DE3216142C1 - Fast-flying projectile with direction-forming charges - Google Patents

Abstract

The invention relates to a method for defence against attacking objects with the aid of fast-flying projectiles, and a projectile which is suitable for this purpose. In this case, the projectile has direction-forming charges (8) and target sensors (2) by means of which the charges are detonated at a predetermined distance from the target at the moment of flying over or past the target, or in the event of direct impact. In order to reduce the cutting length of the direction-forming charges, according to the invention, at least the part of the projectile which supports the direction-forming charges is braked and, if required, aligned, with respect to the translational and, if required, rotational relative speed with respect to the target, by means of explosive charges. Braking, alignment and detonating of the main charges take place virtually simultaneously, controlled via the target sensor. In this way, optimum terminal ballistics of the projectile are achieved. <IMAGE>

Description

The invention relates to a fast flying Projectile according to the preamble of claim 1.

To ward off attacking objects, e.g. B. tanks, Rockets or the like are being guided or faster and faster ballistic flying projectiles and missiles or other load carriers used. The fast speed speed of such projectiles, such. B. in anti-tank defense rockets high subsonic or supersonic, is once due to the higher speed of the objects to be blocked conditionally, on the other hand this can shorten the defense time will.

From US-PS 41 60 415 is a fast-flying projectile known with a directed charge that runs around its length axis rotates and a target seeker, with the projectile revolving ignition sensor. The trajectory of the projectile It is set so that it is the target in less Flying high. Once the target sensor detects the target, depending on the turning position of the load, he gives it to optimal timing from an ignition pulse, so that the Charge is fired towards the target.

To protect against attacking tanks are also also semi-automatically guided anti-tank missiles or rockets known. A shooter needs such semi-automatic steering method only the crosshairs of one Periscope on the attacking object or target pose and follow the target while the defense missile  with the help of a goniometer coupled to the periscope automatically located and based on this location on the Line of sight periscope target is guided.

The projectiles used for defense usually point direction-forming charges, such as hollow, tandem, P or directed fragment charges. The greatest effectiveness have such charges when the defense weakest parts of attacking objects, e.g. B. Tanks are hit. As above for the US PS 41 60 415 mentioned, it is from DE-OS 28 30 859 be knows, tanks not in direct shot, but straight from to attack at the weakest point. This points the projectile has a target sensor, in this case one magnetic field sensor, which is to be warded off upon detection of the the tank around the tank at the moment of the overflight Center of gravity rotates so that the one in the top Hollow charge towards the top of the tank shows.

The procedures used on the above floors to fight tanks are, however, only limited for fast flying projectiles can be used. The effect directional forming charges is essentially because of this true that the speed to be considered ten, d. H. the speed of the object to be defended and the speed of the projectile carrying the load ses negligibly small compared to that of the Ignition of the charge generated projectiles or fragments can be viewed. However, this is too ent winding high-speed projectiles the Relativge dizziness between the floor and the object flying over it no longer in this relation, z. B. the Sting a shaped charge no longer on one more or less focused point of attack  Object and also penetrates it on this Body, but the stinger is with its rear end at a point far from the point of impact Hit the point on the tank to be defended. The armor not only in a concentrated place intersected, but in the manner of an elongated cut permeated. The depth of penetration of the shaped charge spike Obviously, the longer the length, the smaller the length this cut, d. H. is the cutting length of the load. The cutting length is accordingly high translational and / or rotational relative speeds between Projectile and target negatively affected.

The invention has for its object the cutting length of charge for projectiles with high translational and / or rotational speed as small as possible to keep.

This object is according to the invention by the kenn drawing part of claim 1 specified note times solved.

The idea of the invention is therefore aimed at Relative speed of the charge compared to the abruptly reduce the grasping object so as to reduce the Cutting length of the direction-forming load if possible to keep small. Reducing this relative speed can be both  to the translational relative speed between Ge shot and defended object as well as on the rotations refer to the speed of the load. This principle is also applicable to direct hits where the Effectiveness of directional charge with conventional Distance igniters due to the then too short ignition distance not because of the high speed of the projectiles could be achieved.

The deceleration of the projectile or the load relative to the object to be defended can be done in several ways, e.g. B. by against the direction of flight of the projectile acting engine, by a preferably detonative Disassembly of the missile and use of momentum conservation for the negative acceleration of the load, by counter aimed engines to slow down the rotation of the Bullet and so on.

