EP1893935A1 - Projectile or warhead - Google Patents

Abstract

The aim of the invention is to obtain great final ballistic effectiveness of fragmentation bullets and warheads regardless of the impact speed while using as little explosive material as possible. Said aim is achieved by combining explosive shell (3) with a damming inner member (4) in connection with an accelerated outer jacket (2). This arrangement results in the best possible conversion of the explosive energy while offering great creative flexibility regarding the design. A wide range of additional possible effects is created by blast-compacting the inner damming member (4). Furthermore, the shape of the inner damming member allows the fragments to obtain a directionally controlled effect. Depending on the caliber and technical design, the amount of explosive material used can be reduced by 50 to 80 percent compared to conventional explosive bullets at comparable fragment speeds or sub-bullet speeds. The explosive material economized is available as additional effective mass. The accelerated jacket (2) can also be entirely or partly composed of preformed fragments or sub-bullets.

Description

 STOREY OR HEADHEAD

BACKGROUND OF THE INVENTION

1 . Field of the invention

The present invention relates to a fragment or sub-projectile projectile or warhead.

2. Technical background

Explosive projectiles are used to achieve end-ballistic effects with areal easy targets, regardless of the impact velocity of a projectile or warhead by means of explosive-accelerated splinters with a high initial velocity. Such explosive projectiles are characterized in that their volume is taken up for the most part by explosives. By their design, projectiles or explosives-filled warheads contain a relatively large mass of explosives, which is not effective to a considerable extent or partially for physical reasons can not be effective at all. The constructive scope is so limited in the previously known ammunition and focuses on the design of the fragmentation shell and the pyrotechnic components.

In shatter-forming projectiles, the distribution of sufficiently fast accelerated fragments to the largest possible target area or the occupying of the largest possible space (depth) is the decisive factor. However, this goal can only be achieved to a limited extent in the case of pure blasting projectiles, since with a detonation the control possibilities with respect to fragment formation and fragmentation distribution are limited. In conjunction with a sufficient impact velocity of the projectile and the use of relatively small quantities of explosives, the above-mentioned requirements have hitherto only been achieved with so-called ALP projectiles (active lateral effective penetrators). In these laterally dispersive, active projectiles based on the PELE principle (penetrators with increased lateral action), however, the achievable lateral velocities, depending on the type and mass of the pyrotechnic composition used and the structural design, are borders. This quite corresponds to the objective of such penetrators or warheads, since the actual end ballistic performance is provided by the projectile velocity. The functional principle of a projectile according to the ALP principle is the active decomposition of a penetrator before reaching the target in fragments or sub-projectiles. The speed of these components results from the small amount of explosive used, the energy is transmitted via an inert transmission medium according to the shockwave theory and the materials used to the outer active component. The speeds of these active components are between a few m / s and about 200 m / s. The effectiveness or the breakdown power of the active parts is thus dependent primarily on the speed of impact on ALP projectiles as in conventional balancing projectiles.

Previously known at blasting systems arrangements are limited to the charge structure and the design of the splinter shell. A representative example of charge build-up is described in US Pat. No. 5,243,961. It is primarily intended to achieve lower ammunition sensitivity by surrounding a volatile internal explosive component with a more inert component. The main purpose of modifications is to ensure the detonation of the entire charge in order to achieve a sufficient splitter speed. In principle, however, these are pure fragmentation projectiles of conventional type. The interface between the explosive components is preferably of star-shaped design. There are given a variety of possible combinations, which differ essentially only by the explosive content of the mixtures and different additives. The outer layer may also consist of a chemically reacting substance, e.g. for gas generation.

In the case of warheads and missiles, it is the stated goal to achieve the most gentle possible acceleration of sub-projectiles or externally attached containers by means of explosive deposits by means of special superstructures. As a state of knowledge, the two documents DE 35 22 008 C2 and EP 0 71 8 590 A1 can be used. Thus, in DE 35 22 008 C2, the fragmentation effect of the missile 10 from the shell 1 2, the warhead 1 1 to the Engine 1 6. It is generally stated that a certain shell thickness is sufficient to produce the desired breakdown power. This refers exclusively to targets to be controlled by missiles. A transfer to ammunition is not possible. Also, no physical laws are addressed and no general design rules are mentioned. When hitting the entire body is largely or completely hollow, so there is no Dämämmseffekt. The claim that it is not necessary to place a high explosive mass over the entire cross section of the missile in order to achieve a high penetration rate, refers to the explosive occupancy of the inside hollow warhead mantis. Because the interior of the missile is undoubtedly formed by the drive, the control devices and a Wirkladung. The inner shell 1 2c is assigned no function in connection with the splitter shell. Instead, it represents the housing of the engine with the control elements. This is also expressed by the fact that an insulating layer 19 of heat-insulating material is arranged between this jacket 1 2c and the explosive coating. The decisive advantage of an internal dam, which is equivalent in effect to the achievable splitter speed to the influence of the explosive thickness, is not addressed and can not occur in the proposed arrangement.

EP 0 71 8 590 A1 describes the active part of a rocket or a warhead, which accelerates preformed elements to increase the lateral effectiveness by means of a bombardment of explosive material which is annular in cross section. The main objective of the described construction is to convert the high detonation velocity of the explosive layer into a relatively low velocity of propagation of the accelerated elements or active parts. The explosive ring 43 accelerating the active parts is initiated via a ring of pellets (ignition elements 82). The explosive jacket 43 is basically identical in construction and function with the arrangement described in DE 35 22 008. The property of the explosive or of the explosive mixture influences in particular the propagation velocity in connection with the dimensioning of the surrounding sub-projectiles (56). Furthermore, projectiles are known which contain a pyrotechnic charge to increase the end-ballistic effect. A representative example is U.S. Patent 3,302,570. It describes a type of bullet designed primarily for the purpose of breaking armored steel protection structures while minimizing the required projectile energy. This goal is achieved by a massive penetrator with a relatively small diameter and relatively large length of heavy metal as the core of the projectile structure. In addition, the effect in or behind the target should be increased by the use of explosives or fire. The effect of two incendiary devices and the bullet-specific disruption processes are named as factors in addition to the actual target strike.

A high density combustible material encloses a penetrator with a thickened head. The material of high density surrounding the penetrator gives the penetrator additional mass and thus projectile energy and also penetrates through the hole punched by the penetrator head. Due to the larger diameter of the head stripping of the combustible material should be prevented. By breaking the penetrator when passing through harder targets, the combustible material is ignited and splinters are generated or burned spent in the target. In the rear of the projectile, the central penetrator and the combustible material surrounding it are surrounded by the actual projectile body, which is required to stabilize the projectile in the pipe and in flight. By means of a cutting edge on the hardened front edge of the projectile body, the hole of the target material already penetrated by the central main penetrator is to be enlarged and caused by entrainment of target material greater damage inside. In order to fill the space between the central penetrator (1 3) and the projectile body (1 7), another layer of a combustible material (1 6) low density is introduced. The additional layer should hold the central penetrator in its position. When smashing the bullet when entering harder targets, the incendiary charges are ignited. The inventive approach is therefore different from the present invention. In US 3,302,570 flammable materials are conveyed to the target, which are ignited due to the end ballistic processes. There is no talk of pressure build-up in the interior of the projectile. This bullet shape is not Explosive projectile in the true sense. A function according to the present invention is not intended and is not addressed indirectly.

SUMMARY OF THE INVENTION

The present invention is based on the consideration that in conventional blasting projectiles, a significant proportion of the pyrotechnic components can not make any appreciable contribution to splinter acceleration. As a result of the detonation of the explosive, it is dissociated, and the splinter shell is essentially accelerated by the resulting reaction gases. The lateral acceleration of the splinter shell causes an immediate increase in volume and thus relaxation, so that the pressure components of the explosive inner body can only deliver a correspondingly reduced acceleration component.

