FR2771165A1 - DEMINING AMMUNITION - Google Patents

Abstract

The shell comprises a projectile (1) launched by a propulsive charge and containing a disperser (7) for one or more magnetic field generators (8) in the form of magnetic sub-projectiles.

Description

I

  The technical field of the invention is that of demining ammunition, in particular for landmines.

  Demining munitions make it possible to clear a passage in a minefield from a safe distance.

  Depending on their size and power, they are implemented either by a person or by a vehicle.

  Known demining munitions generally include an explosive charge which is initiated at

  in the vicinity of the mines so as to cause them to detonate.

  The patent US4776255 thus describes a self-propelled projectile which deploys a detonating cord on its trajectory.

  The line is initiated when it comes into contact with the ground.

  Demining munitions are also known in which the explosive is initiated at a distance from the ground. It is the breath of the explosion which then causes the initiation of mines.20 These demining munitions are ineffective against anti-tank mines of new generations whose igniter is designed to withstand the shock caused by the initiation of a explosive charge. New generation anti-tank mines are generally equipped with a magnetic sensor igniter which allows them to detect the approach of the large ferro magnetic mass formed by a tank or a vehicle. Known demining systems which make it possible to initiate such mines remotely include an electromagnetic generator secured to a vehicle and which projects in front of the latter a magnetic signature close to that

  of a tank. Patent FR2701105 describes such a demining system.

  However such systems are expensive, consume

  a lot of energy and therefore cannot equip all combat vehicles.

  In addition, they can only initiate mines in front of the vehicle and at a relatively short distance (of the order

3 m).

  It is the object of the invention to provide a demining munition which overcomes such drawbacks.

  Thus, the ammunition according to the invention is inexpensive and can therefore be supplied as an endowment to all combat vehicles to enable them to ensure their self-protection.

  It can also be designed light enough to be used by infantrymen.

  Finally, it is effective against all new generation mines equipped with a magnetic sensor and against which the demining munitions which use explosives are ineffective. Thus the subject of the invention is a demining ammunition in particular for landmines, and comprising at least one projectile launched by means of a propellant charge, ammunition characterized in that the projectile contains at least one magnetic field generator ... According to a particular embodiment, the projectile may include dispersing means making it possible to

  release the magnetic field generator (s) on the trajectory.

  According to a preferred embodiment, the projectile contains several magnetic field generators constituted

  by magnetized sub-projectiles. 25 The sub-projectiles may have the form of balls or else have two conical ends.

  According to a particular embodiment, the sub-projectiles may include a core of magnetic material coated with a plastic casing. 30 The material of the magnetic core or sub-projectile will have a coercive field greater than 40,000 A / m and a field residual greater than 0.8 Tesla. Advantageously, the material of the magnetized core or subprojectile will be chosen from the following materials:

AlNiCo V, SmCo5, Neodymium.

  According to an alternative embodiment, the plastic material of the envelope coating the core is colored and / or fluorescent. According to another embodiment, the projectile will comprise or less a case or container containing the

  sub-projectiles, the dispersing means being constituted by an explosive dispersing charge placed at the axis of the housing or the container.

  Advantageously, the ammunition may include at least two projectiles disposed in a launch tube intended to

  be secured to a shooting platform, tube containing an ejection charge.

  The invention will be better understood on reading the description which follows of particular modes of

  embodiment, description made with reference to the accompanying drawings and in which: FIG. 1 shows a projectile of a munition of

  demining according to a first embodiment of the invention, FIG. 2 shows a projectile of a demining munition, following ... a ... second embodiment of the invention, FIG. 3 represents in section a particular embodiment of a magnetic field generating sub-projectile, FIG. 4 represents in longitudinal section a demining munition according to a third embodiment of the invention, section made along the plane marked BB in FIG. 5 , FIG. 5 is a cross-sectional view of this munition, a section taken along the plane marked AA on the

  Figure 4.30 - Figures 6a and 6b are diagrams showing two operating phases of a munition according to the invention.

