CH685069A5 - Sub-calibre, fin-stabilised projectile which is fired with spin - Google Patents

Abstract

The stability of the flight attitude of sub-calibre fin-stabilised projectiles leaves a lot to be desired. The arrangement shown here brings the incidence angle ( delta ) between the projectile longitudinal axis (8) and the direction of flight (9) back to zero in flight. The sub-calibre projectile (1), which is suitable for firing from rifled barrels, has stabilisation fins (5) which are mounted in a fixed position on the projectile body (3). The fins (5) enclose an angle (which is counted in the positive direction counter to the direction of spin rotation) of more than 90 DEG , preferably 180 DEG with the tangent to the surface of the projectile body (3). <IMAGE>

Description

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The invention relates to a sub-caliber, wing-stabilized projectile which is fired with swirl.

Bullets of this type, for example balancing bullets or arrow bullets, have a large ratio of length to diameter and are fired from large-bore barrel weapons by means of sabots. You get high speed and are able to penetrate relatively thick armor. The prerequisite for this, however, is that the projectile hits with the tip first and with a practically disappearing angle of attack of the projectile in relation to the flight direction. Stabilizing the flight situation is therefore of central importance. Arrow bullets fired at full swirl with conventional tail units start to oscillate, which last until the speed of the bullet has largely subsided. This leads to undesired loss of speed and to irregular, ballistic scattering and to unfavorable angles of attack when hitting the target.

Wing-stabilized balancing projectiles are known, for example, from EP-B 0 295 362. This shows a bullet with a high length / diameter ratio. At the rear of the projectile body, several flat wings are soldered at right angles to it. However, the projectile is not suitable for being fired from a drawn tube. When this projectile is fired from smooth-tube cannons, the problem of pendulum vibrations does not arise. Only smooth-stabilized projectiles can be fired from smooth-tube cannons and no others. In the case of sub-caliber ammunition, the sometimes problematic aerodynamic separation of the sabot must be taken into account.

A known measure for stabilizing arrow projectiles fired from drawn tubes consists in the use of a slipping guide band on the sabot. Furthermore, DE-A 2 924 217 describes a sub-caliber, wing-stabilized balancing projectile and mentions the harmful effect of the swirl on the stabilization of the projectile. As a special measure to reduce this effect, the slipping guide band is provided on the one hand, which reduces the twist transmission by the trains, and on the other hand a stabilizing stabilizer which is rotatable around the longitudinal axis of the projectile and which rotates less quickly in flight than the projectile body. The special constructive measures are aimed at reducing the swirl. However, they are unsatisfactory insofar as they cause large outlet spreads with respect to the speed and speed of the storey due to the frictional forces that depend on the pipe condition and different gas losses.

The task is to significantly improve the flight stability of a sub-calibrated, wing-stabilized projectile that can be fired from drawn tubes.

This object is achieved by the teaching specified in the characterizing part of patent claim 1. Due to the fixed, special arrangement of the stabilizing wings on the projectile body, not only a markedly improved flight stability is achieved, but also a simple wing construction that enables inexpensive manufacture.

The invention is explained in more detail with reference to the figures mentioned below, which show the following:

1 shows an inventive sub-caliber, wing-stabilized projectile in a preferred embodiment, from the side and from behind;

Fig. 2 different wing arrangements viewed from behind with registered reference sizes;

3 to 5 curve of the angle of attack over the distance for three different storeys;

6 shows a concave, unstable wing arrangement in an orthogonal sectional plane to the longitudinal axis of the projectile;

7 to 10 show four different, convex wing arrangements in an orthogonal plane to the longitudinal axis of the projectile.

1 shows, as a projectile 1 according to the invention, an arrow projectile without the sabot, which is essential for the launch. A projectile body 3 has a conical tip 2 and a cylindrical shaft. Stabilizing wings 5 are attached to the rear part 4. The projectile has a right-hand swirl, ie rotates clockwise when viewed from behind, as indicated by a swirl direction arrow 6 in the view from behind. A directional arrow 9 running through the center of gravity 7 of the projectile 1 indicates the current flight direction of the projectile 1. An undesired angle of attack 8 may be present between the longitudinal axis 8 of the projectile and the directional arrow 9 and must be eliminated.

