SE529287C2 - Ways to initiate external explosive charge and explosive charged action components therefore - Google Patents

Abstract

The present invention relates to a method of initiating explosive charges by means of splinter bodies (5) directed towards these at high speed by an external explosion. According to the invention, these splinter bodies (5) are given large surfaces or broadsides compared with their own mass and are forced to hit the explosive charge with their broadsides (5') first in order thereby to transfer sufficient kinetic impulse energy to initiate the explosive charge. The invention also comprises splinter bodies (5) specially configured for the implementation of the said method of initiating explosive-filled bodies (2) and explosive charges (3'), intended for the implementation of the said method and provided with a splinter shell (7) comprising the type of splinter bodies (5) characteristic of the invention.

Description

25 30 35 '529 287 2 1047 SE namely that its own, missile-fighting second missile is able to come close to the first enemy incoming missile or missiles, so that its own second missile can eliminate the incoming first the missile (s) with shrapnel bodies, which are formed or released and are aimed at high speed at the incoming first missile during the detonation of an explosive device loaded in its own, second missile, equipped with a shrapnel-forming shell.

The disadvantage of this method has previously been that large splinters, which hit the incoming missile explosive charge at a high speed, have been required in order for it to be safely initiated for detonation. Hence the need to provide its own missile-fighting second missile with a large impact part comprising a thick splinter-forming outer shell and a powerful, splinter shell fragmenting explosive charge, which automatically meant that the entire weapon system became large and expensive. An example of such an American weapon system is the so-called The Patriot robot.

OBJECT OF THE INVENTION AND ITS FEATURES The main object of the present invention is to provide an improved way of initiating a first external explosive charge, an improved explosive-filled action part for carrying out said method, and one for carrying out said method. method adapted splitter body, which initiation method, action part and splitter body substantially reduces, preferably eliminates, the above-mentioned problems, whereby the initiation method 1:, the favorable effects of the action part and the splitter body can be utilized in a better way than before.

A further object of the present invention is to provide a method for making it possible to markedly reduce the size of the active components included in such missile control missiles, without thereby reducing the ability of the active components to initiate explosive charges in such incoming missiles. , against which the missiles intended for missile combat may be launched.

The said objects, as well as other objects not listed here, are satisfactorily fulfilled via, as stated in the present independent patent claims.

Exemplary embodiments of the invention are set forth in the dependent claims. Thus, according to the present invention, there has been provided an improved method of initiating at least a first external explosive charge by means of a kinetic impulse, which method is characterized in that from the outer shell of the action member, at the action member the detonation of the explosive charge, the shattered bodies released are forcibly given a vehicle with a large wide side in relation to its own mass and that these shrapnel bodies are accelerated flat against the said first explosive charge so that these shrapnel bodies will hit said first explosive device with the necessary high kinetic impulse to the first explosive charge over a sufficient surface to initiate the explosive charge in question to detonation.

According to further aspects of the method according to the invention: that the division of the splitter shell of the action part into splitter bodies with a large wide side in relation to the own mass is ensured by giving the splitter shell different strength in its different parts either by breaking directions in or by reinforcing abutment against the parts of the splitter shell along which a division of the same gives the splitter bodies released from the splitter shell the desired shape. that said planar acceleration of splitter bodies to a certain extent in the detonation direction of the explosive substance accelerating at its detonation, is effected by such an adapted braking of the acceleration of the splitter bodies along that of the edges (a) of the splitter bodies which will first be hit by a detonating detonation wave the detonation wave has time to reach the other edge (b) of the splinter body which is not braked in the same way, whereby the splitter body will be accelerated flat away from the detonating explosive charge. that said planar acceleration of splitter bodies to a certain extent in the detonation direction of the explosive accelerating at the detonation of the splitter bodies, is achieved by giving the splitter bodies a smaller thickness (tg) in advance by phasing along the edge last hit by the detonation wave from the detonating explosive.

Furthermore, for carrying out the methods according to the invention, the adapted splitter body (5) included in the splitter shell (7) used is characterized by: the splitter body having a wide side whose lateral extent substantially exceeds the thickness of the splitter body and that said wide side, preferably, has the shape of a more or less flat circular, elliptical, rectangular or polygonal surface, alternatively that the splitter body has the shape of a relatively flat or flattened ellipsoid, rounded or angled disc, plate, or disc.

