DE3027434C1 - Ammunition for fighting armored targets - Google Patents

Description

The invention is based on ammunition in the preamble of Claim 1 specified and made known by DE-OS 27 41 984 Art.

In the case of the warhead according to DE-OS 27 41 984, the assignment is the means for a flat spike fanning or splitting to the or each shaped charge such that the straightness of the shaped charge spike despite the warhead shift is maintained. It is considered disadvantageous here that the depth effects achievable with such warheads and hole cross sections of their size are often desired leave.

The object of the invention is ammunition in the preamble of the type specified in claim 1 to the extent that that with it largely independence from the relative speed a greater depth effect to the target object of interest not so far with a hole cross-section feasible extent and thus an increased target effectiveness can be achieved.

To solve this problem are in the invention in the characterizing Part of claim 1 provided design features, whereby still in the subclaims 2 to 8 for the task solution claimed advantageous and beneficial further training will.  

One is advantageous in the ammunition according to the invention Cutting effect in the direction of the longitudinal axis of the ammunition, the both in a static ammunition use as well in dynamic ammunition use against targets in question Type in the target material always large depth values and hole cross sections timed. This is explained by this fact, that optimally meets the need for a wide range of applications Takes into account in the special fanning out or Splitting which the or each shaped charge spike consistently or at least in sections, d. H. in the barbed tip or the remaining part of the spine.

The features of the invention and their technical advantages result also from the following description of exemplary embodiments in conjunction with the claims and the schematic Drawing. Show:

Fig. 1 shows a warhead section with a hollow charge for combating armored targets from above a predetermined target distance in axial section,

Fig. 2 to 4 compared to Fig. 1 modified charge designs for the same purpose and

Fig. 5 is a warhead variant with two successively arranged charge in the embodiment of FIGS. 3 and 4.

Fig. 1 shows a warhead section 1 again, which is located above a merely indicated armored target object 2, for example in such a position that its longitudinal axis runs at a distance 3 4 substantially parallel to the target upper page 5. Said warhead section 1 has e.g. B. a rotationally symmetrical explosive charge 6 with such a spike-forming lining or occupancy 7 on a charge face 8 . This shaped charge 6, 7 is arranged with its axis of symmetry 9 transversely to the longitudinal axis 3 of the warhead, with the lining or covering 7 facing downward. On its charge end 10 facing away from the latter, it has two initiation points 11 for simultaneous dual ignition. These are located in the longitudinal center plane of the explosive charge 6 in a mirror-symmetrical arrangement with respect to its axis 9 . The simultaneous initiation of the explosive charge 6 at these points 11 results in a shaped charge spike 12 with a spike tip 13 which has just been fanned out in the direction of the warhead longitudinal axis 3 . Such a shaped charge spike is capable of producing a cut with a large depth dimension and hole cross section in the target material, both with the warhead at rest and with the warhead moving in the longitudinal direction 3 .

The same cutting effect can also be seen if, in contrast to FIG. 1, the hollow charge 6, 7 reproduced without a warhead in the manner shown in FIG. 2, two damper elements 14 are distributed over the circumference of the explosive charge 6 and the two eccentric initiation points 11 pass through a central initiation point 15 are replaced. In this case, a charge initiation results in a shaped charge spike 16 with a residual spike part 17 that has just been split in the direction of the warhead longitudinal axis 3 .

Fig. 3 shows a diagrammatic sketch in turn in the form of a section of a warhead 18 to combat an armored target from above predetermined distance 19 from the direction indicated by a line 20 one top. In contrast to the warhead design according to FIG. 1, this time it has a so-called linear cutting charge 21 as the active part, ie a hollow charge with an explosive charge 22 and a spike-forming lining or covering 23 of symmetrical geometry, in such a spatial position that the one labeled 24 The warhead's longitudinal axis lies in its plane of symmetry and the lining or covering 23 faces the target upper side 20 . In order to achieve particularly good performances in a large target distance range, an inert material body 25 of symmetrical geometry is embedded in the explosive charge 22 at a distance from the apex of the lining or covering 23 and one on its side facing away from the lining or occupancy at the height of the lining or occupancy vertex this following amplifier charge 26 arranged, the detonation speed exceeds that of the explosive charge 22 . In this way, a trailing wave can be achieved in the explosive charge 22 , which ensures a more uniform exposure of the lining or covering 23 to the detonation front than would be the case without these measures. With a cutting charge 21 such as the one described above, a cut-like perforated channel of considerable cross-section can be produced in the target material, so that in the event of a breakdown a large number of fragments can penetrate into the target with high efficiency. In this context, the possibility given without further ado to increase the penetration depth as desired with such cut-like perforated channel with cutting charge copies of the type in question which take effect one after the other should not go unmentioned.

