EP0080210A2 - Tracer projectile, preferably for machine guns, with range reducing device - Google Patents

Abstract

In ammunition, preferably for machine cannons, including a subcaliber stabilized projectile equipped with a body of tracer material and a stabilizing element, the heat released during combustion of the tracer material is utilized to drastically change the strength of the material of an element used to fasten the stabilizing element to the projectile. By being able to set the time of combustion and of the change in the material, the stabilizing element changes its position with respect to the projectile. The system or ammunition in question becomes unstable and drops to the ground.

Description

The invention relates to ammunition according to the preamble of claim 1.

Ammunition of the type mentioned is common in order to largely avoid unintentional damage caused by a missile that misses a target outside a predetermined range. If it is a flight destination, the projectile could endanger its own ground troops. This applies to both surface-to-air use and air-to-air use.

Spin-stabilized explosive projectiles have an explosive charge and an impact detonator. The impact detonator points. Means that let the igniter take effect when falling below a predetermined swirl. The explosive charge is used to self-destruct the projectile, thereby limiting its lethal range. Such a detonator is known from US Pat. No. 3,882,782. Explosive projectiles are usually full-caliber. That is why they have a large inflow cross-section. They are therefore subject to an annoying drop in speed. Your trajectory is therefore comparatively strongly curved. They are therefore largely unsuitable for fighting fast-flying (low-flying and guided missiles) and extremely maneuverable air targets (combat stroke, screwdriver). Since the targets mentioned increasingly have structured and multi-layered areas, the effectiveness of explosive projectiles is also considerably limited as a result. The types of use

The objectives mentioned require their combat with machine guns, which show the highest direct hit probability with high cadence and quick directionality.

In the area of application in question, the sub-caliber bullet of high density is therefore the means of choice. It has a straight trajectory. The disadvantage here is the need for a self-destruct charge, because the average density of the projectile body is impaired by it and the means for its actuation.

The object of the present invention is to provide ammunition of the type mentioned at the outset, which is simple and reliable and which leads to an elongated trajectory due to the highest possible density of the projectile.

This object is achieved by the invention specified in the characterizing part of patent claim 1. This is explained in more detail below with reference to two preferred exemplary embodiments shown in the drawing for a spin-stabilized and a wing-stabilized projectile. The technical solution principle is discernible without the details that are not essential to the invention.

In connection with wing-stabilized projectiles, reference is made to US Pat. No. 4,195,573. It concerns a sub-caliber arrow projectile with a resistance-stabilizing rear part. The latter is designed as a cone with at least two bores arranged outside the projectile diameter, which in turn can be designed as a supersonic diffuser to limit the range of the projectile in a convergent-divergent manner. In the high Mach number range, the holes are flowed through with low throttling. If the speed falls below a predetermined value, a substantial increase in resistance occurs as a result of the so-called blocking. A rapid onset of the movement of the projectile leads to the limitation of the projectile range, so that it becomes a perforated cone tail speaking arrangement is particularly suitable for practice projectiles for use on shooting ranges of limited extent. However, the perforated cone tail is unsuitable for projectiles of a caliber range for machine guns in question: Because of the size of its bore, the diameter of the cone must be so large that it can only be used with larger-caliber barrel weapons, such as armored cannons.

Compared to the speed-dependent perforated cone tail unit, the limitation of the lethal range is only time-dependent in the case of ammunition according to the invention.

In this case, the time dependency can advantageously be predetermined between wide limits using simple means.

• Fig. 1 ein drallstabilisiertes Unterkalibergeschoß im Aufriß,
• Fig. 1a den Heckteil des Geschosses nach Fig. 1 mit der Erfindung im längsaxialen Schnitt in größerer Darstellung,
• Fig. 2 den Gegenstand im Querschnitt nach der Linie II - II in Fig. la,
• Fig. 3 ein flügelstabilisiertes Unterkalibergeschoß im Aufriß und
• Fig. 3a den Heckteil des Geschosses nach Fig. 3 mit der Erfindung, teilweise längsaxial geschnitten in größerer Darstellung.

