DE69618573T2 - Bullet with directed splintering effect - Google Patents

Abstract

The present invention relates to a method and an arrangement for bringing about, from a carrier projectile (1, 9, 14, 29, 36a, 36b) in the form of a shell, missile or equivalent, a concentrated fragment sheaf (35, 40, 44) in the direction of a target detected by a homing sensor (7, 10, 15-18) forming part of the carrier projectile. The invention is particularly characterized in that it uses a limited fragment spread within previously determined limits in the direction directly towards the target instead of, as is otherwise normal, scattering the fragments radially around the entire circumference of the carrier projectile. <IMAGE>

Description

The present invention relates to a rotation-stabilized projectile such as an artillery shell or a rocket for combating ground and air targets, in which fragments are directed at the target by a detonating active part filled with explosives. In addition to an active charge filled with explosives, the active part consists of an externally delimited, fragment-forming housing, which preferably consists of at least partially preformed fragments made of heavy metal and an ignition charge intended for the active charge. The fragments are formed when the active charge detonates. The ignition charge is connected to a target-controlling sensor or target sensor, which is intended to scan a predetermined direction relative to the direction of flight of the projectile during its flight to the target. The target sensor is designed to ignite the ignition charge when targets worth combating are detected, which in turn ignites the active charge. When detonated, the active charge hurls fragments at high speed in directions that are predetermined in relation to the flight direction of the projectile.

The development of microelectronics has led to a significant increase in access to small and efficient target sensors of the infrared, radar or laser type. This meant that opportunities were seen in artillery technology to extend the application of these target sensor-ignited munitions to new fields of application and weapon calibres. Access to efficient target sensors means that the capacity to ignite the active charge of the munitions at absolutely the right time has become affordable. On the other hand, the problem of concentrating the total effect of the active charge present in the direction of the target detected by the target sensor has not yet led to a satisfactory solution. As far as fragmentation-forming projectiles are concerned, the normal procedure up to now has been to design their outer casing in such a way that when the active charge detonates, it forms fragments and scatters them uniformly around its own central axis. For example, in the case of an impact In addition to the fragments scattered in the direction of the target, there is a large number of fragments near the target which are generally not used much because they are scattered in a direction away from the target. There would therefore be much to be gained if it were possible instead to direct the fragments in a concentrated "spray" towards the target detected by the target sensor.

The object of the present invention is then to offer a functional solution to this problem.

The problem that normal warheads spread their fragments everywhere and not just in the direction of the target is part of the state of the art, with several warhead designs having been proposed whose aim was to provide a concentrated spread of fragments in a given direction towards a specific target.

An example of such an embodiment is described in document DE-A-14 53 815, which relates to an artillery shell or rocket intended to attack ground or air targets and which can be fired to selectively disperse fragments in a direction selected by a target sensor. The projectile described therein is, however, somewhat complex, since it is provided with several ignition charges which can be selectively fired by the target sensor to produce fragments in the direction selected by the sensor. This document is a basis for the preamble of claim 1.

Another projectile with a completely different design of its warhead, but which is effective in almost the same way, is described in the document DE-A-40 11 243. The warhead is also provided with several ignition charges, the direction of the fragments spread by its fragmentation insert being determined by which ignition charge is ignited by these.

Document FR-A-2 641 070 also describes a warhead with a single direction of action, intended for an aircraft-carried body and particularly suitable for combating lightly armoured targets.

The basic prerequisite for the invention is therefore that there is access to a rotating active part or projectile, such as a rotation-stabilized artillery shell or a rocket. This can be given a sufficient rotation speed, for example, by means of inclined stabilizing fins. The active part in question must also be equipped with a target sensor that will ignite an ignition charge contained in the projectile if it detects a target worth fighting at a combatable distance during the flight of the projectile. This will in turn ignite the active charge of the projectile. The active charge is enclosed in its main direction of action by a fragmentation-forming housing that will break up into free metal fragments when the charge detonates, which are accelerated at high speed towards the target. By designing the active part that is characteristic of the invention, i.e. the active charge and the fragmentation casing, when the active charge is detonated a concentration of fragments is achieved, which are released with it and accelerated to high speed in one or more connected bursts, in one or more directions, at least one of which coincides with the direction of the target identified by the target seeker.