In the case of such a cut-like perforated channel, so-called "run-up sections" can be recorded even if it was generated by the sting of a stationary cutting charge. As soon as the detonating cutting charge is not a stationary one, but a moving one, "dynamic starting phenomena" are also added to the "static starting phenomena" from the end faces of the charge. The latter lead under the simplifying assumption that the cutting charge 21 is capable of an ideal rectangular depth performance in the case of static detonation, with a charge movement taking place in the direction of arrow 27 and a charge initiation on the charge end face located on the left in FIG. 3 to the following cutting result:

A run-up area 28 with increasing depth of cut 31 can be seen from the left side of the charge in the direction of movement 27 of the cutting charge 21 . This results from the fact that initially only spiked tip parts hit the target material and only in the further course also residual spiked parts which contribute to the further cutting effect. An area 29 of constant depth of cut 32 then follows, since the tips and the remaining tips of the tips always act simultaneously in the target material. The area adjoining it is an outlet area 30 with a gradually decreasing depth of cut 33 . The latter is the case because only the slow parts of the spine carried further to the right have an effect in the target material. The corresponding run-up distances Δ s result from the formula

in which
A the distance 19 of the cutting charge 21 from the target top 20 ,
v _w the speed of travel of the cutting charge 21 in the direction of arrow 27 ,
v _s the tip speed and
v _R the remaining spike speed
mean.

The total length of cut l _total is thus obtained

l _tot = l _w + Δ s ,

where l _{w is} the cutting charge length in the direction of arrow 27 .

The effective cutting length l _e , ie the cutting length on which both the barbed tip parts and the remaining barbed parts are effective, is:

Assuming a cutting charge speed v _w of 0.5 km / s, a distance A of 1 m, a spiked peak velocity v _s of 4 km / s, and an effective radical sting speed v _R of 2 km / s is calculated, therefore, a Δ s of 0.125 m and at a cutting charge length l _w of 0.25 m effective cutting length l _e of 0.125 m.

In FIG. 4, the cutting result shown with dashed lines is that from FIG. 3, where the cutting charge 21 detonates in the direction of movement 27 . If the cutting charge 21 detonates in the opposite direction, the cutting result that can be achieved with this is different, specifically according to the solid lines numbered 34 to 36 in FIG. 4. The difference between the effective cutting length in the first case and the effective cutting length in the second case results from the formula

in the plus sign is at coincident with the direction of movement 27 detonation direction valid, the minus sign in the movement direction 27 opposite detonation direction has its validity, v is the travel speed of the cutting charge 21 in the direction of arrow 27 _w, and D represents the velocity of detonation.

In general, these differences in the effective cutting lengths l _{e, D are} not very large. Under the conditions that the speed v _{w is,} for example, 0.5 km / s and the detonation speed D is, for example, 8 km / s, the changes occurring in the effective cutting length for the aforementioned reason amount to approximately ± 6%. In contrast, changes of a remarkable order of magnitude can be observed if a cutting charge speed v _w of 1 km / s and a detonation speed D of 5 km / s are used as a basis. This changes the effective cutting length by ± 20% with the direction of detonation.

The advantage of a detonation of the cutting charge in the direction of movement 27 is seen in the fact that with a short cutting charge length l _w, the cutting length can be extended by the amount shown above. However, less spike material per unit length will be encountered and the depth of cut will be reduced accordingly.

In contrast, the advantage of a direction of detonation opposite to the direction of movement 27 is that the effective cutting length is shorter, but more barbed material per unit length is encountered and the depth output increases accordingly.

As is known, a deep perforated channel can be produced in armored steel with the spike of a rotationally symmetrical shaped charge. In practice, however, its cross section proves to be too small for the unhindered penetration of the spike by a further rotationally symmetrical hollow charge to the bottom of the perforated channel with the aim of increasing the depth of the perforated channel. In contrast, cuts from cutting loads in armored steel are relatively wide and naturally long. In this respect, there is also the possibility of successfully increasing the depth of cut using a second cutting load or several additional cutting loads. For this purpose, the cutting charges in question - as shown in FIG. 5 using the example of two charge specimens 37 and 38 - must be arranged one behind the other in such a way that their planes of symmetry have the same spatial position. In addition, care must also be taken to ensure that after the initiation of a cutting charge 37, the cutting charge 38 , which is respectively arranged downstream in the direction of movement 39 , is initiated after a time difference Δ t , as can be seen from the formula

results. Mean in this formula
l _v the overall length of the cutting charge arranged upstream in the direction of movement 39 ,
a is the axial design distance between the two cutting charges under consideration and
v _w their speed towards 39 .