Show it:

• 1 is a spin-stabilized sub-caliber floor in elevation,
• 1a shows the rear part of the projectile according to FIG. 1 with the invention in a longitudinal axial section in a larger representation,
• 2 shows the object in cross section along the line II - II in Fig. La,
• Fig. 3 is a wing-stabilized lower-caliber floor in elevation and
• Fig. 3a shows the rear part of the projectile according to Fig. 3 with the invention, partially cut longitudinally in a larger representation.

According to FIGS. 1 a and 2, a rear part 11 of a projectile body 10 of a spin-stabilized projectile according to FIG. 1 with a peripheral surface 12 and a rear surface 14 has a rear bore 16 with a peripheral surface 18 and a front end surface 20. In the latter, a funnel-shaped centering bore 22 is arranged in the projectile body 10 in the region of a central longitudinal axis A. An essentially circular cylindrical stabilizing body 24 has a rear circumferential surface 26 and a concave rear surface 28. A radial step 30 is provided between a front twist 32 and the rear circumferential surface 26. A front end face 34 of the stabilizing body 24 has a centering projection 40 with a central bore 42. The centering projection 40 adapts to the centering bore 22. The stabilizing body 24 has a jacket 36, which extends longitudinally axially between the shoulder 30 and the end face 34, with three centering ribs 38 projecting radially outward against the circumferential surface 18. A respective space between a circumferential surface 39 and the rear circumferential surface 26 of the jacket 38 and the circumferential surface 18 of the bore 16 and the two front end faces 20 and 24 serves as an annular disk 54 and a circular cylindrical hollow body 52 of a tracer set 50. The projection 40 encircles an annular disk 56 of a substance to be discussed, which is in close contact with a cylindrical surface 55 of the annular disk 54. The circular-cylindrical hollow body 52 is interrupted in the area in question by the centering ribs 38. The rear end of the tracer set 50 is formed by a part 51 which fills a space 16 between the rear surface 28 and an edge of the bore 16 located in the rear surface 14. In the central bore 42, a wire 48 is accommodated in an inverted form, which is fastened with a front end at a point 44 on the projectile body 10 and with a rear end at a point 46 on the stabilizing body 24.

According to FIG. 3a, a projectile body 60 of a wing-stabilized sub-caliber projectile according to FIG. 3 has a rear part 62 with a circumferential surface 61 and with a central axial support extension 64 of comparatively small diameter. An unscrewing surface 64 connects the circumferential surface 61 to an external thread 70 of the carrier extension 64 via a relief radius 68. The latter surrounds a double-walled bush 72 of circular-cylindrical cross-section in a form-fitting manner. A front wall 74 connects an inner wall 78 to an outer wall 80, an outer front surface 76 of the front wall 74 of the boring surface 64 nestling. The peripheral surface 80 of the sleeve 72 is connected in a manner not shown with a thin-walled sleeve 86 which forms a stabilizing tail 87 with the stabilizing wings 88 attached to it. A cavity 84 between the mutually facing surface of the inner 78 and the outer wall 80 of the sleeve 72 serves as a receptacle 92, which extends from the front wall 74 to a rear surface 90.

