DE3822998C1 - Submunition system with coupling cable - incorporates cable motion damping system with piston and high viscosity hydraulic oil - Google Patents

Abstract

The submunition system is fired from the barrel with a segmented cage and coupled during trajectory at preset spacing by a cable etc. When the shell is fired a cable (3) stored in magazine (10) in the hindmost shell should be so arranged or designed that directly the two shells (1,2) when fired reach their given spacing (E1) i.e. when the pull impact acts on the shells, energy is used up so as to soften the impact. Pref. the rear end of the cable is fixed to a piston (12) moving in the magazine cylinder (10). The cable is led through a nozzle aperture (11) in the magazine, and at the moment of impact an hydrodynamic medium (29) in the magazine drives out thorugh the nozzle (11) gap (14) and nozzle openings (13) in the piston (12). USE/ADVANTAGE - Weaponary, piercing shells,. Energy consumed at point of impact to keep shell spacing and line of flight for progressive armour penetration.

Description

The invention relates to a floor arrangement with the Merk paint the preamble of claim 1.

Such a Ge lap is known for example from DE-A 31 27 002. Due to the rope connection between the floors can be achieved that both floors on the same Fly trajectory and thus to the same place on one armored target. It should go through the first Bullet an active armor can be deactivated so that the second storey unhindered the further armor can penetrate.

In the known arrangement there is the rope and an unwinding mechanism in the front floor. Thereby be stands for the high-performance balancing in question here shot at high speed, e.g. B. Mach 5, fly, the danger of the rope due to air forces is pulled out too quickly, either in the magazine the wire is already tangled and with it the specified target distance between the two floors is not available. On the other hand, for those in here Question coming KE bullets he large wire diameter required, since there are considerable strong impact shocks that can tear the rope. With the well-known An trim is the rear end of the wire on an elastic resilient suspension attached. Through this elastic fastening can cause vibrations in the rope and occur as a result of longitudinal waves restoring forces that at Flight can affect the stretch of the rope and thus the predetermined distance of the  do not guarantee two storeys from each other.

The object of the invention is therefore to address the disadvantages of be known arrangement to avoid and that the two floors connecting rope to dimension smaller so that the An order for sub-caliber balancing bullets can be used.

The essential to solve the task union features of the invention are in claim 1 ge called. The subclaims indicate types of execution of the Er finding.

The drawing shows embodiments of the new Geschoßan arrangement, namely in Fig. 1 and 2 two on a common trajectory with an axial distance Flugge located, which are connected with a rope, in Fig. 1 before hitting the target and in Fig . 2 after the effective date of the first flight projectile in terms of deactivation of a target area in a tank.

In Fig. 3 to 10 schematiscn rope arrangements and rope attachments between the two floors are Darge provides.

According to FIG. 1, two floors 1, 2 are hinte purely other on one illustrated here as a straight-Community trajectory T, the end point 9 on a medium armor plate 6 between two armor plates 5 and 7 of a schematically illustrated actively armored target. 4 The first floor 1 flying in the S direction is connected by means of a rope 3 , e.g. B. made of nylon or steel, possibly with several braided fibers, connected to the flight floor 2 following in the abbreviated distance E 1. As soon as the projectile 1 hits the armor plate 6 , it triggers a target charge. As a result, the armor plate 6 is accelerated relative to the adjacent armor plates 5 and 7 and thereby interferes with the projectile 1 and impairs its effect.

In Fig. 2 with 8, the 6 designated in Fig. 1 Pan zerplatte is shown during acceleration. The assigned to the armor plate 6 ( 8 ) charge is deactivated by Ge Ge 1 . The following in the distance E 1 and just if directed to the area of the armor plate 6 ( 8 ) projectile 2 can now take effect undisturbed.

The desired distance between the floors is thereby achieved that these different flight resistances ha ben. The length of the rope between the floors is down depending on the target type. It can range from 1 to 10 Meters.

In FIGS. 3 to 10, the front floor 1 is in each case only indicated by an arrowhead on the rope and the rear floor, only the cable tray 10 is shown substantially. In Fig. 3, the rear end of the rope is attached to a piston 12 which is slidably guided in the cylindrical magazine. The magazine has a nozzle-like constriction 11 at the front, which leaves a gap 14 between the rope. Nozzle-like passages 13 are also present in the piston 12 . A hydrodynamic medium 29 is located in the space between the piston 12 and the nozzle-like constriction 11 . That can e.g. B. be highly viscous hydraulic oil or grease. If necessary, air is also possible. Then the passages 13 and the gap 14 must be particularly narrow. In front of the gap 14 there can be a ballistic hood 30 , in the interior of which a portion of the rope can be accommodated before the launch. The interior with a narrow front opening also prevents the medium 29 from escaping directly into the open. This favors the braking effect. This arrangement acts as a shock absorber that converts the impact energy. Fig. 4 shows on the front floor 1 a brake screen 15 which delays the first floor. After sufficient braking, it is capped at the separation point 16 by the impact that occurs when it is fully deployed, that is, by overloading. The capping can be caused by material weaknesses, e.g. B. notching or severing a phase of the brake screen ropes may be favored.

