FR2685077A1 - Explosive device with programmable fragmentation - Google Patents

Abstract

In order to produce a charge with programmable fragment size, a fragment generating wall (2) is composed of at least two walls (2a, 2b) which are superposable and movable with respect to each other. Each wall has its own network (9, 11) of breaking lines. The overall network of the breaking lines is formed by the combination of the networks of each wall. The mobility of the walls with respect to each other allows adjustment of the size of the fragments by alteration of the overall network of breaking lines.

Description

EXPLOSIVE FRAGMENTATION DEVICE
PROGRAMMABLE
The invention relates to the field of burst generating devices, the bursts of which consist of parts of one or more walls surrounding the explosive.

 In the current state of the art, the fragments of this type of charge are constituted by pieces of walls whose perimeter is predetermined by incipient fractures generally constituted by grooves cut in the wall generating fragments. A classic and well-known type of bursting charge is the so-called grenade.

 The external wall of this type of grenade is a wall constituting substantially an ellipsoid of revolution. The grenade is said to be squared because networks of gorges formed along meridians and parallels of this ellipsoid constitute a grid of the wall. The pieces of this kind of grenade are made up of small squares whose perimeter is made up of two parts of meridians and two parts of consecutive parallels. There are also known configurations of military charges comprising a main explosive charge, a casing generating fragments and closing flanges to contain the explosive charge.

The envelope often consists, for loads of sheaves of calibrated flakes, in a pre-machined ferrule, or a smooth ferrule whose flakes are calibrated by pyrotechnic effect as described by the THOMSON-BRANDT ARMEMENTS patent No. 81.06.189.

 The destruction of an objective is obtained all the more easily when the sheaf of shards only comprises calibrated shards of piercing power adapted to the type of target treated.

However, despite the effectiveness of the calibration obtained by known technologies, it follows, by principle itself, that the calibration is optimized for a single type of objective whereas for many applications the explosive charges are brought to be able to process several objectives for example aircraft and missiles. Optimization of the calibration for only one of the types of treatable objectives, or a compromise of optimization with regard to objectives reduce for multi-objective devices the total efficiency of the weapon system.

 The object of the invention is to provide a military flake charge, the potential targets of which are not predetermined at the construction stage by defining the cut and therefore the mass of the flakes. The object of the invention is therefore to provide a military flash charge having the possibility of programming the individual mass of the flashes produced by its ignition. With such a charge, it becomes possible to optimize, for the same charge, the size of the fragments, as a function of the attacked target, for example an airplane, or a missile, the attacked target being known only at the time of the carrying or firing the load. Depending on the version, programming can be done manually or automatically.

 To this end, the subject of the invention is a military flash charge of the type comprising a mass of explosive surrounded at least partially by at least one wall comprising two faces, an internal face and an external face, each wall being intended to be fragmented to produce flakes whose individual mass is predetermined by a pre-established network of breaking lines and by the thickness of the wall, characterized in that the walls intended to be fragmented are at least two in number, ie a first wall producing first flakes and subsequent walls producing so-called next flakes and in that the internal face of each of the following walls coincides at least on one part with the external face of a previous wall and in that the next wall part which coincides with the part of previous wall is capable with respect to the breaking lines of this previous wall of at least two positions, a first e t a second.

 The internal face of a wall denotes the face which is closest to the mass of explosive. By coincidence of an internal face and an external face we mean that there is contact between the two walls to the nearest clearance to allow movement between the two faces.

 The term “rupture line” means the intended rupture lines, whether these lines are materialized on the wall or in its constitution, for example by grooves or by incorporation of wires in the thickness of the wall or else by the overall configuration of the charge in particular of the explosive.

 In the rest of the description, fragments are understood to be the wall parts as they are intended to be cut, taking into account the overall configuration of the load. The fragment will therefore be a potential entity, the corresponding real entity will be called a fragment. A burst is therefore a fragment of a wall after the explosion, therefore of a really fragmented wall.

 We will call network of rupture lines or network of a wall, the set of rupture lines materialized in one way or another on the wall or for the first wall on the explosive. The total network of rupture lines of a wall or total network will be called all the rupture lines resulting from the network of this wall and the rupture lines resulting from the overall configuration of the charge, in particular of the explosive, and of the position of the walls with respect to each other.