Furthermore, according to the invention, the explosive-charged action part is characterized by: that said splitter bodies are provided in advance with an embodiment each having a large, wide side, facing in the acceleration direction of the splitter bodies.

According to further aspects of the explosive heat-charged component, according to the invention: that the splitter bodies contained in its original shrapnel-forming shell at the detonation of the explosive have the shape of fl raised, rounded or oval plates, disks or ellipsoids. that its splinter-forming shell, upon detonation of the explosive device, is produced by powder metallurgical means comprising in a matrix produced by sintering of a metallic powder material splinter bodies with each large wide side relative to each splinter body's own mass and with a higher own strength than the matrix. that the matrix formed in the powder metallurgical shell, in which the splitter bodies are inserted, is designed so that it covers the part (a) of resp. splitter body, which will first be reached by the detonation wave from the detonating explosive charge of the action part with a sufficient amount of sintered powder material so that this first part (a) acceleration away from the detonation point is delayed a sufficient time for it (a) to be accelerated away from the detonation parallel to that part (b) of the same splinter body which is last reached by the same detonation wave and which is not braked in a corresponding manner, ie. is unbraked in relation to the first part (a). that the part (b) of the same splinter body which is last reached by the same detonation wave is covered with a smaller amount of sintered powder material than the part (a) of resp. splinter body which will first be reached by the detonation wave from the detonating explosive charge of the active part. 52 15 28 25 1047 SE that it further comprises abutments arranged on the outside of the splitter shell with such a thickness (tu, t13) and extent that the acceleration of the splitter bodies included in the splitter-forming shell of the explosive charge away from the detonation is slowed down along the edges (a) which first is affected by the detonation wave formed during the detonation of the explosive device for a sufficient period of time for the splinter bodies to be accelerated flat away from the detonation. that the individual splitter bodies are designed as chamfers along the edge (b) last struck by the detonation wave so that the acceleration of the shrapnel bodies included in the shatter-forming shell of the explosive charge away from the detonation is slowed, relative to the acceleration of the chamfered edge (b) along the edges ( . that the explosive shield surrounding the explosive shell forming the explosive shell on its inside facing the explosive is provided with at least one shock wave trap in front of at least one shock wave-affecting material coating in order to guarantee a predetermined division of the splitter shell into splitter bodies of desired size and shape. that it comprises a lighter for initiating the explosive charge contained therein, this lighter which is arranged at one end of the explosive charge being combined with a wave generator. that it comprises multi-initiation igniters with a number of initiation points arranged along the outer surface of the explosive charge for instantaneous initiation of the explosive charge.

ADVANTAGES AND EFFECTS OF THE INVENTION: The basic idea behind the present invention is thus to design the components included in the own action part splitter body, the splitter bodies formed compared to the own mass with a large surface facing towards incoming fi single missile, grenade. bomb, craft, etc. and a correspondingly small thickness in the same direction, which means that the side of the splitter bodies, hereinafter referred to as the wide side, which faces and hits the incoming internal missile, etc., including the above and below named first external explosive charge, 10 15 20 25 30 35 s29 287 6 1047 SE shall have the shape of disks, plates, disks, ellipsoids or equivalent. The invention further includes ensuring that these disc, plate, ellipsoid or otherwise similarly shaped splits should hit the intended target at a sufficiently high speed with their own wide side first, thereby transmitting a sufficient kinetic impulse to the actual first incoming the missile's explosive charge over a sufficient surface to initiate the explosive to detonation. This special design of the splitter bodies thus offers an opportunity to hit the target with splitter bodies which, provided that they have thus initially been given a sufficiently high speed, despite their limited own mass at the time of transmission transmit a sufficient amount of kinetic impulse over a sufficient explosive surface to ensure initiation. of the explosive charge contained in the combat missile. By impulse is meant here, somewhat simply put, a change in the amount of movement, ie. the product of mass times the velocity in a certain direction, in an object.

As the above-indicated shape of the splitter bodies designed in accordance with the invention could be given a large area compared with the own mass, the splinter-forming shell of the action part has been made thinner and thus lighter while a correspondingly smaller one will be required. amount of detonating charge of explosive shield within the splinter-forming shell to give the splitter bodies released therefrom at the detonation of the explosive heat charge charge a sufficiently high initial velocity towards the target, i.e. against the alien missile. This general basic idea thus offers an opportunity to significantly reduce the size of the active element necessary for combating foreign incoming explosive-laden missiles and thus the size of the entire weapon system in question and the costs thereof.