  FIG. 7 is a sectional view of another particular embodiment of a magnetic field generator sub-projectile. Referring to FIG. 1, a demining munition according to a first embodiment of the invention comprises a propellant charge (not shown) and a projectile 1. The projectile here is an artillery or mortar projectile and its propellant charge will for example be contained in a cartridge case or a gargoyle. In a conventional manner, the projectile 1 comprises a body 2 on which a warhead 3 and a base 4 are fixed by threading or riveting. A belt for sealing against propellant gases 5 is crimped at a rear part of the body 2, and it allows the

  firing of the projectile from a weapon system (not shown) such as a cannon or a mortar. 10 The warhead 3 carries at its front part a chronometric rocket 6 programmable, mechanical or electronic.

  This rocket is intended to initiate a gas-generating pyrotechnic composition 7. The body 2 of the projectile contains generating means

  magnetic field 8, which will be described below, as well as a pusher piston 19.

  The magnetic field generating means here consist of magnetic sub-projectiles having the shape of balls (approximately 140 balls of 12 mm in diameter). Figure 3 shows such a sub-projectile 9 in section. It has a parallelepipedic core 10 (here for example

  cubic) made of a magnetized material generating a magnetic field of high intensity, core coated by an envelope 11 of plastic material (for example a deformable polymer such as rubber).

  Each ball has a diameter of 10 to 20 mm, the side of the cube is between 8 mm and 12 mm.

  The magnetic material will be chosen so that it has a coercive field greater than 40,000 A / m and a field

residual greater than 0.8 Tesla.

  We can for example choose as magnetic materials the sintered alloys usually used to make the permanent magnets of DC motors: Al-Ni-Co V (Aluminum / Nickel / Cobalt) whose coercive field is 52000 A / m and the field residual of 1.25 T, Sm-Co5 (Samarium / Cobalt) - coercive field: 440000 A / m, residual field 0.9 T, Neodymium - coercive field: 689700 A / m, residual field:

1.3 T.

  The casing 11 has the function of absorbing the shocks received by the core, both during the firing of the projectile and during the dispersion of the subprojectiles. By its deformability elle5 also allows a positioning of the sub-projectiles without play in the body of the projectile, the sub-projectiles then being kept slightly compressed between the base 4 and the piston 19. It is advantageously possible to produce the envelope in one

  l0 colored or phosphorescent plastic, this will ensure marking of the cleared area.

  The operation of this munition is as follows.

  After locating an area of land to be demined and evaluating its distance, the chronometric rocket 6 is programmed in a known manner (manually or with a programming system not shown) by entering therein data relating to the instant at which the dispersion must be controlled from the instant of shooting. This moment depends on the characteristics of the shot (speeds and angles of

  shooting) and it is given by a shooting table.

  A firing platform launches projectile 1 towards the area to be demined. At the end of the programmed time interval, the rocket 6 initiates the dispersing means constituted by the pyrotechnic charge 7. The pressure of the gases 25 generated pushes the piston 19 which exerts pressure on the base 4 via the balls 9 forming the field generating means 8. The means for securing the base and the body 2 is sheared and the balls 9 are dispersed above the area to be demined. The speeds of the different balls are variable in intensity and orientation and their relative positioning is also variable. This results in a global magnetic field generated by the set of balls which is variable in orientation. The level of this field is sufficient to trigger most passive igniter mines. The variability of the field also makes it difficult

  the design of a mine igniter hardened to this type of decoy.

  FIG. 2 shows another embodiment of a demining munition according to the invention.

  This mode differs from the previous one in that the body 2 of the projectile 1 contains, not a stack of balls, but a container 12 formed of a metal envelope 13 closed at each end by a cover 14a, 14b.

  The cover 14b carries a delay igniter 15 which is connected by a connection 16 to the rocket 6.

  The igniter 15 is connected to an explosive charge of O10 dispersion 17 placed in a sheath coaxial with the container

  12. The dispersion charge will for example be a charge combining aluminum and potassium perchlorate.

  The container 12 contains a magnetic field generator 8 formed by a stack of magnetic beads

  as previously described.

  The operation of this embodiment is as follows.

  When the projectile 1 is above the area to be demined, the rocket 6 causes on the one hand the initiation of the pyrotechnic charge 7 and on the other hand (via the connection 16) that of the pyrotechnic delay of

  the delay igniter 15. The gas pressure pushes the piston 19 which ejects the base 4 and the container 12.

  It then follows its own trajectory towards the ground.