• Beim Abfeuern wird auf nicht näher zu erörternde Weise der Leuchtspursatz 50 im Bereich der Heckfläche 14 gezündet. Mit dem Teil 51 brennt auch der den Stabilisierungskörper 24 umschließende Teil 52 abo. Sobald der.Abbrand des Leuchtspursatzes 50 bis zum Absatz 30 fortgeschritten ist, beginnt die Erwärmung des Mantels 36 mit dessen Zentrierrip-' pen 38. Der Mantel 36 besteht aus einem Werkstoff, dessen Festigkeit sich durch die Einwirkung der beim Abbrand des Leuchtspursatzes 50 freiwerdenden Wärme drastisch verändert. Besteht der Mantel 36 aus einer entsprechenden Magnesiumlegierung, so verliert er seine Festigkeit infolge chemischer Umsetzung, d.h. vorzugsweise durch heftige Oxydation, welche einem Verbrauch durch Abbrand entspricht. Der Stabilisierungskörper 24 - er besteht vorteilhafterweise ebenso wie der Geschoßkörper 10 zum Verbessern der Durchschlagsleistung aus einem Werkstoff hoher Dichte, beispielsweise einer Sinterlegierung mit hohem Anteil an Wolfram oder abgereichertem Uran - . verliert.zunehmend seine Festlegung in der Bohrung. Ein entgegen der Flugrichtung 58 des Geschosses in Richtung des Pfeils 59 vorhandener Sog wirkt auf die konkave Heckfläche 28 des Stabilisierungskörpers 24. Zusätzlich wird beim Reaktions- übergang von dem Teil 54 des Leuchtspursatzes 50 auf die Substanz 56 aus dieser eine größere Gasmenge frei, die größtenteils auf die Stirnfläche 20 des Geschoßkörpers 10 und die Stirnfläche 34 des Stabilisierungskörpers 24 drückt und letzteren dabei in Richtung. des Pfeils 59 axial verschiebt. Vorterseitige Druck- und rückseitige Sogwirkung lassen den Stabilisierungskörper 24 aus der Bohrung 16 heraustreten. Dabei bleibt über den sich abwickelnden Draht 48 die Verbindung zwischen dem Geschoßkörper 10 und dem Stabilisierungskörper 24 bestehen. Das betreffende System wird bei diesem Vorgang ballistisch instabi 1, verläßt seine Flugbahn und fällt nach unten. Auf diese Weise wird die letale Reichweite des betreffenden Fluggeschosses begrenzt. Der Abbrand des Leuchtspursatzes 50 und der Verbrauch des Mantels 36 sind vorteilhagterweise in weiten Grenzen zeitlich vorgebbar, so daß eine kontrollierte Begrenzung der letalen Reichweite auf einfache und zuverlässige Weise gegeben ist. Die zeitliche Einstellbarkeit der Destabilisierung der Flugbahn richtet sich dabei nach der vorgegebenen Kampfentfernung. Innerhalb derselben bleibt das System stabil, so daß beim Auftreffen auf ein Ziel die gesamte Masse aus Geschoß- und Stabilisierungskörper wirksam wird. Erst beim Überschreiten der Kampf entfernung durch Verfehlen des Zieles kommt es zu der beschriebenen Destabilisierung mit der die Reichweite des Geschosses begrenzenden Wirkung.

The mode of operation of the invention is first explained on the spin-stabilized projectile according to FIGS. 1, 1a and 2:

• During firing, the tracer set 50 is ignited in the region of the rear surface 14 in a manner not to be discussed in detail. The part 52 that surrounds the stabilizing body 24 also burns with the part 51. As soon as the erosion of the tracer set 50 has progressed to shoulder 30, the heating of the casing 36 begins with its centering ribs 38. The casing 36 is made of a material whose strength is released by the action of the heat released when the tracer set 50 is consumed changed drastically. If the jacket 36 is made of a corresponding magnesium alloy, it loses its strength as a result of chemical reaction, ie preferably through violent oxidation, which corresponds to consumption by burning. The stabilizing body 24 - it is more advantageous as well as the projectile body 10 to improve the breakdown performance from a material of high density, for example a sintered alloy with a high proportion of tungsten or depleted uranium -. loses increasing its fixation in the hole. A suction present in the direction of arrow 59 against the direction of flight 58 of the projectile acts on the concave rear surface 28 of the stabilizing body 24. In addition, during the reaction transition from part 54 of tracer set 50 to substance 56, a larger amount of gas is released therefrom, most of it presses on the end face 20 of the projectile body 10 and the end face 34 of the stabilizing body 24 and the latter in the direction. of arrow 59 moves axially. Pressure on the front and suction on the back allow the stabilizing body 24 to emerge from the bore 16. The connection between the projectile body 10 and the stabilizing body 24 remains in place over the unwinding wire 48. During this process, the system in question becomes ballistic instabi 1, leaves its trajectory and falls down. This limits the lethal range of the missile in question. The erosion of the tracer set 50 and the consumption of the jacket 36 can advantageously be predetermined within wide limits, so that there is a controlled limitation of the lethal range in a simple and reliable manner. The temporal adjustability of the destabilization of the flight path depends on the specified combat distance. The system remains stable within it, so that the entire mass of the projectile and stabilizing body becomes effective when it strikes a target. Only when the combat distance is exceeded by missing the target does the described destabilization occur, with the effect of limiting the range of the projectile.

