EP0806623A1 - Spin stabilised carrier projectile - Google Patents

Abstract

Payload (20) is contained in an elongated case (1) of a spin-stabilised projectile having several grooves parallel to the longitudinal axis of the projectile on its inside surface to hold the columnar (21) payload in place. An axial fixing arrangement (10) is attached to the case at the front of the load, while a partition wall (7) is provided between the payload chamber and the explosive material chamber, having a damping arrangement (18). The damping arrangement is preferably a gap containing air. The payload is preferably divided into parallel columns and the grooves have the shape of cylinder sectors with curvature smaller than the curvature of the columns.

Description

The invention relates to a spin-stabilizable projectile containing a payload according to the preamble of claim 1.

Projectiles of this type can carry various types of payloads; They are used not only for military but also for civil, for example meteorological, purposes, and they can be used for different uses, i.e. soil / soil, soil / air, air / soil and air / air.

It is obvious that the larger its payload, the more efficient a projectile with the same total volume and weight. In the context of the present invention, the term “payload” is intended to denote the amount of the transport goods accommodated in the payload chamber. Efforts are therefore made to make the best possible use of the space available in the payload chamber, ie to accommodate the payload in the densest possible packing in the payload chamber. The best use of space is achieved Payload is equal to the cross section of the payload chamber; If the payload is divided into columns, as is often the case, the best use of space is achieved if the cross-section of the columns is such that they can be arranged across the board. This could be achieved with columns whose cross-sections are, for example, rectangular, square, triangular or regular hexagonal. However, since other requirements are placed on the columns, such as simple and inexpensive manufacture and assembly, and possibly the possibility of controlling the flight of the columns by means of swirl stabilization, columns with round cross-sections, possibly with approaches for arrow stabilization, are generally used which, with the exception of the achievable space utilization or packing density, are superior to all other cross-sections mentioned.

Traditionally, the payload has been released by detonating the profile jacket by igniting a burst charge and / or ejecting the sub-projectiles from the profile jacket by igniting an ejection charge, requiring a significant amount of explosive for both the burst charge and the ejection charge. However, by installing a relatively large amount of explosive in the projectile, one was forced to limit the payload accordingly, which of course was not desirable.

In order to get by with the smallest possible amount of explosive and thus to be able to provide the greatest possible payload, an attempt was therefore made to provide an opening charge instead of a burst charge for detonating the projectile jacket or instead of an ejection charge for ejecting the payload, since such charge must be significantly less than that Bursting or ejection charge. In principle, the opening charge only serves to create lateral openings in the projectile jacket along a plurality of jacket lines, whereupon the parts of the projectile jacket which are released in the process move in a tangential direction relative to the rest of the projectile; this releases the payload that is no longer held by the profile jacket. The payload emerges as follows: the projectile jacket exerts a centripetal force on the payload, which rotates around the longitudinal axis of the projectile due to the swirl of the projectile. This centripetal force ceases when the projectile jacket is destroyed by creating the passages in the projectile jacket by means of the opening charge, so that the payload leaves its original location under the action of the centrifugal force and moves away tangentially from the projectile or from the rest of the project. The resulting tangential component of the speed of the payload is added to the axial component of the speed of the payload, which is the same in magnitude and direction as the flight speed of the projectile. If the payload is divided into coaxial columns, each column continues to fly at a certain angle of departure relative to the trajectory of the projectile, with the trajectory of the columns generating one Form cones, the axis of which is the trajectory of the projectile and the tip of which is the place where the payload is released.

The above-described type of release of the payload can only be successfully carried out if the swirl of the projectile has completely transferred to the columns of the payload before the projectile jacket is opened, so that these are set into rotation about the longitudinal axis of the project, from which upon release the tangential velocity component of the columns results.

At this point it should be noted that the payload also rotates around itself, i.e. with the rotation around the projectile axis. a self-rotation, which is to be referred to as swirl, is given. The payload rotates on its own axis both before and after it is released; the advantageous effect of this inherent rotation or of this swirl is discussed in more detail below.

In order for the twist of the projectile to be transferred to the payload and the aforementioned tangential component of the speed to emerge from which it is removed from the payload chamber, the payload must be fixed in the payload chamber in such a way that it does not rotate relative to the projectile jacket is in a previously known projectile according to US-603,525, in which the payload is divided into coaxial columns, the payload chamber formed so that it has axially extending, approximately semi-cylindrical grooves, the diameter of which is equal to the diameter of the columns and in which the columns are arranged are.

