NO160743B - PROJECTILE WITH SUBCALIBER FOR ACTIVE ARMING. - Google Patents

Description

The technical area of this invention is artillery projectiles and more specifically projectiles with sub-caliber of the armour-piercing, wing-stabilized type with a detachable driving mirror (AP-FS-DS is an abbreviated designation for the above-mentioned projectile type).

In this area, a large number of projectiles have already been developed that are capable of breaking through simple or passive targets, but few of these can break through multi-layered or active armour.

Ammunition that has hitherto been known as active armor-piercing is often made as hollow charge projectiles, in particular with two hollow charges arranged behind each other.

Of projectiles of the above-mentioned type (AP-FS-DS), a version is known from British patent application 2 110 799 which consists of a main projectile of the KE or arrow type (i.e. whose impact is due to the kinetic energy of the projectile) and in whose tail unit the rear a central bore houses a secondary sub-projectile, also of the KE type, as this is driven out of it at the end of the main projectile's trajectory to attack the first layer of an active armour. At the end of the main projectile's path, the secondary projectile thus follows a path that is independent of this main path, and a gyro stabilization of the secondary projectile is therefore necessary.

In the main projectile and behind the secondary projectile, a propellant/explosive charge is arranged which is ignited on a signal from a proximity detonator, so that the secondary projectile is fired somewhat before the main projectile hits the target.

The central bore in the main projectile thus serves as a launch tube for the secondary projectile.

However, this type of projectile is relatively complicated to manufacture due to the long boring that is necessary, in addition to the fact that manufacture is made more difficult by the fact that the materials used are heavy materials such as reduced uranium or tungsten. The necessary gyro stabilization requires machining of grooves in the bore of the main projectile, and such grooves are far from easy to machine. Omitting the gyro stabilization will not be applicable, because the secondary projectile must follow a path that should not deviate too much from the main penetrator's subsequent main path so that the denfie can hit the target in the area that has already been attacked by the secondary projectile.

The purpose of the invention is therefore to provide an armour-piercing, wing-stabilised projectile with a sub-caliber and a detachable driving mirror, which is capable of attacking multiple targets, possibly active targets, and is relatively easy to manufacture, and with lower costs than the already known projectiles .

This has been achieved by providing a projectile of the type that appears in the introductory part of the subsequent claim 1, and this projectile is characterized by the features that appear in the characteristic in the same claim.

From the body of the projectile, the main penetrator reaches

this approaches the target, a secondary projectile is thus launched in the form of a head penetrator whose path is approximately an extension of the path of the main penetrator itself so that the head penetrator hits the target without being released from the main penetrator

first.

In one of its variants, the telescopic link between the main penetrator and the head penetrator includes a first cylindrical sleeve fixed with band iron on the head penetrator and which incorporates at its rear section another cylindrical sleeve in one piece with a cylindrical abutment surface on the main penetrator and which forms the housing in which the head penetrator can slide itself, the second sleeve in its forward part including a cylindrical stop intended to limit the movement of the head penetrator to its forward position relative to the main penetrator.

According to a preferred variant, the proximity detector and the value of the driving charge are determined in such a way that the impact of the head penetrator against the target takes place before it has reached its forward position in relation to the main penetrator.

The invention and its working method will be better understood with reference to the drawings showing one of the variants, where fig. 1 shows the projectile according to the invention at rest or at the introduction to the path, fig. 2 shows the projectile at the end of the trajectory when the head penetrator is almost fully advanced in its forward position relative to the main penetrator, and

fig. 3 shows the behavior of the projectile when it hits the target.

In fig. 1, the projectile comprises a long arrow-shaped main part or main penetrator 1 of compact material, and the projectile comprises in a conventional manner in its rear part a tail unit 14 and a connecting device 15 intended for

to hold a retractable propellant mirror (not shown) during the ballistic phase after the projectile is fired from the weapon.

According to the invention, the main penetrator comprises 1

in its front part a hollow cylindrical sleeve 5 pressed on the outside of a cylindrical bearing surface 12' of smaller diameter than the rest of the main penetrator. The sleeve 5 can be made of any material, such as a light alloy, steel or a composite material. On its front surface, this sleeve includes a cylindrical opening limited by a flange 13 which acts as a front stop for a head penetrator 2 which can slide inside the inner housing 3 formed by the sleeve 5.

The head penetrator 2 is also made of a compact material such as a heavy material, e.g. tungsten or reduced uranium, and it includes the actual penetrator part which is enclosed by a sleeve 4 made of a light alloy, of steel or of a composite material. The sleeve 4 encloses the head penetrator 2 up to the bottom 16' of the projectile's ballistic nose cone 16 and comprises in its rear part a collar which prevents the head penetrator 2 from moving past its front end position by the collar coming into contact with the stopper 13 on the main penetrator sleeve 5, as the two sleeves 4 and 5 act as a connecting telescopic system between both penetrators.