Thus, it is a fundamental principle characteristic of the invention that both the scanning direction of the target sensor and the dynamic direction of fragmentation of the active part, i.e. the common fragmentation direction of the explosive charge and the fragmentation housing, which is determined by the vectorial sum of the speed of the fragments formed when the explosive charge is detonated and the trajectory speed of the carrier projectile, and at least in certain cases also their rotation speed, should form an angle of more than 40º and less than 90º with the direction of flight of the projectile. The scanning direction of the target sensor and the dynamic direction of fragmentation should therefore be aligned relative to one another in such a way that the fragmentation spray covers the detected target well when it arrives there. This can therefore mean that a smaller inclination is required between the scanning direction of the target sensor and the main direction of action of the fragmentation housing. Such a projectile is equally suitable for combating ground targets and flying targets. When engaging ground targets, the scanning direction of the target sensor and the main direction of action of the active charge, ie its dynamic direction of fragmentation during the projectile's descent, follows a gradually narrowing funnel or cone which forms a spiral-shaped movement in the ground plane towards the centre. A corresponding spiral trajectory will encircle a jacketed air target in the same way and will therefore also accept a relatively large distance of miss in the case of an air target and yet produce the effect in the target in the same time as if it were covering very close impacts near the target, also because the scanning beam of the target seeker passes through this area immediately in front of the projectile.

It is known that it is possible to establish by experience that multiple hits by fragments produce a high probability of elimination, although the effect of each individual fragment is limited. In this variant, the fragment-forming casing of the active charge preferably consists of a plate which is inclined relative to the direction of flight of the projectile and can advantageously consist of a large number of pre-formed balls made of heavy metal which are interconnected. Several different ways of producing such ball plates have already become known, and their effectiveness on various types of targets is well documented. The type of ball pattern which the ball plates in question lead to is in turn determined by their shape. If the ball plates are made convex in the direction of fire, for example, an increasingly scattered ball pattern is obtained, while a reasonably concave ball plate produces a concentrated ball pattern. In a preferred embodiment of this variant, the plate is inclined by more than 40º relative to the flight direction of the projectile, at the same time the ignition of the explosive in the active charge arranged behind the ball plate takes place eccentrically, so that the detonation front hits the plate as close to the vertical as possible. In this embodiment, the balls are ejected from the ball plate at a higher speed than that achieved in the case of a corresponding cylindrical housing. By selecting a suitable shape for the ball plate, it is possible, for example, to induce a ball sheaf in the form of a cone with a half apex angle of, for example, 6 to 20º, so that the ball density, even with a long Target distance can be kept high, such as up to 50 meters from the detonation point.

The invention thus provides a way of achieving good results with unguided projectiles instead of using relatively simple and inaccurate fire control systems. Possible firing arrangements in which the use of the invention could be of interest could therefore be older automatic anti-aircraft guns of 30 to 40 mm calibre and upwards, of which a very large number are still in service. In addition, anti-tank weapons of the reverse-flow or counter-mass type, equipped with projectiles designed in accordance with the invention, could be used against helicopters and other targets which are well delineated against the background.

The invention has been defined in the patent claim and will now be described in more detail in conjunction with the attached figures, in which

Fig. 1 shows a longitudinal section through a projectile provided with a target sensor angled obliquely forwards and a fragmentation-forming casing;

Fig. 2 combating a ground target with a projectile of the type shown in Fig. 1;

Fig. 3 is a basic diagram of a variant of attacking an air target with a projectile of the type shown in Fig. 1.

The projectile 1 shown in Fig. 1 comprises a rear projectile body 1a with a normal belt 2 and an internal explosive charge 5, which is closed off at the front in the direction of flight of the projectile by a fragmentation housing in the form of a ball plate 3 made of heavy metal of a type known per se, which is inclined relative to the direction of flight. As can be seen from the figure, the ball plate 3 made of heavy metal is angled obliquely with its main direction of action 4 at more than 40º relative to the direction of flight of the projectile 1, which coincides with its main axis. There is an ignition charge 6 for igniting the explosive charge 5. Arranged in front of the fragmentation housing, there is There is also a target sensor 7, the scanning direction 7a of which is angled downwards, parallel to the dynamic direction of the fragmentation, so to speak the vectorial sum of the fragmentation speed plus the projectile speed, so to speak the main direction of action 4 of the fragmentation housing. The front part of the projectile is also covered by an aerodynamically designed casing 8, which could be removed after firing in order to give the target sensor a completely clear field of view.

