DE102010032386A1 - Disassembling bullet - Google Patents

Abstract

Abolishing the previous practice of free-flying sub-projectiles (1-16), it is proposed that the sub-projectiles (1-16) be connected to one another so that they remain in operative connection. For this purpose, connecting elements (17) are provided which effect this connection. In a preferred embodiment, the bundling of the sub-projectiles (1-16) is performed by a central core (18) which is connected to the sub-projectiles (1-16) via the connecting elements (17). The central core (18) can be a winding core via which the lengths of the connecting elements (17) can be adjusted.

Description

The invention is concerned with increased projectile action of a cloud of subprojectiles forming in the target area, in particular with an influenceability of the flight behavior of the subprojectiles after disassembly of the projectile. The previous practice of free-flying sub-projectiles is abolishing provided to connect the sub-projectiles together so that they remain in operative connection after ejection from the projectile. For this connection elements are integrated, which cause this connection. In a preferred embodiment, the bundling of the sub-projectiles takes over a central core, which is connected to the sub-projectiles via the connecting elements. The central core may itself be a winding core over which the lengths of the connecting elements can be variably adjusted.

This ammunition, also known as AHEAD, is an Air Burst ammunition http://en.wikipedia.org/wiki/AHEAD (ammunition) which disassembles in the air into individual projectiles and thus destroys the target or at least prevents it from flying on. A programmable 35 mm AHEAD ammunition from Rheinmetall Defense is, for example, on the website http://www.rheinmetall-defence.com/index.php?fid=1098&lang=2&pdb=1 entehmbar.

An ABM (Air Burst Ammunition) with defined sub-projectiles is opened after leaving the firing direction by the ignition of a Zerlegeladung within the projectile such that the payload of the projectile carried subprojectiles give up their compact storage position and depending on the nature and strength of the cutting load of remove the original projectile trajectory seen radially. The distance of the subprojectiles from the original projectile trajectory and also the distance between the subprojectiles increases with time since ignition of the disintegration charge. At a predetermined time, the subprojectiles in a plane perpendicular to the original missile lane form a density distribution of a certain number of subprojectiles per unit area. An optimal density distribution is derived from basically known mechanisms of action between subprojectiles and the object to be combated.

• – das einzelne Subprojektil durchdringt eine Außenhülle des Ziels und beschädigt wesentliche innen liegende Komponenten wie Sensoren, Steuerungselemente oder Antriebseinrichtungen
• – das Subprojektil beschädigt aerodynamische Steuer- und Leitflächen des Ziels
• – das Subprojektil bringt eine brennbare oder explosive Nutzlast des Ziels direkt zur Zündung
• – das Subprojektil löst durch direkten Kontakt einen Zünder, z. B. einen Aufschlagzünder im Ziel aus
• – das Subprojektil interagiert über seine Impulswirkung mit dem Ziel, wobei zumindest ein Teil des Subprojektilimpulses übertragen und z. B. eine Flugbahn des Ziels verändert wird.

Technically, these mechanisms of action are based on one or more of the following non-exhaustive list of possible interactions:

• The single sub-projectile penetrates an outer shell of the target and damages essential internal components such as sensors, control elements or drive devices
• The sub-projectile damages the aerodynamic control and guidance surfaces of the target
• - the sub-projectile brings a combustible or explosive payload of the target directly to the ignition
• - The sub-projectile solves by direct contact an igniter, z. B. an impact fuze in the target
• - The sub-projectile interacts via its momentum effect with the goal, whereby at least a part of the sub-projectile impulse is transmitted and z. B. a trajectory of the target is changed.

Depending on the possibility of interaction, a different number of effective subprojectiles is necessary to successfully combat a target. While only a few individual subprojectiles are sufficient in the penetration of the outer shell, the greatest possible number of interacting subprojectiles is necessary for influencing trajectory by impulse transmission. It is assumed that at least a large part of the sub-projectiles actually hit the target, whereby naturally only then the impulse of this part can be transferred to the target. Accordingly, the momentum of the other subprojectiles is lost.

Here, the object of the invention is to identify a possibility with which a larger proportion of the total momentum of the subprojectiles can be transmitted to the target.

This object is solved by the features of patent claim 1. Advantageous embodiments are reflected in the subclaims.

The invention is based on the fact that so far after the decomposition, the sub-projectiles are no longer actively controlled, but solely influenced by external forces and thereby stabilized by their over the spin of the projectile inherent Eigen and orbital angular momentum.

The previous practice of free-flying subprojectiles abolishing is therefore proposed to connect the sub-projectiles together so that they remain in operative connection. However, it is preferred to connect each sub-projectile with a central element - a so-called winding core - by means of a sufficiently tear-resistant thread or the like connecting material. It is thereby achieved that, if at least some of the sub-projectiles hit the target object, the other sub-projectiles connected to them are drawn onto the target object and can then enclose it and transmit its momentum.

From the DE 34 37 594 A a helicopter missile is known in which at least one mass pair connected by a wire is involved. The wire has a rough surface and is coated with tungsten carbide. The missile fired near the rotor blade of the helicopter ejects the mass pair whose connecting wire is to be caught in one of the rotor blades.

