DE3122356A1 - Empennage for a KE practice round - Google Patents

Abstract

In order drastically to shorten the range of rounds during practice firing on a predetermined flight path (trajectory) while maintaining the ballistic properties, a rod (bar) round (projectile) is provided with an empennage which consists of tubes (2) which are distributed uniformly on the circumference of the round body (1). The internal diameter of the tubes (2) is tapered symmetrically and conically from the air inlet opening as far as a narrowest cross-section which is located a short distance behind the air inlet opening. Behind that point, the cross-section remains constant. This design measure represents a Laval nozzle with a reverse flow which causes aerodynamic blocking above a specific Mach number during flight of the round, which blocking greatly increases the drag (air resistance) and thus rapidly reduces the speed of the round. <IMAGE>

Description

description

Tail unit for a KE training storey A1 KE storeys are arrow or Rod projectiles made of steel, but preferably made of heavy metal. you will be fired at high speed and have due to their relatively large length of usually more than 10 diameters (calibers) a large wet per cross-section. If you hit a hard target with your face, e.g. B. on a When hitting armor, therefore, extremely large kinetic energies per rod cross-section delivered to the meeting point. Due to a special mechanism such Rod projectiles have an outstanding penetration performance.

Stick projectiles with lengths over 6 calibers are for technical reasons no longer stabilizable by twist, they are rather stabilized as arrows with Wings (tail unit) fired.

The high mass necessary for the required penetration capacity at the same time ensures a low loss of speed per cross-section per flight route, so that one is only slightly reduced by the air resistance Impact speed at a target a few kilometers away for the breakthrough, z. B.

the armor is available.

This is desirable for combat projectiles. If the projectile - as with the Practice shooting - but shot so free-flying that it was not stopped by any target in extreme cases, ranges of approximately 100 km can result. Since this creates dangers for a correspondingly extensive area around exercise areas would be seen or because there are no exercise areas of sufficient size in of the Federal Republic of Germany, and no optimally safe bullet catching devices behind the target are available, KE training floors with reduced Range can be used. For wing storeys, however, this requirement is unreachable represent.

KE training bullets, especially for tank guns, must be used Unavoidable technical demands are made: 1. They must be up to the combat range have the impact performance of the combat projectiles with a trajectory that is as aligned as possible.

2. Over longer distances, the range must be drastic be shortened.

3. The shortening of the range must be practically completely reliable function.

If the hit performance is considered according to point 1, the exit ballistic Projectile properties of crucial importance.

All of the characteristic data of the training bullet must be match those of the combat projectile. The same applies to the ballistic Alignment of the trajectories.

The requirement 2. for a shortening of the range when one is exceeded given shooting distance, however, means a drastic change in the ballistic Adjustment to the flight path of the combat projectile after a certain flight path of the practice floor. For this purpose, a control of the air resistance must in principle of the floor with the flight path. Precisely this control mechanism must work extremely reliably.

A KE training floor that meets all three requirements is up to not known at the present time.

At exercise projectiles for the KE-type is both in the Federal Republic Germany as well as in the USA. The deliberations in the Federal Republic are based on a built-in increase in air resistance by means of a conical Tail unit, which is provided with holes almost parallel to the axis (Loclikegel tail unit according to "Soldat und Technik", Ed. 10, 1980, p. 552, Fig. 8). About these holes pressure equalization between the floor and the the flow facing side of the cone take place, the two, flight in uberchallbereich behind a Shock wave lies. The analysis of. Measurement results show that in the supersonic range down to almost twice the speed of sound (Mach 2) a flow to the Floor through the holes in the tail unit takes place, which increases the pressure on the ground and thereby reduces air resistance. If there is supersonic noise, it turns below Mach 2 this direction of flow changes.

So compared to a full cone tail unit is the air resistance of the perforated cone tail unit slightly lower in the high supersonic and in the low Uberschall a little higher. The behavior in the subsonic is still largely unknown.

The main disadvantage of this perforated cone tail unit is its high drag coefficient, which is always above 1, during that of the combat projectile moves 0.3 when fired from the weapon. Furthermore, the exit and the external ballistic properties decisive for the impact performance of those of the Combat projectile so different that it makes point 1. the inevitable technical The overall requirement is not even remotely fulfilled. On the other hand, the demands 2nd and 3rd provided.

In the case of the KE training bullets developed in the USA, the principle the traditional and ballistically proven shape of the (wing stabilized) arrow projectile expanded. In order to reduce the flight distance, the Projectile applied by a built-in mechanism depending on the flight time. The dismantling is triggered by the melting of the bullet tip in succession their aerodynamic heating during flight.

Through this floor: rp is the first of the two inevitable Requirements met by itself, but due to the complicated structure of the cutting mechanism Point 3 must be deemed not to have been achieved by European standards. This will also point 2 affected. Moreover, it must be assumed that height.

Manufacturing costs for the bullet itself significantly increase the frequency of use be limited, especially under today's aspects of: 'increased economic efficiency Priority must be given.

The invention is based on the task of a tail unit for a rw training projectile by means of a constructive measure in such a way that without ballistic losses the range of the projectile is reliably reduced, d. H. that all three at the beginning mentioned requirements are met.

The task is based on a tail unit for a KE training floor with longitudinal values evenly distributed on the circumference of the tail unit according to the invention solved that the inner diameter of the longitudinal tubes each from the air inlet opening in the direction of the projectile stern, but at least over part of the route, symmetrically rejuvenates. The tubes formed in this way represent a Laval nozzle, but which flows in the opposite direction. The invention is based on the physical Principle of aerodynamic blocking applied to arrow projectiles, which both can be fired from rifled gun barrels as well as smooth-barreled cannons.