The aim of the present invention is an endbailistisch high effectiveness of fragment-forming projectiles and warheads regardless of the impact velocity when using the lowest possible explosive mass. This is achieved by combining an explosive casing with a damming inner body in conjunction with an accelerated to high speed outer shell. By this arrangement, not only the best possible implementation of the explosive energy is achieved, but it also opens up a large constructive scope for the design of such ammunition or warheads. The achievable with relatively low explosive occupancy splitter or subquota speeds are between a few 100 m / s to near 2000 m / s and are thus close to those of pure blasting. The explosive compression of the inner damming body results in a wide field of additional possibilities of action. In particular, it is possible to use the inner body to increase the performance of the entire system. Examples include the use of special materials, multilayer arrangements, the introduction of sub-floors and the integration of an additional central pyrotechnic component for disassembly and / or acceleration of the inner body. Furthermore, by the design of the inner dam a direction-controlled effect of the splitter to achieve the conventional explosive projectiles in this form not possible. Special effects can also be achieved by integrating reactive damming components in the penetrator or warhead interior. In conjunction with constructive advantages and the possibility of using further active components, the overall performance of the splinters of accelerating ammunition proposed here is far above those of known explosive projectiles or special munitions.

Essentially, the present invention relies on the effect of an inner dam in conjunction with a significantly lower explosive mass to achieve comparable slab or sub-floor velocities as compared to conventional explosive projectiles. An estimate of the achievable splitter speed is made below.

Basically, the velocity of the envelope is determined by three largely independent effects: the mass distribution between the shell to be accelerated and the inner support, the energy of the explosive layer (energy per unit volume and thickness), and the considered area element size (influenced by the forming element) splitter sizes). This fact is illustrated by the theoretical estimation of the fragmentation velocity, which can be done, for example, using the Gurney equation known from the relevant literature. There are two approaches to the present arrangement: one assumes a cylindrical shape, the other is based on a development of the cylindrical structure in order to obtain a planar surface element. This would then correspond in a first approximation to a reactive protection arrangement. Not only does the mass distribution of the two accelerated sheets (ie the damming ratio) play a decisive role, but also the sandwich size. With a 10 mm thick explosive layer and a 5 mm thick steel casing as well as a strong one-sided dam, for example, according to Gurney, velocities of 1,500 m / s result for very large areas. With a 10 mm thick rear sheet still 750 m / s are calculated. With a narrow sandwich (strip) about 60% of these values are still reached. Further calculation examples: Without boundary effects (assuming a sufficiently extended element size), the theoretical speed is 5 mm steel occupancy, large explosive thickness (> 20 mm) and high internal dam above 2,000 m / s. With a shell thickness of 5 mm and a 5 mm thick explosive layer and an internal dam by an aluminum hollow cylinder with a thickness of 20 mm, the initial splitter speed is in the order of 1 000 m / s and the speed of the inward accelerated hollow cylinder due to the relatively low dam still at about 500 m / s. When combining an 8 mm thick steel shell with a 20 mm thick explosive layer and a different inner dam, the values vary between 800 m / s (high dam) and 200 m / s (low dam). These calculation examples also show that with arrangements according to the present invention it is possible to cover a wide range of splitter and sub-floor speeds, respectively.

In estimating the fragmentation velocity of cylindrical structures, a Gumey equation for conventional explosive munitions may be used: v = D / 3 (M / C + 0.5) - ⁰ ' ⁵ with D as the velocity of detonation, M as the mass of the envelope (of Container, the occupancy) and C as explosive mass. In this case, D / 3 can be assumed to be a good approximation to the characteristic Gurney speed. The splitter speed is thus proportional to the detonation velocity of the explosive used. For general considerations, D / 3 values between 2,600 m / s and 3,000 m / s (mean 2,800 m / s) can be assumed. This formulation is helpful, since it is usually the detonation velocity that is known rather than the Gurney velocity.

The following calculation examples are intended to illustrate the conditions in this approach: With an outer diameter of 100 mm and a wall thickness of the shell of 10 mm (inner diameter 80 mm) and a thickness of the explosive layer of 5 mm results in splinter / shell speed 25% of the Gurney speed , At an inner diameter of 40 mm (ie at 20 mm explosive layer thickness) results in 45% of the Gurney speed, ie about 1 .260 m / s. With an inside diameter of 60 mm and a 10 mm thick explosive layer, 35% of the Gurney speed (about 1 000 m / s) is calculated. With shell filled with explosives, this results in 50% of the Gurney speed, ie approx. 1,400 m / s. With an ideal one-sided (internal) dam and a very thick explosive layer (> 30 mm), the gurney speed is approximately reached for large areas (or diameters).

About the inner dam, which is a central feature of the invention, the optimal implementation of the explosive energy in fragmentation speed, so that correspondingly high speeds are possible at relatively low explosive thicknesses. The influence of the inner dam can be taken into account by a factor, which should be referred to as Verdammungsfaktor (VF). It depends on the quantities M / C, Mmnβrβdam / MHuiie, rhoKem, sigmaKern and the Hygoniot properties of the inner medium. The following estimates can be assumed: Thick sheaths and thick explosive layers as well as thin sheaths and thick explosive layers result in a factor of 1, 1 to 1, 2. This corresponds to a speed increase of 10% to 20%. A thick shell, combined with a thin explosive layer and a thin shell with a thick layer of explosives, results in a damming factor of 1, 2 to 1, 3 (20% to 30% increase in speed). This not only high dams and corresponding explosives can be achieved very high splitter speeds up to about 2,000 m / s and strong Hüllfragmentierungen, but on the other hand on low damming inner body and inert explosives relatively low splinter or sub-floor speeds achieve with correspondingly gentle acceleration.

BRIEF DESCRIPTION OF THE DRAWINGS

1 A Basic structure of a spin-stabilized explosive layer chip projectile with splinter shell, explosive layer and damming inner body and and control or ignition elements.

Fig. 1 B Basic structure of an aerodynamically stabilized explosive layer-splitter projectile with splinter shell, explosive layer and damming inner body and and control or ignition elements. Fig. 2 Example of the cross-sectional design of an explosive layer-fragment projectile with splinter shell, explosive layer and damming inner body.

3 shows a cross section through an explosive layer fragmentation projectile with a damming inner ring or damming hollow inner body.

Fig. 4 Cross-section of an explosive layer-splitter projectile with multi-layer damming internal structure.

5 shows an example of the cross-sectional configuration with a circular outer cross section and any (here octagonal) inner cross section of the explosive layer.

6 shows an example of the cross-sectional configuration with a damming inner body and a circular inner cross section and any (here octagonal) outer cross section of the explosive layer.

7 shows an example of the cross-sectional configuration with any (here square) cross-section of the damming inner body and segmented. Detonation cross section / explosive surface segments (here: separated by the inner body with simultaneous or not simultaneous ignition).

8 shows an example of the cross-sectional configuration with an inner body of arbitrary (here triangular) cross section and inert, pressure-transmitting compensation segments between inner body and explosive layer.

FIG. 9 shows a cross-section with a plurality of (here two) hollow hollow inner bodies and a dynamically acting layer between the explosive layer and the inner wall (top) and / or between the different inner blends (bottom).

10 shows a cross-section with a damming inner body and a dynamically acting layer between the explosive layer and the splinter shell.

Fig. 1 1 Example of the cross-sectional design with outer shell / bullet jacket and underlying fragmentation shell (top) and an additional, dynamically acting layer between the explosive layer and splinter shell (bottom).