However, in order for the disc, plate or ellipsoid, etc. shaped fragments designed in accordance with the invention to give the effect outlined above, it is required that they firstly retain their original shape until they hit the target and secondly that they really hits the target with its wide sides first.

The first of the above conditions means that the splitter shell from which the splitters are released during the detonation of the explosive charge arranged inside the splitter shell is broken only at the very points and along the dividing lines, which were originally assumed and this can be ensured by weaker parts built into the splitter shell from the beginning. for example in the form of goods thinning at said points and along desired dividing lines. A better solution to the same problem, however, is to produce the splitter shell by powder metallurgical means, wherein pre-made splitter bodies are inserted into a matrix produced by powder metallurgical means which separates the splitter bodies from each other and from the explosive charge and which, by the matrix at the detonation of the explosive surrounding the splinters, they give a gentle acceleration, which counteracts a breakdown of the splinters and ensures that they are accelerated in the desired direction, namely in the direction of the incoming missile, etc. the advantage that by producing the splitter bodies separately, they can be given the most advantageous design for each particular case, and also give them a significantly higher strength than the splitter shell initially cohesive matrix material.

In this way, it is thus possible to effectively prevent an undesirable fragmentation of the splitter bodies and to ensure that these, when they are released from the splitter shell and begin to move towards the target, get the design intended for the end needle.

The division of the splitter shell into splitter bodies of the desired shape, regardless of whether the splitter shell is manufactured by powder metallurgical or not, could also to a certain extent be ensured by specific abutting elements arranged externally on the splitter shell along desired breaking lines between the desired splitter bodies.

To reinforce and further ensure the division of the splitter shell into splitter bodies of the desired size and shape along predetermined fracture lines or along the space between prefabricated, splitter bodies baked into a powder metallurgical matrix and to prevent an undesirable further fragmentation of the splitter body with the splitter body. shock wave falloir in the form of one or fl your layers of coatings of material that exhibit strongly deviating acoustic properties compared to the splitter shell in general. Examples of materials that can be used as such shock wave traps are plastics of different hardness and density.

The other conditions stated above, in order for the splitter shell invented according to the invention to give the desired effect in the form of a detonation of the explosive charge in an alien missile, or in an armed target comprising an explosive charge, e.g. an artillery shell, bomb, etc. acc. above, namely that the shrapnel bodies according to the invention must hit the target with their own wide sides first, means that the shrapnel bodies, at the detonation of their own explosive charge and their own release from the shrapnel-forming shell or matrix, must be accelerated flat against the target without any simultaneous rotational movement. 10 15 20 25 30 35 529 287 8 1047 EN Initially, this means that all splitter bodies must be given constant and uniform acceleration conditions, which, when the explosive charge is initiated from one end, can be arranged relatively easily by means of a waveforms built into the initiation end, which compensates for the the point initiation formed the successive change of the detonation wave of the radius of curvature of its own detonation wave during its propagation through the explosive discharge from its initiation end to its other, opposite end.

A more expensive and more complex solution to the same problem is to provide the charge with a lighter for multi-initiation, which along its own outer surface provides an instantaneous initiation over the entire circumference of the charge (mantle surface).

The flat acceleration sought for the method according to the invention further means that the splitter bodies, which have already been indicated, are prevented from being given any form of rotational movement in connection with the detonation of the explosive being released from the explosive shell surrounding the splitter and accelerated towards the target. For the splinter bodies according to the invention, it has been pointed out, as previously pointed out, that these individually have at least a large surface area compared with their own volume and that they must hit the target with this own wide side first. The requirement for its own surface can be met in that each splitter body has a certain extent in the longitudinal joint of the original splitter shell. This in turn means that one edge / side of each specific shatter body will be hit by the detonation wave from the detonating explosive before its opposite edge side, which in turn, if no special action was taken would automatically lead to the shatter at the detonation of the explosive. was given a rotating motion about an axis midway between said edge sides.