This type of shaping of the tubes achieves that, depending the ratio: narrowest cross-section (F +) to inlet cross-section (F) equals F + / F and the Mach number of the incoming air, an aerodynamic blockage in the Tube enters and the incoming air does not flow through it and thus the floor suction can no longer compensate.

The outer diameter of each nozzle depends on the geometry of the bullet. The angle of the front nozzle wall should not exceed 100.

This and the F + / F ratio is the minimum length of the nozzle given. With a further extension with a cylindrical extension, the exit and external ballistic projectile properties of the Ü version to the of the combat projectile to be simulated. It can be through a Approximate calculation that the aerodynamic drag coefficient of the tubular tail unit is not appreciably larger than cler when the flow through the nozzles is unimpeded the corresponding wing version. For the conceptualized in Figure 1 The tail unit is an exercise range that is adapted to the KE combat projectile from a 120 mm cannon of about 3 km and a maximum flight distance of less than 10 km can be expected.

To the compensation twist required for such an arrow projectile of at least 100 revolutions per second should be used, for example bevels attached to the outer surface of the tail units in the spaces between the tubes will. Such additives are conventional and are therefore not listed separately. If other possibilities for generating swirl are being considered, it is imperative refrain from tilting the nozzles.

Based on an embodiment shown in the drawing the invention is explained in more detail.

They show: Figure 1: the basic type of tail unit Figure 2: a diagram, the ratio of the narrowest cross-section (F +) to the inlet cross-section (F) the Mach number is plotted.

On the left side of Figure 1 is the front view of the erfindungsgausßen Practice bullet shown. It shows the evenly around the circumference of the projectile body 1 distributed tubes 2 with the inlet cross-section (F) and, the narrowest cross-section (F +). The right part of Figure 1 shows a section of the projectile from which it can be seen that after the narrowest cross-section (F +) the longitudinal bore to the rear of the projectile 3 has a constant diameter. The outside diameter of each nozzle is of the Floor geometry dependent. The angle of the front nozzle wall 2a should not be 10 ° exceed. Through and through the F + / F ratio is the minimum length of the Nozzle specified. With a further extension with a cylindrical extension you can the exit and external ballistic projectile properties of the KE exercise projectile matched to that of the combat projectile to be simulated.

Figure 2 shows to explain the modes of operation of the tail unit Figure 1 is a diagram in which the cross-section ratio of the narrowest cross-section (F +) for the inlet cross-section (F) F jF plotted against the number @ of the incoming air is. The upper hatched flee indicates the area of a slipping shock wave again, the lower the area in which there is an aerodynamic "clogging", d. H. Advertisement is coming.

These do not have cross-sections that narrow in the inflow direction due to the use of the properties of jet flows in the supersonic range very different air resistances on both the ratio of the. closest Cross-section (F +) to the inlet cross-section (F) as well as the Mach number of the incoming flow Depend on air. This is due to the fact that by the narrowing of the cross-section two qualitatively different flow forms in the nozzle depending on the Mach number be forced. So it is possible that a sudden increase in pressure (shock) in the convergent nozzle part arises, the one with the withdrawing Mach number in the countercurrent direction moves and appears in front of the jet. This indicates that the incoming Gas can no longer be discharged from the nozzle.

The nozzle thus appears aerodynamically blocked and therefore shows one Resistance that corresponds more to that of a full cylinder than that of a tube.

This state of aerodynamic blockage occurs when the Aspect ratio F + / F as a function of the Mach number in the range of lower hatched area of Figure 2 falls.

If the impact occurs only behind the narrowest cross-section, it moves it goes with the flow and exits at the end of the nozzle.

The nozzle thus enables the shock wave to slip through and leads consequently the @ instr @ ming air with @ little resistance to the projectile rear, where the Air can flow out and so the ground suction, which in the high supersonic range approx. 40% of the total resistance, compensated.

This case is shown in FIG. 2 in the upper hatched area.

Such a tube moves with an F + / F ratio of, for example 0.7 as a projectile decelerates with decreasing Mach number, it has above Mach 3.2 a low air resistance, which increases steeply at Mach 5.2 and at Mach 1.8 scan maximum value reached (Figure 2).

Such a tubular projectile for practice purposes, made of drawn gun barrels shot with twist, is already patented under the abbreviation STUP (Spinning Tubular Projectile) known.

The advantages achieved with the invention are in particular: that a) the range of the training bullet is reliably shortened, b) the range reduction is achieved by constructive means, c) the production of the KE training bullet is simple, d) the safety in the area of target practice areas is increased.

LIST OF REFERENCE NUMERALS 1 projectile body 2 longitudinal tubes 2 a front nozzle wall Bullet tail

Claims (5)

Claims 1. Tail unit for a KE training floor with evenly Longitudinal openings (2) distributed on the circumference of the tail unit, characterized in that the Longitudinal tubes (2) forming longitudinal openings are provided which, on the one hand, are connected to the Projectile body (1) and on the other hand are connected to each other, and the constant Outside diameter in each case from the air inlet opening in the direction of the rear of the projectile a continuous reduction of the inner diameter but at least a part experience the route and the air inlet opening is funnel-shaped. 2. tail unit according to claim 1, characterized in that the symmetrical There is tapering only in the area of the air inlet opening. 3. tail unit according to claim 1 and 2, characterized in that the symmetrical taper is preferably conical. 4. tail unit according to any one of claims 1 to 3, characterized in xe'K that the tube diameter is conical following that which is symmetrical to the tube axis The taper to the rear of the floor remains constant. 5. Tail unit according to one of claims 1 to 4, characterized in that that the longitudinal axes of the tubes are parallel to the longitudinal axis of the bullet.