EP2652437A1 - Projectile casing for an explosive projectile and method for handling a projectile casing - Google Patents

Abstract

Fragmentable projectile casing for an explosive projectile (7), having an uneven wall thickness (W) and having predetermined breaking points (2) distributed over the projectile casing (1) for the shaping of fragments, wherein the predetermined breaking points (2) are spaced irregularly apart from one another to achieve uniform fragments; fragmentable projectile casing for an explosive projectile (7), having predetermined breaking points (2) distributed over the projectile casing (1) for the shaping of fragments, wherein the predetermined breaking points (7) are formed as changes in the material structure that run in the longitudinal direction (L) and extend through the entire wall thickness (W); method for handling a fragmentable projectile casing (1) for an explosive projectile (7), having an uneven wall thickness (W) and having predetermined breaking points (2) distributed over the projectile casing (1) for the shaping of fragments, wherein the predetermined breaking points (2) are spaced irregularly apart from one another to achieve uniform fragments. Method for handling a fragmentable projectile casing (1) for an explosive projectile (7), having predetermined breaking points (2) distributed over the projectile casing (1) for the shaping of fragments, wherein the predetermined breaking points (2) are formed as changes in the material structure that run in the longitudinal direction (L) and extend through the entire wall thickness (W).

Description

 Projectile shell for a detonator and

 Method of treating a projectile casing

The invention relates to a fragmentable projectile casing for an explosive projectile, with distributed over the projectile casing predetermined breaking points for shaping of fragments. The invention further relates to a method for treating a fragmentable projectile casing for an explosive projectile, with predetermined breaking points distributed over the projectile casing for shaping splinters. Explosive projectiles are used, for example, as artillery ammunition. An explosive projectile for the defense against assault ammunition, eg mortar shells or rockets, is known from DE 10 2007 007 403 A1. In addition to a projectile casing, projectiles usually have an explosive charge disposed within the projectile casing. As a result of the ignition of the explosive charge at the target or in its vicinity, the projectile shell splinters into a large number of fragments. The splinters are accelerated by the pressure of detonation of the explosive charge and act on the target with a corresponding kinetic energy. Thus, an explosive projectile acts primarily by the fragmentation of its projectile shell.

The effect of the explosive projectile depends to a greater extent on the fragmentation. For example, in detonation of the explosive charge in addition to such splinters that can absorb enough kinetic energy due to their mass to act on the target, even splinters that can not or only to a limited extent act on the target due to low or high mass. In the same way, the shape or surface of the splinters influences their effectiveness. For example, splinters which have an unfavorable shape are braked due to their air resistance.

In order to achieve that predominantly splinters of the desired shape arise during the detonation of the explosive charge, the projectile casing can be provided with predetermined breaking points. For example, DE 21 26 351 C1 discloses a projectile casing which has predetermined break points distributed uniformly over the projectile casing. By means of these predetermined breaking points, the shape of the splinters can be influenced in such a way that fragments of the desired shape are formed to an increased extent. When shooting an explosive projectile from the tube of a weapon, especially in spin-stabilized explosive projectiles, large forces are transferred to the projectile casing. To ensure the strength of the projectile casing even during this increased stress, the projectile casings often have a non-uniform wall thickness. For example, areas of the projectile casing which are subjected to heavy loads may be correspondingly thicker.

Especially with such projectile jackets with uneven wall thickness, it has proved to be disadvantageous to provide evenly distributed predetermined breaking points, as results in detonation of the explosive charge by the uneven wall thickness and an uneven splinter formation. Although the shape of the splinters formed by the uniformly distributed predetermined breaking points is similar, the mass of the fragments differs greatly from one another. In the areas of low and large wall thickness form slivers with too low or too large mass, which are not or only partially effective, whereby the effect of such explosive projectiles is affected to the target. Another disadvantage of the projectile casing known from DE 21 26 351 C1 is that the predetermined breaking points are formed as extending along the circumference of the projectile casing and along a direction parallel to the longitudinal axis of the projectile casing lines, with only the running in the circumferential direction predetermined breaking points over the entire Wall thickness extend. As a result, the projectile casing tends to break in detonation of the explosive charge in the circumferential direction rather than in the longitudinal direction. It is possible that the predetermined breaking points do not break in the longitudinal direction. The result is an uneven fragmentation and a reduced effect of the explosive projectile in case of fragmentation of the projectile casing. The object of the invention is to provide a fragmentable projectile casing and a method for treating a fragmentable projectile casing which has an improved effect on the target.