• Das Anzünden des Leuchtspursatzes 92 erfolgt abfeuerungsweise im Bereich der Heckfläche 90. Die beim Abbrand bei hoher Temperatur freiwerdende große Wärmemenge geht sowohl auf die Innen- 78 wie auch Außenwand 80 der Büchse 72 über. Während über die Außenwand 80, die Hülse 86 und die Stabilisierungsflügel 88 eine weitgehende Abführung der Wärme an die Umgebung möglich ist, entsteht im Bereich der Innenwand 78 ein starker Wärmestau. Hierdurch kommt es zur Erweichung des Werkstoffs der Innenwand 78. Sobald der Abbrand des Leuchtspursatzes 92 weit genug fortgeschritten ist, geht folglich der Formschluß zwischen der Büchse 72 und dem Trägerfortsatz 64 verloren. Das Stabilisierungsleitwerk-87 trennt sich in Richtung eines Pfeils 96 entgegen der Flugrichtung 94 vom Geschoßkörper 60 und führt dessen unmittelbarem Instabilwerden, so daß er seine ursprüngliche Flugbahn verläßt und nach unten fällt. Über die zeitliche Einstellbarkeit der Destabilisierung gilt analog die im Zusammenhang mit dem Geschoß nach den Figuren la und 2 gegebene Beschreibung.

The mode of operation of the invention on a wing-stabilized projectile according to FIGS. 3 and 3a is described below:

• The tracer 92 is ignited in the region of the rear surface 90 in a firing manner. The large amount of heat released during the burning at high temperature is transferred to both the inner 78 and outer wall 80 of the sleeve 72. While extensive dissipation of the heat to the surroundings is possible via the outer wall 80, the sleeve 86 and the stabilizing wings 88, a strong heat accumulation occurs in the area of the inner wall 78. As a result, the material of the inner wall 78 is softened. As soon as the burn-up of the tracer 92 has progressed far enough, the form fit between the sleeve 72 and the carrier extension 64 is lost. The stabilizing tail unit 87 separates from the projectile body 60 in the direction of an arrow 96 in the direction opposite to the direction of flight 94 and leads to its immediate instability, so that it leaves its original trajectory and falls down. The description given in connection with the projectile according to FIGS. 1 a and 2 applies analogously to the temporal adjustability of the destabilization.

Since the stabilizing wings usually have a low pitch for generating a slight compensating rotation, this additionally favors the separation from the projectile according to the invention.

In the case of proposed solutions, a fragmentation charge is to be initiated via a tracer set after a predetermined time. This has considerable disadvantages: the fragmentation charge can already be actuated in the barrel, thereby damaging the weapon system or making it unusable. The fragmentation charge requires a central axial bore to accommodate it. This hole reduces the penetration rate of the projectile on armored targets. To ensure sufficient effectiveness, the fragmentation charge must have a certain minimum size. This affects the density of the projectile.

All of the disadvantages listed are definitely avoided by the invention. Even with a faulty tracer set, the entire floor leaves the barrel and the weapon system remains ready for use.

Claims (5)

1. Ammunition, preferably for machine guns, with a tracer and a stabilizing element. projectile, the lethal range of which is limited when a target is missed, characterized by the following features: a) the floor (10; 60) is sub-caliber, b) the stabilizing element (24; 87) is fixed relative to the projectile (10; 60) by means of a consumable material (36; 72), c) the consumption of the material (36; 72) can be predetermined and d) by the consumption of the material (36; 72), the element (24; 87) changes its original stabilizing position. 2. Device according to claim 1, characterized by the usability due to preferably chemical change. 3. Device according to claim 1, characterized by the usability due to preferably physical change. 4. Apparatus according to claim 1, 2 or 3 in a spin-stabilized projectile, characterized in that the stabilizing element as a body (24) in a rear bore (16) of the projectile (10) is arranged. 5. Apparatus according to claim 1, 2 or 3 in the case of a wing-stabilized projectile, characterized in that the stabilizing element is designed as a tail unit (87) arranged on the rear side of the projectile (60).

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