WO2020164869A1 - Method for combating aerial targets by means of guided missiles - Google Patents

Abstract

The invention relates to a method for combating an aerial target (6) by means of a guided missile (1), wherein the guided missile (1) is launched following detection of the aerial target (6) and is steered on a course for combating the aerial target (6), wherein a flight path of the aerial target (6) is determined. Highly dynamic and hardened aerial targets (6) can be successfully combated in three-dimensional space by using a guided missile (1) with a hollow charge (7) disposed transversely to the principal axis of the missile, wherein the course of the guided missile (1) is selected such that, as it flies past, the course of the guided missile (1) lies anti-parallel to the flight path of the aerial target (6), wherein the guided missile (1) flies past the aerial target (6) anti-parallel at a specified distance, wherein a position of an explosive charge (6a) on the aerial target (6) is determined when the aerial target (6) is detected, wherein the hollow charge (7) is detonated according to the position of the explosive charge (6a), and wherein the hollow charge (7) sets off the explosive charge (6a) of the aerial target (6).

Description

"Procedure for combating air targets using guided missiles"

The invention relates to a method for combating air targets by means of guided missiles with the features of the preamble of claim 1.

The invention relates to the combat and defense against air targets, namely threats from the air such as e.g. Mortars, Cruise Missiles or Precision Guide Bombs (PGMs), in particular through ground-based defense devices in the form of surface-to-air guided missiles, which act against the air targets. Air targets can for example be missiles with a warhead, the warhead having an explosive charge.

Surface-to-air guided missiles for defense against threats from the air are known in principle. They mostly use an explosive charge as a warhead, which is detonated near the air target and is then supposed to act on the air target through the pressure wave and the resulting fragments. This is successful for unprotected or lightly protected air targets such as airplanes or drones, but fails for protected or hardened targets such as e.g. Mortars.

When destroying old ammunition, it is known to detonate them by igniting an additionally installed shaped charge. The shaped charge has sufficient kinetic energy to penetrate the shell of the old ammunition and then to ignite the explosive mass inside, which detonates the old ammunition.

Also known are guided missiles for combating ground targets, in particular battle tanks, with a shaped charge as a warhead, whereby the strongly protected front of the battle tank is not attacked, but the guided missile flies over the battle tank at a low altitude and then the shaped charge from above onto the less protected areas, like the top of the armored turret, ejects. Such designs are known from EP 1 767 893 and US Pat. No. 5,932,833. In this overflight combat, the guided missile is not directed to a direct hit on the target, but to an overflight at a defined distance from the target. In this overflight combat, the shaped charge is used to achieve unspecific damage to the battle tank. There is no explicit aim to convert existing explosive masses. This type of missile control is comparatively simple, since the absolute speed of the main battle tank is negligible relative to the high speed of the missile (for example in the range up to Mach 2 to 3). The main battle tank is to be seen as a static target. These known guided missiles and methods fail for highly dynamic air targets with comparable speeds. Such systems are referred to as "overfly top attack" systems and are used against ground-based battle tanks.

From DE 35 29 987 a guided missile for combating ground targets when flying over is known. The guided missile has a shaped charge.

Because of the strong directional characteristics of the hollow charge, it is known to vary the exit direction of the hollow charge needle with respect to the main axis of the guided missile and thus with respect to the direction of flight.

DE 27 41 984 discloses a shaped charge warhead, the shaped charge being able to assume different angles to the path tangent of the missile.

From EP 1 328 769 a guided missile with a shaped charge is known, whereby a directional correction can be made as a function of the flight speed of the guided missile through targeted control of a multi-part shaped charge ignition. This guided missile is used against battle tanks.

From DE 35 25 546 a guided missile with a pivotable shaped charge in a warhead is known. The warhead is in the missile tiltable from the starting position into an inclined position. When the guided missile has flown over the ground target, the warhead is directed against the rear parts of the target in the direction of flight.

These guided missiles have a complex structure or require a lot of space, which is usually not available when the space of a guided missile is limited.

When combating threats from the air, it is also known to infer the specific type of threat from the data of a search sensor system (e.g. a search radar), such as a reflection characteristic and a trajectory curve of the air target. There are extensive databases for this purpose, which are integrated into target acquisition systems and can serve as an aid in fighting.

The prior art lacks solutions with which highly dynamic and hardened air targets in three-dimensional space can be successfully combated.

