DE3327043A1 - Device for scattering electromagnetic decoy material, particularly from a rocket - Google Patents

Abstract

In a device for scattering electromagnetic decoy material, the dipoles (24) are arranged in sub-bodies (5) having an essentially sector-shaped cross section around a centre rod (6) with a central ejection charge (13) for each layer of sub-bodies (5). The sub-bodies (5) are held together by a clamping strap (9) of spring steel surrounding them in the form of a ring, and each sub-body exhibits on both sides of a centre partition (17) two payload spaces (18) open at the end for receiving payload carriers (19) with dipole packets (20) arranged disc by disc so that after the lateral ejection of the sub-bodies (5) from the sub-body carrier (4), the ejection charges in the sub-bodies (5) are ignited with a time delay and eject the payload carriers (19) with the dipole packets (20) arranged thereon in an exactly predetermined manner. The dipoles (24) are arranged standing between separating discs (25) which are flocked with synthetic threads or the like, in such a manner that when the dipole packets (20) are flying through the free air space, only the dipoles present on the outside of the dipole packets (20) are gradually removed. <IMAGE>

Description

Patent application

Device for scattering electromagnetic decoy material, in particular from a rocket The invention relates to a device for scattering Electromagnetic decoy material in the form of dipoles made from tinfoil strips or the like, especially from a rocket.

The problem with such devices is that the hair is fine Dipoles, which are also known as chaff, and in particular to interfere with radar systems serve, with their aerodynamic properties very quickly in one, accordingly their optimal distribution density, large air space evenly to spread. This is necessary because the dipoles or Düppe after their entry into the air space due to their low mass and great aerodynamic drag after leaving the launcher, there is only a slight intrinsic movement in the air and just follow the air movements.

The invention is based on the object of the device for spreading electromagnetic decoy material according to the preamble of claim 1 so train that the dipoles initially as larger masses in the form of dipole packets are ejected outward from the launcher, with those on the outer surface of the dipole packages lying dipoles gradually and largely evenly through the airstream are removed in such a way that they are after leaving the launcher and after largely uniformly forming a thin cloud of dipole strips. It must be taken into account here that the dipoles are both introduced into the dipole packets in the individual sub-bodies as well as in the later distribution in the surrounding ones The air space must be treated carefully because of the high pressure and other loads of the dipoles to nest and thus to reduce the electromagnetically effective Lead the reflecting surface of the formed dipole cloud.

This object is achieved according to the invention by the characterizing part of the Claim 1 solved, while in claims 2 to 12 particularly advantageous developments of the invention are characterized.

Because the dipoles are in sub-bodies around a central rod with central ejection charge for each Laae sub-body are arranged, the sub-bodies after removing the hollow cylindrical rocket head shell by igniting the central Ejection charges initially from the sub-body support in different directions Laterally repel before the ejection of the dipoles from the sub-bodies begins.

This results in a particularly favorable distribution of the sub-bodies by the feature of claim 2, while the feature of claim 3 ensures that the sub-bodies of each sub-body layer charge after the ignition of the central ejection be thrown outwards at the same time by the sub-body support.

The feature of claim 5 sorat that with the repelling the sub-body from the sub-body carrier also has central ejection charges in the sub-bodies be ignited, through the two open end payload compartments on the sub-bodies stored payload carriers with dipole packages arranged in slices accordingly the feature of claim 6 are thrown outwards. A particularly cheap one Ejection effect is achieved by the feature of claim 7, while the Features of claims 9 to 11 on the one hand for a particularly favorable arrangement of the dipoles in the two payload spaces of each sub-body, the other not only for the assembly of the individual sub-bodies, but also for the later Even distribution of the dipoles during the flight of those ejected from the sub-bodies Dipole packets through the free air space is advantageous.

Further details and advantages of the invention emerge from the The following description of an exemplary embodiment shown schematically in the drawing. Show it Fig. 1 is a partially broken away partial representation of a Missile with sub-bodies arranged therein in the flow, Fig. 2 shows the exposed sub-body carrier the missile after removing the hollow cylindrical missile head shell and before the side Repel the sub-bodies arranged thereon by central ejection charges, Fig. 3 the lateral repulsion of the sub-bodies from the sub-body support by the central ones Ejection charges, FIG. 4 shows an enlarged section through the sub-body carrier according to FIG Section line IV - IV of Fig. 2 before the lateral pushing off of the sub-bodies from the Sub-body carrier, Fig. 5 is an enlarged sectional view of the sub-body according to the lateral repulsion from the sub-body support according to section line V - V of FIG. 3, 6 shows an enlarged longitudinal section through the upper of the four sub-bodies according to FIG Section line VI - VI of FIG. 5 before the subsequent ejection of the mirror images of one another and two dipole packets lying coaxially opposite one another, FIG. 7 shows an axial longitudinal section through this sub-body when ejecting the two dipole packets through the central one Ejection charge and FIG. 8 shows the gradual removal of those on the outer surface of a Such a dipole package lying dipoles during free flight through the surrounding air space after ejection from the sub-body according to FIG. 7.

