DE2731693A1 - WITH A HOLLOW CHARGE OR A SHAPED CHARGE AND AN APPROXIMATE EXPLOSIVE BULLET - Google Patents

Description

Explosive projectile fitted with a shaped charge or a shaped charge and a proximity fuse

The invention relates to an explosive projectile provided with a shaped charge or a shaped charge and a proximity fuse, the proximity sensor of which supplies a signal which indicates that the projectile is at a predetermined distance from a target.

Such explosive projectiles are generally used for perforating metal plates or the like, for example tanks, although they can also be directed against flight targets.

In the case of explosive projectiles of this type, proximity detonators are generally not used, but rather impact detonators which detonate the charge as soon as the projectile strikes the target to be destroyed. The impact fuse is located in the front part of the projectile and consists of a set of piezoelectric quartz crystals or a set of ceramic crystals.

Such impact detonators have several disadvantages. Since such an impact fuse is located in the front part of the projectile, i.e. in front of the shaped charge or in front of the shaped charge, it lies precisely in the path of the very high temperature jet flame that is caused by the explosion

Charge is generated. This practically prevents a quick and immediate effect of the jet flame on the target to be destroyed. In addition, when the explosion is triggered by an impact, it is not possible to easily and precisely determine the moment of flame formation in such a way that the flame emerges at an appropriate distance from the object in question, which is essential for the satisfactory effect of a shaped charge. In addition, due to the nature of such impact detonators, the time that separates the sensor's impact on the target (i.e. ignition of the shaped charge or the shaped charge) from the point in time at which the fully developed jet flame begins to pierce the target is an effect of the remaining kinetic energy of the projectile at the moment of impact.

The invention is therefore based on the object of designing explosive projectiles with proximity detonators in such a way that the jet flame that forms during ignition is not influenced by the sensor of the proximity detonator.

This object is achieved according to the invention by a sensor which consists of a ring-shaped electrical coil having a large number of turns and an annular permanent magnet arranged concentrically in the coil in such a way that the field lines generated by it close again at least partially across the coil and by a gain and threshold circuit connected to the coil. Since the sensor designed according to the invention and arranged in the head of the projectile in front of the charge leaves a channel free, the jet flame generated by the sensor via the amplification and threshold value circuit, the detonator and the charge can be practically unhindered escape and are brought to effect better than when impact detonators are used.

It is useful to arrange the amplifier and threshold value circuit in the base of the projectile and to let the axis of the coil and the axis of rotation of the projectile lie in one line.

The invention is explained below with reference to an exemplary embodiment shown schematically in the drawing.

The drawing shows a section through an explosive projectile with a proximity fuse designed according to the invention.

The projectile 10 has an ogive, ballistic cap 12, a base 14 and a main body 11 connected to these parts and comprising a hollow or shaped explosive charge 16.

In the ballistic cap 12, i.e. in front of the explosive charge 16, there is an electrical coil 18, which has a plurality of turns and which runs coaxially to the axis of rotation 20 of the projectile, and in it an annular permanent magnet 22, which also extends coaxially to the axis of rotation 20 and has a radial or axial magnetization.

The coil 18 and the permanent magnet 22 form part of the proximity fuse according to the invention, which works in that the magnetic field lines of the magnet that close again across the windings are modified by the approach to a magnetic object, e.g. an armored car, and this change in the Coil induces an electrical voltage which changes on the magnetic flux in the turns and the larger the number of turns, the larger and easier it is to use.

The amplification and threshold value circuit 24 belonging to the proximity fuse, which triggers the electrical detonator 32 via a mechanical or electrical delay 34 when the threshold value is reached, is arranged in the base 14. The circuit 24 is supplied by an electric generator 30, which can consist of a battery, in order to trigger the ignition by opening an electric gate (not shown).

The proximity fuse triggers the ignition process at a certain distance from the target, which is selected so that the effect of the charge of the projectile is optimal.

The coil 18, which has a plurality of turns of very fine wire (10 microns (10 [high] -6m)) so that a sufficient induced voltage of several millivolts can be obtained. The coil 18 forms a central channel 26, the diameter of which is sufficiently large to allow the jet flame formed by the explosion of the charge an adequate passage cross-section. The jet flame is not disturbed, as is the case with known impact detonators, the effect of the projectile is therefore much better than with an impact detonator

Claims (4)

1. With a shaped charge or a shaped charge and provided with a proximity fuze explosive projectile, the proximity fuze supplies a signal indicating that the projectile is at a predetermined distance from a target, characterized by a sensor which consists of a plurality of turns having, annular electrical coil (18) and consists of an annular permagnet (22) arranged concentrically in the coil in such a way that the field lines generated by it close again at least partially across the coil, and by a with the coil (19) connected gain and threshold circuit (24). 2. Explosive projectile according to claim 1, characterized in that the coil (18) of the sensor in the head (12) of the projectile (10) is arranged in front of the charge (16) and its inner diameter is dimensioned such that the cross section of a through this diameter Defined channel (26) is sufficient to allow a jet flame formed by the explosion of the charge of very high temperature to pass through the coil. 3. Explosive projectile according to claim 1, characterized in that the amplification and threshold value circuit (24) is arranged in the base (14) of the projectile (10). 4. Projectile according to one or more of claims 1 to 4, characterized in that the axis of the coil (18) of the sensor and the axis of rotation (20) of the projectile lie in a line.