The invention is therefore based on the object of specifying a method and thus a type of control with which highly dynamic and hardened air targets can be successfully combated in three-dimensional space.

This object on which the invention is based is now achieved by a method having the features of patent claim 1.

The method is used to combat an air target by means of a guided missile, the guided missile being launched after the detection of the air target and being steered onto a course to combat the air target, a flight path of the air target being determined. According to the invention, a guided missile is used with a shaped charge arranged transversely to the main axis of the missile. The missile main axis is formed by a longitudinal axis. The longitudinal axis is directed in the direction of flight. The guided missile is designed in particular as a rocket. It's at least one Shaped charge present in the guided missile. This shaped charge is essentially oriented in such a way that the shaped charge needle can emerge laterally from the missile, in particular perpendicular to the main axis of the missile.

The course of the guided missile is chosen such that the course of the guided missile is anti-parallel to the flight path of the air target during the flyby, the guided missile flies past the air target in an anti-parallel manner at a specified distance, with a position of an explosive charge on the detection of the air target Air target is determined, the shaped charge being ignited as a function of the position of the explosive charge, with the shaped charge triggering the explosive charge of the air target. So that we extend the two-dimensional overflight combat of battle tanks from the state of the art and transfer it to the combat against air targets. This makes it possible to combat non-static air targets, for example air targets that themselves fly at a speed of Mach 2-3. As a result, the detonation of the explosive charge of the air target completely destroys the air target, leaving only very small fragments. These fragments are then no longer suitable for causing significant damage to the threatened object; this is a significant advantage over just damaging / rendering the air target harmless, for example by disabling the threat detonator.

Furthermore, it is possible to use a relatively small shaped charge in a light and agile guided missile to successfully combat even larger and hardened air targets. For example, air targets of the BLU-109 class can be fought. A BLU-109 air target is a hardened penetration warhead that is used for free-falling bombs, but also for guided bombs or guided missiles.

A simplification of the structure of the guided missile is achieved in that a rolling movement of the guided missile is carried out, the exit direction of the shaped charge being aligned in the direction of the flight path of the air target. In a preferred embodiment, the shaped charge cannot be pivoted with respect to the main axis of the missile. This means that there is no installation space for wasted a mechanical device. The structure of the guided missile is simplified. The shaped charge is aligned in that the guided missile is steered around all three axes (pitch, yaw, roll) by means of several pairs of movable wings or steering flaps. The rolling movement of the guided missile is used to align the shaped charge; no directional mechanics are required within the guided missile, which saves installation space and complexity.

Preferably, a ground-based target acquisition system is used to acquire data on the air target and the trajectory of the air target, the type of the air target and thus a position of an explosive charge of the air target, namely in particular a position of a warhead of the air target, being determined using the data by means of a target type database.

The typical top-to-bottom structure of an aerial target is:

a) a mostly small area for the detonator or the seeker head and b) a larger area with a warhead consisting of explosive material as well

c) then a small area for drive and control.

This distribution of these typical areas is known from target acquisition and the coupling with a target type database in the specific individual combat case and is transmitted to the missile by the ground-based target acquisition system. In order to implement the explosive charge of the air target through the shaped charge needle, it must act on the area with the warhead. The ignition of the shaped charge of the missile is therefore controlled in such a way that the shaped charge can act on the warhead and thereby implement the explosive charge of the air target.

Early combat is made possible by the fact that the guided missile flies at supersonic speed. The guided missile is highly dynamic and can be aligned accordingly at its own high speed, for example Mach 2 to 3, due to the control by means of several pairs of movable steering flaps. This is particularly beneficial when using the Guided missile is fought against an air target flying at supersonic speed.

The guided missile is preferably designed as a surface-to-air guided missile, the surface-to-air guided missile being launched from the ground. The surface-to-air guided missile is launched from the ground, in particular mostly vertically from a battery of surface-to-air guided missiles. After launch, the surface-to-air guided missile is guided on a course to combat the air target. After take-off, the surface-to-air guided missile flies towards the air target, but instead of aiming for a frontal collision, the surface-to-air guided missile flies past the target at a small but fixed, predetermined distance anti-parallel to the flight path of the target.

The guided missile can embark on an anti-parallel course that lies below the course of the air target, with the shaped charge being aligned accordingly upwards. Alternatively, the anti-parallel course of the guided missile can be selected in such a way that the anti-parallel course of the guided missile lies laterally to the course of the air target, the shaped charge being directed laterally to the air target.

