DE3607921C1 - Device for horizontal ballistic target engagement from a missile or aircraft - Google Patents

Abstract

The invention relates to a device for horizontal ballistic target engagement from a missile or aircraft which ejects submunitions, in the form of projectiles, bombs or similar means of warfare in the form of scattered weapons by means of one or more energy sources in order thus to make possible engagement of known enemy targets at ranges of approximately 400 m and at altitudes of less than 50 m, objectively and in a tightly constrained manner in terms of area. <IMAGE>

Description

The invention relates to a device for hori Zonal ballistic targeting from a missile or aircraft from according to the generic term of the An saying 1.

Such facilities are under the term missile or firearm container itself in different versions known forms. The applicant itself has the sem area, for example in DE-AS 29 34 620 a Ver drive open to cover an area with cluster munitions beard. Here is a complete sprinkler on a la brought stabilized ballistic trajectory, whereby him a movement around his pitch axis with a certain Nick speed imprinted and the ammunition across to the direction of flight of the gritter with differ Chen ejection speeds is ejected. On the The respective stray field width is determined in this way and reached. The variable ejection speed results only from the angular acceleration of the scattering waf window container. The occupancy density is constant here this requires a high ammunition requirement, however a target hit rate is achieved that is compared to The effort for targets such as tanks etc. is too low. For However, this is human or vehicle columns form extremely effective. A spreading container or a device according to the preamble of the claim 1 is known from DE-PS 35 00 163 by the applicant been.

The present invention is based on the object to create a facility of the type mentioned at the beginning, with the particularly at distances of about 300  a target up to 400 m at an altitude of less than 50 m combat is made possible laterally from the trajectory and in doing so a concentrated allocation around the recognized Target is done.

This object is achieved by those listed in claim 1 Measures solved.

In the subclaims are advantageous sticking designs are shown and in the follow an embodiment is explained in the description and additionally sketched in the figures of the drawing. It shows

Fig. 1 is a side view of an ammunition tube of the cluster weapons container with its central axis gelege nem same buffer space,

Fig. 2a shows a pressure-path diagram for a minimum off impact speed,

Figure 2b is a pressure-path diagram for a maximum from impact velocity.,

Fig. 2c is a pressure-path diagram for a minimal delay sti the ejection speed V _0,

Fig. 3 is a sketch of the proposed Bekämp evaporation system, in a schematic representation

Fig. 4 is a transverse view of the spreading arms ammunition container with a diagonal tube assembly in schemati shear representation,

Fig. 5 is a sketch of the area coverage with litter weapons according to the prior art.

From FIGS. 1 and 4 is the embodiment of a cluster weapons container 10, which is appendable to an aircraft or itself is provided with a drive, can be seen. Mostly, however, it will be a dockable aircraft underbody container. In the central container axis 10 a , a so-called buffer space 14 is formed, to which the ammunition tubes 11 connect in the diagonal and are connected to one another by means of overflow channels. In a special example, it is provided that in the Streuwaffenbe container 10 two ammunition tubes 11 are arranged in their direction of impact from the flight direction in one container diagonal and two further ammunition tubes 11 a in the opposite direction in the other diagonal of the container 10 . This training makes it possible for a target to be fought even after the combat area has already been flown over. Often targets in the approach are not recognizable or discoverable by natural or artificial camouflages, but mostly then in the so-called "retrospective" location.

The projectiles or munitions 12 are stored in the ammunition tubes. In the usual way, they are coupled with the ignition and control electronics of the computer of the weapon system. This computer receives its information - also in a known manner - from the location and distance measuring system and together with the values of the airspeed, the altitude and the flight path, it now determines the ejection speed required for the respectively discovered and to be fought target and accordingly activates it Ignition and the timing of the individual submunitions 12 .

In the aforementioned buffer space 14 two or more re gas generators 13 a , 13 b are arranged, which are controlled in their mode of operation by the determined values of the computer, that is to say regulated in their temporal activation state and in the pressure required in each case. Through the bypasses the pressure gas generated in the end cap respectively between the tube 17 and the ammunition driving piston ge 18 formed buffer space 15 is guided, acted upon with the calculated gas pressure that or those ammunition driving piston 18, whereby the controlled ammunition ejection he follows.

Now mechanically, a number of solutions are conceivable here, which however fall under the inventive concept. For example, instead of one or more pressure pistons, a turntable with various diameters of gas guide holes can be arranged, which - controlled by the computer - swivels in the holes corresponding to the determined and required values. Whether the ejection force of the generator gas is directed directly onto the ammunition via gas routing channels, or it is ejected via displaceable pressure pistons, is left to the concept selected. It is essential that the possibility is given to act upon all of the ammunition 12 by the ejection force simultaneously or each ammunition body individually by it. This ensures that the target is combated, as can be seen sketchily from FIG. 3 of the drawing. It is easy to see that in this way not only a considerable ammunition saving is achieved, but also the mission duration can be extended considerably because the ammunition supply lasts longer or the enemy surfaces and targets to be fought can be considerably larger in size.

From the given in Figs. 2a to 2c pressure-slide diagrams, the proposed system is easily understandable Lich, so that further statements no longer appear necessary.

Claims (5)

1. A device for horizontal ballistic targeting from a missile or aircraft which, using one or more energy sources, submunitions in the form of projectiles, bombs or similar ordnance-type weapons, by means of compressed gas, emits gas at different speeds, characterized in that immediately before or while the ammunition output, the output speed (V ₀ ) for the individual or group to be discharged munition ( 12 ) can be varied by several gas generators ( 13 a , 13 b) individually or together each generate a different gas pressure determined by the on-board computer, the acts on the correspondingly selected ammunition ( 12 ). 2. Device according to claim 1, characterized in that the gas generators ( 13 a , 13 b) are arranged in a central buffer space ( 14 ) of the missile container ( 10 ) and overflow channels ( 16 a , 16 b) in the individual and Lead group chambers of the ammunition ( 12 ) or the ammunition tube ( 11 ). 3. Device according to claims 1 or 2, characterized in that the ammunition tubes ( 12 ) at their respective rear end between Rohrab cover ( 17 ) and ammunition piston ( 18 ) have a buffer space ( 15 ) for the generator gas. 4. Device according to claims 1 to 3, characterized in that the ammunition driving piston ben ( 18 ) is designed such that either all ammunition ( 12 ) by the ejection force simultaneously or each ammunition body is acted upon individually. 5. Device according to one or more of claims 1 to 4, characterized in that in the missile container ( 10 ) two ammunition tubes ( 11 ) are arranged in their ejection direction to the flight direction in the egg nen container diagonal and two ammunition tubes ( 11 a) in the opposite direction and in the other container diagonal.