According to a development of the invention, however, it has been found possible to ensure the flat acceleration of the splitter bodies by means of well-dimensioned abutments which are placed on the outside of the original splitter shell. These abutments, which can be included in the original splitter shell matrix in the form of a sectionally arranged increased material thickness against the outside of the splitter shell, alternatively as separate abutments arranged on the outside of the splitter shell. These abutments thus have the task of resisting when the detonation wave first reaches the first one edge side of each splinter body and thereby prevent the first hit edge / side of the splitter body from being accelerated away from the detonation front before the detonation wave reaches the opposite edge side of the same splitter body. 10 15 20 25 30 35 529 287 9 1047 SE By utilizing abutments of the type specified above, it has thus proved possible to resist, ie. brake, the acceleration of the edge / side of resp. splinter body until the detonation wave reaches the opposite edge side of the splitter body, the result being that the splitter body is accelerated flat away from the detonating explosive. In a splitter shell produced by powder metallurgical means, such resistors would e.g. can be formed from the splitter shell matrix produced by powder metallurgy by means of cutting processing. Another method used for the same purpose would be to design the individual splinters which are chamfered along the edge last struck by the detonation wave.

The invention has been specified in the following claims and it will now be described in more detail in connection with the appended claims.

Additional advantages and effects will become apparent upon study and consideration of the following detailed description of the invention, including a number of its advantageous embodiments, the claims and the accompanying drawings.

LIST OF FIGURES Referring to the accompanying drawings, Fig. 1 schematically shows the principles behind the use of the invention in the combat of an incoming single missile, Fig. 2 a particularly advantageous shape of the splitter bodies characteristic of the invention, Fig. 3 an oblique projection of one in accordance with the invention. designed action part, Fig. 4 a longitudinal section through a modified action part and Fig. 5 an enlarged detail from Fig. 4.

DETAILED DESCRIPTION OF THE EMBODIMENT Fig. 1 shows schematically and in particular an explosive-charged single missile 2 arriving at a target 1, hereinafter also referred to as the first missile 2. To combat this first missile 2, in accordance with the present invention, it has its own missile 3, below also called second missile 3, is launched alternatively fired from another carrier such as an eyepiece, which second missile comprises an operative part A, see Fig. 3. This second missile 3 does not have to hit the first missile 2 to completely 10 15 20 25 30 35 s29 287m 1047 SE be able to eliminate this. In the immediate position of the second missile 3 relative to the first missile 2, a charge contained in the second missile 3 with explosive substance 3 "is instead initiated, whereby splitters 4 formed in accordance with the invention are sent out in a swarm towards the first missile 2. When hit in the explosive charge 2 "of the first missile 2 is initiated by this extreme explosive charge 2" by said splitter 4. In order to ensure that the splitter 4 ejected from the second missile 3 will actually transmit a sufficient amount of kinetic impulse to the explosive charge 2 "in the first missile 2 to detonate this charge 2 "has for the invention, see Fig. 4, distinctive splinter bodies 5 been inserted into the second missile 3 (only schematically indicated by a dashed line) explosive charge 3" splinter-forming outer shell 7. These splitter bodies 5, see Fig. 2, each have a large wide side 5 ”compared to their own mass, ie. they are, for example, in the form of plates or ellipsoids or other disk shapes which give the splitter bodies 5 large wide sides 5 "but a limited thickness t, which wide side 5" is intended to hit the enemy, first missile 2. A particularly advantageous design of the splitter body 5 is a rounded button or coin shape 5 with the wide side 5 ', the embodiment of which is illustrated in Fig. 2 and Fig. 3.

However, any other design which satisfies the characteristics of the invention is conceivable. Such embodiments thus include, for example, button, coin, rectangle, square, polygonal shape, etc. forms (not further specified here). For best effect, it is essential that the splitter 4 formed during the detonation of the explosive charge 3 "in its own second missile 3 comprises splitter bodies 5 with at least one side surface 5" of each splitter body 5 which is substantially large in relation to the mass of the splitter body 5 and its total volume. .

The action part A of the second missile 3 illustrated in Fig. 3 is thus provided with an internal explosive heat charge 3 "and a larger number around the explosive charge 3" in a splinter body 5 collected at the first detonation detonation shell. In Fig. 3 only one bands of such splitter bodies 5 plus a single splitter body 5 have been drawn, but in reality the entire splitter hall 7 of the active part A must contain such, see also Fig. 4.