The device shown in the drawing is used for spreading electromagnetic Decoy material in the form of dipoles 24 (Fig. 8) made of tinfoil strips or the like from a rocket 1. The rocket 1 has a rocket head 2 with a hollow cylindrical Sheath 3, which encloses a cylindrical sub-body support 4 and after reaching a selected target area is separated from it.

As can be seen in detail in FIGS. 1 to 5, those of the Device to be scattered dipoles 24 in several sub-bodies 5 with a substantially circular sector-shaped cross-section around a central rod 6 with a central discharge charge arranged for each sub-body 5 layer. The sector-shaped cross-section of the sub-bodies 5 has an opening angle 8 of in each case approximately 600 to 1200, preferably 900, see above that around the central rod 6 in each case six to three, preferably four sub-bodies 5 are arranged.

As can also be seen in FIGS. 3 to 5, the sub-bodies are 5 held together by a clamping band 9 made of spring steel sheet surrounding them, which according to Breaking a predetermined breaking point releases all four sub-bodies 5 at the same time and with two end-side bores exactly spaced from the sub-body circumference through one Notched or shear rivet 10 is attached to one of the sub-bodies 5. The tension band 9 is sunk in a central circumferential groove 11 on the enclosed sub-bodies 5 arranged so that the straps neither when assembling the rocket 1 nor when Removing the hollow cylindrical rocket head casing 3 from the sub-body carrier 4 is a hindrance could be.

As can be seen in particular in FIGS. 4 and 5, discharge bores open 12 of central ejection charges 13 on the central tube 6 in radial or radial form from the central tube 6 outwardly directed bores 14 for central ejection charges 15th in the sub-bodies 5, and each sub-body 5 has one in relation to each other to the thin cylindrical outer walls 16 strong central partition 17 two Payload spaces 18, which are opposite one another and are open at the ends, for a recording of payload carriers 19 with dipole packages arranged in a disk shape 20 on.

Those directed radially or radially outward from the central tube 6 Bores 14 for the central ejection charges 15 on the sub-bodies 5 are shown in FIG central partition wall 17 of each sub-body 5 arranged so that of each bore 14 two diametrically opposite cross connection bores 21 in the the two payload spaces 18 for the payload carriers 19 with the dipole packets 20 open.

The ejection charges 15 consisting of propellant charge powder are shown in FIG the bores 14 on the sub-bodies 5 in a light metal sleeve 22 (Figs. 6 and 7) arranged and equipped with detonators 23 of different ignition timing in such a way that they differ after the lateral push of the sub-body 5 from the sub-body support 4 delayed ignition. In the process, the light metal sleeve 22 breaks at the cross-connecting bores 21 to the payload compartments 18 and the gas pressure pushes the two payload carriers 19 with the dipole packets 20 (Fig. 7 and 8) in opposite directions from the Subbody 5 outwards.

The dipoles 24 are also in the two payload spaces 18 on both sides the middle partition 17 between separating disks 25 in the form of a sector of a circle around a spacer tube arranged centrally in the axial direction of the payload spaces 18 26 or the like arranged upright, the Spacer tubes 26 of several dipole disks arranged coaxially one behind the other from one above the dipole packs 20 through hollow rivet 27, from a screw or the like are interspersed.

To prevent the payload package from sliding out of the side between the To prevent cutting disks 25 and to ensure that only those on the outer surface of the dipole packets 20 lying dipoles 24 gradually into the surrounding air flow 28 (FIG. 8), the separating disks 25 are towards the dipole packs 20 each over the whole area or part of the area, e.g. point or grid shape, with short, Fluff-like or flake-like plastic threads for holding the ends in between vertically arranged dipoles 24 flocked.

The device for scattering electromagnetic decoy material works so that after ignition of the central ejection charge 13 in the central rod 6 a pressure builds up between the central rod 6 and the surrounding sub-bodies 5, which on the one hand sets the ignition chain of the sub-body ejection charge 15 in motion and on the other hand brings the sub-body 5 under radial pressure, through which the sub-body 5 on the sub-body support 4 initially cohesive tensioning band 9 is stretched so tight that the head of the Notched or sheared rivet 10 is sheared off. When this is done, all will four sub-bodies 5 held together are completely released from each sub-body layer and leave the sub-body carrier 4 and thus the trajectory of the missile 1 by one Angle of 900 each offset to the side or at a different angle accordingly the number of sub-bodies in a drawer.