 Preferably, the wall parts which coincide are parts of surface of revolution about the same axis and the transition from the first to the second position is obtained by a rotation of the next wall around this axis of rotation.

 In a possible variant of embodiment, the parts of the first wall and the following walls have faces whose surface is generated by a straight line constrained to maintain a fixed direction in space and the transition from the first to the second position is obtained by a translation.

 Finally, if the first wall and the following walls are parts of the surface of revolution generated by a straight line parallel to the axis of revolution of the surfaces, the transition from the first to the second position may be obtained by rotation, translation or rotational and translational movement for example a helical movement.

 The transition from the first to the second position can be carried out manually before carrying or firing the device and in this case the device comprises means for holding the second wall in the chosen position.

 The passage from the first to the second position can be controlled and accomplished by a power member and in this case the maintenance in the selected position can only be ensured by the position commanded to the power member.

 The advantage of the movement of the two walls relative to each other is to move the planned breaking lines of one of the walls relative to the planned breaking lines of the other.

 The invention lies in the fact that when two surfaces are in coincidence, the perimeter of each of the fragments of face in coincidence is determined not only by its own rupture lines but also by the rupture lines of the other. So for example if in a first position the rupture lines of a first and a second surface are in coincidence, that is to say are superimposed on each other, we will obtain in this first position fragments made up of fragments of surface wall S. If in a second position the breaking lines of the first and second surfaces are offset, the network of breaking lines ~ of each of the first and second surfaces becomes the combined network of breaking lines of the first and second according to the geometry of the breaking lines of the first and second networks, the network of breaking lines of the first and second networks may generate in the second position fragments of surface S / 2 or S / 4 of individual mass reduced to half or a quarter of the fragments obtained when the two walls are in the first position.

 The coincident walls are generally metallic, but it is possible that they have non-metallic parts.

In general the choice of obtaining mass flakes M
M / 2 or M / 4 will be sufficient to treat the targets likely to be assigned to a type of load and therefore in general loads with two walls in coincidence will be sufficient.

 The invention is not however limited to loads with two walls. Thus, for example, the invention may include a third wall, also comprising a network of rupture lines, movable relative to the second wall, itself movable relative to the first wall. The total network of rupture lines of the three walls will consist of the assembly of the rupture networks of each of the walls and therefore of the relative position of the three walls at the time of the explosion. By having the possibility of moving two networks of breaking lines, the number of possible combinations of the network of resulting breaking lines is increased, and therefore the number of possibilities of individual masses of flakes.

 If walls are added, each additional wall allows an increase in the choice of the individual masses of the fragments.

 Some embodiments will now be described with reference to the accompanying drawings.

 In these examples Figure 1 is a perspective view of a first embodiment.

 Figure 2 is a perspective view of the embodiment of Figure 1 for showing a means of rotation of a second ferrule relative to a first ferrule.

 Figure 3 is an exemplary embodiment of the load according to Figure 1 intended to be programmed manually.

 FIG. 4 represents a perspective view of another exemplary embodiment.

 FIG. 5 represents a perspective view of a load according to the invention in which the passage from the first to the second position is obtained by translation.

 Figures 6 and 7 show other exemplary embodiments.

 Referring to Figure 1 there is shown a charge 1 with splinter formation. This charge i comprises a central charge 3 consisting of a mass of explosive. This mass is a straight cylinder of revolution around an axis 00 '.

A shrapnel-generating envelope 2 of straight cylindrical shape with axis 00 ′ surrounds the cylindrical lateral surface of the explosive mass. This fragment-generating envelope consists of two concentric walls, a first wall 2a comprising an internal face 4 and an external face 5 and a second wall 2b comprising an internal face 6 and an external face 7. The external faces 5 of the wall first 2a and internal 6 of the second wall 2b are in contact with each other with sufficient play to allow relative movement.

 The load of FIG. 1 also comprises two end flanges, in the form of discs fixed to the ends of the device shown in FIG. 1. In the case where the load is a part of a projectile, these flanges are often fixed to a cylindrical shell located in generaI between the explosive mass 3 and the fragmentable envelope 2. This shell is intended to absorb the structural forces connecting the military charge to the rest of the projectile. When one of the walls 2a or 2b is fairly rigid and resistant, it can act as a ferrule for transmitting structural forces.