With the invention it is achieved that in fast-flying Shot the directional charges against that object to be defended be aligned so that a high Effectiveness of these charges with a short cutting length is guaranteed. For the floor is from Ab braking and possible alignment an optimal end ballistics achieved until the charges detonated.

Further embodiments of the invention go from the subclaims forth.

The invention is made in several management examples explained in more detail with reference to the drawings. In the drawings represents

Figure 1 shows a cross section through a first embodiment example of a projectile according to the invention.

Fig. 2 is a schematic cross section through a Ge shot according to a second embodiment according to the invention to reduce the rotational speed of the projectile;

Figure 3 is a schematic cross section through a third embodiment of a projectile according to the invention for reducing the translatory relative speed between missile and from zuwehrendem object.

Fig. 4 shows a fourth embodiment of a projectile according to the invention also for reducing the translational relative speed between the projectile and object to be warded off.

In Fig. 1, a fast flying antitank missile 1 is shown, which in the top of a target sensor is not greater detail, 2, then an electronic control unit 3 for control of the missile and for processing the data supplied by the target sensor 2, in a further body part, an engine 4 and then has a cargo part 5 in the rear. Jet guide tubes 6 of the engine are directed outwards on the periphery of the missile 1 from the engine and surround the cargo part 5 . In addition, the missile can still carry several only indicated tail units 7 .

The charge part 5 has a main charge 8 , in this case a shaped charge, which is ignited by an ignition system 9 at the bottom of the shaped charge. In the conical recess of the hollow charge 8 , a clearing charge 10 is mounted, between which and the engine 4 there is still a cutting charge 11 acting perpendicular to the missile longitudinal axis. At the rear of the missile an auxiliary engine 12 is provided in the form of a small solid propellant, the pulse of which acts perpendicular to the longitudinal axis of the missile and which, upon ignition, imparts a rotation to the missile as described below. Instead of such an auxiliary power unit 12 , a plurality of auxiliary power units acting at different angles can be provided.

The function of the missile described is as follows:

The missile is accelerated with the aid of its engine onto a tank to be combated and is directed towards the target in a manner not of interest here. The end ballistics of the missile is from the target sensor 2 , for. B. an electromagnetic sensor with impact contact. As soon as the missile reaches a position favorable for the ignition - either when it hits a direct hit or above the tank during a flyover - the cutting charge 11 and then the clearing charge 10 are ignited. With the cutting charge, the missile fuselage between engine 4 and clearing charge is severed, with the clearing charge, the front missile part is thrown out of target sensor 2 , control part 3 and engine, but the charging part 5 is braked. It is advantageous to ignite the evacuation charge 10 eccentrically, so that the front missile part is not only accelerated to the front, but is also buckled away from the main charge. In any case, the space in front of the hollow charge 8 is cleared. Depending on the desired target position and direction of action of the main charge 8 , the auxiliary power unit 12 is ignited, whereby the main charge 8 is rotated in the desired direction of action. The main charge 8 is then ignited in this direction by the ignition system 9 . Advantageous in this design of the missile is the already relatively large firing distance to the tip of the missile and the main charge, which is absolutely necessary for fast-flying projectiles to form the shaped charge spike. On the other hand, the space charge and the cutting charge clear the space in front of the shaped charge, so that its action is not hindered by missile parts. Likewise, the auxiliary power unit or the auxiliary power units enables the shaped charge to be oriented in the desired direction of action.

In Fig. 2 a fast-flying rotating projectile 1 ' is shown schematically. This floor is used to ward off z. B. tanks in overflight. In the fuselage of this floor three shaped charges 8 ' are arranged, all of which point downward in their direction of action in the position shown, but the two outer shaped charges are set slightly against the verti cal axis of the central shaped charge in opposite angular directions. In order to achieve the lowest possible relative speed between the object and the projectile when the shaped charges are fired on this projectile, brake devices not shown here are again provided, at least for the charge part of the projectile. This braking can, as described for the above embodiment example, in turn by acting in both directions de, comparable to demolition charges happen. In order to additionally brake the rotation of the projectile 1 ' , along the circumference of the missile two opposing radially acting brake engines 13 are provided. To align the shaped charges 8 ' so that they point at the moment of ignition against the object to be defended and the Ge shot has the lowest possible rotation speed to reduce the cutting length of the shaped charges 8' in the circumferential direction.