After the expiry of the sub-body in the central ejection charges 15 5 built-in delay, the ejection charge becomes 15 in the respective Sub-body 5 ignited, the resulting gas pressure breaks the surrounding light metal sleeve 22 at the cross-connecting bores 21 to the two arranged laterally thereof Payload spaces 18 and pushes the two payload carriers 19 with the dipole packages 20 with mutual support in opposite directions.

After leaving the payload compartments 18, one falls during the installation of the dipole packages 20 cut-open, in the drawing, not shown wrapping film from the dipole packets 20 from, so that the surrounding air flow or wind 28 (Fig. 8) now the respective lying on the outer surface dipoles 24 can be removed evenly, while the remaining dipole mass due to the point or flat flocking on the cutting discs 25 is initially still held and only gradually released evenly. The dipoles 24 are so finely and widely distributed in the surrounding air space.

In a modified embodiment, the dipoles 24 can only be used Part in the sub-bodies 5 and the other part in the lower part of the sub-body support 4 can be accommodated without a special ejector, so that this part of the dipole material is only carried away by the airstream.

Claims (12)

Claims FX ½ device for spreading electromagnetic Decoy material in the form of dipoles made of tinfoil strips or the like, in particular from a rocket, which shows that the dipoles (24) in sub-bodies (5) around a central rod (6) with a central ejection charge (13) for each layer of sub-bodies (5) are arranged. 2. Apparatus according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the sub-bodies (5) have a substantially circular sector-shaped cross section with an opening angle (8) of in each case approximately 600 to 1200, preferably 900, of this type have that around the central rod (6) each about six to three, preferably four sub-bodies (5) are arranged. 3. Apparatus according to claim 1 or 2, d a d u r c h g e -k e n n z e i c h ne t that the sub-body (5) by a ring-shaped surrounding tension band (9) are held together from spring steel sheet, preferably at two end holes at a precise distance from the circumference of the sub-body (5) by means of a notched or sheared rivet (10) is attached to one of the enclosed sub-bodies (5). 4. Apparatus according to claim 1 to 3, d a d u r c h g e -k e n n z e i c h n e t that the tension band (9) in a central circumferential groove (11) on the enclosed Sub-bodies (5) is arranged sunk. 5. Device according to one of claims 1 to 4, d a d u r c h g e it is not indicated that the ejection bores (12) of the ejection charges (13) the central tube (6) in radial form or radially from the central tube (6) to the outside aerated bores (14) for central ejection charges (15) in the sub-bodies (5) flow out. 6. Device according to one of claims 1 to 5, d a d u r c h g e it is not noted that each sub-body (5) is on both sides of a central partition (17) two payload compartments (18) open at the ends for receiving payload carriers (19) with dipole packs (20) arranged in slices. 7. Device according to one of claims 1 to 6, d a d u r c h g e it is not noted that the bores (14) for the central discharge charges (15) on the sub-bodies (5) in the central partition wall (17) of each sub-body (5) in this way are arranged that of each bore (14) two diametrically opposite one another Cross connection bores (21) in the two payload compartments (18) for the payload carrier (19) open with the dipole packets (20). 8. Device according to one of claims 1 to 7, d a d u r c h g It is not shown that the ejection charges (15) on the sub-bodies (5) in a light metal sleeve (22) and with igniters (23) of different ignition time sequences are equipped in such a way that after the sub-body (5) has been pushed off from the sub-body support (4) can be ignited with different delays. 9. Device according to one of claims 1 to 8, d a d u r c h g it is not shown that the dipoles (24) in the two payload spaces (18) between cutting disks (25) in the form of a circular sector around one in the axial direction of the Payload spaces (18) centrally arranged spacer tube <26) or the like are arranged standing. 10. The device according to claim 9, d a d u r c h g e k e n n -z e i c h n e t that the spacer tubes (26) of several coaxially arranged disc-shaped Dipole packets (20) from a hollow rivet (27) extending over the dipole packets (20), are penetrated by a screw or the like. 11. The apparatus of claim 9 or 10, d a d u r c h g e -k e n n z e i h n e t that the cutting disks (25) over the whole area or part of the area, such as e.g. punctiform or grid-shaped, with short, flake-like plastic threads for a end-side holder of the dipoles (24) arranged between them are flocked. 12. The device according to claim 1, d a d u r c h g e k e n n -z e i c h ne t that the dipoles (24) are only partly in the sub-bodies (5) and partly in the other Part in the lower part of the sub-body support (4) without a special ejector device are housed.