Fig. 1 2 Example of the cross-sectional design with outer shell and fragment body / preformed projectiles / thermal or mechanical fragmentation measures containing intermediate layer. Fig. 1 3 Example of the cross-sectional design with (here square) damming inner body and explosive segments with planar / linear / punctiform ignition device in the explosive layer (above) or with introduced into the inner body ignition elements.

14 shows an example of the cross-sectional configuration with arbitrarily (in this case square) shaped explosive surface and pressure-transmitting segments between the explosive layer and the fragment casing or projectile casing.

Fig. 1 5 Example of the cross-sectional design with two-layer explosive composition and two Dämämmungsschichten.

Fig. 1 6 Example of a projectile or a warhead with multi-part inner body (here consisting of four circle segments of the same or dissimilar material) with central pyrotechnic body.

17 Example of a projectile or a warhead with multi-part inner body (here four cylindrical penetrators) with central pyrotechnic body (top) or inert central body or empty inner volume.

Fig. 18 Example of the cross-sectional design with projectile casing / geometrically shaped inner surface of the splitter shell / correspondingly shaped explosive layer and inner insulation.

Fig. 1 9 Example of the cross-sectional design with geometrically shaped inner surface of the splinter shell and correspondingly shaped explosive layer.

Fig. 20 Example of the cross-sectional configuration with geometrically shaped inner surface of the explosive layer (above) or explosive longitudinal strips or explosive surface elements (below).

Fig. 21 Example of the cross-sectional configuration with internal insulation and introduced into the explosive layer separating elements or geometric structures (here longitudinal strips).

22 shows an example of the cross-sectional configuration with a hollow hollow inner ring and a central / damming inner body designed as a container.

Fig. 23 Example of the cross-sectional configuration with a damming central container (top) or a central inner body and a provided with webs space between the explosive layer and inner body.

Fig. 24 Example of a longitudinal section with splinter shell, explosive layer, damming (here two-part) inner body and control or ignition elements for the explosive layer.

Fig. 25 Example of a longitudinal section with variable explosive thickness and cylindrical fragment shell (top) and with variable fragment shell and explosive thickness (bottom).

FIG. 26 shows an example of a longitudinal section with explosive layer / inner-body diameter jump (above) or split-body damming / inserted penetrator body or penetrator ring (bottom). FIG.

Fig. 27 Example of a longitudinal section with a diameter jump of splinter shell and explosive layer.

28 shows an example of a longitudinal section with multi-part (here separated) explosive layers and (here) different splinter shell diameter (top) or continuous explosive layer with a diameter jump (bottom).

Fig. 29 Example of the geometric design of the splinter shell to achieve desired effects or preferred splitter directions. Here: Direction control and rotation of the fragment body / splinter rings and continuous explosive layer with cylindrical damming inner body.

Fig. 30 Example of the geometric design of the splinter shell to achieve desired effects or preferred splitter directions. Here: Direction control of the fragment bodies and separate explosive layers and geometrically adapted damming inner body.

Fig. 31 Example of the geometric design of the splinter shell to achieve desired effects or preferred splitter directions. Here: explosive charge for different splinter directions and splitter speeds.

FIG. 32 shows an example of a longitudinal section through an explosive layer fragment projectile or warhead with an explosive-laden fragment body inside and a gap between the outer shell and. FIG Sliver body and an empty or partially filled outer ballistic hood (top) or a solid / filled top (bottom).

Fig. 33 Example of a longitudinal section with complete explosive coverage (projectile body and tip area - top) and explosive-filled tip (bottom).

Fig. 34 Example of a longitudinal section with an explosives body inserted into the damming interior.

35 shows an example of a longitudinal section with a core (top) embedded in the damming inner region or a slender cylinder with a tip (bottom).

FIG. 36 shows an example of a longitudinal section with a pointed core embedded in the damming inner region with focusing / deconvolutioning explosive backing (top) or core with step tip and centering (core accelerating) explosive backing (bottom). FIG.

37 shows an example of a longitudinal section with a geometrically designed inner body and corresponding explosive composition for directional splintering action (top) or with splitter directivity through shaping of a damming inner body, explosive surface and splinter casing (bottom).

Fig. 38 Example of a longitudinal section corresponding to FIG. 37 with additional splitter components.

Fig. 39 Example of a longitudinal section with (here) two-stage directional fragmentation effect and continuous explosive charge (top) and not continuous explosive charge (bottom).

40 shows an example of a longitudinal section with additional, primarily axially accelerated splinter cone in the front region of the projectile, accelerated by an explosive surface.

Fig. 41 Two examples of a longitudinal section with pronuclear / step core as damming medium.

Fig. 42 Example of the cross-sectional design with explosive-accelerated individual segments. Fig. 43 Example of the cross-sectional configuration with variable thickness of the

Shrapnel mantle and (here four) explosive segments with lenticular (basically free to design) cross section.

FIG. 44 shows an example of the cross-sectional configuration with a shaped explosive surface and adapted inner damming body. FIG.

Fig. 45 Example of the cross-sectional design with (here eight) segments and free-form explosive surface.

Fig. 46 shows examples of a longitudinal section with a multi-part damming inner body (e.g., radially and axially divided).

47 shows an example of the cross-sectional configuration of a projectile or warhead according to FIG. 42 with a damming inner body, constructed here from cylinders in a pressure-transmitting matrix.

48 shows an example of the cross-sectional configuration of a projectile or warhead according to FIG. 43 with a segmented, single-layer or multi-layer damming inner body and a central penetrator.

Fig. 49 Example of a longitudinal section, executed as a multi-part active body (different levels with different functions) and different configuration or occupancy.

Fig. 50 Example of the arbitrary cross-sectional configuration of an explosive layer chip projectile or warhead.

Fig. 51 Further example of the arbitrary cross-sectional configuration.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS FIG. 1 A shows the basic structure of a spin-stabilized explosive layer chip projectile 1 A with a fragmentation shell / splinter shell / fragmentary projectile shell 2, an explosive layer / explosive substance / explosive surface / pyrotechnic layer 3 located underneath the shell and a damming inner body 4 Indicated are integrated ignition elements with control or ignition electronics for the explosive layer. The triggering and triggering of the explosive layer must be adapted to the respective state of the art. The effectiveness of the arrangement remains largely unaffected. The functional principle according to the invention likewise allows the application to aerodynamically stabilized projectiles, as shown schematically in FIG. 1B. Again, the basic structure of the explosive layer chip projectile 1 B with splinter shell 2, explosive layer 3 and damming inner body 4 and ignition elements or other projectile or warhead devices is shown. The positioning of the ignition elements is not relevant to the function of the fragment-forming projectile; they can be accommodated in the floor of the floor, in the damming inner body 4, in the projectile nose or as modules at several points (cf., for example, FIGS. 24 and 45).

In Figs. 2 to 23 and 42 to 45 and 47 to 51, examples of the cross-sectional configuration of projectiles or warheads according to the present invention are shown.

Thus, Fig. 2 shows the cross section through an inventive explosive layer chip projectile with splinter shell 2, explosive layer 3 and damming inner body 4. In the illustration, which shows the simplest variant of the possible designs, the damming, dynamically correspondingly incompressible inner body 4 as solid, homogeneous formed cylindrical member. As materials for the damming component are basically all materials into consideration, which cause a desired dynamic dam. Their dynamic properties, and in particular the consequent degree of damding, are determinative of the achievable splinter speed or the required explosive thickness for achieving a desired acceleration of the casing. Because as already mentioned, the dam is equivalent in its effect on the achievable splinter speed to the influence of the explosive thickness

Further impact-relevant properties are the geometric dimensions of the fragmentation shell or its mass and also their mechanical dynamic properties. However, it is a particular advantage of the invention that no special demands are placed on the individual components. So almost all properties can be achieved by a suitable choice of material without high technical complexity. In Fig. 3 the cross section through an explosive layer-splitter projectile with damming inner body 5 is shown. In this case, it has an annular cross-section which surrounds a cavity 6. Thickness and material of the ring 5 are to be chosen so that a sufficient dam of the explosive layer takes place. The explosive zone can be composed of one layer as well as of two or more identical or different layers. For the basic function, incompressibility of the damming medium is not a mandatory requirement. Rather, the degree of compressibility affects the achievable speed of the splitter to be accelerated.

