DE3824524A1 - Armour-piercing projectile - Google Patents

Abstract

An armour-piercing projectile having a sub-calibre kinetic-energy penetrator (7) which is arranged in a tubular casing (6) of equal calibre, which casing is closed at the rear end by a base piece and is open at the front end. The kinetic-energy penetrator is sealed with respect to the inner wall of the casing (6) and an additional propellant charge is arranged between its rear end and the base piece of the casing (6), which propellant charge is detonated with a delay after firing by means of a detonating device arranged on the projectile. This results in a tandem propellant charge which leads to a higher projectile terminal velocity. <IMAGE>

Description

The invention relates to an armor-piercing projectile with the features from the preamble of the patent Proverb 1. The development of reactive armor has to do this led the effect of shaped charge projectiles for the penetration of modern armor is no longer sufficient, while the reactive armor against so-called "KE- Projectiles ", also known as" balancing projectiles " become less effective.

Such bullets, so bullets that do not contain explosives and on Aim to work only through their kinetic energy are on known and for example in Rheinmetall "weapons technical paperback, 5th edition 1980 ".

However, it must be expected that the known high-performance balancing bullets more modern armor methods can be stopped and that an improvement in the performance of such force bullets only by significantly increasing their lift catch speed will be achieved.

Doing so is raising the initial speed longer pipes, larger cargo spaces and more propellant powder sets physical limits.

They are so-called RAP projectiles (Rocket-Assisted-Pro ejectile) known, in which on the floor for the additional acceleration a rocket engine is installed. Such projectiles are in the area of artillery where high individual accuracy is not important  settable, but are so far for the use of hochge shooting cannons were not feasible, because the spread of the bullets with afterburner is clear is larger than that of conventional balancing bullets.

The invention has for its object a tank breaking projectile with the characteristics from the generic term of claim 1 to create, in which by a increased acceleration a much higher endge speed (over 2000 m / sec.) and thus a higher Breakthrough performance at the target with high Accuracy and low scatter is achieved.

This object is achieved with the invention the features from the characterizing part of the patent saying 1.

Advantageous further developments of the invention Projectiles are described in the subclaims.

With the projectile according to the invention it is achieved that using a new type of ammunition also at Shot from conventional tank cannons and at one same cross-section of conventional KE projectiles achieved significantly higher initial speed and thus increasing the penetration of the projectiles becomes.

The basic idea of the invention is that the tank cannon from the case of the same caliber and the KE penetrator special projectile ver is shooting, which is basically a flying cannon represents, from which by the additional Treibla accelerated rate, the final for the goal  certain KE penetrator is fired. It deals is a kind of "tandem propellant charge", whereby analogous to the principle of the stage rocket, the one with the speeds generated in both propellant charge sets add up, creating a higher top speed and Breakdown performance is achieved.

The delayed ignition of the additional propellant charge and possibly another additional propellant charge (Claim 5) takes place by means of special ignition devices, that provide the necessary delay. This ignition devices can be in various ways, for example as electrical ignition devices, trained det be. But it has turned out to be particularly simple and proven to be reliable if the ignition devices are in accordance with claims 8 and 9 as the different ignition rooms interconnecting bores are formed, the length and diameter of the hole being the delay of ignition.

The following are based on the attached drawings Embodiments of the projectile according to the invention explained in more detail.

The drawings show:

Figure 1 shows the basic principle in a schematic sectional view of a tank cannon with a projectile leaving it.

Fig. 2 in longitudinal section an embodiment of an armor-piercing projectile in the state before firing;

Fig. 3 is a perspective view of the projectile of Figure 2 when the KE penetrator emerges from the sleeve.

FIG. 4 in a representation analogous to FIG. 3, the KE penetrator exits at a later stage compared to FIG. 3;

FIG. 5 is an illustration analogous to Figure 3 and 4 the exit of the KE penetrator of Gechosses according to Figures 2 to 4 after the complete withdrawal from the sleeve..;

Fig. 6 in a longitudinal section a second embodiment of an armor-piercing projectile in the state prior to launch;

Fig. 7 in a perspective exploded Dar position the exit of the projectile of Figure 6 from the tank cannon.

Fig. 8 in partial longitudinal section from a third embodiment of an armor-piercing projectile;

Fig. 9 in a schematic diagram analogous to Fig. 1, the processes when firing a projectile according to Fig. 8;

Fig. 10 in a perspective exploded Dar position, the projectile of Fig. 8 after exiting the tank cannon.