In order to open the projectile jacket as intended in zones along the longitudinally provided jacket lines and also to keep the amount of the explosive required as low as possible, the projectile jacket is designed in known projectiles in such a way that it has several, at least approximately axially arranged, distributed over the circumference has predetermined breaking zones along which it opens for the columns under the action of the ignited explosive.

In the previously mentioned known projectile according to US-603,525 , such predetermined breaking zones occur, although they are not expressly designated as such, by the above-mentioned grooves with an approximately semi-cylindrical shape, which, as described above, for tangential fixing of the outer layer of the columns lying on the projectile jacket serve relative to the projectile. As already described, these grooves extend axially along the inner wall of the subprojectile chamber and have the consequence that the projectile jacket has changing wall thicknesses in the circumferential direction, the predetermined breaking zones naturally also the areas of the smallest wall thickness coincide. The predetermined breaking zones are more efficient the more abruptly the wall thickness changes.

For the continued use of the payload, it is of the utmost importance that it is not damaged when the opening charge explodes in the explosive chamber. It must be noted that the projectile already mentioned according to US-603,525 is unsatisfactory in this regard , since the pressure wave that arises when the opening charge explodes naturally affects the relatively weak base plate, so that there is no guarantee that the effect the opening charge is used exclusively to break open the projectile jacket; there is a risk that the payload will be damaged before it is released.

The object of the invention is therefore seen in creating a projectile of the type mentioned at the outset which does not have this disadvantage and in which the payload is not damaged before and during its release. The forces arising as a result of the explosion of the opening charge must not affect the payload via the partition, but the area around the explosive chamber must be designed so that a flow of force occurs that essentially only results in the opening of the projectile jacket.

According to the invention, this object is achieved by the features of the characterizing part of patent claim 1.

Advantageous further developments and preferred exemplary embodiments of the projectile according to the invention are defined by the further claims dependent on claim 1.

The projectile according to the invention thus differs from the projectile according to the prior art mentioned in that the partition is stable, that it is integrally formed on the projectile jacket or is firmly connected to the projectile jacket, and that, due to an axial damping arrangement, the forces generated when the opening charge explodes act immediately on the project jacket and primarily result in the opening of the projectile jacket so that the payload is not damaged. This has the further advantage that no explosives are used uselessly, so that the smallest possible amount of explosives can be used and the largest possible payload can be installed accordingly.

In a simple and very effective embodiment, the damping arrangement can be realized by an air-filled gap, through which the explosive from the Partition is spaced while it lies close to the explosive chamber wall in the radial direction.

The gap can of course also be filled with a damping mass.

So that the projectile jacket really tears open as intended in the axially running predetermined breaking zones, its wall thickness should be dimensioned such that it decreases in the axial direction from the back to the front; so that the tearing is not stopped at the location of a reinforcement of the wall; Usually, however, project coats with a constant wall thickness are selected, which are easier to manufacture and which also achieve satisfactory results. Functionally disadvantageous and therefore projectile coats with increasing wall thickness are to be avoided.

The payload can be formed by a single column; in most cases, however, it is divided into several coaxial columns arranged side by side.

In order for the payload to move away from the projectile's trajectory as intended, it must perform a rotational movement about the longitudinal axis of the project before it is released or rotate together with the projectile. For this purpose, it must be fastened in the projectile in such a way that it rotates together with the projectile or does not rotate relative to the projectile. In the projectile described in the repeatedly mentioned US-603,525 , the payload divided into columns is indeed very well fixed in that the columns lying on the projectile jacket engage with grooves with practically semicircular profiles with almost half their circumference. However, this arrangement has the disadvantage that the columns of the payload must be dimensionally precise, so that only processes with which the required precision can be achieved can be used for their manufacture, such processes generally being quite expensive; Inexpensive processes, especially in the field of non-cutting production, are not considered. In order to avoid this disadvantage, in a preferred embodiment of the project according to the invention, the curvatures of the profiles of the grooves are chosen such that they are in any case less than the curvatures of the cross sections of the subprojectiles, even if their radii are within a relatively large tolerance range.

The profiles or cross sections of the grooves can be formed by different curves. For reasons of manufacture, grooves are generally preferred whose profiles are circular arc sections, so that the grooves themselves have the shape of cylindrical sectors.