 These flanges and the ferrule, as well as their fixing means, which are not necessary for understanding the invention, have not been shown in FIG. 1.

 Likewise, an arming and firing safety device, necessary for the operation of the load but not necessary for understanding the invention, has not been shown. The wall 2b can rotate around the axis 00 'from a first position to a second position. The first position is shown in Figure la and the second position is shown in Figure lb.

 The wall 2a is made of steel and has a crossed network of helical grooves 9 on its external face 5. This network consists of grooves 91 '93 93 ... 92n + l equidistant and parallel to each other each of the grooves having the shape of a helix and grooves 90, 92, 94. 94 92n also parallel to each other and equidistant having a helix shape. The grooves 9 with an odd index and those with an odd index are crossed so that they form small diamonds 10 on the surface of the external face 5 of the wall 2a.

 The perimeter of each of the diamonds 10 consists of 2 consecutive odd index grooves and two consecutive even index grooves. The grooves 9 constitute the breaking lines of the first wall 2a of the envelope.

 The second wall 2b is made of steel and has a crossed network of helical grooves 11 on its internal face 6. This network consists of parallel grooves 111, 113, 112nui and parallel grooves i1 112 ... 112n parallel to each other and crossed at raw. This network It defines diamonds 12. This network is such that in the first position of the wall 2b, the networks 9 and 11 of the casings 2a and 2b are superimposed. This means that the diamonds 12 whose perimeter consists of two consecutive lines 112p * 1, 112p + 3 (p <n) and two consecutive lines 112p, 112p + 2 are the same size as the diamonds 10.

 In the second position shown in FIG. 1b, the lines 11 are dotted and the lines 9 in solid lines.

In this second position the vertices of the diamonds 12 are on a diagonal of the diamonds 10. Thus each diamond 10 is divided into 4 by the breaking lines constituting the diamonds 12 and vice versa. It follows that in this second position the flakes will be four times smaller and therefore of mass four times less.

 FIG. 2 represents the means of rotation of the envelope 2a with respect to the envelope 2b. This means is constituted by a jack 13, one of the ends 14 of which is rotatably fixed to the casing 2a and the other end of which is rotationally fixed to the casing 2b. This cylinder is capable of two positions, a first and a second. In the first position a piston 16 of the cylinder is retracted and in the second position the piston is deployed.

 In the first position of the jack 13 the envelopes 2a and 2b have their superimposed rupture lines and in the second position the rupture lines of the envelope 2b are in the position shown in FIG. The transition from the first to the second position is effected by pyrotechnic thrust by means of a micro-charge (not shown) electrically initiated by wires 17.

 The invention is not limited to the embodiment which has just been described and numerous variants are possible. The main thing is to move the breaking lines of a first wall with respect to a second.

 The variants may relate to the shape of the envelopes, the manner of moving them relative to one another (translation rotation or helical movement).

 They may relate to how to obtain the breaking lines and their geometry.

 FIG. 3 illustrates a manual mode of rotation of the second envelope with respect to the first. In this mode the two envelopes 2a, 2b are free to rotate relative to each other and the only technical problem to be solved ~ is that of maintaining in one of the chosen positions.

 In Figure 3 this holding is achieved by a ball 18 pushed by a spring 27 which is fixed in a hole 19 or 20 of the first envelope according to the desired position for the second envelope. It would have been possible to use other fixing systems known in themselves such as screws, pins ...

 FIG. 4 shows another geometry of the breaking lines, making it possible to halve the surface of the fragments when the second envelope is in the second position.

 In this embodiment, the grooving network of the second envelope only includes the propellers 11 of odd rank.

 Under these conditions a rotation or a translation of this second network from a position where the lines of this second network are superimposed on the lines of the network constituting the first envelope to a position where these lines occupy a median position to the lines of the network of the first envelope will cause the surface of the flakes to be halved.

 The ways of obtaining the breaking lines are known in the art and will be recalled below only for information and not exhaustive. These lines can be obtained by grooving, by inserting wires in the cast iron of the envelope as described in patent DE 29.23.877, by the geometry of the explosive, the envelope being smooth. This last possibility will be particularly interesting if one of the envelopes must serve as a ferrule for connecting the load with other parts of a machine.