G e l ö s t, this object is in a fragmentable projectile casing for an explosive projectile, with a non-uniform wall thickness and distributed over the projectile casing predetermined breaking points for shaping of splinters, characterized in that the predetermined breaking points to achieve uniform splinters are unevenly spaced from each other.

The predetermined breaking points can be arranged at an irregular distance from each other. In this way, the number of chips whose mass is in a desired range can be increased. At the same time, the number of slivers that are too heavy and / or too light can be reduced. Thus, an improved fragmentation with an increased number of effective splinters can be made possible. The effect of the explosive projectile resulting from the fragmentation of the projectile casing can be improved. Hereinafter, further embodiments of a projectile casing according to the invention will be explained, wherein initially on the arrangement of the predetermined breaking points to be discussed in more detail.

According to an advantageous embodiment, it is initially proposed that the predetermined breaking points have a smaller distance from one another in a region of greater wall thickness. This can cause regions of greater wall thickness to splinter into the desired mass when the explosive charge detonates. In a comparable manner, the predetermined breaking points in an area of lesser wall thickness can be an increased distance have from each other. As a result, the bullet casing can also fragment into a fragment of the desired mass in a region of lesser wall thickness. Thus, the predetermined breaking points can be arranged depending on the wall thickness such that they have similar shape and mass even with uneven wall thickness. It is possible that the predetermined breaking points each have an adapted to the wall thickness distance from each other.

In a further embodiment, it is provided that the predetermined breaking points are formed as lines. The lines can be straight or curved. The predetermined breaking points can be arranged in the manner of juxtaposed points which form predetermined breaking lines. Furthermore, the predetermined breaking points can be formed as continuous lines.

Another advantage is an embodiment in which the predetermined breaking points are arranged in the manner of a grid. The individual predetermined breaking points can be part of a predetermined breaking grid, which extends over the entire projectile shell. Due to the screening of the projectile casing by the predetermined breaking points, a uniform shape of the splinters can be achieved. The grid can be designed in the manner of a dot matrix or a line grid. It is possible that the grid is formed of predetermined breaking lines. Furthermore, the grid may extend in the direction of the surface of the projectile casing and / or in the direction of the wall thickness of the projectile casing. The grid may have meshes of uneven size. In particular, the size of the meshes of the grid can be adapted to the wall thickness of the projectile casing.

Furthermore, it is proposed in a structural design that the predetermined breaking points extend parallel to a longitudinal axis of the projectile casing and / or along the circumference of the projectile casing. The predetermined breaking points can be advantageously integrated into the projectile casing by automated methods. bring. In particular, in the case of rotationally symmetrical projectile floors, predetermined breaking points which run along the circumference can be generated in a simple manner by means of a fixed generator during the rotation of the projectile casing about its longitudinal axis.

According to a further embodiment, it is proposed that the predetermined breaking points, which run parallel to a longitudinal axis of the projectile casing, are unevenly spaced from each other and that the predetermined breaking points, which extend along the circumference of the projectile casing, are equally spaced from each other. In particular, in projectile casings, the wall thickness in the longitudinal direction is non-uniform, non-uniformly spaced apart predetermined breaking points in the longitudinal direction can cause a uniform splinter formation. Such a predetermined breaking grid, in which the predetermined breaking points are non-uniformly spaced apart in the longitudinal direction, can compensate for irregularities in the fragment formation. As a result, a uniform fragmentation can be effected even in a projectile casing with nonuniform wall thickness in the longitudinal direction.

In a preferred embodiment, the chips have a mass in the range of 5 g to 9 g. Splinters in this mass range have proven to be particularly beneficial for the defense of offensive bodies, such as mortar shells or missiles, in the air. Due to their mass, they exhibit a kinetic energy during the explosion of the explosive projectile, which is suitable for neutralizing flying missiles. Such splinters can penetrate the shell of the attack body and prematurely bring about or prevent the ignition of an explosive charge of the attack body. In the following, further embodiments of a projectile casing according to the invention will be explained, with a closer look at the nature of the predetermined breaking points. In a further embodiment, the predetermined breaking points are formed as points with reduced hardness. Due to the reduced hardness of the material in the region of the predetermined breaking point, the projectile casing may, in the event of detonation of the explosive charge, be more likely to break in the region of the predetermined breaking point. The predetermined breaking points can be designed as material structure changes. Due to the predetermined breaking points, cracks in the material of the projectile casing can be generated. In particular, when arranged in the manner of a grid predetermined breaking points, a hardening grid can also be formed in the projectile casing. Alternatively, the predetermined breaking points can be designed as mechanical predetermined breaking points, in particular as notches.