The grooves are preferably dimensioned and arranged so that the packing density of the payload is practically optimal, ie as tight as it is for columns with the same circular shape Cross sections are possible at all, although certain deviations of the column mass from the nominal dimension should be permissible. At the same time, the grooves should be dimensioned and arranged so that the angle of rotation of the payload relative to the payload chamber is as small as possible. This can be achieved if the columns of the payload are arranged in such a way that their envelope curve forms an n-corner, preferably a regular hexagon, in cross-section, and that n grooves are provided, which are arranged in n / 2 groups of two grooves each , whereby the angular spacing of the groups is 360 degrees / (n / 2) and the mutual spacing of the groups is of course larger than the spacing of the grooves of a group.

Since one and the same projectile can be used to transport different payloads, and since the same payloads in the axial direction can also have slightly different dimensions due to manufacturing tolerances, it is advantageous if the axial fixing device for the payload is fastened to the projectile jacket by means of a screw connection , since this allows the length of the payload chamber to be adapted to the length of the payload in the sense of tolerance compensation. A further length adjustment of the payload chamber can be achieved if the axial fixing device is designed in such a way that it has an extension projecting into the payload chamber. As already mentioned, the payload is often divided into axial columns. The number of columns is arbitrary upwards and depends, among other things. depending on the characteristics and purposes of the payload. In addition to this division in the axial direction, the columns can be divided into column sections transversely to their longitudinal direction or consist of column sections, whereby these column sections - like the one-piece columns - need not be prismatic or non-cylindrical.

In a preferred embodiment of the project according to the invention, the payload consists partly or exclusively of sub-projectiles. As is also possible for other payloads, these can take up the entire length of a column or can be stacked together to form a column. In the context of this application, the term “subprojectile” is intended not only to refer to ammunition of various types but also to all types of payloads from which a specific onward flight on a defined trajectory is expected after their release. While with the previously mentioned payloads only a release by the projectile was intended at a certain point in time or at a certain place, and the onward flight of the payload was of secondary importance, subprojectiles have the additional requirement that their flight after the release by the projectile to continue individually in a predetermined manner. This requires the stabilization of the subprojectiles. It is possible to train certain, especially longer, sub-projectiles in such a way that they fly at least partially arrow-stabilized; However, stabilization by swirl is preferred in any case. The required twist of the subprojectiles, ie their rotation around itself, is generated to a certain extent automatically with the projectile according to the invention, as follows: As already mentioned above, the columns forming the payload during their flight in the projectile are not only rotated about the longitudinal axis of the project but also self-rotated or twisted granted. It is now only necessary to ensure that this swirl of the subprojectiles is maintained during and after the release by the projectile, since otherwise the subprojectiles will not continue to fly stably but will stagger. The consequences of staggering essentially consist of a loss of energy of the subprojectile, as well as of the restriction in the choice of the shape of the subprojectile, since these take into account the departure angle, i.e. the angle between the trajectories of the projectile and the subprojectile, and the one to be achieved Swirl stabilization of the subproject style must be selected. So that the required twist of the subprojectiles is maintained, it is essential that the subprojectiles in the area of the partition are not damaged by the explosion of the opening charge and that their release is trouble-free, which is the case according to the invention, since only by the explosion of the opening charge indirect or direct forces are exerted to a very limited extent on the subprojectiles.

In particular, if the projectiles or the subprojectiles are designed as ammunition for military purposes, the hit pattern or the subprojectile distribution that can be achieved with this is of great importance for the efficiency of the weapon system, of which they form a part. It is known and easy to see that projectiles in which the subprojectiles are not subdivided in the axial direction result in a subprojectile distribution in which the same subprojectiles are located on a circle at the same distance from the projectile axis, the originally being close to the projectile axis Subprojectiles arrive at a circle with the smallest radius, while the subprojectiles originally arranged at greater distances from the projectile axis can be found on circles with larger radii concentric to the circle mentioned. With a suitable embodiment variant of the projectile according to the invention, a greatly improved hit pattern can now be achieved according to the following explanations. As already mentioned, different types of sub-projectiles can be built into the projectiles according to the invention. Taking advantage of the fact that the payload chamber opens under the effect of the ignited opening charge essentially along a surface line similar to a zipper from the back to the front, a particularly advantageous hit pattern or a particularly good distribution of the subprojectiles can be achieved if subprojectiles are used, which are stacked in a row in a stack to form the pillars of the payload. The opening of the payload chamber begins at the back and continues towards the front; while the payload chamber is being opened, the spin-stabilized projectile continues to rotate about the projectile longitudinal axis; this means that the subprojectiles of a column are not released at the same time, but that the rear subprojectile is released from the payload chamber first can emerge, whereupon it is followed at regular intervals by the other subprojectiles of the same column until the last subprojectile has left the payload chamber as the last subprojectile. In the resultant subprojectile distribution, subprojectiles of a column essentially reach an at least approximately circular arc. In contrast, subprojectiles of a column, which are all released simultaneously, hardly distribute, so that their hit pattern lies on a very short section of a radial beam and shrinks almost to a point. It is easy to see that thanks to the progressive opening of the payload chamber, the probability of a hit is increased significantly without the use of additional subprojectiles. As a supplement only, it should be added that the hit pattern or subprojectile distribution generally also depends on the distance of the projectiles from the longitudinal axis of the projectile. Subprojectiles of a first pillar, which is closer to the projectile longitudinal axis, will therefore be found on an arc section whose radius is smaller than the radius of the circle, on which subprojectiles of a second pillar come from near the projectile jacket.