 Figure 5 shows this case. In this figure, an envelope 2 ′ consists of three walls, a first wall 2 ′ a and two subsequent walls 2 ′ b and 2 ′ c. The intermediate wall 2'b does not have any specific network of breaking lines. Under these conditions the total network of the wall 2'b would be constituted in the absence of the wall 2'c by the network of breaking lines of the wall 2'a. In the presence of the wall 2'c the total network of rupture lines of each of the walls including the wall 2'b is constituted by the rupture lines of the walls 2'a and 2'c.

 The casing 2 is cylindrical with an axis of revolution 00 '.

The network 9 ′ of rupture lines of the wall 2 ′ a is constituted by equidistant meridians 9 ′ 1 ′ 9 ′ 3. . 9'2n + 1 parallel to the axis 00 'and by equidistant parallels 90, 92' "92n perpendicular to the meridians.

 The network 11 ′ of the third wall 2 ′ c is constituted in the same way and comprises equidistant meridians 111112n + l and equidistant parallels 110 ... 112n.

 In the first position, not shown, the two networks 9 'and 11' are superimposed. In the second position shown in FIG. 5, the two networks have been offset by rotation so that each parallel of the network 11 'is equidistant from two consecutive parallels of the network 9. In this second position, the fragments of each of the walls are massed half the mass of the fragments obtained in the first position. Note that if the wall 2'c is capable of a third position, the mass of the fragments can still be divided by 2.

 The third position is obtained by translation towards the rear of the wall 2 ′ c. This translation is obtained if a holding latch 21, holding the wall 2c in the front position is retracted when the projectile leaves.

 This lock consists of one end 22 of a core of a coil 23. This end is engaged in a slot 24 of an extension 25 of the wall 2c. If a current is sent to the coil 23 the lock retracts. The acceleration due to the departure causes the rearward movement of the wall 2c up to a stop not shown.

 The wall 2c is held in this position by the return of the end 22 of the core which then engages in another slot 26 of the extension 25.

 By superimposed networks we mean that two meridians of networks 9 and 11 are located in the same meridian plane and that two parallels of networks 9 and 11 are located in the same plane.

 In the second position a meridian plane containing a meridian of the network 9 is bisector of two consecutive meridian planes of the network 11. In the third position a plane containing a parallel of the network 9 is equidistant from two planes containing two consecutive parallels of the network 11.

 Figure 6 is intended to show another possible embodiment; FIG. Ga represents an assembled ferrule and FIG. 6b an exploded view before assembly.

 In this embodiment, the envelope 2 "consists of two walls 2" a, 2 "b, the surface of which is generated by rotation about an axis 00 'of a concave line. The internal wall 2" a consists of two half walls 2na1, 2 "a2 which at the time of assembly are welded, the weld plane being perpendicular to the axis 00 '. The transition from the first to the second position is obtained by rotation around the axis 00' .

 If the line generating the envelope had been concave, the 2 "b external wall would have been in two parts.

 FIG. 7 represents yet another embodiment in which the casing 2 "'consists of two walls 2"' a, 2 "'b whose surface is generated by a straight line parallel to an axis 00' and which s' presses on a polygon which, in the represented case is regular, located in a plane perpendicular to the axis 00 'and having for center the intersection of this plane with the axis 00'. The second position is obtained by translational movement one of the walls has a network of breaking lines formed by meridians and equidistant parallels between them; the other wall has a network of breaking lines formed by parallels which in the first position shown in Figure 7a are superimposed on the parallels of the first network and which in the second position shown in Figure 7b are each equidistant from two consecutive parallels of the first network, with the exception of the parall is the most rear.

 Figures 3 to 7 are only intended to illustrate the scope of the invention which is not limited to the embodiments thus presented. In particular, the elements and particularities described on the occasion of the description of each of the embodiments can replace or be added to the elements described on another of the embodiments. The concave shape represented in FIG. 6 could just as well be convex, the regular polygon represented in FIG. 7 could be any polygon without departing from the scope of the present invention.