In Fig. 3, another non-rotating projectile 1 '' with a shaped charge arrangement 8 '' corresponding to FIG. 2 is shown. These three shaped charges point downwards, so that the projectile is used to access objects from above when passing over or when the projectile is rotated past by flying from the side. To brake the projectile and thus to reduce the relative speed between this and the object to be defended, the projectile has two or more rearward-facing engines 14 on its outer casing. These retrot engines 14 are ignited by a target sensor, not shown, via which the end ballistics of the bullet is controlled.

In Fig. 4 another floor 1 '''is shown, which in turn has a shaped charge arrangement of three shaped charges 8''' corresponding to the two floors above in Figs. 2 and 3. The shaped charges are arranged in a housing 15 , which is kept longitudinally displaceable in the projectile body. Between this housing 15 and the bow of the Ge lap 1 ''' , an explosive charge 16 is arranged. The explosive charge 16 is ignited shortly before the ignition of the shaped charges 8 ''' via the target sensor, not shown, whereby the Ge housing 15 with the shaped charges a direction of flight of the Ge opposing acceleration in the direction of arrow P is impressed. This countermovement of the shaped charges reduces the relative speed between them and the object to be defended and, if the projectile and the explosive charge 16 are appropriately dimensioned, can be reduced to almost zero. The shaped charges 8 ''' are then ignited again by the target sensor.

In all embodiments, the reduction the translational or rotary relative speed between charges of the projectile and the one to be defended Object an optimal training of the shaped charge spike possible, so that the above-mentioned cutting length ver wrestles and thus the effectiveness of the charges conventional floors is increased.

Claims (10)

1. Fast-flying projectile, such as guided or ballistic-projectile, missile or charge carrier, for anti-tank or missile defense or the like. with direction-forming charges, such as hollow, tandem, P or ge directed fragment charges, and a sensor device for target detection to determine the ignition timing for the charges, characterized in that the projectile ( 1 ) or at least the charge ( 8 ) load-bearing parts ( 5, 15 ) of the projectile by means of explosive substances and by the sensor device ( 2 ) un directly before the ignition of the charges ( 8 ) controlled pulse generator ( 10, 11, 12; 13; 14; 16 ) for sudden braking of the projectile ( 1 ) with regard to translation and possibly rotation. 2. Projectile according to claim 1, characterized in that an explosive charge acting on both projectile parts ( 10, 16 ) is provided between the projectile parts ( 5, 15 ) carrying the charges ( 8 ) and the remaining projectile for accelerating the charge part against the direction of flight of the floor. 3. Projectile according to claim 2, characterized in that in the direction of flight of the Ge round ( 1 ) acting charge ( 8 ) the explosive charge ( 10 ) serves as a clearing charge for the remaining part of the projectile ( 2, 3, 4 ) and this part of the projectile Direction of action of the load ( 8 ) rotates. 4. Projectile according to claim 3, characterized in that the clearing charge ( 10 ) is arranged in a recess of the direction-forming charge (hollow charge 8 ). 5. Projectile according to claim 4, characterized in that the clearing charge ( 10 ) can be ignited eccentrically. 6. Projectile according to one of claims 2 to 5, characterized in that a cutting charge ( 11 ) for separating the two projectile parts is additionally provided between the charge part ( 5 ) and the remaining projectile part ( 2, 3, 4 ). 7. Projectile according to one of claims 2 to 6, characterized in that an auxiliary explosive carrier, preferably a solid fuel engine ( 12 ) is provided for aligning the charge ( 8 ) to the target. 8. Projectile according to claim 1, characterized in that retro-engines ( 14 ) are provided for translational braking of the projectile ( 1 '' ). 9. Projectile according to claim 1, characterized in that the direction-forming charges ( 8 ''' ) within the floor ( 1''' ) are arranged in a longitudinally sliding housing ( 15 ), and that for displacement (arrow direction P) of Housing ( 15 ) within half of the projectile against the direction of flight of the Ge an explosive or propellant charge ( 16 ) is provided. 10. Projectile according to one of claims 1 to 9, characterized in that to reduce a rotational movement of the projectile ( 1 ' ) along the circumference of the projectile in the opposite direction to the rotational movement explosive carrier, in particular solid fuel engines ( 13 ) are provided.