-known tandem warheads, the Blast effect of pre-charge, that is, when detonated the precharge is released to the rear Vapor expansion energy, by accelerating the Swath shield towards the main hollow charge, d. H. into kinetic energy. So that Swath shield not when returning to the Impact the main hollow charge and damage it, however, the main charge must be ignited beforehand. Accordingly, the time delay between the Detonation of the precharge and detonation of the Main hollow charge in the well-known tandem warheads by the quotient from the distance between the Swath shield and the main hollow charge on the one hand and the Return speed of the steam shield after Detonation of the precharge is limited on the other hand. For an optimal effect of the shaped charge spike on his Railway into the finish line, however, it is necessary that the Main hollow charge only at an optimal effective distance from the target detonated, d. H. there must be one certain period of time after which the Main charge is ignited with a delay. So that these Time span is reached, one is with the known Tandem warheads forced to use the swath shield train very large mass or the distance between the pre-charge and the main charge and thus the To increase the length of the warhead.  

To further reduce the steam expansion energy, in the well-known tandem warheads Warhead cover in the area of the swath shield torn open. On the one hand the high To withstand steam expansion pressure and on the other hand in cases with sufficient structural strength Ensuring tearing open to relieve pressure is that Swath shield tapered towards the front, e.g. B. funnel-shaped, dome-shaped or in cross-section ogiveniform, so that the swaths to the base of the Swath shield to be directed.

To reduce the swath expansion energy To achieve detonation of the precharge are after EP 01 54 580 B1 in the warhead shell between Pre-shaped charge and steam shield blow-out openings intended. However, this increases the structural strength warhead shell lowered. Beyond that these holes are sealed from the environment. For example, for cables connected to the Blow holes on the inside of the warhead shell run an additional electromagnetic Shielding required.

The object of the invention is a tandem warhead to provide high performance and reliability with this despite the reduction in length and / or mass a sufficiently long time delay between the Detonation of the precharge and detonation of the Main hollow charge is possible.

This is according to the invention with that in claim l marked warhead reached. In the Advantageous refinements of the Invention reproduced.  

That is, in the warhead according to the invention that is Swath shield across the longitudinal axis of the warhead divided, being between the two parts annular damping element is arranged.

This damping element is caused by the shock load deformed when the precharge is detonated. So that will part of the steam explosion energy Deformation work of the damping element accordingly the following formula:

E _tot = E _kin + E _form

where E _{tot is} the steam _explosion energy, E _kin the kinetic energy of the backwards accelerated steam shield and E _shape the work of deformation.

According to the invention, the proportion E _shape is increased by the damping _element at the expense of E _kin , which results in a lower return speed of the swath shield.

Accordingly, according to the invention without changing the overall length of the warhead a much larger one Delay time of the detonation of the main hollow charge can be achieved. This means that even those who are active Armor can be effectively combated, which is a longer one delayed detonation of the main hollow charge require, for example, that of the active  Armor with a relatively thick plate accordingly slow speed towards the warhead is fired.

At the same time, the mass of the swath shield of the warhead according to the invention are reduced, especially to increase the performance of the Haupthohlladung or Vorhohlladung, but also for Increasing the range of the warhead. By So the invention will have greater flexibility the design of a tandem warhead.

In order to achieve a high level of deformation work, the damping element preferably consists of a plastically deformable, that is to say a soft material, for example a soft metal, such as lead or copper, or plastic. Plastics usually have the advantage of lower weight compared to metal. If a metal is used for the damping element, it should have a modulus of elasticity which is not higher than that of copper, i.e. less than 1.5 × 10 ⁵ MPa (150 × 10 ⁹ N / mm ² ), in order to achieve the highest possible plastic deformation work. . When plastics are used for the damping element, plastics with an elastic modulus of less than 10,000 MPa are generally preferred. For example, the damping element can consist of polytetrafluoroethylene or polyvinyl chloride.

By dividing the swath shield according to the invention it is further divided into a front and a rear part possible the two parts according to their design different in the event of detonation of the precharge deform, depending on the cone angle of the two Parts of the swath shield.  

Because they released when the precharge was detonated Swaths primarily to the top of the Swath shield is directed is the front part exposed to a particularly high load. In contrast comes the rear part more the function of a Support structure of the front part and a steering of the Swaths too. That is, the rear Part is designed so that the swaths and Fragments upon detonation of the pre-shaped charge to the outside distracts to the warhead shell, under relatively low momentum transmission to the rear part the swath shield, but with a correspondingly large one Impulse transmission to the warhead shell. The Warhead cover tears open relatively easily, so that the swaths and fragments from the warhead can exit and thus the acceleration of the Steam shield is stopped backwards.

To deflect the swaths and fragments Achieving warhead shells is after for example, tapering swath shield funnel-shaped or dome-shaped or in cross-section ogive or bell-shaped.

Because the front part of the swath shield is a special one exposed to high stress, it exhibits a high Compressive strength. This can be done by appropriate Material selection and / or a greater thickness of the front Partly opposite the rear part of the steam shield respectively.  

Generally the front part has one Compressive strength that is at least twice as large like the compressive strength of the rear part. At same The rear part can be made of materials accordingly have a smaller thickness, which means another Weight reduction is achieved.

