The technical scope of the present invention is that of anti-air shells intended to scatter sub-projectiles during their trajectory.
Anti-air shells that generate a spray of sub-projectiles during their trajectory are well known. Generally, these sub-projectiles are constituted by metallic balls or cylinders. Reference may be made, for example, to patent EP-2578987 which describes a medium calibre anti-air shell constituted by an ogive shaped nose cone extended by a casing and a rear end cap enclosing an air burst charge, made integral by joining means. The sub-projectiles are integrated into the casing and when the air burst charge functions the sub-projectiles are released.
The main drawback to this shell lies in the fact that the separation of the nose cone from the casing and the separation of the casing from the rear end cap are made by a single means. As a result, it is difficult to control the functioning of this shell.
The aim of the present invention is to supply an anti-air shell whose functioning is made in two steps so as to make the scattering of the sub-projectiles more reliable.
The invention thus relates to a medium calibre fin-stabilised anti-air shell intended to produce a spray of sub-projectiles, wherein it comprises an ogive shaped nose cone extended by a case tube and a central pin delimiting with the case tube a housing enclosing sub-projectiles, a casing covering the case tube attached, by means of an upstream thread at its front end, to a flange on the nose cone and attached by means of a downstream thread at its rear end onto a rear end cap enclosing an air burst charge, translation means being positioned between the rear end cap and the case tube so as to ensure the shearing of the upstream and downstream threads.
According to one characteristic of the invention, the translation means are arranged in the casing and are activated by the ignition of the air burst charge.
According to another characteristic of the invention, the shell comprises a liner arranged in the housing and adjusted to the internal diameter of the case tube, the sub-projectiles being arranged in said liner.
Advantageously, the liner is arranged upstream and presses against a flange on the nose cone and downstream against the translation means.
According to yet another characteristic of the invention, the translation means are constituted on the one hand by a finger meshed on the free end of the central pin of the nose cone and on the other by a disc pressing on the free end of the case tube.
According to another characteristic of the invention, the translation of the finger drives the shearing of the upstream thread and the translation of the disc drives the shearing of the downstream thread.
According to yet another characteristic of the invention, the shell incorporates at least one sleeve arranged to press both on the rear end of the liner and against the sub-projectiles.
According to yet another characteristic of the invention, the liner is constituted by a set of retainer petals for the sub-projectiles.
Advantageously, the sub-projectiles are constituted by cylinders of heavy metal.
A first advantage of the invention lies in the fact that the separation of the different elements is performed step by step. Indeed, the nose cone is firstly separated from the casing, then the casing from the rear end cap.
Another advantage of the present invention lies in the fact the release device gives the casing greater strength than that of classical casings of telescoped ammunition. Indeed, the sequential double unlock device eliminates the necessity of including a mechanical embrittlement of the casing to allow the sub-munitions to be scattered.
Another advantage of the present invention lies in the specific conditioning of the sub-projectiles.
Yet another advantage of the present invention lies in the fact that the shell has a profile that is well suited to ammunition of this type.
Yet another advantage of the present invention lies in the use of the nose cone as a means to confine the sub-projectiles.
Other characteristics, advantages and particulars of the invention will be more apparent from the additional description given hereafter with reference to a drawing, in which:
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As mentioned previously, the aim is to produce a spray of sub-projectiles in the direction of a target such as a missile or other by means of an anti-air shell. This shell contains a large number of sub-projectiles which must be ejected with the greatest effectiveness.
The shell according to the invention addresses this issue and thus relates to a medium-calibre fin-stabilised anti-air shell 1 intended to produce a spray of sub-projectiles.
This shell 1 comprises a nose cone 2 extended by a case tube 3 and a central pin 4. The case tube and the pin delimit a housing 5 enclosing sub-projectiles 6. A casing 7 covers the case tube 3 over its full length in a close fit and is attached to it by means of an upstream thread 8 at its front end on a flange 9 of the nose cone 2. The casing 7 is attached to a rear end cap 10 by means of a downstream thread 11 at its rear end.
The sub-projectiles 6 may be constituted by cylinders of heavy metal.
To complete the sealing of the casing 7 with respect to the nose cone 2, a seal 12 is arranged in a groove in the flange 9. It is the same case between the casing and the rear end cap where this rear end cap presses against a rear seal 13 in a chamfer made at the free end of the casing.
The rear end cap 10 encloses an air burst charge 14 connected to an igniter 20.
The shell 1 integrates translation means 15 for the sub-projectiles 6 positioned between the rear end cap 10 and the case tube 3 so as to ensure the shearing of the upstream 8 and downstream 11 threads. These translation means 15 are activated by the ignition of the air burst charge 14 as will be explained hereafter.
These translation means 15 are constituted by a finger 16, on the one hand, meshed with the free end of the central pin 4 of the nose cone 2 and on the other, by a disc 17 pressing against the free end of the case tube 3. It goes without saying that the finger 16 may be freely inserted into a drill hole made in the free end of the central pin 4.
The Figure shows that the sub-projectiles 6 are arranged in a liner 18 itself arranged in the housing delimited by the case tube 3, the liner being adjusted to the internal diameter of this case tube 3. This liner 18 is made of an easily split and scatterable material.
It can further be seen that the liner 18 is arranged upstream pressing against a flange 19 on the nose cone 2 and downstream on the translation means 15 via at least one washer 20 arranged to press both against the rear end of the liner 18 and against the sub-projectiles 6. This liner 18 may be constituted by a set of retainer petals for the sub-projectiles 6.
Advantageously according to the invention, the finger 16 drives the shearing of the upstream thread 8 during its translation, thereby causing a first release of the nose cone 2 and casing 7 and the disc 17 causes the shearing of the downstream thread 11, thereby driving a second release of the casing 7 and the rear end cap 10.
This double release system ensures the separation of the three elements constituting the shell 1 and the release of the sub-projectiles.
Functioning is as follows.
When the shell is launched further to the approach of a threat, the igniter 20 ignites the air burst charge 14 on the trajectory according to a predefined firing sequence. The thrust generated by the charge 14 firstly activates the rod 16 which shears the upstream thread, then activates the disc 17 which in turn shears the downstream thread 11. The three elements constituting the shell 1, the rear end cap 10, the casing 7 and the nose cone 2 are thus separated and distanced from one another. Then the liner 18 containing the sub-projectiles 6 is separated from the nose cone 2 under the effect of the difference in mass.
Further to the disintegration of the liner 18, the sub-projectiles 6 continue on their trajectory in the form of a spray of predefined volume.
The sub-projectiles 6 scatter in space following the laws of general mechanics, that is to say the solid angle of the cone is almost entirely determined by the spin rate of the shell which creates the centrifugal acceleration. The spin rate of a telescoped ammunition shell, however, has the advantage of not dropping by more than 20% over its full trajectory.
The solid angle of the dispersion cone is, classically, between 12° and 15°.
Number | Date | Country | Kind |
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FR1909820 | Sep 2019 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2020/077869 | 10/5/2020 | WO |