4 shows a cross-section with a multi-layered damming internal structure, with a second inner body / central body 7 being located in the damming inner jacket / inner body 5 designed as a hollow cylinder. Of course, components 5 and 7 may have different mechanical or physical properties. It is also conceivable that an inner body is first compressed and only then causes a sufficient or increased dam. Furthermore, it is conceivable that takes place by the design or the structure of the inner body a temporally changing Verdämmungshöhe corresponding to the technical requirements. This property can be called a loss of insulation. For this purpose, a whole range of materials with corresponding Hygoniot curves is suitable. According to these considerations, particularly interesting effects can be achieved with materials which have specific Hygniot properties. These include e.g. Glass or vitreous substances or liquid or pasty components.

FIG. 5 shows an example in which the explosive layer 3A has a circular shape on the outside and an arbitrary shape on the inside (octagonal in this example). The damming inner body 8 shows a corresponding contour. The explosive layer (the explosive shell) 3A can exert a differentiated effect on the splitter shell by virtue of its shape. This can support fragmentation and influence the fragment shape and splinter speed. For the properties and the technical or material-specific design of the fragmentation shell or the projectile or warhead mantle basically all embodiments and technological possibilities come into consideration, which are known in connection with conventional fragmentation projectiles.

6 shows an example with a damming inner body of the explosive layer 3B, which here has an octagonal outer cross section and a circular inner cross section. Of course, other design options / outer shapes of the explosive layer 3B are conceivable. The splinter shell 2A has an octagonal inner contour corresponding to the shape of the explosive. Thereby, e.g. the fragmentation process of the envelope can be influenced by means of different shell thicknesses, densities and explosive layer thicknesses and by means of pyrotechnic properties.

7 shows an example with a basically arbitrary, in this example square cross section of the damming inner body 9. By the contact surfaces / contact surfaces of the inner body 9 with the splitter shell 2, the explosive body / the explosive part under the splitter shell 2 is separated in this illustration by the inner body , This results in a segmented detonation cross section or explosive surface segments are formed. In this case, a simultaneous or non-simultaneous ignition of the explosive segments 10 is possible. The damming inner body 9 can of course also be dimensioned so that the explosive shell is closed for a ring ignition. The inner body 9 may e.g. be held in position by means of webs.

In Fig. 8, an inner body 1 1 is combined with (in this example) a triangular cross-section with inert, pressure-transmitting compensating segments 1 2, which fill the space between the outer surfaces of 1 1 and the annular (cylindrical) explosive shell 3. These inert segments 12, for which the same conditions apply to the materials as for the damming inner bodies, can be formed as fragment-forming bodies. Besides, they can contain additional active parts. Of course, these segments can also be assigned other functions. Thus, for example, they can be manufactured as sub-penetrators, for example made of heavy metal, hard metal or hardened steel, for achieving end-ballistic performances.

Another construction for a projectile according to the invention is shown in FIG. Shown are two variants of cross sections with dynamically effective inner layers / ring surfaces. This dynamic efficiency derives from the specific properties of the layer relative to the passage of shock waves. The interfaces between the dynamic layer and the adjacent materials are crucial. The physical properties result from the acoustic impedance. This determines the reflectance of the shock waves in the interface between two media by the ratio m-1 / m + 1 with m as the quotient of the products density and longitudinal speed of sound of the two media.

The upper part of Fig. 9 shows a projectile cross-section with two damming, hollow inner bodies 5, 5A and a dynamically acting layer 13 between the explosive layer 3 and the dam 5. In the center is here still an additional body 7A, for example, a central penetrator. The lower part of the illustration shows a dynamically effective layer 13A between the damming first body 5 and a second damming layer 5A as an inner part in FIG. 5. As a result, the dynamic effects described above can be achieved, such as, for example, FIG. B. buffering (shock-absorbing or the Stosswellendurchgang influencing or shock-enhancing) properties for temporal influence on the shock or insulation effect and thus the fragmentation speed, splintering and / or splinter distribution.

FIG. 10 shows a cross section with a damming inner body 4 and a dynamically acting layer 13B between the explosive layer 3 and the splinter shell 3. Due to the properties and structure of the dynamic layer 13B, the acceleration effect of the explosive layer 3 on the splinter shell 2 can be influenced. A similar construction is shown in the lower partial cross-section in FIG. 11, in which case the dynamically effective layer 13C is positioned in the outer, fragment-forming region of the splitter outer casing 14, which consists of two parts. As a result, the fragment development of the overlying fragmentation shell 2 is to be influenced. In the upper partial cross section, an example with outer shell / shell jacket 14A and underlying fragmentation shell 2 is shown. The design of the outer projectile casing 14A can not only be derived from internal ballistic requirements, but this can also develop a dynamic effect in the sense described.

Fig. 1 2 shows an example with outer shell 14A and a fragment body or a matrix 16A. Here preformed projectiles 16 or other ballistically active elements such as fragment-forming bodies 15 can be embedded. The acceleration / activation in turn takes place through the explosive jacket 3. In the inner body 17 is here an ignition element 1 8 embedded, which can support or cause an additional decomposition of the damming component. By embedding an ignition element 18A in FIG. 17, a dynamic compression effect can also be achieved by the formation of a pressure field. In this way, e.g. a disassembly of 17 after arrival or only be initiated inside the destination.

FIG. 13 shows further examples with integrated ignition elements. The cross-sectional design here includes a (in the representation square) damming inner body 9 and explosive segments 1 OA. In the upper part of the image contains the explosive layer or the explosive segment 1 OA an ignition element 18A, which may be formed as a planar, linear or punctiform device. In the lower part of the illustration, a corresponding ignition element 18B is introduced into the inner body 9.

Fig. 14 shows an example of the cross-sectional configuration with basically any shaped, in this example square explosive surface 3C. Between 3C and the chip layer 2 are pressure transmitting segments 1 2A. The damming inner body 9 has a corresponding to the explosive layer 3C square cross section. The segments 1 2A, in turn, in addition to their pressure-transmitting function to meet a number of other specific requirements, such as having a damping or the splitter speed of 2 influencing effect. In this case too, as in FIGS. 5 to 7, different splitter speeds or splinter shapes can be set for the fragmenting splinter shell, in this case due to the different thickness of the active segments 1 2A.

FIG. 15 illustrates an example with two-layer explosive coating 1 9, 20 and correspondingly two insulation layers 4A, 21. The ignition of the explosive deposits can take place simultaneously or with a time offset. Such a structure results in a particularly wide range of effects. Thus, for example, the outer layer in front of a target, the inner component in the target passage or only in the target interior are ignited. In this case, the inner damming layer 4A may be made to have end-ballistic performance, i. it can be a penetrator. In this way, it is possible to achieve a broadly staggered power development optimally adapted to the task of control.