It has already been mentioned that the projectile according to the invention is designed in such a way that the payload or the sub-projectiles are released undisturbed, so that they maintain a swirl stabilization and continue to move in a predeterminable manner due to the maintenance of their swirl. Since the problem of swirl stabilization of the subsidiary storeys is mastered, it is possible to provide daughter storeys of various designs, in particular those whose front part has a shape for which the external and / or end ballistic performance is optimal.

The projectile according to the invention can be designed to be polyvalent as described below. A large number of conventional similar projectiles are designed in such a way that they only develop their optimum effect by sub-projectile hits, i.e. when the sub-projectiles are released in flight, but not by projectile hits, also called direct hits, before the projectile is released. In contrast, the projectile according to the invention can be designed such that there is a good effect even when the projectile is hit. For this purpose, a device is arranged in the area in front of the subprojectile chamber within the ballistic hood or ogive, which acts as a penetrator or plow to a certain extent in the event of a direct hit. The ballistic hood is advantageously attached to the projectile jacket in such a way that it tends to press the envelope radially away on impact; This has the favorable effect that not only does penetration into the target object take place under the action of the penetrator, but that the subprojectiles can also diverge radially.

Fig. 1

ein erstes erfindungsgemässes Projektil in einem Längsschnitt;

Fig. 2

das in Fig. 1 dargestellte Projektil in einem Schnitt längs der Linie II-II der Fig. 1;

Fig. 3

ein durch die Subprojektile des in Fig. 1 dargestellten Projektils erzeugtes Trefferbild bzw. eine Subprojektilverteilung, in einem Schaubild;

Fig. 4

ein zweites erfindungsgemässes Projektil, ausschnittweise, zur Darstellung einer weiteren Dämpfungsanordnung;

Fig. 5a - 5e

fünf Ausführungsbeispiele von aus Subprojektilen gebildeten Säulen, in einer seitlichen Ansicht; und

Fig. 6a - 6c

drei Ausführungsbeispiele von in einer Säule angeordneten Subprojektilen, ausschnittweise, in einer seitlichen Ansicht.

In a particularly optimal, because weight-saving design, the axial fixing device with which the subprojectiles are clamped together can be designed as such a penetrator or plow.
Further details and advantages of the projectile according to the invention are described in detail below on the basis of preferred exemplary embodiments and with reference to the drawing. It shows:

Fig. 1

a first projectile according to the invention in a longitudinal section;

Fig. 2

the projectile shown in Figure 1 in a section along the line II-II of Fig. 1.

Fig. 3

a hit image generated by the subprojectiles of the projectile shown in FIG. 1 or a subprojectile distribution, in a diagram;

Fig. 4

a second projectile according to the invention, in sections, to illustrate a further damping arrangement;

5a-5e

five exemplary embodiments of columns formed from subprojectiles, in a side view; and

6a-6c

three exemplary embodiments of sub-projectiles arranged in a column, in sections, in a side view.