Fig. 1 illustrates the processes when shooting the armor-piercing projectile from an armored cannon 1 with a base piece 2 , a breech 3 , a propellant chamber 4 and a gun barrel 5th The projectile to be fired consists in principle of a sleeve 6 closed at its base, in which a KE penetrator 7 is arranged, sealed off from the inner wall of the sleeve.

The shot of the sleeve 6 from the tank cannon 1 is carried out by first igniting a conventionally propellant charge in the propellant chamber 4, which drives the sleeve 6 out of the gun barrel 5 , as described in more detail below, the hot propellant gases 8 by a suitably executed Enter the hole in the bottom of the sleeve 6 and ignite an additional propellant charge 9 there with a slight delay, as a result of which the KE penetrator 7 is finally driven out of the sleeve 6 . Here, the speeds generated by the two firings of propellant charges add up, but it must be taken into account that the pulse generated in both directions acts on the second shot and thus only a partial amount is available to generate an additional speed component in the forward direction. If the sleeve 6 and the KE penetrator 7 have approximately the same mass, about half of the additionally generated speed component is available in the forward direction.

However, it must be taken into account that the initial speed derived from the main propellant speed will be lower than in conventional projectiles, because the mass of the projectile consisting of the sleeve 6 and the KE penetrator 7 will be greater than the mass of projectiles introduced. It should also be taken into account that the tube length of the sleeve 6 is shorter than the length of a conventional weapon barrel. Overall, however, an increase in final speed, depending on the design of the system, can be achieved of 20 to 30% compared to previously possible final speeds.

A first exemplary embodiment of an armor-piercing projectile and the processes taking place when it is fired will be explained in more detail below with reference to FIGS. 2 to 5.

The projectile shown in FIG. 2 has a sleeve 10 of the same caliber as the gun barrel, not shown, with guide bands 11 on the outer wall 10.1 , which is closed at its rear end with a base piece 10.2 through which an ignition channel bore 12 enters the interior of the sleeve 10 is introduced. A conventional KE penetrator 15 is arranged over its entire length inside the sleeve 10 , wherein it is guided on the inner wall of the sleeve 10 via a sabot 16 which has a pressure receiving plate 14 at its rear end opposite the base piece 10.2 . An additional propellant charge 13 is arranged between the base piece 10.2 and the pressure receiving plate 14 . The KE penetrator 15 has a stabilizing tail unit 17 at its rear end.

When firing the projectile from a tank gun, not shown, with a conventional propellant charge, the sleeve 10 , guided by the guide bands 11 , is driven through the gun barrel, while the hot gases of the propellant charge of the gun barrel through the ignition channel 12 meet the additional propellant charge 13 and ignite them with a slight delay. The resulting gas vapors meet the pressure plate 14 and drive the KE penetrator 15 , guided by the sabot 16 , out of the sleeve 10 .

In FIGS. 3 to 5, the operations during firing are shown in more detail.

In the initial phase of egress shown in FIG. 3, the plastic guide elements 16.1 , 16.2 and 16.3 of the sabot 16 are still close to the KE penetrator 15 , while they occur during further off, as shown in FIG. 4, due to the attacking air forces and because of the elasticity of the plastic bend outwards and finally, as shown in Fig. 5, completely detach from the KE penetrator 15 . The guide elements 16.1 , 16.2 and 16.3 tear off their adhesion to the pressure-receiving plate 14 . The pressure receiving plate 14 is in a manner known per se from a high-strength aluminum alloy. By producing the guide elements 16.1 to 16.3 of the plastic sabot 16 , a considerable weight reduction of the entire floor is achieved. The separation of the propellant charge space from the propellant cage 16 by means of the pressure receiving plate 14 ensures that the thermally induced deformation of the plastic is kept within reasonable limits.

The efficiency of this projectile depends not only on the type of propellant powder used but also on the length of the sleeve 10 used . Due to the conditions in combat vehicles, in particular battle tanks and their automatic loaders, the length of the sleeve 10 should only be slightly larger than 1000 mm. Because this limits the possible acceleration path in the tube, another embodiment is shown in the fol lowing with reference to FIGS . 6 and 7 by the acceleration path is increased ver.