In Fig. 1 6 an example is shown with a multi-part damming inner body 23, which is here composed of four circular segments 24, which may consist of similar or different materials. Between the segments 24, layers 25 may be located. These may be designed as dynamically effective layers in the sense of the above description, ie consist of rubber / elastomeric materials or of materials with plastic or damping properties. The individual components 23 may be loosely mounted or fixed, eg connected by gluing, screwing or vulcanization. The projectile structure is provided in this example with a central pyro- technical body 22, which provides an additional decomposition / lateral component (especially for the individual components 24). The segments 24 can in turn be fragment-forming, contain bodies or have their own end-ballistic performance in the sense of central penetrators. FIG. 17 shows two further examples with multi-part damming inner bodies / central penetrators 26. These consist, for example, of four cylindrical penetrators 27. In the upper part of the image, in the center of the cylindrical penetrators 27, there is a central pyrotechnic body 22A, which gives the inner body 26 designed as a combination of penetrators a lateral velocity component. In the lower part of the image, instead of 22A, there is an inert central body 28 (or an inner space) between the components 27A. The explosive layer 3D surrounding the inner body 26 has a different thickness due to the shape of 26 and 27, respectively. This results in a different local acceleration of the sheath fragments. The explosives can be interrupted by the elements introduced (above) or through them (below).

FIG. 18 shows an example with projectile casing / casing 14A, a splitter casing 29 with a geometrically designed inner surface, a correspondingly shaped explosive layer 33 and the inner insulation 4. The shape elements 31A reaching into the splinter casing 29 cause a local weakening of the splinter casing 29 achieved, which allows the fragmentation in a determinable manner (eg strip-like, latticed to form certain fragments). There are different configurations of the elements 31 A shown. A corresponding principle is based on the cross-sectional configuration with a geometrically modified inner surface of the splitter jacket 32 and the correspondingly shaped explosive layer 31 in FIG.

In FIG. 20, the inner surface of the explosive layer 34 is geometrically designed in the upper partial image, the explosive layer forming a closed jacket here. In the lower part of the picture, the explosive component 35 is composed of explosive longitudinal strips or explosive surface elements 36. The correspondingly shaped inner body 4C acts as a separation between the individual explosive components.

The principle of the segmented explosive shell is also realized in FIG. 21. The example shows the cross-sectional design with internal insulation 4 and in the Explosive layer 36A introduced separating elements or geometric structures basically any configuration. In the present example, they represent longitudinal strips 37.

Fig. 22 shows an example with a hollow hollow inner ring 21 and a central body (also possibly supporting the dam) designed as a container with the wall 38A. The filling 39 of the container may be for example a solid, a pasty or liquid substance or an inhomogeneous conglomerate of elements.

Also shown in Fig. 23 are cross-sectional shapes with containers. In the upper Teilbiid the projectile is provided with a damming, filled with a liquid, pasty or with a compacted powder mass 39 central container 38. In the lower part of the figure, an annular inner container 38B is connected to the wall 38C and the filling 39A by means of webs 38D with a central inner damming body 4B. Depending on requirements, the webs 38D may be designed as independent active parts (inert or pyrotechnically effective).

According to these examples of the cross-sectional configuration of arrangements according to the present invention, a number of examples for the design of the longitudinal sections of corresponding projectiles or warheads follow in FIGS. 24 to 51.

Thus, FIG. 24 shows a longitudinal section with splinter casing 2, stepped / variable-thickness explosive layer 3 and a multi-part damming inner body 41. Plotted with positions for the installation of control or ignition elements for the explosive layer. The damming inner body 41 is here formed in two parts. In this way, different splitter speeds and / or different splitter distributions can be achieved in the longitudinal direction. In the head or in the bottom of the projectile Steuerbzw. Ignition elements 40 to be installed, which of course also applies to the other presented bullet structures according to the invention. FIG. 25 shows a longitudinal section through a projectile with variable explosive thickness and cylindrical fragment shell in two variants. The upper part of the diagram shows an arrangement with a longitudinally variable explosive layer 42 and correspondingly shaped dam, the lower partial image shows a variant with a thickness-variable fragmentation jacket 43 and variable explosive layer 42A.

In Fig. 26, the explosive layer / inner body has a diameter jump. The projectile shown in the upper part of the image has a variable thickness of the explosive layer 44 with a continuous damming inner body 45 with a diameter jump or a different diameter change. The lower part of the picture shows a projectile with a divided damming body or an inserted penetrator or penetrator ring 41 A with different diameters. Depending on their nature, the inner bodies can fulfill different functions.

Fig. 27 shows an example of the variable thickness of the explosive jacket 44A and the cylindrical inner body 4. The splinter shell 45 and the explosive layer 44A have a diameter jump or a continuous diameter change.

In the examples in FIG. 28, the upper variant is provided with multipart, here separated explosive layers 47 and adapted splinter shell 45. The damming, stepped inner body 46 accordingly shows a variable diameter. The projectile shown in the lower part has a continuous explosive layer 48 with a change in diameter.

Arrangements in accordance with the present invention make it possible to achieve highly effective combinations or designs of splinter casings and explosive layers in a technically particularly simple manner. Starting from a projectile according to FIG. 24, examples are shown in FIGS. 29 to 31. Thus, Fig. 29 shows a geometric configuration of the splinter shell for achieving desired effects or preferred splitter directions. Here, directional control and rotation of the fragmentation body / splitter rings 50 are effected. The longitudinal sawtooth-shaped explosive layer 49 is provided here continuously with a cylindrical damming inner body 4. The example with separate explosive layers 49A shown in Fig. 30 effects directional control of the splitter bodies 50A. The damming inner body 4 is geometrically adjusted. FIG. 31 shows a splitter assignment 51 for different splitter directions and splitter speeds with correspondingly adapted explosive layer 49B.

In Figs. 32 to 34 and 37 to 41 further embodiments of the arrangement according to the invention are shown by the combination with designated projectile components. FIGS. 35 and 36 show examples of the integration / combination of arrangements with penetrators.

Fig. 32 shows two longitudinal sections with internal explosive occupied splitter body 2 and a space 52 between the outer shell 14B and fragment body and an empty or partially filled outer ballistic hood 53 (upper part of the picture) and a solid / filled tip (lower part). This representation represents, for example, subcaliber projectiles, projectiles with sabot or full caliber bullets with inner active part of smaller diameter.

33 shows two longitudinal sections with complete (continuous) explosive coverage 3 and 54. The upper partial image shows the projectile body and the inside dammed tip area 55, the lower partial image of an explosive-filled tip 56th

FIG. 34 shows a longitudinal section with an explosive body 57 inserted into the damming inner region 4 of basically any shape. Such an explosive component can locally cause particularly high lateral splitter velocities or even desired effects in the body 4 itself Compressions or mechanical loads to disassembly or accelerations effect.

FIG. 35 shows two longitudinal sections with a hard or heavy metal core 58 (upper partial image) embedded in the damming internal region 4 and a slender cylinder with a tip 59 (lower partial image). Of course, any variant of an end ballistic effective body can be introduced. The combination of breakdown power and fragmentation shown here covers a particularly broad range of effects.

FIG. 36 shows two examples with a core 58A embedded in the damming interior (here, pointed) with a focussing, inwardly conical rear region 60 of the core. By means of the explosive deposit 61, an acceleration and / or a decomposition of the core 58A can be effected (upper partial image). The lower part of the figure shows a core with stepped tip 58B and conical rear part 62 with centering, the core accelerating explosive deposit 61 A. The effective directions of the configurations of the rear area with core and splinter shell are symbolized by the arrows 6OA and 62A.

In Fig. 37 are two longitudinal sections with inner body 64 and corresponding Sprengstoffbelegung 63 in conjunction with a top module 72 for directional increased fragmentation effect in the axial direction (upper panel) and with splitter directivity by shaping of damming inner body 64, explosive surface 66 and fragmentation shell 65 (bottom Partial image). The corresponding arrows 72A, 65A, which symbolize the directions of action, are also shown (see also FIG. 40).