1 , the spin-stabilizable projectile contains a projectile body with a projectile jacket 1 , preferably made of light metal, a ballistic hood 2 attached to the front of the projectile jacket 1 and an igniter 3 attached to the rear part of the projectile jacket 2 , which in this exemplary embodiment is designed as a programmable timer. However, it is conceivable to use another igniter, for example a distance igniter, the ignition of which is triggered by transmission means. The detonator can also be arranged on the front part of the projectile jacket, with the disadvantage that this results in an axially continuous ignition channel, so that the cross-sectional area available for the payload is smaller. The projectile furthermore has a payload chamber 4 for a payload 5 fixed therein, a detonator space 6 , a guide band 8 and 6 arranged behind the payload chamber 4 and partially separated by a web-like partition 7 Indentations 9 for attachment to a cartridge case, not shown. An axial fixing device, which is designed as a retaining screw 10 , holds the payload 5 fixed in the axial direction and connects the projectile jacket 1 to the ballistic hood or ogive. 2. The fixed in the fuse area, a known time fuse 3 includes an igniter housing 11, a data receiver coil 12, a power supply 13, for example with a shock generator, an electronic time fuse module 14, an igniter 15, a detonator 16 and arranged in a explosive chamber Oeffnungsladung 17 .

An explosive charge is provided as the opening charge 17 , which in the radial direction is in full contact in the detonator or time fuse 3 and / or in a projectile shell part 1A connected to the projectile jacket 1 and in the axial direction at a distance which forms a damping arrangement 18 from the web-like partition 7 is arranged. As such, the opening charge 17 can be arranged directly in the projectile body part 1A , in which case the ignition chain to the detonator or timer 3 or detonator 16 must be ensured. The damping arrangement 18 can be in the form of an air gap between the web-like partition 7 and the opening charge 17 , as shown in FIG. 1 , or for example in the form of a material 18A arranged between the web-like partition 7 and the opening charge 17 with damping properties, as shown in FIG 4 , be formed.

According to FIGS. 1 and 2 , in this exemplary embodiment the payload 5 derives from a large number of cylindrical sub-projectiles 20 made of heavy metal, which form a plurality of columns 21 in the payload chamber 4 in a coaxial arrangement parallel to the longitudinal axis of the project. The columns 21 are arranged so that their envelope is a regular hexagon in cross section. Eight subprojectiles 20 arranged one above the other form a column 21 , and nineteen such columns 21 are firmly fixed in the payload chamber 4 by the screwed-in axial fixing device 10 . As will be explained further below, this axial fixing device 10 acts as a kind of plow or penetrator in the event of a projectile hit. The projectile jacket 1 is designed in the region of the payload chamber 4 as a hollow cylinder 22 with additional recesses or grooves 23 running in the longitudinal axis direction of the projectile; 2 , six grooves 23 are provided in three groups of two grooves 23 , the groups being distributed at an angular distance of 120 degrees along the circumference of the payload chamber 4 , and the mutual distance between the groups being greater than the distance between the subprojectiles one Group. The grooves 23 are eccentrically arranged cylindrical sector-shaped recesses. These recesses or grooves 23 , on the one hand, secure the sub-projectiles 20 or the columns 21 in cooperation with the axial fixing device against movements relative to the projectile jacket 1 , with a certain margin in the radial direction for accommodating manufacturing-related tolerances of the sub-projectiles but the relative angle of twist is as small as possible; on the other hand are formed by the grooves 23 axially extending frangible zones 24 at the points where the smallest wall thickness of the projectile jacket. 1

The mode of operation of the spin-stabilizable projectile to achieve sub-projectile hits is described below. If the detonator 15 is ignited, the projectile jacket 1 or the payload chamber 4 is opened via the detonator 16 and the opening charge 17 , with the subsequent discharge of the payload 5 or the subprojectile 20 relative to the projectile in the tangential direction. Due to the structural arrangement in the area of the opening charge 17 , the shock waves of the detonation act immediately in the radial direction and with a time delay in the axial direction. As a result, the projectile jacket 1 is torn open laterally from the area of the guide band 8 and the payload chamber 4 is continuously opened along the predetermined breaking zones 24 from the back to the front, for example in the manner in which a zipper opens or a banana is peeled; the parts of the projectile jacket 1 thus freed are flung away under the action of the centrifugal force. Due to the damping arrangement 18 , the payload 4 is only slightly pressurized. The release of the undamaged subprojectile 20 is delayed and practically trouble-free. From now on, the sub-projectiles 20 forming the payload will continue to fly, individually spin-stabilized, at an acute angle of departure.

From the sub-projectile distribution or scatter shown in FIG. 3 of such a projectile with one hundred and fifty-two sub-projectiles 20 , the result of the arrangement of the sub-projectiles 20 in nineteen coaxial columns 21 , each with different distances from the longitudinal axis of the project, and the trouble-free 'tier-wise' or cyclical release of the Subprojectile 20 can be seen. For example, the framed group of points 25 can be traced back to subprojectiles 20 from a first column at the greatest distance from the longitudinal axis of the project, ie adjacent to the projectile jacket, point 26A corresponding to the rearmost and point 26B to the foremost subprojectile of this column.