There are now a number of possibilities for designing and developing the method according to the invention. For this, reference may first be made to the claims subordinate to claim 1. In the following, preferred embodiments of the invention are explained in more detail with reference to the drawing and the associated description. In the drawing shows:

1 shows a schematic, partially sectioned illustration of a surface-to-air steering body in the form of a rocket with an explosive charge arrangement and an air target to be combated,

FIG. 2 shows the first explosive charge arrangement from FIG. 1 in a schematic, sectional representation, 3 shows the first explosive charge arrangement according to FIGS. 1 and 2 in a schematic, longitudinal and cross-sectional representation,

In Fig. 1, a surface-to-air steering body 1 in the form of a rocket 1 with a filling 2 and a head 3 and several wings 4 is shown. The wings 4 are circumferentially spaced apart in a rear area and in a front area. Eight wings 4 are preferably provided. It is conceivable that there are also fewer than eight, for example three, four or six wings.

The rocket 1 now has an explosive charge arrangement 5. The explosive charge arrangement 5 has a shaped charge 7 and optionally a fragmentation charge 8. The explosive charge arrangement 5 does not have to be arranged on the head of the rocket 1, but is in particular arranged in a central fuselage area of the rocket 1. The explosive charge arrangement 5 is designed in such a way that the shaped charge 7 and the fragmentation charge 8 can emerge from the rocket 1 in a lateral direction and can act. A transverse direction to the longitudinal axis of the rocket 1 is referred to here as a lateral direction. The shaped charge 7 and the fragmentation charge 8 act essentially in the radial direction relative to the longitudinal axis of the missile 1, i.e. also radial to the direction of flight of the rocket 1.

The method serves to combat an air target 6 by means of a guided missile 1. The air target 6 has a warhead 6a with an explosive charge 6a. The guided missile 1 is launched after the detection of the air target 6 and steered on a course to combat the air target 6. When the air target 6 is recognized, a position of an explosive charge 6a on the air target 6 is determined.

A trajectory of the air target 6 is calculated. The course of the guided missile 1 is selected in such a way that the course of the guided missile 1 is anti-parallel, ie offset in the opposite direction to the flight path of the air target 6 when it flies by, wherein the guided missile 1 flies past the air target 6 in an anti-parallel manner at a specified distance

The shaped charge 7 arranged transversely, in particular perpendicular to the missile main axis, is ignited as a function of the position of the explosive charge 6a, with the shaped charge 7 triggering the explosive charge 6a of the air target 6. A hollow charge jet H is indicated here by an arrow. The hollow charge jet H emerges here at high speed (for example up to 10 km / s). The distance between the guided missile 1 and the air target 6 is preferably only small, and is preferably in the range of less than 10 m. The method enables the aerial target 6 to be completely destroyed, leaving only small fragments which no longer cause damage. The effect of the shaped charge 7 can be supported by the fragmentation charge 8. The shaped charge 7 and the fragmentation charge 8 are arranged inside the shell 2 of the missile 1. The fact that the hollow charge 7 and the fragmentation charge 8 act transversely to the longitudinal direction 1 of the rocket 1 means that air targets 6 can be fought very well as they fly past. In particular, 6 missiles can be fought as air targets in a side flyby.

The hollow charge 7 and the fragmentation charge 8 are each assigned a separate explosive 9, 10. The shaped charge 7 and the fragmentation charge 8 have

Explosives 9, 10, the explosive 9 of the hollow charge 7 detonating more rapidly than the explosive 10 of the fragmentation charge 8. The explosive 9 has a greater detonation speed than the explosive 10.

Both explosives 9, 10 are ignited by means of an igniter (not shown) at the base of the hollow charge 7. Through the different

Detonation speeds of the explosives 9, 10 can

Shaped charge jet (not shown) exit completely before the fragmentation charge 8 detonates and emerges. In this way an interaction between the two detonations can be avoided.