The stabilization is based on the effect of the air flow forces on the stabilizing wing 5 together with the swirl. 2 shows a schematic cross-sectional view from the rear in five sectors a to e of five different arrangements of stabilizing wings, the surfaces of which run parallel to the longitudinal axis 8 of the projectile. A cylindrical projectile body surface 10 appears as a circle, which is divided into five sections. The projectile body 3 rotates in the direction of the swirl direction arrow 6 in a clockwise direction about the longitudinal axis 8 of the projectile. In this view, the air flow relative to the projectile runs in concentric circles around the longitudinal axis 8 of the projectile, opposite to the swirl direction; it is indicated by flow arrows 11.

Sector a shows the situation with known projectiles, as mentioned in the introduction. A stabilizing wing 5a with lateral boundary surfaces 51a and 52a and a virtual central surface 53a is arranged at a connection point 12a orthogonal to the cylindrical projectile body surface 10. The virtual middle surface 53a and a virtual connecting line 15a from the tip of the stabilizing wing 5a to the connecting point 12a fall in this example.

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together. They enclose the angle a of + 90 ° with the projectile body surface 10, represented by its tangent 13 in the swirl direction at the connection point 12a, that is, the angle a is counted positively from the projectile body surface 10 to the virtual connection line 15a against the direction of rotation of the swirl. The angle of incidence β of the relative air flow, represented as the angle between a tangent 14 to the flow arrow 11 and the line of the virtual central surface 53a, is accordingly a right angle.

If a projectile with a wing arrangement according to FIG. 2, sector a is fired with swirl, the intended stabilization only occurs after the projectile speed has declined to a considerable extent. After the shot, the arrow projectile flies with a fluctuating angle of attack 8. The fluctuations subside, but the mean angle of attack remains. The values depend on the outage disorders. 3 shows a profile 21 of the angle of attack amount | 8 | plotted over a flight distance x. The angle is still zero when exiting the tube, i.e. at the distance x = 0. Immediately afterwards, the projectile begins to oscillate and the angle of attack 8 fluctuates. The amplitude of the fluctuations depends on the termination disturbances, e.g. the sabot dropping. It is delimited by an upper envelope 22 and a lower envelope 23. The two envelopes both approach a horizontal straight line 24 asymptotically. The projectile therefore flies in a metastable state, the mean angle of attack | 8m | is.

In sector b of FIG. 2, a stabilizing wing 5b is shown, which is arranged convexly relative to the projectile body surface 10, that is, in which the inflow 11 takes place at an angle β 90 °. It is a flat wing that is fixed to the projectile body 3 in a stationary or rigid manner such that its virtual connecting line 15b with the tangent 13 to the projectile body surface 10 encloses an angle a> 90 °.

Such a wing arrangement has a stabilizing effect. If the projectile 1 flies with a certain angle of attack 8 to the flight direction, a part of the at least three wings is in a shadow zone of the air flow. The air forces on the wings are different. The resulting force depends on the angle of attack ß, i.e. on the wing position. This force, together with the swirl of the projectile, causes it to precede. With the right direction of the resulting force, the movement is dampened. In the case of convex wing arrangements, the projectile precesses with decreasing amplitude in the direction of swirl.

FIG. 4 shows, analogously to FIG. 3, a profile 21 'of the angle of attack | 8 | about the flight distance x. An upper envelope 22 'falls asymptotically against the x-axis, and a lower envelope 23' also after an initial slight increase. The angle of attack | S | decays towards 0. The projectile flies stable.

The sector c of Fig. 2 shows the reverse situation. A flat stabilizing wing 5c is arranged on the projectile body 3 such that it forms an angle a <90 ° with the projectile body surface 10. The air flow 11 takes place at an angle β <90 °. This concave wing arrangement leads to unstable flight behavior. The bullet precesses against the twist direction. Here, too, the fluctuations in the angle of attack 8 decrease, but the mean angle of attack itself grows steadily.

5 shows, analogously to FIG. 4, a profile 21 "of the angle of incidence | 5 | over the flight distance x. An upper envelope 22" and a lower envelope 23 "approach each other, but both rise asymptotically. The average angle of incidence constantly increases The projectile flies unstably.