Particularly preferred is an embodiment in which the predetermined breaking points are formed by heat treatment, in particular by electron beam welding and / or laser welding. By heat treatment, the material of the projectile casing can be temporarily melted in a limited area. In the heat treated areas, material texture changes can be made in the projectile casing. The material structure changes may be inhomogeneities in the material of the projectile casing, which act as predetermined breaking points. In particular, the changes in the material structure may have a greater resistance to the remaining material of the projectile casing.

Above a projectile casing according to the invention and advantageous embodiments of this projectile casing has been described, which allow a uniform splinter formation despite a non-uniform wall thickness. in the Below is a projectile casing according to the invention and its advantageous embodiments will be explained, in which the predetermined breaking points break with increased probability and thus draw a uniform splintering.

In the case of a fragmentable projectile casing for an explosive projectile, with predetermined breaking points distributed over the projectile casing for shaping fragments, the object mentioned at the outset is achieved by designing the predetermined breaking points as material structure changes running in the direction of the longitudinal axis Wall thickness extend.

Due to the material structure changes predetermined breaking points in the longitudinal direction of the projectile casing can be formed. The predetermined breaking points can extend over the entire wall thickness, whereby the predetermined breaking points break with detonation of the explosive charge with increased probability. The resulting from the fragmentation of the projectile casing effect of the explosive projectile can thus be improved.

In a further embodiment, it is proposed that the predetermined breaking points are formed as running along the circumference of the projectile casing material structure changes that extend over the entire wall thickness. Thus, the projectile casing may have a predetermined breaking grid, which is formed from continuous material structure changes. Furthermore, in the projectile casing described above, the advantageous embodiments described in connection with the previously mentioned, fragmentable projectile casing with an uneven wall thickness can also be used. In a method according to the invention for treating a fragmentable projectile casing for an explosive projectile, with an uneven wall thickness and with predetermined breaking points distributed over the projectile casing for shaping splinters, the initially mentioned object is achieved in that the predetermined breaking points are uneven in order to achieve uniform splinters be spaced apart.

The predetermined breaking points can be arranged at an irregular distance from each other. In this way, the number of chips whose mass is in a desired range can be increased. At the same time, the number of slivers that are too heavy and / or too light can be reduced. Thus, an improved fragmentation with an increased number of effective splinters can be made possible. The effect of the explosive projectile resulting from the fragmentation of the projectile casing can be improved.

In the method described above, the advantageous embodiments mentioned in connection with the projectile casing according to the invention can also be used in an analogous manner. In a method for treating a fragmentary projectile casing for an explosive projectile, with predetermined breaking points distributed over the projectile casing for shaping splinters, the object mentioned at the outset is solved in that the predetermined breaking points are formed as material structure changes running in the direction of the longitudinal axis which extend over the entire length Wall thickness extend.

By introducing the continuous material structure changes predetermined breaking points in the longitudinal direction of the projectile casing can be formed. The predetermined breaking points can extend over the entire wall thickness, whereby break the predetermined breaking points with detonation of the explosive charge with increased probability. The resulting from the fragmentation of the projectile casing effect of the explosive projectile can thus be improved. In an advantageous embodiment of the method, the predetermined breaking points are introduced by heat treatment, in particular by electron beam welding and / or laser welding. Through a heat treatment, the material of the projectile casing in a limited area can be temporarily melted. In the heat-treated areas, material structure changes can be formed in the projectile casing. The material texture changes may be softer than the remaining material of the bullet casing, thereby acting as break points. Furthermore, the predetermined breaking points can be introduced without contact into the projectile casing by means of a heat treatment. It is possible to create predetermined breaking points in the projectile casing without removing material from the projectile casing.