The compressive strength of the front part should be at least 100 N / mm ² (10 kp / mm ² ), but preferably more than 500 N / mm ² (50 kp / mm ² ), in particular more than 1000 N / mm ² (100 kp / mm ² ). For example, the front part and / or the rear part can consist of high-strength steel or another metal with the specified compressive strength.

The invention is described in more detail below with reference to the drawing explained. In it show:

Fig. 1 shows a longitudinal section through a schematically illustrated warhead;

Fig. 2 is a diagram representing the pressure load of the steam plate on detonation of Vorhohlladung; and

Fig. 3 is a schematic representation of the experimental arrangement with which the diagram of FIG. 2 was obtained.

Referring to FIG. 1 a provided with a funnel-shaped liner 2 Vorhohlladung 3 is provided in a cylindrical, thin-walled warhead casing 1 which is secured to the warhead casing 1 by means of a support structure 4. 5 with the ignition device at the rear end of the pre-charge 3 for igniting the same.

Arranged behind the pre-hollow charge 3 is a swath shield 6 which is essentially conical with the tip pointing forward. The main hollow charge 7 with the funnel-shaped lining 8 is arranged behind the steam shield 6 at the front end and the ignition device 9 at the rear end.

The swath shield 6 is divided according to the embodiment shown in the upper half of the drawing in the radial direction, that is to say transversely to the longitudinal axis 10 of the warhead, so that it consists of the front conical part 11 and the frustoconical rear part 12 . An annular damping element 13 , for example made of Teflon, PVC, lead or copper, is arranged between the base of the front part 11 and the front end of the rear part 12 . Bolts 14 inserted from the side of the main hollow charge 7 firmly connect the two parts 11 and 12 and fix the damping element 13 clamped in between. The connection between the two parts 11 and 12 should be as free of play as possible. Penetration of the swaths released by the arrows 15 upon detonation of the pre-hollow charge 3 into the spike formation space between the swath shield 6 and the main hollow charge 7 is thus prevented. The swath shield 6 is attached to the warhead shell 1 at the base of the rear part 12 .

The embodiment shown in the lower half of Fig. 1 differs from the embodiment shown in the upper half essentially only in that the front part 11 overlaps with its base the front edge of the rear part 12 and the annular sealing element 13 'in the Overlap area between the front part 11 and the rear part 12 is arranged. The front part 11 and the rear part 12 can, for. B. be glued to the annular sealing element 13 'in order to obtain a play-free connection of the two parts 11 and 12 of the swath shield 6 .

From Fig. 2 at which point the parting plane between the two parts is in connection with FIG. 3 projecting, 11 and 12 of the steam shield 6 is to pass.

Fig. 3 shows schematically a section through one half of a test warhead with a pre-hollow charge 3 with a conventional swath shield 6 'in a warhead casing 1. The points a, b, c and d on the swath shield 6 ' in Fig. 3 represent measuring sensors with which the pressure at these points is measured when the precharge 3 is detonated.

With an inner radius of the shell 1 of 70 mm, the pressure sensor a is arranged at the tip of the swath shield 6 ', that is to say in the longitudinal axis of the warhead, the pressure sensor b is at a distance of 25 mm from the longitudinal axis of the warhead, and the sensor c is at a distance of 50 mm and the pressure sensor d with a distance of 70 mm.

In Fig. 2, the pressure curve upon detonation of the pre-charge 3 at the points a to d of the swath shield 6 'is shown.

As can be seen from this, is opposite the tip a at the point b, at which the outer diameter of the swath shield 6 'with 25 mm is about a third of the outer diameter of the swath shield 6 ' at the base (70 mm), the peak pressure already by more than that Five times smaller, and practically the same size at point c (50 mm) as at point d, i.e. at the base (70 mm).

Accordingly, the outer diameter of the base of the front part 11 of the swath shield 6 of the warhead according to the invention is preferably less than half the outer diameter of the base of the rear part 12 , in particular less than a third.

Claims (6)

1. warhead with a pre-hollow charge, a main hollow charge and an axially displaceable, tapering forward swath shield between pre-hollow charge and main hollow charge, characterized in that the swath shield ( 6 ) consists of a front part ( 11 ) and a rear part ( 12 ) and that the two parts ( 11 and 12 ) are connected to one another via an annular damping element ( 13 , 13 '). 2. Warhead according to claim 1, characterized in that the outer diameter of the base of the front part ( 11 ) is less than half the outer diameter of the base of the rear part ( 12 ). 3. Warhead according to claim 1, characterized in that the outer diameter of the base of the front part ( 11 ) is less than a third of the outer diameter of the base of the rear part ( 12 ). 4. Warhead according to one of the preceding claims, characterized in that the front part has a compressive strength of at least 100 N / mm ² . 5. Warhead according to one of the preceding claims, characterized in that the compressive strength of the front part ( 11 ) is at least twice the compressive strength of the rear part ( 12 ). 6. Warhead according to one of the preceding claims, characterized in that the damping element ( 13 , 13 ') consists of a metal with an elastic modulus of less than 15 × 10 ⁴ MPa or of a plastic with an elastic modulus of less than 10 ⁴ MPa.