Sector d of FIG. 2 shows a further, convex wing arrangement, this time with a wing 5d with curved outer surfaces, a main inflow surface 51d and an opposite side 52d facing away from the flow. A virtual middle surface 53d of the wing 5d meets the projectile body 3 at the connection point 12d. A virtual connection line 15d is entered from the connection point 12d to the wing tip. The angle a between the tangent 13 to the projectile body surface 10 and this connecting line 15d is more than 90 °.

A wing 5e, as shown by sector e of Fig. 2, has an angled profile. In addition, the rear part of the projectile body is frustoconical. A part of the projectile body surface 10 "is therefore visible in the view. A connecting line 15e from the connection point 12e of the wing center surface 53e with the projectile body surface 10 'to the wing tip forms an angle a <90 ° with the tangent 13' to the projectile body surface 10 ' concave wing arrangement leads to unstable flight of the projectile.

Fig. 6 shows from behind a projectile 16 with a concave arrangement of the stabilizing wing 5, which flies unstably. An auxiliary circle 31 marks the maximum radial extent which fixed, for example four wings 5 have; in extreme cases, this is the tube caliber. The swirl direction arrow 6 marks the clockwise rotation. The wings 5 are obviously arranged at an angle a of 0 ° (not shown) to the projectile body surface 10.

Contrary to the projectile 16 according to FIG. 6, a projectile 1 according to the invention according to FIG. 7 has, for example, four wings 5 which are attached to the projectile body 3 at an angle a (not shown) of 180 ° to the projectile body surface 10. This projectile 1 flies stable.

8 to 10 show further variants of convex wing arrangements on a projectile 1 viewed from behind with a right-hand twist. The projectile of FIG. 8 has three flat wings 5. The direction of the projectile body surface 10 at the point of penetration is indicated by the tangent 13. The angle from this to the wing surface is more than 120 °.

The four wings 5 of the projectile shown in FIG. 9 have curved surfaces. she

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are attached to the projectile body 3 essentially at right angles to the projectile body surface 10 and then curve with a constant direction of curvature against the direction of rotation of the swirl. The connecting line 15 between the wing tip and wing root forms an angle a of over 120 ° with the projectile body surface 10 at this point - the direction is shown by the tangent 13 in the figure.

10 are fixed tangentially to the projectile body surface 10 and are also provided with a constant curvature, here the direction of curvature and radius of curvature, counter to the direction of rotation of the twist. The angle a between the connecting straight line from the wing tip to the root and the projectile body surface 10 is greater than 180 ° here.

The invention is of course not limited to the examples given here. Arrangements for left-hand twist instead of right-hand twist, with more than four wings, other wing profiles and similar variations can be readily specified in the knowledge of the invention. The invention is also not limited to stabilizing wings, the side surfaces of which run parallel to the longitudinal axis of the projectile. However, the embodiment with cylindrical wings has advantages in terms of manufacturing technology, since it can be manufactured in the simplest way from extruded profiles.

Claims (6)

Claims 1. Sub-caliber, wing-stabilized projectile (1), which is fired with swirl, characterized by a fixed arrangement of the stabilizing wings (5) on the projectile body (3) such that a virtual connecting line (15) lies in a sectional plane orthogonal to the longitudinal axis of the projectile (8). which extends from the tip of the stabilizing wing (5) to the connection point (12) of the same with the projectile body surface (10), with an tangent (13) at the connection point (12) in the twist direction to the projectile body surface (10). of more than 90 °. 2. Projectile according to claim 1, characterized in that side surfaces (51, 52) of the stabilizing wing (5) run parallel to the longitudinal axis of the projectile (8). 3. Projectile according to claim 1 or 2, characterized in that side surfaces (51, 52) of the stabilizing wing (5) have a constant direction of curvature. 4. Projectile according to claim 1 or 2, characterized by a flat side surface (51) of the stabilizing wing (5). 5. Projectile according to one of claims 1 to 4, characterized in that the angle (a) is at least 120 ° 6. Projectile according to claim 5, characterized in that the angle (a) is 180 °. 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 4th