DE4123308A1 - Guidable projectile for combating re-entry warheads - has hot gas generator drive material, extending as large dia. central core over essential part of projectile length and carrying shrapnel - Google Patents

Abstract

The guidable projectile has a cylindrical core of drive material for a hot gas generator for cross impulse nozzles over the greater part of its length which has a thin layer of explosive for shrapnel in or under the projectile casing, through which the nozzles with their control devices radially project. The hot gas drive material with explosive extends between electrical devices in the rear and at the peak of the projectile. Several rings with nozzles including their control equipment are provided in axially counterposed, displaced cross-sectional planes, of which one runs through the projectile centre of gravity. USE/ADVANTAGE - In military applications, to destroy reentry warheads.

Description

The invention relates to a projectile according to the preamble of the An saying 1.

Such a projectile is regarding a steering method for optimal encounter situation with the warhead to be defended in the GB 22 29 294 A and the defense strategy also on page 36 (Figure 4) of the "Spectrum of Science" from February 1986 explanatory shown. Basically, it should be aimed at the attacking Ge intercept the warhead at the greatest possible height and at least as far to damage that it no longer has a significant effect in the target can. At a height of several kilometers, however, the air density is so high ring that with conventional aerodynamic means none are sufficient the lateral accelerations for quick navigation of the intercept projectile are more achievable. Its control is therefore more convenient by means of an actuating system, the effect of which on the reaction to Querim pulsing with respect to the longitudinal axis of the projectile. The cross can impulse in the radial throwing of masses exist; more appropriate is, however, the use of a hot gas generator, its reaction gases can escape through redially oriented nozzles if and as long these are temporarily opened by the steering control.  

The nozzles including their control devices are in the project til envelope arranged in a ring in at least one cross-sectional plane, the z. B. runs through the projectile focus, so that the impulse reaction of an open nozzle approximates to the lateral offset of the momentary trajectory of the projectile. If a nozzle ring cross section plane is axially offset from the center of gravity, by the impulse response evoked a torque around the center of gravity to curve the intercept trajectory. Such a pulse nozzle system for a cross-sectional plane is shown approximately in US 46 89 845. Out the relatively large need for hot gas volume, which is due to the individual if the nozzles are temporarily turned on, the result is a high one Volume requirement for the hot gas generator, i.e. large axial installation vo lumen for its fuel. That is why only the ax is in itself relatively short space between the individual nozzle cross-sectional levels ordered hot gas generators for a splinter warhead for ver Addition, such as that from DE 25 01 419 B1 as a splitter assignment an explosive core is known. But this axial limitation limits the available splinter mass and thus the effect in the defensive warhead.

The invention is based on the knowledge of such relationships on the basis of an interception projectile of the generic type form that it while maintaining logistical dimensions as well as maintaining its high long-term maneuverability with hot gas nozzles a decisive increase in defense experienced through increased available splinter mass.

This object is essentially achieved in that the generic projectile according to the labeling part of the An Say 1 is designed.

According to this solution there is no split in the longitudinal direction of the projectile between hot gas generator sections and fragmentation given head sections. Rather, the splinterge extends fencing head essentially over the entire length of the projectile between the front and rear electronics areas, and  The hot gas pulse control system is integrated into the splinter warhead freezes. This combination of control system and warhead exists in it, the fuel of the hot gas generator over the in to allow the entire length of the projectile to extend and this relatively large volume in the core area of just a thin one Layer of explosives for the radial acceleration of the fragments give. The splinter mass itself is also over this length of Projectile formed in or behind the shell, only interrupted through the radial from the outer surface to the hot gas fuel sweeping nozzles with their nozzle controls.

On the one hand, this means that the largest part of the interior of the projectile and thus a large volume of fuel for hot gas development tion available, so that one in terms of intensity and duration sufficient maneuverability of the projectile can be ensured, while on the other hand practically the entire shell for receiving Splinter material is available, which is a very large splinter mass brings. It is true that the acceleration of this splinter mass by thin behind (and thus on the hot gas fuel) Explosive layer not particularly large; but it only needs there for being laid out, breaking open the shell and using the splinters radial movement component with respect to the longitudinal axis of the projectile add because the kinetic effect in the warhead to be defended in essentially determined by its high approach speed is.