Deployable tissue shields for intercepting incident steepfire ammunition on a field camp are the DE 10 2007 019 105 A removable. By limiting the splinter propagation of the incoming munitions within the tissue shield, the risk of collateral damage is reduced.

A projectile that builds up a spatial network of metallic or non-metallic fibers after triggering a cutting charge is used with the DE 37 22 420 A published. The network has the task of exerting a friction or cutting action on the rotor blades of a helicopter and thereby combat it.

The not pre-published DE 10 2009 016 147.3 also describes a disassembling projectile which disintegrates at a defined point in time, but whose main components are tied up by connecting elements after disassembly, or at least remain connected to one another. With the associated fragments of the projectile casing while a large cross-section is achieved because not only the fragments but also the connecting elements can act on the object to be controlled, for example by looping of rotating or other parts, such as rotor or wing. The connecting elements can be glued, jammed or potted in the production of the projectiles or ammunition and are formed by steel wires, stable fibers or the like. The connecting elements can be supplemented or reinforced by components with which cutting action can be achieved at the target. Such connecting elements are also usable in the present idea. - Although there are approaches to incorporate fasteners in a bullet in order to obtain a cutting action on the target by this, the connecting elements of the idea proposed here, however, have a different function, although they also act on the target itself. The bundled subprojectiles should increase the impulse impact on the target. Of course, the fact that the fasteners between the subprojectiles can be used to control objects with rotor blades can be used in the form of a cutting action, but the primary purpose of the ABM ammunition is to combat RAM targets (Rocket, Artillery, Mortar) and the like.

The subprojectiles remain loosely connected by the connecting elements after ejection in the cloud, the threads not or hardly affect the flight behavior. If a certain minimum number of subprojectiles meets the target, the tightening connecting threads allow the impulse of the subprojectiles that do not strike directly to be transferred at least partially to the target, so that the momentum of these projectiles is not completely lost. The subprojectiles are preferably connected to each other via a central core, which also acts as a sub-projectile.

By choosing the respective thread length, the maximum total extent of the sub-projectile cloud can be limited and thus influenced. The choice can be implemented by a winding core. If the winding core has an up or unwinding function, possibly taking advantage of the overall projectile, the thread length can still be controlled by the known control devices after the ejection of the subprojectiles and can be adapted to the target type and / or target size. For this purpose, the control device can be connected to one or more sensors, which determine the dimensions of the target and / or the target type. If the winding core is also designed as endphasengelenkter core, the ejected cloud is also endphasensteuerbar. The attachment of the thread on the projectile requires a maximum of a general freewheeling function, if it is to be achieved that the projectile spin does not lead to rewinding and shortening of the thread.

The advantage of implementing the idea, to increase the effect in the target or only to connect the sub-projectiles with a central point of the projectile, is that the ammunition as such has the same dimensions as the already known conventional. As a result, they can also be spent with the conventional weapon systems.

Reference to an embodiment with drawing, the invention will be explained in more detail. It shows:

1 a schematic representation of the projectile with the subprojectiles,

2 a sketchy representation of the subprojectiles in their function.

3 a particularly preferred embodiment of the projectiles according to the invention

1 shows in a sectional view of a projectile 100 with several subprojectiles, here 1 - 16 , In addition to the known other components such as Zerlegeladung 101 / igniter 102 etc. has the projectile 100 a central core 18 on that with each of the submunitions 1 - 16 over fasteners 17 connected is.

After firing of the projectile 100 on a goal 20 the sub-projectiles are ejected in a known manner after a predetermined time at a predetermined location. These subprojectiles 1 - 16 approach the target object 20 that from the subprojectiles 1 - 16 to be taken.

Because the subprojectiles 1 - 16 through rice-proof fasteners 17 , like threads or fibers etc., with the in the bullet 100 integrated and with pushed out central core 18 These can only be within the scope of the length of the connecting element 17 remove each other.

If then - as in 2 shown - now only the subprojectiles 8th . 15 . 16 the target object 20 directly meet, arise for the further effect different basic possibilities, which actually occur in mixed forms.

The three direct subprojectiles 8th . 15 . 16 bounce off the target, but are slowed down compared to the other sub-projectiles. As a result, then tighten the fasteners 17 and the subprojectiles 8th . 15 . 16 are pulled away from the target again. This represents the least optimal case and corresponds in the momentum transfer essentially a projectile known from the prior art without connecting elements 17 ,

In a wide variant, one or more subprojectiles get caught in or at the target 20 z. B. by penetrating the outer shell of the target 20 , This slows down the corresponding sub-projectile, and then the fasteners tighten 17 with the other subprojectiles. The anchored position creates a connection between the target and all other subprojectiles, which in turn can transmit at least part of their momentum to the target. This transfer is only by the tear strength of the fasteners 17 on the one hand and anchoring on the other.