FIG. 38 shows a longitudinal section corresponding to the lower part of FIG. 37 with splinter jacket 67 and additional fragment components in a splitter pocket or splinter ring 68 with the embedded active parts 68A (knitting arrows 68B). 39 shows two longitudinal sections with (here) two-stage damming inner body 70A with directed fragmentation effect due to a special design of the damming inner body 70 or 70A and continuous explosive coverage 69 (top). as well as non-continuous explosive charge / separate explosive rings 69A (below).

40 shows an example with an additional, primarily axially accelerated splitter body 73 (symbolized by the action arrows 73A) in the front region of the projectile, accelerated by an explosive surface 71 of the splitter shell 3, which is also dammed up by the inner body 4.

Fig. 41 shows two longitudinal sections with partial explosive occupancy in the form of a damming body with pronuclear / step core 74 (top). Such a pronucleus 74A can also be introduced separately (below). For example, this pronuclear 74A may consist of a highly ballistic end hard material such as hard or heavy metal, or even a brittle material that disintegrates under dynamic load from the impact, such as highly brittle tungsten carbide or pre-fragmented bodies. It primarily serves to penetrate massive target plates. Due to the step-like training the attack on a tilted plate is improved or only possible.

FIG. 42 shows a cross-sectional configuration with explosive-accelerated projectiles or warheads according to the invention with individual (here four) segments 75. The individual segments 75 correspond in their function to those of the examples already shown with a circular cross-section. Due to the segmentation and the separation 76, which may be both a structure / supporting inner wall and a shock wave barrier, the individual segments can be controlled separately. This example therefore stands for penetrators or warheads with partial occupancy in the longitudinal / axial direction, in which the possibility of a subfield occupancy in the room is given by splinters.

Fig. 43 shows an example of variable thickness of the warhead effect jacket 77 and explosive segments 78 (here, four) of lenticular (in principle, however, free to formative) uerschnittsform ^Q. The inner contour of the explosive segments 78 is formed by the corresponding inner damming body 9A. It goes without saying that the splinter and the explosive layer according to FIG. 42 can run separately or continuously. By means of such arrangements very differentiated splitter distributions can be achieved, which are symbolized in FIG. 43 for a segment by the arrow field 78A.

Fig. 44 shows an example of the cross-sectional configuration with the explosive surface 80 as a convex stripe and with the female intermeshing body 9B fitted. FIG. 45 shows a corresponding example with (here eight) segments 81 with the explosive coating 8OA separated by the surfaces 75A. While in FIG. 44 the fragment-forming arrangement is in a shell 14, in FIG. 45 the fragment-forming (or homogeneous) stripes 79A are exposed. In addition, this example still has a central ring 82, which supports the dam 81 of the segments. Furthermore, the cylinder 82 may be hollow or contain a central penetrator.

FIG. 46 shows a longitudinal section through a basic projectile construction 83 with a multi-part damming inner body, which can be constructed from radial, axial or combined elements. In this way, the damming effect may be combined with mechanical pre-fragmentation, or different bodies with different mechanical and physical properties may be combined.

Fig. 47 shows the cross-sectional configurations of a shell of Fig. 46 with fragmentation shell and damming inner body 84, here constructed of cylinders 86 (continuous or stacked) of the same or different diameter or materials in a pressure transmitting matrix 85. The central region 87 may be formed by a penetrator be or also be filled with individual bodies. An additional pyrotechnic component according to FIG. 1 2 can also be incorporated. The cylinders 86 may have a higher degree of slimming (length / diameter ratio) or may be formed from a stack of short cylinders. 48 shows a further example of the cross-sectional configuration of a projectile according to FIG. 46 with segmented, single-layered or multi-layered damming inner body 88 and a central penetrator 82A. FIG. 49 shows a longitudinal section through an explosive layer splitter projectile 89, which is constructed as a multi-part / multi-stage active body. This can be formed, for example, from different, separated by a layer 91 or related stages with different functions or introduced construction spaces 90.

In the examples presented so far cylindrical fragmentation sheaths were shown. This is of course no mandatory requirement for arrangements according to the invention. By layer-like accelerating elements rather any shapes can be realized even with external components without any limitation of the effectiveness. As a result, there are no limits to the design possibilities. It is equally obvious that arrangements according to the invention are not limited to individual bodies. Precisely by the creative freedom, corresponding fragment-forming devices can be arranged in groups.

A few examples are shown in FIGS. 50 and 51 for this purpose. Thus, in FIG. 50, the splitter body 92 has a square cross section which is accelerated by an explosive layer 3F as shown in FIG. In Fig. 51, the fragmentation shell has an octagonal cross section 92A as an example of the arbitrary shape. The acceleration takes place here via an annular explosive layer 3.

Of course, the arrangements listed as examples can also be combined both in a projectile and in a warhead, if this makes sense.

The main features and advantages of the invention are summarized below:

The shatter-forming active components or sheaths containing fragments or sub-projectiles are accelerated by means of an explosive layer which is thin relative to the projectile or warhead diameter. The explosive mass needed to accelerate splinters is minimized. Compared with conventional explosive projectiles, the explosive mass can be reduced by 50% to 80%, depending on the caliber and technical design, at comparable splinter or sub-floor speeds.

The saved explosive mass is available as additional active mass. As a result, the scope in the interpretation of splinters or sub-projectiles accelerating projectiles or warheads is considerably expanded.

The least strength of the explosive layer is determined by ensuring ignition or spark ignition. By introduced ignition aids such as detonating cords very thin planar explosive layers can be ignited. Likewise, the choice of explosive is free, so that very small thicknesses up to an order of 2 mm can be realized.

Depending on the inner dam, thicker casings can be disassembled or accelerated to high speeds via larger explosive layer thicknesses. The theoretical maximum speed of the splinters is approximately reached with explosive layers in the order of 20 mm with high internal insulation.

The explosive layer may be in the form of a hollow cylinder and have a constant or variable wall thickness and / or cross-sectional shape.

The explosive layer can be prefabricated and incorporated as a film or as an arbitrarily shaped body, be cast in or introduced in any manner, such as e.g. pressed or sucked in by vacuum. It can consist of one or more superimposed layers.

A projectile or warhead may contain a continuous layer of explosive or may be composed of multiple explosive layers in both the axial and radial directions. The explosive layer may be homogeneous or contain admixtures or embedded bodies.

Ignition of the explosive layer or zones or explosive fragments may be accomplished in any conceivable manner in accordance with the prior art blasting projectiles or warheads.

By means of the type of ignition and the design of the explosive layer and the inner body, the speeds and the direction of the splinters or sub-projectiles can be varied within very wide limits.

The damming inner body can be one or more parts. It may consist of metallic or non-metallic materials or of their combination. There is thus an almost unlimited variety of materials with different mechanical, physical or chemical properties to choose from. Thus, a homogeneous metallic inner body on one side, e.g. consist of a metal of low density such as magnesium, on the other side of a heavy or hard metal body (homogeneous or segmented) high density with a correspondingly high end ballistic performance.

On the properties of the inner body or the inner body under high pressure load (Hygoniot properties) can be determined their behavior or it can be selectively selected materials with specific dynamic properties in conjunction with the pyrotechnic components used and the technical design of the projectile or warhead.

Homogeneous inert inner damming bodies may consist of or contain such metallic or non-metallic matter which is reactive under high pressure at locally high temperature.

Due to the combination possibilities with damming inner bodies, it follows that (eg through the use of different materials, such as by embedding of sub-floors in a matrix material) the design bandwidth are practically no limits.

The damaging inner body may be made of brittle or embrittled under dynamic load material. Likewise, he can pre-fragmented or mechanically or thermally pretreated yours.

The damming inner body can also be designed as a hollow cylinder or contain a cavity in any cross-sectional area. This inner cavity may in turn be empty or filled with a more or less damming substance. This results in another possibility for the influence on the dam and thus on the speed or acceleration of the shell of fragment-forming or sub-projectile projectiles or warheads.