  Its orientation relative to the ground and its speed can be corrected by conventional means used on submunitions and not shown here: braking fins, parachute ... 30 When the pyrotechnic delay of the igniter 15 is consumed, the charge Explosive dispersion 17 is initiated and it causes the container 12 to rupture and the magnetic balls to disperse. The advantage of this embodiment compared to the previous one is that it allows the balls to be released at a shorter distance from the ground (for example of the order of 2 to 5

  m), this results in less dispersion of the balls in space and a greater efficiency of mine clearance.

  As a variant, it is of course possible to have several separate containers 12 inside the

  body of the projectile 1. Each container will contain magnetic beads and an explosive charge of dispersion initiated by a pyrotechnic delay. This will result in a better spatial distribution of the beads.

  Figure 4 shows ammunition according to a third embodiment of the invention.

  This ammunition 101 comprises a case 102 which carries at the level of a rear part 102a a base 103 carrying a radial lug 104 which authorizes a fixing of the ammunition by a bayonet mounting on a launcher (not shown) which is integral with a structure such as a vehicle or a fixed structure.15 The case 102 is closed at its front by a plug

  secured to the case by at least one radial pin 121.

  The case 102 has a rear flange 102b which is pinched between a shoulder of the base 103 and a nut 105

screwed to the base.

  The base 103 carries an electric igniter 106 fixed on a support 107 glued to the base 103. The electrical wires of the igniter 106 are connected to an axial contact 108 on the one hand and to the base 103 on the other hand , the axial contact being electrically isolated from the base. The support 107 contains a pyrotechnic ejection charge 109 which is constituted, for example, by a propellant powder or an ignition powder. The case 102 also contains a piston 110 on which is placed a stack of two demining projectiles IIIa, IIIb. The piston 110 has a diameter smaller than that of the case 102 and is supported on a counterbore arranged at the rear of the projectile IIIa. The case 102 thus constitutes a launching tube for the projectiles 111, the ejection charge 109 being intended to

  generate gases which will be applied to the piston 110 which will push the projectiles out of the case.

  Each projectile 111 is formed by a cylindrical casing 112, for example made of aluminum and which is closed by

  a bottom 114 and a cover 113 screwed.

  The bottom 114 carries an axial housing which receives an ignition plug 116 comprising a pyrotechnic composition with

  delay. 5 An explosive charge of dispersion 117 is placed in a plastic sheath 118 coaxial with the housing 112.

  The housing also contains a magnetic generator formed by a stack of balls of the type described

  previously (approximately 70 balls of diameter 12 mm per 10 casing).

  The bottom 114 of each projectile 111 is positioned set back relative to the rear end of the housing. Such an arrangement allows on the one hand to provide a chamber 122a between the rear projectile 11la and the piston 110 and a

  chamber 122b between the two projectiles lla and lllb.

  The housing of each projectile has two radial notches 123 arranged at its rear part (see FIG. 5) and

  the housing 112a of the rear projectile IIIa also has two longitudinal grooves 119 along two generators.

  The notches 123 of the rear projectile make it possible to pass part of the propellant gases generated by the ejection charge 109 to the chamber 122a and the delay igniter of the rear projectile 111a. 25 The longitudinal grooves 119 also pass part of the gases propellants towards the chamber 122b separating the

  two projectiles Mlla and lllb, this through the notches 123 arranged on the housing 112b of the front projectile lllb.

  The propellant gases therefore also ensure the ignition of the pyrotechnic compositions with delay of the two projectiles, these compositions will ensure the initiation on the trajectory of the dispersion charges 117. These grooves 119 are calibrated so as to let pass enough gas for the ignition of the delay and avoid a

  too much pressure between the two projectiles which would brake the rear projectile.

  The operation of such ammunition will now be described with reference to Figures 6a and 6b.

  The case 102 of the ammunition is fixed to a launcher 124 secured to a vehicle or a structure 125.

  When firing the ammunition the ejection charge is initiated and it causes the opening of the cover 120, the ignition of the delays 116 and the expulsion of the two projectiles 111a, IIIb. At the end of the combustion of the pyrotechnic delays of each projectile, the charges of dispersions 117 are

  initiated (fig 6a) and they cause the dispersion of the magnetic balls (fig 6b) which detonate the mines 126.