As already pointed out, the splinter bodies 5 must be accelerated flat against the incoming missile 2 so that the splitter bodies 5 hit the first, i.e. incoming, the missile 2 with its wide side 5 'first. One way of achieving this effect is illustrated in more detail in Fig. 4 and Fig. 5. The action part A illustrated in these longitudinal sections 4 and 5 contains a said explosive charge 3 ", a said splitter-forming shell 7 in which a suitable embodiment of the splitter bodies 5 are inserted. Furthermore, there is a 10 8 20 25 30 35 529 zsrn 1047 SE lighter 8 for initiating the explosive charge 3 ”. Inside the lighter 8, a wave former 14 is inserted. The wave former 14 does not comprise layers of, for example, air and metal described in more detail here. On the face 15 of the shatter-forming shell 7 towards the inside 15 of the explosive charge 3 ', a shock-absorbing coating 9 is arranged to form a shock-wave trap 16. This coating 9 comprises material combinations, preferably in different material layers, with different acoustic properties and has the task of ensuring the shell 7 is broken in the right places without damaging the splinter bodies 5. Examples of suitable materials in the shock wave folds contained therein are plastics of various kinds, which have advantageous properties for the invention and then mainly different hardness. Other advantageous properties can be, for example, different densities, etc.

From Fig. 4 and Fig. 5 it further appears that the explosive charge 3 "is initiated at one end of the igniter 8. It follows that a detonation wave will be displaced by the explosive charge 3". The successive displacement of this detonation wave through the explosive charge 3 'has been illustrated with arc lines 10 and a detonation direction arrow 11. As further appears from Fig. 5 in particular, the detonation wave 10 will first reach the edge of resp. splitter body 5, which splitter body 5 has a certain definite extent in the detonation direction l1, which is closest to the detonation direction l 1. In Fig. 5, this edge of the splitter body 5 in the first detonation direction has been denoted by a. the edge a of the said first splitter body 5 has begun to be accelerated away in the direction of the arrow a 'before the detonation wave 10 reaches the second, opposite edge b of this splitter body 5, which second edge b is consequently accelerated away in the direction b' of the detonation wave 10 but slightly later than the edge a The result would thus have been that the splitter body 5 would have been given a rotating movement about an axis midway between the edges a and b. acceleration is equal, no rotation takes place.

In order to avoid this undesirable effect, the matrix, see further below, which constitutes the continuous part of the splitter shell 7 and in which the splitter bodies 5 are baked in has been given "resistance 12 resp. 13 with different thickness tj; and tj; at the height of the edges a of the splitter body 5 resp. b, see Fig. 5. The splitter shell 7 thus has a saw-toothed cross-section. The result is that the part a of resp. splitter body 5 which is first reached by the detonation wave 10, i.e. its side edge a in Fig. 5, has a greater abutment thickness tu and thus a greater resistance to overcome before it is accelerated away from the detonation than the part, i.e. edge, b which the detonation wave 10 reaches somewhat later with the thinner resistance force t13 of the splitter shell 7 to overcome. With correctly dimensioned abutment thicknesses 12, 13, the splitter bodies 5 can thus be given the flat acceleration sought for the method according to the invention, i.e. that said planar acceleration of the splitter bodies 5 is effected by such an adapted prevention / braking of the acceleration of the splitter bodies 5 along that of the edges a of the splitter bodies 5 which will first be hit by a detonation wave 10 from the detonating explosive 3 "that the detonation wave 10 has time to reach the second edge body 5. b, which other edge b acceleration b ”is unobstructed / unbraked, ie. which is not braked in the same way as the first edge a, before the first edge a is released from the rest of the splitter shell 7 and has begun its acceleration a 'whereby the splitter body 5 will be accelerated flat away from the detonating explosive charge 3 "_ The type of splitter shell 7 shown in Fig. 4 and Fig. 5 is intended to be made on. powder metallurgical route, which in this case would mean that prefabricated splitter bodies 5 are baked into a powder matrix which is sintered to a coherent strength which is preferably given an at least slightly lower own strength than the splitter bodies 5 baked therein.