In a further embodiment of the method, it is proposed that the projectile casing is moved relative to a stationary heat source. The heat source can be arranged immovably at a fixed position during the processing of the projectile casing. Furthermore, the projectile casing can be moved by means of a receiving device below, above or at the side of the heat source. By moving the projectile casing, the arrangement of the predetermined breaking points on the projectile casing can be specified. Furthermore, a method is proposed in which the surface of the projectile casing is smoothed after introduction of the predetermined breaking points. The heat treatment can cause material increases on the surface of the projectile shell, which adversely affect the flight behavior of the projectile. The material increases can be achieved by mechanical processes, such as turning, milling, planing, filing, grinding, lapping or vibratory grinding are removed.

In the method described above, on the one hand, the advantageous embodiments mentioned in connection with the first-mentioned method according to the invention and, on the other hand, the advantageous configurations mentioned in connection with the projectile envelopes according to the invention can be used.

Further details and advantages of a projectile casing according to the invention as well as an associated method for treating a projectile casing are explained below with reference to an exemplary embodiment shown in the figures. Show:

1 is a partially sectioned side view of a blasting shot,

2 is a side view of a schematic representation of a receiving device for a projectile casing to illustrate the treatment method,

3 is a side view of a schematic representation of a projectile casing for illustrating the arrangement of the predetermined breaking points and FIG. 4 is a side view of a schematic representation of a projectile casing.

In Fig. 1, an explosive projectile 7 is shown, which is suitable for firing with a large caliber (eg caliber 155 mm) artillery gun. The Explosive projectile 7 has a fragmentable projectile casing 1 and an explosive charge 3 arranged within the projectile casing 1. Furthermore, an igniter 9 is provided for igniting the explosive charge 3 in the front region of the explosive projectile 7.

On the surface 8 of the projectile casing 1, moreover, a groove 10 is arranged, in which a guide strip can be accommodated. When the explosive projectile 7 is fired from a drawn tube of the gun, a rotational movement can be transmitted to the explosive projectile 7 by means of the guide belt. Further, usually behind the region of the groove 10, a propellant charge is introduced into the tube of the gun, which is fired to shoot the explosive projectile 7. Large forces are transmitted to the area behind the groove 10. In order to ensure the strength of the projectile casing 1 in the region of the groove 10 during the firing of the explosive projectile 7, the wall thickness W of the projectile casing 1 rises in the region of the groove 10. Thus, the wall thickness W runs unevenly in the direction of the longitudinal axis L of the projectile casing 1.

The effect of the explosive projectile 7 is based on the fragmentation of the shell shell 1. The explosive projectile 7 is fired from the barrel of the gun in the direction of a target. As soon as the explosive projectile 7 is in the vicinity of the target, the detonation of the explosive charge 3 is brought about by means of the igniter 9. As a result of the built-up by detonation pressure in the projectile casing 1, the projectile casing 1 splinters into a plurality of splinters, which, accelerated by the detonation, act on the target. Due to the substantially cone-shaped spreading of the splinters after the detonation, the explosive projectile 7 is particularly suitable for the defense of attacking missiles, such as mortar shells or rockets. In conventional, known in the art, explosive bullets are formed in the fragmentation of the projectile casing 1 in addition to effective splinters that can absorb enough kinetic energy due to their mass to act on the target, even those splinters due to low or too high mass not or only to a limited extent can affect the goal. In order to achieve fragmentation with a high number of effective splinters, in the projectile casing 1 according to the invention, as shown in the following, predetermined breaking points 2 distributed over the projectile casing 1 are provided for the shaping of splinters. As a result, a uniform splinter formation is achieved.

To defend against missiles, splinters having a mass in the range of 5 g to 9 g, have proven to be particularly effective. For other targets, however, the mentioned range of the mass of effective splinters may assume deviating values.

As shown in Fig. 3, the predetermined breaking points 2 are formed as lines in the projectile casing 1, which are distributed over the projectile casing 1 in the manner of a grid. The grid is formed of predetermined breaking points 2, which extend along the circumference U of the projectile casing 1 and are equally spaced from each other, and predetermined breaking points 2, which run parallel to the longitudinal axis L of the projectile casing 1, and uneven distances from each other. In areas of the projectile casing 1, which have a greater wall thickness W, such as in the region 11 of the groove 10, the predetermined breaking points 2 are spaced less far from each other than in areas having a smaller wall thickness W. An area 12 with a small wall thickness W is located in the front, conical part of the projectile casing 1. In this region 12, the predetermined breaking points 2 are correspondingly widely spaced from each other.

