EP0214409A1 - Hollow charge training projectile - Google Patents

Abstract

A wing-stabilized hollow charge shell constructed as dummy ammunition and having a tail unit (13) of the same caliber comprises a front explosive chamber (1) and a rear explosive chamber (2) and at the end face of the shell case is provided with a detonator rod (4). The entire shell case, including the detonator rod (4), is formed by parts (3, 5, 7) consisting of the same or similar material which are undetachably connected together.

Description

The invention relates to a wing-stabilized shaped charge projectile designed as a test ammunition with a caliber-like tail unit, which has a front and a rear explosive chamber and which is provided with an ignition rod on the end face of the projectile casing.

Hollow charge bullets achieve their armor-piercing effect with the help of the so-called hollow charge effect. This effect is essentially due to the fact that, as a result of the detonation of the explosive, the insert elements which collide in the middle of the charge form a metal beam called a spike, which emerges from the charge cavity at speeds of up to 10 ⁵ m / s and, because of this high speed, also thick armor penetrates. The ignition rod provided on the end face of the projectile shell initiates the ignition while maintaining the distance necessary for the shaped charge development - the effect of a shaped charge depends on the distance of the shaped charge from the armor at the time of the detonation of the explosive.

Wing-stabilized shaped charge bullets are provided on their rear part with a tail unit which, due to the aerodynamic flow, generates air forces and thus counter-moments as soon as the projectile is deflected from its normal flight position by interference. The tail unit is generally made of aluminum.

Training ammunition is used for training on the weapon, ie for practicing loading, aiming and hitting. This presupposes that this ammunition has exactly the same ballistics and therefore the same shape, the same weight and the has the same focus as combat ammunition. Training ammunition is also used for functional and acceptance tests on weapons.

Hollow-charge projectiles designed as training ammunition have the same shell as the combat ammunition. Instead of the explosive charge, an inert mass of the same density is pressed or poured into the shell.

In the known shaped charge projectiles, the ignition rod and the part of the projectile casing forming the rear explosive chamber are made of aluminum, while the part of the projectile casing forming the front explosive chamber is made of steel. The individual parts of the shell are screwed together - as in the case of combat ammunition - and must be processed accordingly. The production of the known training ammunition requires a very high outlay and therefore very high costs.

The invention has for its object to design the hollow charge projectile of the type mentioned at the beginning so that it is simple and inexpensive to manufacture.

The solution to the problem is that the entire shell, including the ignition rod, is formed by parts made of the same or similar material, which are inextricably linked. For example, all parts of the shell can be made of steel.

In the case of the practice ammunition according to the invention, on the one hand, the individual parts of the projectile casing do not need to be provided with a thread, which makes their manufacture considerably easier and cheaper, while on the other hand no contact corrosion can occur between the individual parts of the projectile casing.

In an embodiment of the invention, the part of the projectile casing which forms the rear explosive chamber and the front end plate of the projectile casing which has the end face are designed as forgings with the ignition rod and are connected to one another by a tube which forms the front explosive chamber.

Forgings are easy and cheap to manufacture; Pipes are inexpensive mass-produced items. If the forgings are made by drop forging, the interior of the parts is already given its final shape, so that no rework is required.

In a further embodiment of the invention, the front end plate with the ignition rod and the front explosive chamber or the front explosive chamber and the rear explosive chamber are designed as a one-piece forged part, so that the projectile casing consists of only a few individual parts and thus also has only a few connection points. The parts can be produced by extrusion or stretch pressing.

The individual parts of the projectile casing are advantageously connected to one another by friction welding. It should be noted that the individual parts at the connection points must have a certain excess or that the tube forming the front explosive chamber must be correspondingly longer than in its final state. It is not necessary to process the inner friction welds.

In a further development of the invention, a support disk is arranged between the front and the rear explosive chamber. This support disc prevents the projectile casing from being compressed by the high launch pressure of approximately 5000 bar, so that the projectile casing requires only a small wall thickness.

In a preferred embodiment of the invention, the front end plate and the ignition rod are provided with a bore. This hole is used to provide the projectile with a low explosive charge and an impact detonator. On the one hand, this ensures that the point of impact is well marked, while on the other hand the projectile is at least partially disassembled, thereby preventing uncontrollable ricochets and ricochets.

In the drawing, an embodiment of the invention in side view, partly in section, is shown, namely the right half of a projectile shell in the unprocessed state and the left half finished and provided with a seal and a locking ring and with an empennage.

The projectile shell shown has a front explosive chamber 1 and a rear explosive chamber 2. The front explosive chamber 1 is formed by a tube 3 and closed by means of an end plate 5 provided with an ignition rod 4. The end plate 5 and the ignition rod 4 are provided with a bore 6. The part 7 forming the rear explosive chamber 2 is provided at its end facing the front explosive chamber 1 with a recess 8 into which a support disc 9 is inserted. The support disc 9 is due to the friction welding Any heat that has occurred is non-positively and positively fixed by the protruding friction weld. The rear explosive chamber 2 has at its end facing the front explosive chamber 1 a flange-like extension 10 against which an annular seal 11 abuts. The seal 11 is held by a shrunk-on or pressed-on locking ring 12. At its end part, the part of the projectile casing forming the rear explosive chamber is provided with an empennage 13.

The projectile shown in the drawing is produced in such a way that after overturning the end faces of the tube 3 and the connection points of the front end plate 5 with the ignition rod 4 and the part 7 forming the rear explosive chamber, the end plate 5 and the ignition rod 4 with the Bore 6 and part 7 are provided with the recess 8. Then the support disc 9 is inserted into the recess 8. Then the end plate 5, the tube 3 and the part 7 are connected to one another by friction welding. Subsequently, the projectile casing receives its final external shape by twisting, whereby previously attached centering receptacles ensure that the internal and external forms run centrally to the central axis of the projectile casing, so that no wall thickness differences can occur over the circumference. Finally, the seal 11 and the locking ring 12 are applied. Finally, the tail unit 13 is attached to the rear end of part 7.

Claims (7)

1. Training ammunition wing-stabilized shaped charge projectile with caliber-like tail unit, which has a front and a rear explosive chamber and which is provided on the end face of the projectile shell with an ignition rod, characterized in that the entire projectile shell, including the ignition rod (4), by the same or similar material existing parts are formed, which are 'non-detachably connected. 2. Hollow charge projectile according to claim 1, characterized in that the part of the projectile casing forming the rear explosive chamber (2) and the front end plate (5) of the projectile casing with the ignition rod (4) are formed as forgings and by a the front explosive chamber ( 1) forming tube (3) are interconnected. 3. shaped charge projectile according to claim 1, characterized in that the front end plate (5) with the ignition rod (4) and the front explosive chamber (1) are formed as a one-piece forged part. 4. shaped charge projectile according to claim 1, characterized in that the front explosive camera (1) and the rear explosive chamber (2) are designed as a one-piece forged part. 5. Hollow charge projectile according to claim 2, 3 or 4, characterized in that the individual parts of the projectile casing are connected to one another by friction welding. 6. shaped charge projectile according to one of claims 1 to 5, characterized in that a support disc (9) is arranged between the front explosive chamber (1) and the rear explosive chamber (2). 7. shaped charge projectile according to one of claims 1 to 6, characterized in that the front end plate (5) and the ignition rod (4) are provided with a bore (6).

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