The sawtooth profile of the splitter shell 7 shown in Fig. 4 and Fig. 5 comprising the abutments 12, 13 can then be easily formed by cutting machining from the sintered matrix material so that a larger amount of matrix material, i.e. the abutment 12 with the greater thickness tu, remains at the edge a of the splitter body 5 first reached by the detonation wave 10, while a smaller amount of matrix material, i.e. the abutment 13 with the smaller thickness t13, remains at the edge b of the splitter body 5 last reached by the detonation wave 10. The amount of matrix material, i.e. the thickness between the abutment 12 and the abutment 13, suitably decreases, seen in a longitudinal section, rectilinearly between said abutment 12, 13 (Fig. S).

ALTERNATIVE EMBODIMENTS The invention is not limited to the embodiments shown, but can be varied in various ways within the scope of the claims. It is understood, for example, that the specific goal specifically described herein, i.e. the incoming missile 2 specified in the above embodiment can also be included by any other air, water or ground target which comprises an explosive device which can be initiated according to the claims, for example a grenade fired by means of a suitable barrel weapon. The own missile 3 can also in the same way consist of a barrel projectile.

It is further understood that, as previously indicated, the sawtooth profile can be replaced by Lex. a bevel along the edge of the splitter body that is last hit by the detonation wave.

It will be appreciated that the number, size, material, properties and shape of the elements and details included in the action part A, for example the splitter bodies, waveforms, shock wave traps etc. are adapted to the other elements and details included and the actual target action part is intended to combat.

Claims (5)