  We will play on the values of the different delays to ensure the initiation of each projectile at a desired point of the ballistic trajectory. 15 We could for example produce a munition for which the first Mlla projectile is initiated at a distance Dl from the launcher of the order of 15 m and the second lllb projectile is initiated at a di-stance-D2-of the launcher - of the order of 40 m. For each projectile the heights Hi and H2 relative

  on the ground are substantially the same and close to 3 m.

  The balls are then distributed on the ground over an area of approximately 200 mz.

  A vehicle equipped with such a launcher of demining ammunition can therefore easily ensure the clearance of passages

  about 10 m wide by 20 m long.

  The launcher and the ammunition are light and inexpensive elements which can equip any type of vehicle, from the tank to the light infantry vehicle. Launchers adapted to this ammunition are already in service on many vehicles and30 allow the dispersal of smoke ammunition or close defense grenades. Demining ammunition according to

  the invention therefore makes it possible to easily and inexpensively provide these vehicles with a rapid demining capacity which is also more effective than pyrotechnic deminers against new generation mines.

  FIG. 7 shows another embodiment of a magnetic sub-projectile 9.

  This sub-projectile differs from that of FIG. 3 in that the core 10 is a rectangular parallelepiped and the casing 11 is formed by a central cylindrical part lla on which two conical ends llb and 11c.5 are connected. The axis 19 tapered ends and the cylindrical part of the envelope 11 is perpendicular to the direction 20 of great length 21 of the core 10. Thus the magnet formed by the core 10 has its north (N) and south (S) poles located on either side of axis 19 of

envelope 11.

  Such sub-projectiles are placed in a projectile as described with reference to FIGS. 1, 2 or 4 with their axes 19 all parallel to one another and parallel to the axis of the carrying projectile (1 or 111) .15 The aerodynamic structure particular of this sub-projectile favors its rotation around its axis 19 compared to the rotations along other axes ... a rotation around the axis 19 causes a periodic variation of the orientation of the magnetic field generated by

  each core 10. This improves the effectiveness of mine clearance.

  As a variant, it is of course possible to give other forms to the sub-projectiles, for example to define a sub-projectile having two conical ends connecting at their large bases (a projectile according to FIG. 7 devoid of part cylindrical 11a). It is also possible to define sub-projectiles made of magnetic material and devoid of a plastic casing. he

Claims (7)

  1-Demining ammunition in particular for landmines, and comprising at least one projectile (l, llla, lllb) launched by means of a propellant charge, characterized in that the projectile contains at least one magnetic field generator (8) . 2-demining ammunition according to claim 1, characterized in that the projectile (l, llla, lllb) comprises   dispersing means (7,17,117) enabling the magnetic field generator (s) to be released on the trajectory.   3-demining ammunition according to claim 2, characterized in that the projectile (l, llla, lllb) contains   several magnetic field generators constituted by magnetized projectiles (9).   4-demining ammunition according to claim 3, characterized in that the sub-projectiles (9) have the shape of balls. 5-demining ammunition according to claim 3,   characterized in that the sub-projectiles (9) have two conical ends.   6-demining ammunition according to one of claims 3 to   , characterized in that the sub-projectiles (9) comprise a core (10) of magnetic material coated by an envelope (11) made of plastic.   7-demining ammunition according to one of claims 3 to   6, characterized in that the material of the core (10) or of the magnetic sub-projectile (9) has a coercive field   greater than 40,000 A / m and a residual field greater than 0.830 Tesla.   8-demining ammunition according to claim 7, characterized in that the material of the core or the sub   magnetic projectile is chosen from the following materials: AlNiCo V, SmCo5, Neodymium. 35 9-Demining munition according to one of claims 6 to   8, characterized in that the plastic material of the envelope   (11) is colored and / or fluorescent.   -Mining clearance according to one of claims 3 to   9, characterized in that the projectile comprises at least one box or container (12,112) containing the sub-projectiles (9), the dispersing means being constituted by an explosive dispersing charge (17, 117) disposed at the level of the axis S of the case or container.   11-Ammunition according to one of claims 1 to 10, characterized in that it comprises at least two projectiles   (llla, lllb) arranged in a launch tube (102) intended to be made integral with a shooting platform, tube   containing an ejection charge (109).