Due to the uneven arrangement of the predetermined breaking points 2, a uniform splinter formation during the detonation of the explosive charge 3 is effected. The projectile shell 1 splinters into fragments of similar mass. The number of too heavy and too light splinters is thus reduced and it generates the largest possible number of effective splinters. Furthermore, the predetermined breaking points 2 are formed as points with reduced hardness, so that the projectile casing 1 has a hardening grid. Such predetermined breaking points 2 can be formed by changes in the material structure, which are produced by a heat treatment of the projectile casing 1, for example by electron beam welding or by laser welding. In such a heat treatment, the material structure of the projectile casing 1 can be changed within a limited to a few millimeters range. At the selected locations, the material is melted locally. In the subsequent cooling, the material then solidifies in a structure which has a reduced strength compared to the original material structure. The material structure changes may be in the form of martensite and / or bainite, so-called intermediate structure. A material removal does not take place during the heat treatment.

Both the predetermined breaking points 2, which run in the direction of the longitudinal axis L, as well as the predetermined breaking points 2, which extend along the circumference U, are further introduced into the projectile casing 1 so that they extend over the entire wall thickness W. The predetermined breaking points 2 are thus not limited to the surface 8 of the projectile casing 1, but penetrate the projectile casing 1 completely. Because of these consistently trained changes of the material structure, the probability of breakage in the fragmentation of the projectile casing 1 is increased both in the direction of the longitudinal axis L and along the circumference U at the predetermined predetermined breaking points 2. A method for treating a fragmentable projectile casing 1 will be described below with reference to the representation in FIG. 2:

FIG. 2 shows a projectile casing 1 which is held in a substantially horizontal position by means of a receiving device 6 and a rotating device 4. In the area above the projectile casing 1, a heat source 5 is fixedly arranged. With the heat source 5, for example an electron beam welding device or a laser welding device, the projectile casing 1 can be heated without contact in a limited area.

By means of the immovable heat source 5, the material of the moving below the heat source 5 projectile casing 1 is locally melted. The area of the projectile casing 1, on which the heat source can act, has a width of 1 mm to 3 mm and extends over the entire wall thickness W of the projectile casing 1. Formed in the molten region of the projectile casing 2, as described above , Material structure changes that act as predetermined breaking points 2. By the movement of the projectile casing 1 predetermined breaking points 2 are introduced into the material, which form the solid lines of a grid.

When processing the projectile casing 1 with the heat source 5, the projectile casing 1 is moved relative to the stationary heat source 5. For producing predetermined breaking points 2, which extend along a direction parallel to the longitudinal axis L of the projectile casing 1, the receiving device 6 moved together with the projectile casing 1 in the direction of the longitudinal axis L with respect to the heat source 5. The receiving device 6 holds the projectile casing 1 in the region of the groove 10 and guides them in their movement parallel to the longitudinal axis L.

The production of predetermined breaking points 2, which extend along the circumference U of the projectile casing 1, by rotation of the projectile casing 1 relative to the heat source 5. At its front end, the projectile casing 1 is rotatably mounted in a rotating device 4, with the projectile casing 1 below the Heat source 5 can be rotated.

In the method according to the invention, the predetermined breaking points 2 are unevenly spaced apart to achieve uniform splinters. A lienförmigen predetermined breaking point 2 along the circumference U is generated by the fixed heat source 5 acts selectively on the projectile casing 1, while this rotates about the longitudinal axis L by 360 °. Before the production of another, spaced from this breaking point 2, linear predetermined breaking point 2 along the circumference, the receiving device 6 is moved by a value corresponding to the distance of the two predetermined breaking points 2. The distance of the predetermined breaking points is adapted to the wall thickness W of the projectile casing 1.

To generate predetermined breaking points 2, which run along a direction parallel to the longitudinal axis L, the projectile casing 1 is moved over its entire length with respect to the heat source 5 by the receiving device 6. A distance between the predetermined breaking points 2 running parallel to the longitudinal axis L can be achieved by rotating the projectile casing 1 in each case after the production of a predetermined breaking point 2 running along the longitudinal axis L by a predetermined angle. In this way, along the route U generated equally spaced predetermined breaking points 2, which extend along the longitudinal axis L. Since the wall thickness W of the projectile casing 1 is uniform along the circumference U, the distances between the predetermined breaking points 2 along the circumference are also uniform.