Fig. 2 is intended to illustrate the use of a projectile 29 of the type shown in Fig. 1 for engaging ground targets. The target sensor scanning beam 30 can be considered as a straight line, while the fragment-forming casing, when the main charge is detonated, produces a fragment spread which will cover a certain area on the ground plane. However, for the sake of simplicity, the fragment spread can, as can be seen, begin as a straight line 31 which represents its main direction of action, so to speak its dynamic direction of fragment formation, and which in the figure coincides with the target sensor scanning beam. The scanning beam and the main axis of the fragment spray, which could thus be formed at any moment when the main charge had detonated, will, as a result of the rotation of the projectile, follow a path 33 which spirals inwards towards the theoretical point of impact 32 of the projectile 29 during the downward path into the ground plane of the latter. The effective area of the projectile therefore covers the entire area inside the spiral path 33. If, as shown in the illustration, there is a target at point 34 to which the projectile's target finder responds and therefore ignites the projectile's main charge, the target and the surrounding area, designated here as 35, will be covered by the fragments of the bullet burst formed when the projectile detonates.

Finally, Fig. 3 shows a variant in the case of combating an air target with a projectile of the type shown in Fig. 1. The projectile is shown on its own trajectory 37 in a first position 36a and a second position 36b. In addition, it is assumed that the projectile's target seeker has a scanning angle α. In the figure, one and a half turns of the spiral curve 38a and 38b were then drawn for both projectile positions 36a and 36b, with the target seeker and the main direction of action the active charge, so to speak its dynamic direction of fragmentation, at an arbitrary distance, which is the same in both cases, in front of the projectiles 36a and 36b respectively. If it is then assumed that a target which is worthy of engagement and can be detected by the target sensor is located at point 39, when the projectile has reached the position 36b shown in the figure, where the main charge of the projectile detonates, this will be swept over by the ball pattern indicated by the reference numeral 40 which has the cover 41 around the target. The line 42, also drawn in the figure and representing the scanning beam of the target finder when the projectile is in position 36a, has been included only to show that when the projectile is in this position the scanning beam can never hit the target at point 39, but can hit a target located at a greater distance from the projectile trajectory 37, for example at point 43, which in this case can be covered by the ball spray 44 with its cover 45 around the target, in connection with which the fragmentation density and hence the effect on the target will, however, be correspondingly reduced.

Claims (1)

1. Rotationally stabilized projectile such as an artillery shell or rocket (1 and 29) for combating ground and air targets, comprising: an explosive charge (5) arranged in a projectile casing (1a); an ignition charge (6) for igniting the explosive charge (5); a fragmentation plate (3) designed such that, upon detonation of the explosive charge (5), it releases fragments which are accelerated at high speed in a continuous sheaf in a predetermined main direction of action; a target sensor (5) connected to the ignition charge (6) and designed to trigger the ignition charge (6) when the sensor has detected a target (34, 39 and 43) worth fighting in flight, the search direction of the sensor being aligned with the dynamic direction of a splinter spray generated by the splinter formation plate, characterized in that the search direction (7a, 30, 42 and 46) of the target sensor and the dynamic fragmentation direction (31, 42 and 46) of the active charge and the fragmentation shell, respectively, are inclined relative to the flight direction (32, 37) and the main axis of the projectile, but are directed forwards, the inclination angle being more than 40º and less than 90º; that the projectile casing (1a) is closed by the fragmentation plate (3), wherein the explosive charge (5) is arranged directly behind the fragmentation plate (3); that the target sensor (7) is arranged in front of the fragmentation plate (3); that the ignition charge (6) is arranged eccentrically at the rear end of the explosive charge (5).