10 15 20 25 30 35 i 529 287 1047 SE 14 PATENT CLAIMS A method of initiating at least one first external explosive charge (2 °) by means of a kinetic impulse which is transmitted to said first external explosive charge (2 °) by high external velocity splitter bodies (5) directed towards this first external explosive charge (2 '). from a second explosive-filled element initiated on its own initiative, with an explosive substance (3 ”) surrounding it, and at its detonation splitter-forming outer shell (7) provided part A, characterized in that from the outer shell (7) of the active part (A), at the the detonation of the explosive charge (3 ") contained in the active part A, the shattered bodies (5) released forcibly are given a shape with a large wide side (5") in relation to their own mass and that these shrapnel bodies (5) are accelerated flat against the said first explosive charge (2) °) so that these splinter bodies (5) will hit said first explosive charge (ZP) with their own wide side (5 °) first and thereby supply a sufficient h and kinetic impulse to the first explosive charge (2 ”) over a surface sufficient to initiate the explosive charge (2 °) in question to detonation. A method according to claim 1, characterized in that the division of the splitter shell (7) of the action part (A) into splitter bodies (5) with a large wide side (5 ") in relation to the own mass is ensured by giving the splitter shell (7) different strength in their various parts either by means of breaking instructions in or by means of reinforcing abutments (12 and 13, respectively) against the parts of the splitter shell (7) along which a division thereof gives the splitter bodies (5) released from the splitter shell (7). A method according to claim 1 or 2, characterized in that said planar acceleration of splinter bodies (5) to a certain extent in the detonation direction (11 ') of the explosive substance (5') accelerating at its detonation, is achieved by such an adapted braking of the acceleration of the splinter bodies (5) along that of the edges (a) of the splitter bodies (5) which will first be hit by a detonation wave (10) from the detonating explosive (3 *) that the detonation wave (10) has time to reach the second of the splitter body (5) edge (b) which is not braked in the same way whereby the splitter body (5) will be accelerated flat away from the detonating explosive charge (3 '). 710 15 20 25 30 35 1047 SE 529 287 Ü A method according to any one of claims 1-3, characterized in that said planar acceleration of splinter bodies (5) to a certain extent in the explosive substance (3 ') accelerating upon detonation of the splinter bodies (5). detonation direction (l 1), is achieved by giving the splitter bodies (5) in advance by chamfering a smaller thickness (tg) along the edge (b) which is last hit by the detonation wave (10) from the detonating explosive (3 ”). For the implementation of the method according to any one of claims 1-4 adapted, and in the splitter shell (7) used thereby, splitter body (5), characterized in that the splitter body (5) has a wide side (5 ") whose extension laterally substantially exceeds the thickness of the splitter body (5) and that said wide side (5 °), preferably, has the shape of a more or less planar circular, elliptical, rectangular or polygonal surface, alternatively that the splitter body (5) has the shape of a relatively flat or flattened ellipsoid, rounded or fl raised disc, plate, or disk. Explosive-charged (3 °) action part (A), provided with a splinter-forming outer shell (7), intended to release, at high velocity detonation of its own explosive charge (3 "), splinter bodies (5) intended to in accordance with the methods according to any of claims 1-4 are used for initiating at least one external explosive charge (2 ') by transmitting a sufficient amount of kinetic impulse to said external explosive charge (2 ") to initiate the same to detonation, characterized in that said splinter bodies (5) in advance ensured a design with each large, wide side (5 ') facing in the acceleration direction of the splitter bodies (5). Explosive charged (3 ”) action part (A) according to claim 6, characterized in that the splinter bodies (5) included in its original shatter-forming shell (7) forming the explosive (3 °) detonation have the shape of fl corner, rounded or oval plates, discs or ellipsoids. Explosive-charged (3 ') action member (A) according to any one of claims 6-7, characterized in that its, upon detonation of the explosive (3'), splinter-forming shell (7) is produced by powder metallurgical means comprising in a sintering of a matrix made of metallic powder material, inserted splinter bodies (5) each with a large wide side (5 ”) relative to the respective mass of the splitter body (5) and with a higher own strength than the matrix. 10 15 20 25 V30 35 1047 SE 10. ll. 1 1529 287% Explosive charged (3 ”) action part (A) according to any one of claims 6-8, characterized in that the matrix (7) formed in a powder metallurgical manner, in which the splitter bodies (5) are inserted, is formed as follows: that it covers the part (a) of resp. splitter body (5), which will first be reached by the detonation wave (10) fi from the detonating explosive charge (3 ”) of the action part (A) with a sufficient amount (12) of sintered powder material (12) for this first part (a) acceleration away from the detonation point a sufficient period of time is required for it (a) to be accelerated (a °) away from the detonation parallel to the part (b) of the same splitter body (5) which is last reached by the same detonation wave (10) and which is not braked in a corresponding manner, i.e. . is unbraked in relation to the first part (a). Explosive charged (3 ”) action part (A) according to claim 9, characterized in that the part (b) of the same splinter body (5) which is last reached by the same detonation wave (10) is covered with a smaller amount (13) of sintered powder material than the part (a) of resp. splitter body (5) which will first be reached by the detonation wave (10) from the detonating explosive charge (3 ”) of the action part (A). Explosive charged (3 °) action part (A) according to any one of claims 6-10, characterized in that it further comprises abutments (12 - 13) arranged on the outside of the splitter shell (7) with such a thickness (tg, t13) and extent; that the acceleration (a °) of the splinter bodies (5) contained in the shale-forming shell (7) of the explosive charge (3 °) away from the detonation is braked along the edges (a) first touched by the detonation wave (10) formed by the explosive (3 °) detonation for a sufficient period of time for the splitter bodies (5) to be accelerated flat away from the detonation. Explosive shield (3 ') action part (A) according to one of Claims 6 to 10, characterized in that the individual splitter bodies (5) are designed as chamfers which are chamfered along the edge (b) last struck by the detonation wave (10) so that the explosive charge (3) ') the acceleration (a °) of the shrapnel-forming shell (7) of the shrapnel bodies (5) away from the detonation is slowed down, in relation to the acceleration (b') of the chamfered edge (b '), along the edges (a) first touched by the the detonation of the explosive (3 ”) formed W 10 15 20 1047 SE 1 3. 1 4. 1 5. 529 287 17 detonation wave (10) for a sufficient period of time for the splitter bodies (5) to be accelerated flat away from the detonation. Explosive charged (3 ') action part (A) according to one of Claims 6 to 12, characterized in that the explosive (3 °) surrounding the explosive shell (7) surrounding the explosive (3 °) detonates on its inside facing the explosive (3'). (15) is provided with at least one shock wave trap (16) in the form of at least one shock wave affecting material coating (9) in order to guarantee a predetermined division of the splitter shell (7) into splitter bodies (5) of the desired size and shape. Explosive charge (3 ") actuating member (A) according to any one of claims 6-13, characterized in that it comprises an igniter (8) for initiating the explosive heat charge (3") contained therein, this igniter (8) being arranged in the explosive charge of the explosive charge. (6) one end combined with a waveform (14). Explosive charge (3 °) action part (A) according to one of Claims 6 to 14, characterized in that it comprises multi-initiation igniters with a number of längs along the explosive charge (3 °) outer surface arranged initiation points for instantaneous initiation of the explosive charge (3 °).