In order to increase the likelihood of breaking the projectile casing 1 at the predetermined breaking points 2, the predetermined breaking points 2 extending in the longitudinal direction L and along the circumference are formed as material structure changes which extend over the entire wall thickness W of the projectile casing 1.

As a result of the heat treatment 1 material increases can form on the surface 8 of the projectile casing. These material increases are removed in a further process step. The surface 8 of the projectile casing 1 is smoothed, so that a flat surface 8 results, cf. Fig. 4. To smooth the surface 8, a mechanical method, such as turning, milling, planing, filing, grinding, lapping or vibratory finishing, can be used.

In the above-described fragmentable projectile casing 1 for an explosive projectile 7, with a non-uniform wall thickness W and distributed over the projectile casing 1 arranged predetermined breaking points 2 for shaping of fragments, the predetermined breaking points 2 to achieve uniform splinters are unevenly spaced from each other. In this way, the number of chips whose mass is in a desired range can be increased. At the same time, the number of slivers that are too heavy and / or too light can be reduced. Thus, an improved fragmentation with an increased number of effective splinters can be made possible. Reference numerals:

1 storey shell

2 predetermined breaking point

3 explosive charge

 4 turning device

5 heat source

 6 recording device

7 explosive projectile

8 surface

 9 detonators

 10 groove

 1 1 area

 12 area

L longitudinal axis

 U circumference

 W wall thickness

Claims

Patent claims:

1. Fragile projectile casing for an explosive projectile (7), with an uneven wall thickness (W) and with predetermined breaking points (2) distributed over the projectile casing (1) to form splinters, thereby ensuring that there is no marking,

that the predetermined breaking points (2) are unevenly spaced apart to achieve uniform splinters.

2. Projectile casing according to claim 1, characterized in that the predetermined breaking points (2) are at a smaller distance from one another in an area of greater wall thickness (W).

3. Projectile casing according to one of the preceding claims, characterized in that the predetermined breaking points (2) are arranged in the manner of a grid and/or are designed as lines.

4. Projectile casing according to one of the preceding claims, characterized in that the predetermined breaking points (2) run parallel to a longitudinal axis (L) of the projectile casing (1) and / or along the circumference (U) of the projectile casing (1).

5. Projectile casing according to one of the preceding claims, characterized in that the predetermined breaking points (2), which run parallel to a longitudinal axis (L) of the projectile casing (1), are unevenly spaced from one another and that the predetermined breaking points (2) which run along the circumference (U) of the projectile casing (1), are evenly spaced from one another.

6. Projectile casing according to one of the preceding claims, characterized in that the splinters have a mass in the range of 5 g to 9 g.

7. Projectile casing according to one of the preceding claims, characterized in that the predetermined breaking points (2) are designed as points with reduced hardness.

8. Projectile casing according to one of the preceding claims, characterized in that the predetermined breaking points (2) were created by heat treatment, in particular by electron beam welding and / or laser welding.

9. Fragmentable projectile casing for an explosive projectile (7), with predetermined breaking points (2) distributed over the projectile casing (1) for shaping splinters, in particular according to one of the preceding claims,

that the predetermined breaking points (7) are designed as material structural changes running in the direction of the longitudinal axis (L) and extending over the entire wall thickness (W).

10. Projectile casing according to one of the preceding claims, characterized in that the predetermined breaking points (2) are designed as material structural changes running along the circumference (U) of the projectile casing (1) and extending over the entire wall thickness (W).

11. Method for treating a fragmentable projectile casing (1) for an explosive projectile (7), with an uneven wall thickness (W) and with predetermined breaking points (2) distributed over the projectile casing (1) to form splinters,

characterized,

that the predetermined breaking points (2) are unevenly spaced apart to achieve uniform splinters.

12. Method for treating a fragmentable projectile casing (1) for an explosive projectile (7), with predetermined breaking points (2) distributed over the projectile casing (1) to form splinters,

characterized,

that the predetermined breaking points (2) are formed as material structural changes running in the direction of the longitudinal axis (L) and extending over the entire wall thickness (W). 13. The method according to claim 11 or 12, characterized in that

Predetermined breaking points (2) are introduced by heat treatment, in particular by electron beam welding and/or laser welding.

1 . Method according to claim 13, characterized in that the projectile casing (1) is moved relative to a stationary heat source (5).

15. The method according to any one of claims 11 to 14, characterized in that the surface (8) of the projectile casing (1) is smoothed after the predetermined breaking points (2) have been introduced.