With an overall length l _v of 0.25 m, a distance a of 0.1 m and a speed v _w of 500 m / s, this results in a time difference Δ t of 700 µs.

The speed of rotation of a combat part with such Cutting loads, however, must be relatively small. Given is she with

Assuming that the deviation of the cut of the cutting charge 38 initiated as the second from the cut of the cutting charge 37 initiated as the first may be a maximum of only 5 mm, the charge distance A from the target is 1 m and the time difference Δ t amounts to 700 μs the calculation according to the above formula a maximum permissible rotation speed of 1.14 revolutions per second.

In view of the fact that the speed v _w cannot be kept exactly constant, it is advisable for the length of the cutting charges to increase in the direction of movement 39 from charge to charge.

Claims (8)

1. Ammunition for fighting armored targets from above from a predetermined target distance, with one or more hollow charges for a spike formation directed downwards transversely to the longitudinal axis of the ammunition and means for a flat spike fanning out or splitting of spikes, characterized in that the means ( 11, 14, 25, 26 ) of the at least regionally flat spike fanning or spike splitting in the direction of the longitudinal axis of the ammunition ( 3, 24 ). 2. Ammunition according to claim 1, the hollow charge or hollow charges in the case of rotationally symmetrical charge and lining or occupancy geometry at the end of the charge or lining remote from the load, each with two equal distances from the axis of symmetry diametrically opposed initiation points for simultaneous dual ignition as a means for planar spike fanning out or Spike splintering, characterized in that when the axis of symmetry ( 9 ) of the shaped charge or shaped charges ( 6, 7 ) extends transversely to the longitudinal axis of the ammunition ( 3 ), the two initiation points ( 11 ) in one through the longitudinal axis of the ammunition ( 3 ) and the axis of symmetry ( 9 ) arranged level are arranged. 3. Ammunition according to claim 1, the hollow charge or hollow charges with rotationally symmetrical charge and lining or occupancy geometry on the load circumference in a diametrical position has or have two elements for section-wise charge insulation as a means for planar spike fanning or spike splitting, characterized in that with the axis of symmetry ( 9 ) of the shaped charge or shaped charges ( 6, 7 ) running transversely to the longitudinal axis of the ammunition ( 3 ), the two elements ( 14 ) for the section-wise charge insulation are arranged mirror-symmetrically to the longitudinal axis of the ammunition ( 3 ). 4. Ammunition according to claim 1, characterized in that with the same symmetrical charge and lining or occupancy geometry, the or each shaped charge ( 21, 37, 38 ) lies with its plane of symmetry in the longitudinal axis of the ammunition ( 24 ) and on its linear lining or The side facing away ( 23 ) for a drag ignition in the direction of the longitudinal axis of the ammunition ( 24 ) is an amplifier charge ( 26 ) following the lining or occupancy apex and which can be initiated on one end face and preferably has an inert substance body ( 25 ) adjacent for detonation wave guidance on the lining or occupancy side Has longitudinal extension as a means for planar spike fanning or spike splitting, the booster charge ( 26 ) each having a higher detonation speed than the explosive charge used for the hollow charge ( 21, 37, 38 ) in question. 5. Ammunition according to claim 4, characterized in that in the case of taking effect the same when flying over the target (20) in the direction of flight (39 27) oriented ammunition longitudinal axis (24) of the charge initiation respectively seen in the direction of flight (27, 39), front charge end face serves. 6. Ammunition according to claim 4, characterized in that when the same becomes effective when it flies over the target ( 20 ) with the longitudinal axis of ammunition ( 24 ) of the charge initiation pointing in the direction of flight ( 27, 39 ) of the charge initiation, the rear face of the charge seen in the direction of flight ( 27, 39 ) serves. 7. Ammunition according to claim 5 or 6, characterized in that in the case of two or more, in the direction of the longitudinal axis of the ammunition ( 24 ) at a distance (a) successive shaped charges ( 37, 38 ) their initiation starting from the charge specimen seen in the direction of flight ( 39 ) ( 37 ) from load ( 37 ) to load ( 38 ) graded according to the formula takes place, where l _v represents the axial longitudinal extension of the front ( 37 ) of two successive shaped charges ( 37, 38 ) seen in the direction of flight, a the axial constructive distance between them and v _w the ammunition speed. 8. Ammunition according to one of claims 4 to 7, characterized in that with two or more, in the direction of the longitudinal axis of the ammunition ( 24 ) successive hollow charges ( 37, 38 ) in the flight direction ( 39 ) from charge ( 38 ) to charge ( 37 ) have increasing lengths.