Additional alternatives and further training as well as further features and advantages of the invention result from the further claims and, also taking into account the explanations in the summary solution, from the description below one in the drawing below  Restriction to the essentials is highly abstract and not entirely Preferred implementation example for the er outlined to scale solution according to the invention. The only figure in the drawing shows in Axial longitudinal section with the steerable projectile in its Splinter warhead integrated positioning system.

The slim, low-twist projectile 11 , which can be fired from a gun barrel, has a high-frequency seeker 13 behind a pointed radome 12 . The rear area contains in front of a - if necessary after the projectile 11 was fired - floor 14 a battery 15 for central power supply and a remote control receiver part 16 . Whose antenna is arranged on the curled winding tail assembly 17, which is still rolled here. Before that, over a large part of the length of the projectile 11 to directly behind the target seeker head 13 with its high-frequency electronics, a concentric combination of a centrally arranged control system 18 and this hollow cylindrical surrounds splinter warhead 19 .

The actuating system 18 essentially has a cylindrical core made of propellant 20 for the development of hot reaction gases, which can emerge from the projectile shell 22 through individually controllable nozzles 21 . Preferably, at least two axially against each other the offset nozzle rings 23 are provided in the lateral surface of the sleeve 22 , one of which lies in the cross-sectional plane through the projecting center of gravity 24 and one in a cross-sectional plane which is offset as far as possible. As a result, a transverse offset of the projectile 11 parallel to its longitudinal axis 25 can be caused by opening a nozzle 21 in the cross-sectional plane through the center of gravity 24 as a result of the reaction effect of the emerging hot gas jet, while a pulse release with an axial offset on the other hand causes the projectile to pivot. Longitudinal axis 25 around the center of gravity 24 and thus leads to an at least temporarily curved trajectory.

Around the propellant 20 of the hot generator extends a layer of explosive 26 which is comparatively thin compared to the radius of the propellant core and which is only interrupted by the nozzles 21 with their control devices. This layer of explosive 26 essentially only needs to be designed to initiate the target seeker head 13, which also serves as a proximity fuse, to break open the projectile sleeve 22 and accelerate it radially with respect to the longitudinal axis 25 of the projectile. In the sketched example, the splitters 27 are prefabricated small balls or cuboids which are fixed on the inside of the casing 22 ; instead, or in addition, a more solid casing 22 with predetermined breaking points can also be provided, which is broken up into radially accelerated splinters 27 by initiation of the explosive layer 26 .

The kinetic effect of the splinters 27 in the encounter situation of the intercepting projectile 11 with a projectile or missile warhead to be deflected results less from the lateral acceleration of the splinters 27 than primarily from the high speed of encounter with the target object. Because at the high approach speed of the order of 1,5000 m / s of the reentry warhead to be defended, the speed of the fragments 27 released by the projectile 11 hardly contributes to the high approach speed.

Therefore, the explosive 26 needs to be dimensioned only on breaking the splinter shell 22 , so that the propellant material 20 of the large-volume gas generator for the operation of the tax over the entire length and almost the entire diameter of the warhead 19 within the thin hollow cylindrical explosive 26 Nozzles 21 can extend.

Claims (5)

1. Steerable projectile ( 11 ) for combating, in particular, reentry warheads of ballistic missiles, characterized in that the projectile ( 11 ) has a cylindrical core made of propellant ( 20 ) of a hot gas generator for cross-pulse nozzles ( 21 ) over the greater part of its length. which is surrounded by a thin layer of explosive ( 26 ) for fragments ( 27 ) provided above, in or under the projectile shell ( 22 ), through which the nozzles ( 21 ) with their control devices pass radially. 2. Projectile according to claim 1, characterized in that the hot gas propellant ( 20 ) with explosives arranged thereon ( 26 ) extends between electrical devices in the rear and in the radome ( 12 ). 3. Projectile according to claim 1 or 2, characterized in that preformed splitters ( 27 ) are provided in or under the projectile cover ( 22 ). 4. Projectile according to claim 1 or 2, characterized in that a solid shell ( 22 ) with splinter predetermined breaking points is provided over the explosives ( 26 ) carried by the propellant ( 20 ). 5. Projectile according to one of the preceding claims, characterized in that several rings ( 23 ) with nozzles ( 21 ) including their control devices are provided in axially offset cross-sectional planes, one of which runs through the projectile center of gravity ( 24 ).