EP2154470A1 - Switchable cylindrical explosive charge - Google Patents

Abstract

The charge (1) has a set of pellets (4a, 4b) tubularly arranged in a form of a disk and provided with a holder, where a tubular part (2) and a disk-shaped part (3) of the holder are interconnected. A perpendicular part (3) is arranged in a pre-determined distance from an insert (5), and the tubular part is arranged on the insert relative to a lying side of the disk-shaped part. A set of ignition mechanisms (ZK1, ZK2) is arranged along a main axis (6) of the charge at different areas (7a, 7c) depending upon intended effect within the tubular part or at the perpendicular part of the holder.

Description

The invention relates to a switchable cylindrical active charge of a warhead with a arranged within the explosive charge holder for a plurality of distributed pellets, which is tubular or arranged in the form of a disc approximately perpendicular to the main axis of the active charge, and at least one ignition device for an explosive charge a shaped insert.

The future use of weapons in changing scenarios requires a new ammunition, which can equally effectively combat point or area targets. Taking into account the requirement to minimize collateral damage, ammunition types with metered and / or reversible action are of particular interest.

The applicant has already filed various concepts of multifunctional active charges, which have already proven themselves.

From the DE 10 2006 018 687 A1 a reversible charge has become known. Within the explosive charge, a disc-shaped, approximately perpendicular to the main axis arranged inert holder is arranged with a plurality of pellets. Alternatively, it is proposed to arrange a tubular holder for a plurality of pellets within the explosive charge. However, further arrangements are not described here and were not required within the scope of the given task.

It is an object of the present invention to provide a multifunctional active system, which allows an optional switching of different modes of action in the axial and in the radial direction.

This object is achieved in a surprisingly simple manner in that the tubular and the vertical part of the support of the pellets abut each other or are interconnected, wherein the disc-shaped part is arranged at a predetermined distance from an insert, and wherein the tubular part on the Insert opposite side of the disk-shaped part is arranged, and that along the main axis of the effective charge at depending on the intended effect different locations within the tubular part or on the disc-shaped part of the holder at least two ignition devices are arranged.

Due to the first time so proposed arrangement of a cylindrical and a disc-shaped holder for pellets, it is possible to adjust in stages, the nature of the effect development and their direction as needed.

Advantageously, one of the ignition devices is arranged in the center of the vertical part of the holder. This allows the formation of an EFP projectile in the case of ignition.

As an advantageous embodiment is further proposed. in that, along the main axis of the active charge in the explosive, a recess lying opposite the insert is arranged as far as the disk-shaped part of the holder, in which at least one ignition device is displaceably mounted by means of a drive.

This ensures that, depending on the chosen location of the ignition device in the case of ignition, the sizes of the votes in the axial and radial directions splitter can be determined within wide limits.

Another embodiment is determined by the fact that a damping layer is arranged on the insert facing the end of the recess. As a result, the propagation of the detonation front, which originates from the ignited in the recess ignition device, before arriving at the in the disc-shaped part of the holder located ignition device delayed and reduced in amplitude.

Fig. 1:

den Aufbau einer zwischen radialer und axialer Wirkung umschaltbaren Wirkladung,

Fig. 2:

die Initiierung zur Erzeugung radialer natürlicher und axial kontrollierter Splitter,

Fig. 3:

die Initiierung zur Erzeugung radialer kontrollierter und axial kontrollierter Splitter,

Fig.4:

die Initiierung zur Erzeugung radialer kontrollierter Splitter und axial kontrollierter Splitter mit aufgeweitetem Streuwinkel,

Fig. 5:

die Initiierung zur Erzeugung radialer natürlicher Splitter und eines axialen EFP-Projektils.

An embodiment of the invention is shown schematically simplified in the drawing and will be described in more detail below. Show it:

Fig. 1:

the construction of a switchable between radial and axial effect active charge,

Fig. 2:

the initiation of generating radial natural and axially controlled splinters,

3:

the initiation to produce radial controlled and axially controlled splinters,

Figure 4:

the initiation to produce radial controlled splinters and axially controlled splitter with expanded spreading angle,

Fig. 5:

the initiation to create radial natural splinters and an axial EFP projectile.

In the FIG. 1 is the basic structure of a switchable active charge 1 simplified. The explosive charge 8 is radially outwardly surrounded by a fragment-forming sheath 11, which may for example consist of metal and either has no formation of the splitter supporting notches or is also pre-scored. The active charge is completed in the weft direction with an insert 5. On the main axis 6 of the active charge 1, one or more ignition chains ZK1 are arranged on the insert 5 opposite side and also within the explosive charge 8 at different positions 7a, 7b, 7c. These can be firmly positioned within the cargo and also, as in FIG. 1 shown to be slidably disposed within a recess 12 extending along the main axis 6 in the illustrated arrow direction.

Essential for the switchability of the active charge here is the free choice of the place of initiation of the ignition ZK1. Furthermore, the possibility is provided to use the further ignition chain ZK2 as an aid in the initiation of the first ignition chain ZK1 or to initiate the further ignition chain ZK2 alone. It is equally possible to install several ignition chains KZ1, which can be optionally initiated. In this case, the recess 12 can be completely omitted.

Furthermore, within the explosive charge 8, a one-piece or multi-part holder 2, 3 for pellets 4a, 4b arranged. This holder is made of inert plastic material and has distributed pellets 4a, which consist of explosives. The radial part 2 of the holder is arranged in the form of a tube rotationally symmetrical about the main axis 6 in the explosive 8 and has the shell 11 at a distance in the order of some pellet diameter. The approximately perpendicular to the main axis 6 arranged disc-shaped part 3 of the holder also has a plurality of distributed arranged similar pellets 4b. In the region of the main axis 6, the further ignition chain ZK2 can be arranged in this part of the holder 3. The distance between the disc-shaped part 3 of the holder and the insert 5 is dimensioned so large that in the case of initiation of the ignition chain ZK1, the pellets in the disc-shaped part of the holder and the ignition chain ZK2 greatly modified with respect to the local pressure distribution detonation wave enough running distance Available to fragment the insert 5 in the desired manner.