The projectile shown in Fig. 6 also has a caliber with the gun barrel, not shown, the same sleeve 10 'with guide bands 11 and a bottom piece 10.2 ' at the rear end through which the Zündka channel 12 is guided. The KE penetrator 15 'is arranged in this case within a launch tube 22 which is arranged coaxially in an additional driving piston 18 which lies in the sleeve 10 ' and on the sleeve inner wall 10.1 'is guided. This additional driving piston 18 is designed as a hollow cylinder which is open at its rear end and closed at its front end with a closing piece 18.2 , while the launch tube 22 has a tube 22.1 which is open at the front end and is closed off at the rear end by a bottom 22.2 , through which an additional ignition channel 20 is passed. The open end of the driving piston 18 is the bottom piece 10.2 'of the sleeve 10 ' directly opposite and a first additional propellant charge 13 'is arranged in the annular cylindrical space between the tube 18.1 of the driving piston 18 and the tube 22.1 . A second additional propellant charge 19 is arranged in the launch tube 22 behind the KE penetrator 15 '. The latter is of the same caliber as the launch tube 22 , with the result that no conventional stabilizing tail unit can be arranged at its end. For this reason, a so-called winding guide 21 known per se is used. This winding guide consists of elastic spring steel sheets, which find place in a machined annular groove of the KE penetrator 15 'and only unfold when the KE penetrator 15 ' emerges from the launch tube 22 .

Upon firing of the projectile of FIG. 6 made of a forth conventional tank gun 5 (s. Fig. 7) is ignited by the hot gas vapors of the primary propellant charge initially on the first ignition channel 12 (Fig. 6), the first zusätz Liche propellant charge 13 '. As a result, the drive piston 18 is driven out of the already accelerated sleeve 10 ', which is supported within the sleeve 10 by guide bands 11 '. Now that the driving piston 18 telescopically pushes out of the sleeve 10 , the guided length of the "tube" increases by almost 100% compared to the embodiment according to FIG. 5. This enables a higher final speed of the driving piston 18 to be achieved. Through the hot gas clouds of the propellant charge 13 ', the second additional union propellant charge 19 is ignited via the second ignition channel 20 , whereby the KE penetrator 15 ' is expelled from the propellant piston 18 , which corresponds to a third stage. Only a slight increase in the speed of the overall system is expected from this "third stage". The second additional propellant charge 19 has the main purpose of driving the KE penetrator 15 'out of the launch tube 22 because the otherwise usual removal of the KE penetrator from a propellant cage by splitting in, for example, three segments due to the necessary sealing of the propellant piston 18th compared to the gas plumes of the propellant charge 13 is not possible.

After the final exit of the KE penetrator 15 ', the winding guide 21 is in the position shown in Fig. 7.

In FIGS. 8 and 9 an embodiment of the mass is shown for a floor, in which tries to keep the total projectile as small as possible while still achieving a post-acceleration by an additional propellant charge.

The projectile shown in FIG. 8 has a sleeve 10 '' which is guided over guide bands 11 in the gun barrel 5 and which is somewhat shorter than the sleeve according to the exemplary embodiment according to FIG. 2. In the bottom piece 10.2 '' of the sleeve 10 '' is in turn a Ignition channel 12 arranged. The KE penetrator 15 '' is only with its rear end within the sleeve 10 ''. With the outside of the sleeve 10 '' arranged parts, the KE-Pene trator 15 '' is supported directly by a cage 24 on the wall of the gun barrel 5 . At the rear end of the drive cage 24 is an open end of the sleeve 10 '' ver closing drive plate 23 is arranged.

The principle of operation of this exemplary embodiment can be seen from FIG. 9. As can be seen, the separation between the KE penetrator 15 '' and the sleeve 10 '' already takes place within the gun barrel 5 , which is designed as an extra-long tube.

First, a conventional propellant charge is ignited in the propellant charge chamber 4 in the tank cannon 1 , where the sleeve 10 '' drives the gun barrel 5 . Dung by the hot gas vapors of the primary Treibla, the additional Treibla dung on the ignition channel 12 is ignited at the moment 13, in which the sleeve about half has 10 '' made their way through the gun barrel 5, so that the additional propellant 13 additively to already received acceleration the KE penetrator 15 '' post-accelerated. By a suitable design of the ignition channel 12 , the exact time of ignition of the additional propellant charge 13 can be determined so that there is an optimum increase in speed for the KE penetrator 15 ''.