Claims (16)

 1. Military charge (1) with flashes of the type comprising an explosive mass (3) surrounded at least partially by at least one wall (2) comprising two faces, an internal face and an external face, each wall being intended to be fragmented to produce flakes whose individual mass is predetermined by a pre-established network of breaking lines and by the thickness of the wall, characterized in that the walls intended to be fragmented are at least two in number, ie a first wall (2a ) capable of producing first flakes and of the following walls (2b, 2c) capable of producing so-called following flakes and in that the internal face (6) of each of the following walls coincides at least in part with the external face (5 ) of a previous wall and in that the next wall part (2b, 2c) which coincides with the previous wall part (2a, 2b) is capable with respect to the breaking lines (9oJ 9 92n + 1) of this prec wall dente at least two positions, a first and a second.  2. Load (1) according to claim 1, characterized in that the walls (2a, 2b) intended to be fragmented are constituted by two trunks of cylinder of revolution around a same axis 00 'the inside diameter of the second trunk of cylinder (2b) being equal to the clearance to allow movement of one cylinder relative to the other to the outside diameter of the first cylinder (2a).  3. Load according to claim 2, characterized in that the rupture lines ....... 92n + 1) forming a rupture network (9) of the first wall (2a) and the rupture lines (lolo, 112n + 1) forming a rupture network (11) of the second wall (2b) are constituted by spirals having for axis, the axis 00 'of the cylinders.  4. Load according to claim 3, characterized in that the wall (2a) constituting the first cylinder is smooth, and in that the breaking lines (9o.. 92n + 1) of the wall (2b) are constituted by grooves dug on one side of the wall (2b).  5. Load according to claim 3, characterized in that the breaking lines ....... 92n + 1 of the network 9 of the first wall (2a) and the network lines (11 112n + 1) of the network ( 11) of the second wall (2b) are superimposed on each other in the first position and offset in the second position so that each line of the second network (11) constitutes a median line of two consecutive lines of the first network (9 ).  6. Load according to claim 3, characterized in that the spirals constituting the breaking lines (90 '.. 92n + 1) of the first network (9) comprises two sub-networks of crossed spirals (9oJ 92' 92n and 91. 92n + 1) the spirals of each of the sub-networks being equidistant from each other, in that the spirals constituting the breaking lines of the second network are made up of spirals (lolo, 112> 112n) which in the first position are superimposed on only one of the sub-networks of the first network (9) and which in the second position constitute the midlines of the consecutive spirals of this same sub-network.  7. Load according to claim 2, characterized in that the network (9) of rupture lines of the first wall (2a) consists of meridians and parallels equidistant from each other, in that the network (11) of the second wall consists of meridians and parallels equidistant from each other and in that in the first position the two networks (9 and 11) are superimposed and that in a second position each of the meridians of the second network (11) is equidistant from two consecutive meridians of the first network (9).  8. Load according to claim 7, characterized in that in a third position each of the meridians of the second network (11) is equidistant from two consecutive meridians of the first network (9) and that each of the parallels of this same network (11) to the exception of the rearmost parallel is equidistant from two consecutive parallels of the first network (9).  9. Load according to one of claims 2 to 7, characterized in that the transition from the first to the second position is obtained by means of a controllable jack (13) capable of two positions and having two ends a first (14 ) and a second (15) each of the ends being rotatably integral with one or the other of the walls (2a, 2b).  10. Load according to one of claims 2 to 7, characterized in that it comprises holding means (18, 19, 20) of the second wall (2b) in the first position and holding means (18, 19, 27) of the second wall (2b) in the second position.  11. Load according to claim 8, characterized in that it comprises means for holding in each of the three positions.  12. Load according to claim 1, characterized in that the walls (2a, 2b) intended to be fragmented consist of two cylinder trunks generated by a straight line required to rest on a polygon and to remain perpendicular to the plane of the polygon .  13. Load according to claim 1, characterized in that the walls intended to be fragmented are constituted by a ferrule of revolution generated by a convex segment in rotation about an axis 00 '.  14. Load according to claim 13, characterized in that the network (9) of rupture lines of the first wall (2a) consists of meridians and parallels equidistant from each other and that the network (11) of the second wall consists meridians which in the first position are superimposed on the meridians of the first network and which in the second position are equidistant each of two consecutive meridians of the first network.  15. Load according to claim 1, characterized in that it comprises three walls.  16. Load according to claim 15, characterized in that one of the three walls does not have its own network of breaking lines.