Instead of the described sub-projectile hits, a projectile hit, also called direct hit, occurs in cases in which no ignition took place arbitrarily or involuntarily before the projectile hit a target object. The axial fixing device 10 , which acts as a penetrator, also gives a good end ballistic effect in these cases.

5a-5e show subprojectiles 20A-20E in various designs, only one column 21A-21E being shown in each case. 5a shows subprojectiles 20A which are similar to the subprojectiles 20 described above. 5b contains a column 21B with very short, practically disc-shaped sub-projectiles 20B , which allow very good swirl stabilization. It can be seen from FIG. 5c that a long subprojectile 20C which forms the entire column 21C is also possible; the illustrated embodiment is a partially projectile-stabilized sub-projectile. FIG. 5d shows a sub-projectile 20D , which is also partially arrow-stabilized, two of which correspond to the length of the column 21D . 5e shows subprojectiles 20e which have a spherical shape.

6a-6c show three examples of subprojectiles 20E, 20F, 20G which are similar in their proportions to the subprojectiles of FIG. 5a , but have differently designed front parts.

Although the payload is always shown as a sub-projectile in the figures, other types of payloads are nevertheless possible; For example, payloads for generating false targets or for dazzling a flight destination, CHAFF or FLARE payloads can be provided in the weapon area. Subprojectiles of different types and with different purposes can be accommodated in a single projectile. In other areas of application of projectiles according to the invention, for example for meteorological and other purposes, numerous other payloads are conceivable. The invention is not intended to be limited by the examples given, but rather to be defined exclusively by the claims.

Claims (12)

Twist-stabilized projectile containing a releasable payload (5) - An elongated projectile jacket (1) which laterally delimits a payload chamber (4) , the inner contour of which has a plurality of grooves (23) at least approximately parallel to the longitudinal axis of the project with at least approximately circular arc-shaped boundaries, for fixing the payload (20) forming at least one column (21) parallel to the longitudinal axis of the project. against radial and tangential movements and to form predetermined breaking zones (24) in the projectile jacket (1) which are at least approximately parallel to the longitudinal axis of the project , - an axial fixing device (10) which limits the payload chamber (4) at the front and is attached to the projectile jacket (1 ), a partition wall (7) which delimits the payload chamber (4) at the rear and separates it from an explosive chamber and contains an explosive which lies in the circumferential direction on the wall of the explosive chamber, characterized by
that a damping arrangement (18) is provided between the partition wall (7 ) connected to the projectile jacket (1) and the explosive. Projectile according to claim 1 ,
characterized,
that the damping arrangement (18) is formed by a gap which preferably contains air. Projectile according to claim 1 ,
characterized by
that the wall thickness of the projectile jacket (1) is constant or decreases in the direction of the profile front Projectile according to claim 1,
characterized by
that the payload (5) is divided into several parallel columns (21) . Projectile according to claim 4 ,
characterized,
the grooves (23) have the shape of cylindrical sectors. Projectile according to claim 4,
characterized,
that the curvature of the grooves (23) is smaller than the curvature of the cross sections of the columns (21) . Projectile according to claim 6,
characterized,
that the columns (21) are arranged in such a way that their envelope curve forms an n-corner, preferably a regular hexagon, in cross-section, and that n grooves (23) are provided, which are arranged in n / 2 groups with angular distances of 360 degrees / ( n / 2) and two grooves are distributed along the circumference of the payload chamber (4) , the mutual distance between the groups being greater than the distance between the grooves within a group. Projectile according to claim 1 ,
characterized,
that the axial fixing device (10) for the payload (5) is screwed to the projectile jacket (1) in order to adapt the axial length of the payload chamber (4) to the payload (5) . Projectile according to claim 1,
characterized by
that the at least one column (21 ) forming the payload (5 ) is divided into column sections (20) transversely to the longitudinal axis of the project. Projectile according to claim 1,
characterized by
that the payload (5) is at least partially formed by subprojectiles (20) . Projectile according to claim 1,
characterized,
that a penetrator device (10) arranged in front of the payload chamber (4) is arranged. Projectile according to claim 1,
characterized,
that the axial fixing device (10) is designed as a penetrator.

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