In a particular embodiment, the damming inner body can represent or contain a container. The inner cavity or container may be e.g. be filled with a solid, powdery, pasty or liquid substance. Furthermore, it may contain a reactive substance, e.g. contain a flammable liquid.

In the simplest case, the shell of the projectile or the warhead is homogeneous. With regard to their pretreatment in support of fragmentation, it is possible to use all methods and techniques which correspond to the state of the art in conventional fragmentation projectiles.

The accelerated shell may also consist wholly or partly of preformed splinters or sub-floors. Such a layer may itself represent the projectile casing or be incorporated as a layer between the explosive and the outer shell. About this structure can be introduced between the explosive layer and the outer shell and a pre-fragmented or very brittle or embrittled under dynamic load layer. In a large caliber ammunition or warheads, it is also conceivable that between the explosive layer and the outer skin is filled with a pasty or liquid substance intermediate layer, which may also contain solids or individual body.

Between the explosive layer and the damming inner body there may be a layer dynamically supporting the dam. Their mode of action is determined by the acoustic impedance of the materials involved.

Likewise, between the explosive layer and the fragmentation shell, a medium having a dynamic damping action can be introduced as a layer which reduces the acceleration impact.

The explosive layer may be composed of contiguous surfaces or of surfaces separated in the radial or axial direction.

The explosive layer can have an arbitrarily shaped surface (contour), so that spatially different splinter formations and also splitter speeds can be achieved.

Through the shape of the inner dam, the explosive layer can form an angle to the projectile axis. Thus, splinters or sub-projectiles can be accelerated direction-controlled. Such arrangements may be provided at certain positions of the projectile (e.g., in the tip region) or extend over the entire surface.

The explosive layer will usually have the shape of a hollow cylinder. This can be open at the ends or closed on one or both sides by means of a front or rear explosive layer.

Explosive disks (explosive bridges) can be introduced over the entire penetrator length. Thus, for example, inner bodies can be accelerated in the axial direction. Parts of the tip can be accelerated via a frontal explosive coating. In addition, the tip of the projectile or warhead may be wholly or partially filled with explosives.

The tip or tip region may also consist of or contain an end ballistic inert body to effect end-ballistic effects via this component.

Further embodiments of arrangements according to the present invention result from the introduction of an additional pyrotechnic component within the damming inner body. This can either be ignited by the detonation of the explosive layer or be controlled directly. In such arrangements, e.g. In addition to splinters or sub-shot from the shell area radially accelerated elements are generated from the interior.

Function and efficiency of arrangements according to the invention are independent of the type of stabilization. Thus, the active bodies may be cannon-fired projectiles, combat components of a missile or missile, parts of a bomb or the active part of a torpedo.

LIST OF REFERENCE NUMBERS

A spin stabilized explosive layer chipboard with splinter shell 2,

Explosive layer 3 and inner body 4 B arrow-stabilized explosive layer - splitter projectile with splinter shell 2,

Explosive layer 3 and inner body 4 Fragmentation shell / fragmentation shell / fragmental projectile shell A Fragmentation shell with basically arbitrary (here octagonal) inner cross section Explosive shell / explosive substance / explosive layer / explosive surface / pyrotechnic layer A Explosive shell with basically arbitrary (here polygon) inner cross section B Explosive layer with basically arbitrary (here octagonal) External cross-section C Explosive layer with basically any (here rectangular) cross-section D with explosive-filled gap between 27 and 2 damming inner body / inner dam A dam for 20 B central inner body C inner body with surface structure hollow damming inner body / damming inner shell / inner ring / support ring A second (inner ) damming layer central cavity (arbitrary cross-section) second (here central) damming inner body A inner body / central Penetr Ator damming inner body with basically any (here octagonal cross-section) damming inner body with (basically any) here square cross section A damming inner body B damming inner body C damming inner body 0 explosive segment between 9 and 2 0A explosive segment between 9 and 2 1 central body with basically any (here triangular) cross section 2 inert / pressure transmitting segment (homogeneous or Containing body) / fragment forming segment between 1 1 and 3 2A inert / pressure transmitting segment (homogeneous or body containing) / fragment forming segment between 3C and 2 3 dynamically acting layer between 9 and 3 3A dynamic acting layer between 5 and 7 3B dynamically acting layer between 3 and 2 3C dynamic layer between 2 and 14 4 outer splitter ring 4A projectile shell / shell jacket / skin 4B projectile shell / warhead wall 5 splinters / preformed elements containing ring area between 14 and 3 6 bodies embedded in 1 6A / preformed spli or preformed projectiles 6A matrix of 1 5 7 inner body (central or decentralized) with embedded ignition element 18 8 ignition element (detonating cord) embedded in 17 8A ignition element in 10A, 18 8B in 10A inserted ignition element / ignition cable of any shape and cross section 9 outer explosive layer 0 inner explosive layer 1 inner working sheath / inner splinter ring (dam for 1 9 and splinter sheath for 20) 2 central charge (detonating cord) / pyrotechnic body A central explosive body for the radial acceleration or disassembly of 26 multi-part (here divided into four circular segment cross-sections 24) inner body single element of 23 separation / separation layer between the elements 24 multi-part, basically arbitrarily shaped inner body (here four cylinders 27 and 27A formed) Cylinder / body with basically any (here circular) cross section A body with basically any (here circular) cross section inert central body in 26 / interior / cavity fragmental wall with variable wall thickness / with incisions / with internal structure 30 incision / internal structure explosive layer with structured outer contour A Fragment / explosive web Splinter shell with structured / molded interior. Explosive shell with incisions Explosive layer with change in diameter / diameter jump / notches / notches on the inside segmented / interrupted explosive layer / explosive surface element A explosive strip / explosive segment separating layer / separating element / separating strip / separating grid between 36A central container / inner body A wall of 38 B container in the form of an intermediate layer C wall of 38B D bar / holder / Connection structure filling / content of 38 A filling / content of 38B / liquid ring Control / Ignition element 1 multi-part / multi-stage damming body 1 A multi-part damming body (same or unequal diameter) Explosive layer of variable thickness (here inner diameter variable) A as 42, outer diameter variable Splinter cover with variable thickness Explosive jacket with (here inner) diameter jump / diameter change 4A Diameter jump / Diameter change 5 graded fragment sheath / shard sheath with variable thickness 6 stepped inner body 7 divided / multi-part explosive sheath 8 explosive sheath with diameter jump / diameter change 9 explosive sheath (here continuous) for a directed splinter effect 9A explosive sheath of individual sections / employees, separate