In a third variant, an anchoring of the reticulated bundle of subprojectiles by wrapping the target through the combination of the subprojectiles succeeds 1 - 16 and the connecting elements 17 , This also enables the transmission of a large part of the total momentum of all subprojectiles 1 - 16 to the goal 20 ,

At the central core 18 it may be in a particular form to a kind of winding core, the length of the fasteners 17 can influence. In this case, in a first simplest embodiment, all subprojectiles are 1 to 16 with fasteners 17 connected, which in turn are wound on the central winding core all in the same winding direction. After firing the Zerlegeladung the subprojectiles - possibly supported by the spin rotation of the projectile - radially accelerated from the projectile trajectory to the outside. This radial movement is only on reaching the length of the connecting elements 17 stopped, which naturally also have different lengths. In this embodiment, therefore, the maximum extent of the subprojectiles is limited by the choice of the lengths of the connecting elements. The connecting elements 17 can also be formed by elastic but limited in their maximum length fibers or threads.

In a further embodiment, the central winding core 18 executed in two parts, the part being the connecting elements 17 carries, is rotatably mounted relative to a second part. Both parts are in operative connection with each other via a brake or motor device known per se. As soon as the sub-projectiles have reached a certain radial distance from the winding core after ignition of the cutting charge, the brake or motor device stops the further rotation of the first part of the winding core 18 from now on, so that the individual sub-projectiles no longer continue from the central hub 18 can remove. Depending on the target type, a variable sub-projectile density can be set.

In a third embodiment, the central winding core is made in two parts and both parts are rotatably connected to each other. Here is a first part (eg one half) of the subprojectiles 1 - 16 over fasteners 17 wound on the first part of the winding core, wherein the winding direction is selected in the projectile direction, for example in a clockwise direction. A second part (eg the other half) of the subprojectiles 1 - 16 is about fasteners 17 wound on a second part of the winding core, wherein the winding direction is selected for this part opposite to that of the first part. Now, after firing the Decomposition charge, seek the subprojectiles 1 - 16 radially outward, so in each of the two parts of the central winding core produce a rotation overlapping the original twist, but which are each opposite to each other. With appropriate choice of the masses involved, the induced total angular momentum on the winding core (neglecting the spin rotation of the projectile) is therefore zero. To stop a radial movement of the sub-projectiles, it is therefore sufficient to stop the relative rotation of the two parts of the central hub. This can be done with basically known Braking devices such as friction linings, locking lugs or magnetic brakes done.

In a preferred fourth embodiment as an extension of the third embodiment are in 3 the two parts 18a and 18b the central winding core spaced from each other and via a mechanism in the manner of a threaded rod 19 connected with each other. Unless the aforementioned rotation of the parts 18a and 18b used, move with an appropriate choice of winding directions and the type of thread, the two parts to each other and stop as soon as the two parts 18a and 18b of the winding core meet. With a suitable choice of the spacing, the radial extent of the subprojectiles can thus be determined. If the spacing z. B. can be adjusted by an impulse when launching the projectile, so succeeds in an individual determination of the thread length and thus an individual determination of the radial extent of the subprojectiles. The setting of the spacing can z. B. be achieved by moving the receiving point of the threaded rod in one or both parts of the winding core.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 3437594A [0010]
• DE 102007019105 A [0011]
• DE 3722420 A [0012]
• DE 102009016147 [0013]

Cited non-patent literature

• http://en.wikipedia.org/wiki/AHEAD (ammunition) [0002]
• http://www.rheinmetall-defence.com/index.php?fid=1098&lang=2&pdb=1 [0002]

Claims (9)

Ammunition ( 100 ) with at least two, preferably several subprojectiles ( 1 - 16 ), characterized in that the subprojectiles ( 1 - 16 ) via connecting elements ( 17 ) and a central subprojectile ( 18 ), wherein the connecting elements ( 17 ) between the respective sub-projectile ( 1 - 16 ) and the Central Subprojectile ( 18 ) are involved. Ammunition according to claim 1, characterized in that the Zentralsubprojektil is designed as a central core, in particular as a winding core, and preferably with a Endphasenlenkung. Ammunition according to claim 2, characterized in that the winding core ( 18 ) two-piece ( 18a . 18b ). Ammunition according to claim 3, characterized in that the winding core halves ( 18a . 18b ) rotatable or by preferably also pourable threaded rods ( 19 ) are interconnected. Ammunition according to one of claims 2 to 4, characterized in that it has an open and / or Abrollmechanik. Ammunition according to one of claims 2 to 5, characterized in that by the winding core ( 18 ) the length of the connecting elements ( 17 ) is adjustable, wherein the length adjustment is effected by a control device. Ammunition according to one of claims 2 to 6, characterized in that the length selection depending on the size and / or the type of an object ( 20 ), for which the ammunition has at least one sensor which determines the dimensions of the target and / or the target type and gives this information to the control device. Ammunition according to one of claims 2 to 7, characterized in that the windings can also be wound in opposite directions. Ammunition according to one of claims 1 to 8, characterized in that the connecting elements ( 17 ) rice-resistant threads, fibers, etc. are.

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