Fig. 5 shows at the front of the rear floor 2 a sensor 17 which triggers a pulse engine 18 after a defined time, due to a defined rope length, which accelerates the rear floor 2 to the speed level of the first floor 1 . Fig. 6 shows in the upper position Dar 6 a the rope 3 in loops in a plastic body 19 and in the lower representation the rope and the plastic body tightened by the stretching impact. The plastic body can be arranged at different points on the rope. It can be very small in diameter and can be thrown off after stretching.

Fig. 7 shows an arrangement with a conically widening rope 20 , z. B. of fiber material, with a rear end plate 21 as a final reinforcement. The nozzle-like constriction 11 has a constant cross section and causes the rope to constrict. Here the impact energy is reduced by increased friction. As a final reinforcement you can use a pin or a knot at the rear end of the rope.

Fig. 8 shows a forwardly conically tapered magazine 22. The end of the cable 3 is arranged on a piston-like component 23 which can be deformed in the magazine. The plastic deformation when pulling out the rope mitigates the stretch impact.

According to FIG. 9, the end of the cable to a conical Trom is mel 24 wound. The drum 24 is connected to a friction brake or spring brake 28 . The cone shape of the drum changes the moment that the rope acts on the brake when it is pulled out. The drum can also be cylindrical.

Fig. 10 shows a rope 25 with very great elongation, through which a significant proportion of the impact energy is absorbed. The other longer ropes 26 , 27 with higher strength take up the remaining impact energy due to their lower elongation.

The advantage of all embodiments is that the occurring stretch impact by the systems shown ge is mitigated, making the rope smaller can and so the arrangement for sub-caliber KE projectiles is applicable.

Claims (11)

1. Storey arrangement for with a segmentable propellant cage jointly to be fired from a tube sub-caliber projectiles which are connected to one another by a rope or the like at a predeterminable distance on a trajectory, characterized in that the shot in the rear floor ( 2 ) , e.g. B. in a rope magazine ( 10 ), located rope ( 3 , 20 , 25 ) is arranged or designed so that as soon as the two floors ( 1 , 2 ) after the shot was from the predetermined (E 1 ) reach each other, that is at the time of a stretch impact on the two storeys, an energy-reducing effect of the stretch impact occurs. 2. Projectile according to claim 1, characterized in that when pulling out the rope ( 3 , 20 , 25 ) from the rear floor ( 2 ) acting on the rope, the pulling out braking resistance stood with increasing rope length increases. 3. Arrangement according to claim 1, characterized in that the rear end of the rope ( 3 ) on a piston ( 12 ) in the cylinder formed out magazine ( 10 ) is fixed, and that the Ma magazine ( 10 ) front a nozzle-like constriction ( 11 ) has through which the rope ( 3 ) is carried out, and that there is a hydrodynamic medium ( 29 ) in the space between the piston ( 12 ) and the nozzle-like constriction in the magazine, which occurs when the stretch impact occurs through a gap ( 14 ) between the nozzle-like constriction ( 11 ) and the rope ( 3 ) and / or through one or more nozzle-like passages ( 13 ) in the piston ( 12 ). 4. The arrangement according to claim 1, characterized in that the front projectile (1) an aerodynamic brake z. B. is a screen ( 15 ), which folds before reaching the stretch shock ent and then at separation points ( 16 ), z. B. me can be cut mechanically or pyrotechnically. 5. Arrangement according to claim 1, characterized in that on the rear Ge lap ( 2 ) is a sensor ( 17 ) for determining the length of the rope ( 3 ), a pulse engine ( 18 ) at the rear end of the shortly before the time of the stretch impact triggers rear floor ( 2 ), which accelerates the rear floor ( 2 ) to the speed level of the first floor ( 1 ). 6. Arrangement according to claim 1, characterized in that the ignition of a pulse engine in the ( 18 ) at the rear end of the rear floor ( 2 ) shortly before or at the time of the stretch impact triggered by the rope connecting the two floors ( 3 ) as a rip cord becomes. 7. Arrangement according to claim 1, characterized in that a portion of the rope ( 3 ) is arranged in loops in a plastic body ( 19 ) so that the loops are stretched with the plastic body at the time of the stretch impact. 8. Arrangement according to claim 2, characterized in that the rope ( 20 ) becomes conically stronger towards the rear and a rear end strengthening, z. B. end plate ( 21 ) or a z. B. formed by splicing the rope, and that the nozzle-like constriction ( 11 ) of the magazine ( 10 ) surrounds the rope. 9. Arrangement according to claim 2, characterized in that the magazine ( 22 ) tapers conically towards the front and that the rear end of the rope ( 3 ) on a piston-like, rests on the inner wall of the magazine plastically deformable component ( 23rd ) is attached. 10. The arrangement according to claim 2, characterized in that the rear end of the rope ( 3 ) in the magazine ( 10 ) on a conical or cylindrical drum ( 24 ) of a friction or spring brake ( 28 ) is wound. 11. The arrangement according to claim 2, characterized in that the rope ( 25 ) between the two floors ( 1 , 2 ) has a very large elongation, and that between the two floors further ropes ( 26 , 27 ) of increasing length and greater strength are arranged, which absorb impact energy due to their lower elongation.