The head penetrator 2 can be moved forward in relation to the main penetrator 1 by means of an explosive charge 6 arranged in a recess 6' located axially on the front surface of the main penetrator.

The charge 6 is activated by a proximity detector 8 taken up in the ballistic nose cone in the head penetrator, and the activation takes place by the detector 8 turning on an igniter 17 placed in the rear part of the head penetrator. An axial channel 18 allows electrical wire connection between the detector 8 and the igniter 17.

The proximity detector's activation of the explosive charge to advance the head penetrator is preferably determined so that it only has time to cover a distance somewhat smaller than the length of the sleeve 5 before it reaches the target, i.a.o. the target impact will take place while the head penetrator is still moving in relation to the main penetrator 1 and before the collar 11 reaches the flange 13 of the sleeve 5. Thus the head penetrator will have a maximum kinetic energy to attack the first layer of the selected target.

The thus described projectile according to the invention works as follows: In rest position and during the longest section of the trajectory, the head penetrator is in its rear position in the front part of the main penetrator 1, and the fuse 17 is in contact with the explosive charge 6 (see fig. 1).

Close to the target, the proximity detector is activated and switches on the detonator 17 which detonates the charge 6. The combustion gas from the charge 6 is then captured in the casing 3 and drives the head penetrator forward (see fig. 2) so that it comes into contact with the target before the end of its possible movement in the sleeve 5. The head penetrator then has maximum kinetic energy, and its absolute speed is the sum of the main penetrator's speed and the relative speed in relation to the main penetrator.

When the head penetrator has reached the outermost layer 20 of a target 19 (Fig. 3) and. has penetrated this, it may possibly have deviated by an angle a in relation to the path of the main penetrator 1 due to an oblique impact whereby the telescopic link between the two penetrators is broken by the sleeves 4 and 5 bursting. However, such a break will not have any harmful effect on the path of the main penetrator 1 thanks to the materials used in the manufacture of the sleeves 4 and 5, as these are designed to burst easily. Thus, the path of the main penetrator 1 is not affected by breaking through the outermost layer 20 of the target, and the penetrator 1 can penetrate the hole 21 formed therein and can then break through the inner layer of the target.

With regard to the manufacture, such a projectile has several advantages because the manufacture can be made simple and the projectile function (a single trajectory for both penetrators) makes it redundant with ballistic calculations of a separate

trajectory of the penetrator.

The invention can be produced in different versions, and in particular different types of proximity detectors can be used, e.g. passive or active infrared detectors, magnetic, detectors based on the Doppler effect, or others. In the same way, the telescopic link between the two penetrators can be designed in detail in some other way without this going beyond the scope of the invention.

The invention can be used for artillery fire with medium or coarse caliber and is particularly applicable for combating multi-layered or active targets.

Claims (4)

1. Armour-piercing, wing-stabilised projectile with a sub-caliber and detachable propellant mirror, intended for use against multi-layer armor such as active armour, and having a main penetrator (1) and a secondary penetrator or head penetrator (2) arranged to be launched by means of a propellant charge ( 6) under the command of detector means (8) from the main penetrator at the end of its path, CHARACTERIZED BY the fact that an inner cylindrical enclosure (3) is arranged at the front of the main penetrator (1) which encloses the head penetrator (2), in that this is slidably displaceable from a retracted to a forward position in relation to the main penetrator, and that the head penetrator (2) is connected to the main penetrator (1) by means of a telescopic joint so that the head penetrator is controlled in the enclosure (3) after activation and follows the same path as the main penetrator (1) without disturbing its path. 2. Projectile according to claim 1, CHARACTERIZED IN THAT the telescopic link between the main penetrator (1) and the head penetrator (2) comprises a first cylindrical sleeve (10) attached to the outside of the head penetrator (2) and which in its rear part has a collar (11) which cooperates with a second cylindrical sleeve (12) in one piece with a cylindrical bearing surface (12') on the main penetrator and forms the housing (3) in which the head penetrator (2) can be displaced, the second sleeve (12) in its front part comprising a cylindrical stop (13) arranged to limit the movement of the head penetrator (2) to its forward position relative to the main penetrator (1). 3. Projectile according to claim 2, CHARACTERIZED IN THAT the detector means have the form of a proximity detector (8) and activate the projectile's head penetrator (2) by proximity action from a target (9) using the propellant charge (6), this and the detector (8) being arranged so that the impact of the head penetrator (2) against the target (9) will take place before this has reached the end of its path in relation to the main penetrator (1). 4. Projectile according to one of the preceding claims, CHARACTERIZED IN THAT the proximity detector (8) is an active or passive infrared detector.