In principle, the effective charge can be triggered in four different modes, which are described in more detail below. In the FIG. 2 The mode for the simultaneous generation of radially outgoing natural splitter and axially outgoing controlled generated splitter is shown. The term natural splinters is used for those splinters that are generated without the aid of agents that affect the shape and / or size of the splinters as they form. Controlled splinters, on the other hand, are specifically influenced in the formation phase in terms of their shape and / or size.

As in FIG. 2 the ignition chain ZK1 is shown in the already in FIG. 1 indicated position 7a initiated. The front of the detonation wave DW passes through the explosive 8 in the direction of the insert 5. Its course is shown in the phases A, .., D. It strips the tubular part of the holder 2, whereby the pellets 4a stored in the holder are indeed initiated, but this does not affect the detonation wave between the holder 2 and the casing 11. In the contact area of the detonation wave DW with the shell 11, this is decomposed into natural splinters 13 a, which depart radially to the main axis 6. Of course, it is also possible to use a pre-notched sheath or equivalent means to create controlled fragments.

A slight deformation of the detonation wave DW takes place when passing through the damping layer 10. Upon reaching the disc-shaped holder 3, the front of the detonation wave DW initiates the pellets 4b stored therein. This results in a superposition of the original detonation wave DW with those generated by the pellets. This results in a pattern of pressure peaks resulting from the arrangement of the pellets, which finally breaks up the insert 5 into controlled splinters 14a. Since the detonation front strikes the insert 5 approximately frontally, these splinters go bundled relatively axially in the axial direction.

In the FIG. 3 Another adjustable mode is shown, in which radially controlled splitter and axially controlled bundled splitter can be generated. A firing chain ZK1 is chosen for the initiation, which in a position 7b approximately in the middle between the position of the ignition chain ZK1 from the FIG. 2 and the disc-shaped holder 3 is located. The front of the detonation wave DW generated in this case spreads from there approximately radially, which is represented by the different phases A, B, C of the detonation wave. In phase B it penetrates the tubular part of the holder 2 and the disc-shaped part 3 of the holder, thereby initiating the pellets 4a and 4b. As a result, the front of the detonation wave DW becomes the corresponding one Detonation wave pattern C imprinted. This results in the sheath 11 being dissected into this pattern in a controlled manner. In the case of large preformed splinters these are broken down into smaller splinters. The disc-shaped part of the holder is in a similar manner as already FIG. 2 described, about frontal impacted. This also leads to the imprinting of a detonation wave pattern and to the corresponding decomposition of the insert 5 into controlled splinters 14a, which likewise go bundled.

In the FIG. 4 another adjustable mode is shown in which radially controlled splitter and axially controlled splitter with expanded propagation direction can be generated. A firing chain ZK1 is chosen for the initiation, which in a position 7c is even closer to the further firing chain ZK2 than in FIG FIG. 3 had been described. Both parts of the holder are traversed in a corresponding manner from the front of the detonation wave DW, which is represented by the phases A, B, C. In the radial direction splinters are generated in about the same way as already described. However, since the location of the initiation of the explosive charge is closer to the insert 5, the front of the detonation wave is more curved. This leads to a slightly different size distribution of the splitter 14b, which has been generated in a controlled manner, and to a widened outflow region of the splinters.

The FIG. 5 finally shows an adjustable mode for generating natural splitter in the radial direction and a projectile in the axial direction. Here, the ignition chain ZK2 is initiated, which is arranged in the immediate area or in the disc-shaped holder 3. The front of the detonation wave DW runs directly on the insert 5, whereby it is converted into a projectile 15. All pellets 4a, 4b in the two brackets 2 and 3 are struck by the front only grazing, which is why the initiation of the pellets done, but this does not affect the detonation wave between the holder and shell. The shell therefore decomposes into natural splinters. In the case of preformed fragments these are only accelerated radially.

Claims (4)

Reversible cylindrical active charge of a warhead with an arranged inside the explosive charge holder for a plurality of distributed pellets, which is tubular or arranged in the form of a disc approximately perpendicular to the main axis of the active charge, and at least one ignition device for a charge with a shaped insert,
characterized in that - The tubular part (2) and the disc-shaped part (3) of the support of the pellets (4) abut each other or are interconnected, wherein the vertical part (3) at a predetermined distance (d) from an insert (5) is arranged , and wherein the tubular part (2) is arranged on the side of the disc-shaped part (3) opposite the insert (5), - along the main axis (6) of the active charge ( 1 ) depending on the intended action different locations (7a, 7b, 7c) within the tubular part (2) or on the vertical part (3) of the holder at least two ignition devices (ZK1, ZK2 ) are arranged. Wirkladung according to claim 1, characterized in that an ignition device (ZK2) in the center of the disc-shaped part (3) of the holder is arranged. Wirkladung according to claim 1 or 2, characterized in that along the main axis (6) of the active charge ( 1 ) in the explosive (8) extending from the insert (5) side to about the disc-shaped part (3) of the holder extending Recess (9) is arranged, in which at least one ignition device (ZK1) is mounted displaceably by means of a drive. Wirkladung according to claim 3, characterized in that on the insert (5) facing the end of the recess (9) has a damping layer (10) is arranged.

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