Ring surfaces 9B structured (here consisting of ring surfaces with circular cross-section) explosive jacket 0 Splitter assignment to achieve a directional effect OA segmented splinter assignment of 49A 1 splinter shell of convex rings 2 cavity between 2 and 14B (empty or with internal structure) 3 tip with explosive shell 54 / external ballistic Hood 4 explosive layer in 53 5 damming inner body in 53 6 with explosive / a pyrotechnic medium filled tip 7 in 4 embedded explosive body 8 in 4 embedded penetrator (here hard, heavy metal or steel core 58) 8A core with rear inner cone 60 8B Kernel with a conical tail 62 9 central penetrator / cylinder embedded in 4 0 Rear inner cone in 58A OA arrows, symbolizing the effective direction of the explosive zone 61 1 explosive zone at the stern of 58A for acceleration / deconstruction of 58A 1 A explosive zone at the stern of 58B for acceleration of 58B 2 conical tail of 58B 2A arrows, symbolizing the effective direction of the explosive zone 61 A 3 explosive composition for partially reinforced axial fragmentation internal body in 63 A inner body in 65 5 Splinter shell with axial splinter effect 5A Arrow, symbolizing direction of action 6 Explosive shell 7 Splinter shell corresponding to 65 with splitter pocket 68 8 Splitter pocket / splitter ring 8A in 68 Embedded bodies 8B Arrows, symbolizing the effective direction of the splinter pockets 67 9 Explosive shell with variable inside diameter for directional splinter acceleration 9A Explosive shell elements for facing Splitter acceleration (here with sectional / multi-level explosive layer) 0 Damming inner body with outer contour for directional fragmentation OA Damming inner body with outer contour for directional splintering action 1 axially acting explosive zone 2 Point module with directional splinter effect 3 arrow, symbolizing direction of effect 3A arrows, symbolizing the effective direction of splinter assignment of 73 4 damming inner body with partial explosive charge 4A multi-part inner body with stepped tip 5 segment of a damming inner body with cylindrical contour 5A Segment of a damming inner body with cylindrical contour 6 separating surface 7 splinter casing 8 lenticular explosive segment / segment of arbitrary cross section 8A arrows, symbolizing direction of effect 9 splitter segment 79A splitter segment

79B accelerated splitter segment 79A

79C disassembled and accelerated splitter segment 79A

80 explosive ring of segments of any design 8OA explosives segment of any design

81 Segment of a damming inner body with any contour

82 inner body, central penetrator 82A inner body, central penetrator

83 Sectionally constructed / assembled damming inner body

84 Ring of rods / cylinders / body of any cross section

85 separating layer between 80

86 rods / cylinder / body of any cross section

87 central body

88 sectioned rings

89 storey with different damming inner bodies

90 inert section

91 distance / buffering inert element / separation layer

92 Splinter ring / fragment shell of any shape (here square) 92A Splinter ring / splinter shell of any (here octagonal) shape

Claims

1 . Splinter or sub-projectile projectile or warhead (fragment-forming ammunition) with partial explosives occupancy, characterized in that a fragment-forming projectile casing (2) over a relative to

Projectile diameter thin explosive layer (3) are arranged, which in turn surrounds an explosive layer (3) damming inner body (4).

2. Projectile or warhead according to claim 1, characterized in that the thickness of the explosive layer (3) is between 2 mm and 20 mm.

3. projectile or warhead according to claim 1, characterized in that the explosive layer (3) is introduced by casting or as a preformed body or pressed or introduced via negative pressure.

4. projectile or warhead according to claim 1, characterized in that the explosive layer (3) has the shape of a hollow cylinder with a constant or variable wall thickness and / or cross-sectional shape.

5. projectile or warhead according to claim 1, characterized in that the explosive layer (3) is homogeneous or contains admixtures or embedded body.

6. projectile or warhead according to claim 1, characterized in that the ignition of the individual explosive segments (8) or more explosive layers is punctiform, linear or annular at one or more points.

7. Projectile or warhead according to claim 1 or 6, characterized in that the ignition takes place via a time, distance or impact fuse, via a program-controlled signal or by radio.

8. projectile or warhead according to claim 1 and 7, characterized in that the ignition of several explosive elements (8) by pre-ignition, simultaneous ignition or series ignition (offset in time) takes place.

9. projectile or warhead according to claim 1, characterized in that the inner body (4) is constructed in one piece (metallic or non-metallic) or multi-part.

10. projectile or warhead according to claim 1, characterized in that the inner body (4) consists of a brittle or embrittling under dynamic load material.

1 1. Projectile or warhead according to claim 9, characterized in that the inner body (4) contains sub-projectiles (steel, hard metal, heavy metal).

12. Projectile or warhead according to claim 9, characterized that the inner body (4) is pre-fragmented or pretreated mechanically or thermally.

13. projectile or warhead according to claim 1, characterized in that the inner body (4) is formed as a homogeneous or segmented penetrator or contains such.

14. projectile or warhead according to claim 9, characterized in that the inner body (4) consists of several (same or dissimilar) Sub- shot / inner bodies.

15. projectile or warhead according to claim 14, characterized in that the sub-floors include an inert volume.

16. projectile or warhead according to claim 1 or 14, characterized in that the inner body / the inner body (4) has any cross-sectional area / any cross-sectional areas / have.

17. projectile or warhead according to claim 1, characterized in that the inner body (4) represents or contains a container.

18. projectile or warhead according to claim 17, characterized in that the inner body / container is filled with an inert or reactive medium.

19. projectile or warhead according to claim 1 and 16, characterized in that the inner body (4) consists of a medium under pressure or under the influence of temperature.

20. projectile or warhead according to claim 1, characterized in that the projectile has two or more explosive layers in the radial direction.

21. Projectile or warhead according to claim 1, characterized in that the explosive layer (3) is composed of contiguous surfaces or of surfaces (separated in the radial and / or axial direction).

22. projectile or warhead according to claim 1, characterized in that the explosive layer (3) forms an angle to the projectile axis.

23. projectile or warhead according to claim 1, characterized in that the explosive layer (3) is formed of separate or connected segments with any surface shape.

24. Projectile or warhead according to one of the preceding claims, characterized in that the accelerated shell (2) consists wholly or partly of preformed fragments or sub-projectiles.

25. projectile or warhead according to claim 24, characterized in that the splitter / sub-projectiles are directionally accelerated.

26. Projectile or warhead according to claim 1, characterized that fragment bodies are introduced between the explosive layer (3) and the projectile casing (2).

27. Projectile or warhead according to claim 26, characterized in that the fragmentation bodies are embedded in a matrix.

28. projectile or warhead according to claim 1, characterized in that there is a layer of a brittle material between the explosive layer (3) and the projectile casing (2).

29. projectile or warhead according to claim 1, characterized in that the deposited with explosive layer is positioned within a projectile outer shell.

30. projectile or warhead according to claim 29, characterized in that there is a cavity between the explosive layer (3) and the projectile casing (2).

31. Projectile or warhead according to claim 1, characterized in that between the explosive layer (3) and the projectile casing (2) a liquid jacket is inserted.

32. Projectile or warhead according to claim 1, characterized in that there is a dynamically damping medium between the explosive layer (3) and the projectile casing (2).

33. projectile or warhead according to claim 1, characterized in that between the explosive layer (3) and the inner body (4) is a the Verdämmungswirkung dynamically supporting layer.

34. projectile or warhead according to claim 1, characterized in that the longitudinal section of the explosive layer (3) has an arbitrary shape (contour).

35. projectile or warhead according to claim 34, characterized in that the explosive layer (3) over its entire length is the same thickness or unilaterally has different contours.

36. Projectile or warhead according to claim 1, characterized in that the explosive layer (3) is a hollow cylinder with one or both ends closed ends or intermediate layers (explosive bridges).

37. Projectile or warhead according to claim 1 or 36, characterized in that introduced inner bodies are accelerated via explosive elements in the axial direction.

38. projectile or warhead according to claim 1, characterized in that the damming inner body (4) contains a pyrotechnic element.

39. projectile or warhead according to claim 1, characterized in that the projectile is constructed in one or more stages in the axial direction.

40. projectile or warhead according to claim 1, characterized in that the projectile has a tip (1 C), which is partially or completely filled with explosives.

41. Projectile or warhead according to claim 1, characterized in that a tip or a tip portion of the projectile consists of an end ballistic effective inert part.

42. Projectile or warhead according to claim 1, characterized in that the active body consists of a combination of individual arrangements.

43. Projectile or warhead according to claim 1, characterized in that the active body is spin-stabilized or aerodynamically stabilized.

44. Projectile or warhead according to claim 1, characterized in that the active body represents a cannon-fired projectile, the combat part of a missile, a bomb or the combat part of a torpedo.