The shaped charge 7 has a metal insert 11 in the form of a shaped charge cone 11. The shaped charge cone 11 preferably has copper. The The axis of symmetry (not shown) of the shaped charge cone 11 is aligned in the radial direction of the rocket 1. The shaped charge cone 11 thus points in the radial direction to the inner circumferential surface of the cylindrical casing 2. The fragmentation charge 8 has a plurality of fragment fragments 12. The splinter fragments 12 are preferably made of steel or tungsten. The fragment fragments 12 are arranged between the casing 2 and the corresponding explosive 10. Viewed in the axial direction, the shaped charge 7 is arranged in the center of the fragment charge 8. The fragmentation charge 8 surrounds the shaped charge 7.

The explosive charge arrangement 5 is characterized in that the fragmentation charge 8 is arranged near a head end 13 of the hollow charge 7. The fragment fragments 12 are arranged between the explosive 10 and the casing 2 of the rocket 1. The fragmentation charge 8 has a preferably circular passage 14 for the shaped charge 7. The splinters 12 cover an angular range of preferably 135 ° of the circumference of the rocket 1. The fragment fragments 12 are arranged in an annular cylinder segment with an opening angle of 135 °, for example. No splinter fragments 12 are arranged in the area of the passage 14. The explosive 10 is arranged in a cylinder segment, the cylinder segment likewise having the same opening angle as the cylinder ring segment of the fragmentation charge 8. The explosive 10 also has a passage 15, the hollow charge 7 with the corresponding explosive 9 being arranged within the passage 15.

The explosive 9 is arranged within a housing 16. The shaped charge cone 11 is arranged within the housing 16. The space between the shaped charge cone 11 and the housing 16 is filled with the explosive 9. The housing 16 has a cylindrical area which engages in the passage 15. The passage 15 is designed to match the outer circumference of the housing 16. The housing 16 tapers like a pot outside of the passage 15 up to the igniter, which is not shown in detail. The housing is made in particular from aluminum. This arrangement of the fragmentation charge 8 enables a relatively large effective area to be generated. The individual fragment fragments 12 are each preferably arranged in further individual housings (not shown in detail). Individual explosive charges of the fragment fragments 12 are thereby separated from one another. The fragment fragments 12 can thus be designed with their own explosive charge, which is arranged within the individual housing. These explosive charges can detonate on impact on the air target 6. The explosive charge of the fragment fragments 12 can likewise trigger ignition of the explosive charge 6a of the target in a targeted manner, as a result of which the air target 6 is completely destroyed.

List of reference symbols:

1 surface-to-air guided missile / missile

2 cover

3 head

4 wings

5 Explosive Charge Order

6 air target

6a Warhead of the air target / explosive charge of the air target 7 Shaped charge

8 fragmentation charge

9 explosives

10 explosives

11 shaped charge cone

12 Shard Fragment

13 head end

14 passage

15 pass

16 housing

H shaped charge beam

Claims

Patent claims:

1. A method for combating an air target (6) by means of a guided missile (1), wherein the guided missile (1) is started after the detection of the air target (6) and is steered onto a course for combating the air target (6), with a trajectory of the air target (6) is determined, characterized in that a guided missile (1) with a shaped charge (7) arranged transversely to the missile main axis is used, the course of the guided missile (1) being selected such that the course of the guided missile (1) anti-parallel to the flight path of the air target (6) during the flyby, the guided missile (1) flies past the air target (6) anti-parallel at a specified distance, with a position of an explosive charge (6a ) is determined on the air target (6), the shaped charge (7) being ignited depending on the position of the explosive charge (6a), the explosive charge (6a) of the air target (6) being triggered with the shaped charge (7).

2. The method according to claim 1, characterized in that a rolling movement of the guided missile (1) is carried out, the exit direction of the hollow charge (7) being aligned in the direction of the flight path of the air target (6).

3. The method according to any preceding claim, characterized in that data about the air target (6) and the flight path of the air target (6) are recorded by means of a ground-based target acquisition system, the type of the air target (6) and thus the type of the air target (6) using the data using a target type database a position of an explosive charge (6a) of the air target (6), namely in particular a position of a warhead (6a), is established.

4. The method according to any one of the preceding claims, characterized in that the guided missile (1) flies at supersonic speed.

5. The method according to any one of the preceding claims, characterized in that the guided missile (1) is used to fight an air target (6) flying at supersonic speed.

6. The method according to any one of the preceding claims, characterized in that the guided missile (1) is designed as a surface-to-air guided missile (1), the surface-to-air guided missile (1) being launched from the ground.

7. The method according to any one of the preceding claims, characterized in that the guided missile (1) has a fragmentation charge (8).