In Fig. 10, the launching process is shown again as an explosion drawing, the sleeve 10 '' when leaving the gun barrel 5 can be seen, and the detachment of the elements of the sabot 24 from the KE Penetra gate 15 ''.

Claims (9)

1. Armor-piercing projectile with a sub-caliber KE penetrator, which is connected to a detaching device at the latest after leaving the gun barrel, characterized in that the guide device is designed as a tubular, caliber-like sleeve ( G , 10 ), which at the rear end is closed with a bottom piece ( 10.2 ) and is open at the front end, the KE penetrator ( 7 , 15 ) being arranged at least over part of its length inside the sleeve ( 6 , 10 ) and sealed against the inner wall of the sleeve and between the KE penetrator and the base piece ( 10.2 ) of the sleeve ( 10 , 6 ) an additional propellant charge ( 9 , 13 ) is arranged, which can be ignited with a delay compared to the firing by an ignition device ( 12 ) arranged on the projectile. 2. Projectile according to claim 1, characterized in that the KE penetrator ( 15 ) is arranged over its entire length within the sleeve ( 10 ), whereby it is caged over part of its length within the sleeve ( 10 ) by a drive ( 16 ) is guided, which has at its rear end a pressure receiving plate ( 14 ) arranged between the KE penetrator ( 15 ) and the additional propellant charge ( 13 ). 3. Projectile according to claim 2, characterized in that the sabot ( 16 ) has a plurality of plastic guide elements ( 16.1 , 16.2 , 16.3 ) arranged in the longitudinal direction of the KE penetrator ( 15 ), which are connected by adhesive bonding to the metal pressure plate ( 14 ) are. 4. Projectile according to claim 1, characterized in that the KE penetrator ( 15 '') is arranged with its rear part inside half of the sleeve ( 10 '') and on the outside of the sleeve ( 10 '') arranged part via a Drift cage ( 24 ) on the inner wall of the gun barrel ( 5 ) is guided, at the rear end of the sabot ( 24 ) one, the open end of the sleeve ( 10 '') closing drive plate ( 23 ) is arranged. 5. Projectile according to claim 1, characterized in that within the sleeve ( 10 ') a guided on the sleeve inner wall driving piston ( 18 ) is arranged, which is designed as an open at the rear end and at the front end locks Nes tube and in the coaxially at the rear end with a bottom ( 22.2 ) closed and at the front end open launch tube ( 22 ) is arranged and the KE penetrator ( 15 ') with the launch tube ( 22 ) of the same caliber and along its entire length in the launch tube ( 22 ) and a first additional propellant charge ( 13 ') between the propellant piston ( 18 ) and the bottom piece ( 10.2 '') of the sleeve ( 10 ') and a second additional propellant charge ( 19 ) between the rear end of the KE penetrator ( 15 ) and the bottom (22.2) of the launcher tube are arranged (22), wherein 'the first additional propellant charge (13 arranged ignition device (12)) relative to the Ab schu by a first, on the sleeve (10)' is retarded ignited, while the second additional propellant charge (19) relative to the first additional propellant charge (13 ') is delayed by a second disposed on the launching tube (22), ignition apparatus (20) can be ignited. 6. Projectile according to claim 5, characterized in that the driving piston ( 18 ) is arranged over its entire length within the sleeve ( 10 '), with its open rear end immediately in front of the bottom piece ( 10.2 ') of the sleeve ( 10 ') and the first additional propellant charge ( 13 ') in the annular space between the outer wall of the driving piston ( 18.1 ) and the wall ( 22.1 ) of the launch tube ( 22 ) is arranged. 7. Projectile according to claim 5 or 6, characterized in that the KE penetrator ( 15 ') is provided at its rear end with a winding guide ( 21 ). 8. Projectile according to one of claims 1 to 7, characterized in that the ignition device or the first ignition device as through the bottom piece ( 10.2 , 10.2 ') of the sleeve ( 10 , 10 '), the space of the additional propellant charge ( 13 ) or the first additional Treibla extension ( 13 ') with the space within the gun barrel connecting bore ( 12 ) is formed with a predetermined diameter. 9. Projectile according to one of claims 5 to 8, characterized in that the second ignition device as through the bottom ( 22.2 ) of the launch tube ( 22 ), the space of the second additional propellant charge ( 19 ) with the space of the first additional propellant charge ( 13th ') Connecting end bore ( 20 ) with a given diameter is formed.