FR2691798A1 - Chemical self destruct system for sub-munition of carrier shell - Google Patents

Abstract

The self destruct system for the explosive consists of a secondary firing pin (15) mounted inside a housing (5b) in the sliding unit (5) that moves the detonator (6) from its safety position to its armed position in line with the main firing pin. A control device (16) releases the secondary firing pin (15) after a predetermined delay when a corrosive agent (30) attacks the retaining element (25) that holds the sec. firing pin (15) against its seat (28) by an arming spring (26).

Description

 The present invention relates to a mechanical system for self-destruction of a munition, in particular of a submunition ejected from a cargo shell, the ammunition being provided with a military charge initiated by a pyrotechnic chain comprising a main striker. and an initiating device consisting of a slide movable from a safety position to an arming position and which carries a means of initiating the load, the system being of the type comprising a movable secondary striker inside a slide housing intended to strike the initiating means, and a device for controlling the movement of the secondary striker towards the initiating means after a predetermined delay.

 In general, after ejection of a submunition from a cargo shell, the slide which carries the means for initiating the load goes into the cocking position, and when the submunition comes into contact with the ground or of a target, the main striker initiates the military charge by percussion of the priming means.

 However, in the event of a malfunction of the pyrotechnic chain, the ammunition will not explode on contact with the ground or a target. However, once stabilized on the ground, the ammunition remains dangerous, because any new shock can possibly restore the functioning of the pyrotechnic chain and cause the explosion of the munition.

 To overcome this dysfunction, it is known to equip such submunition, on board a cargo shell, with a self-destruction system which causes the explosion of the military charge after a predetermined delay which is greater than the time. flight in free fall of the ammunition before reaching the ground or a target moving on the ground.

 The document US Pat. No. 4,873,927 describes a system of self-destruction by a pyrotechnic delay which is initiated at the time of the arming of the carrier beam slide. After a certain time of combustion of the pyrotechnic delay, the initiation of the military charge is initiated. However, such a system has the disadvantage of being very expensive.

 Document US-4 998 476 describes a self-destruction system comprising a hydraulic or pneumatic piston. This piston, pressing against an oil chamber, moves as soon as a reduction in the volume of this chamber occurs as a result of the opening of a calibrated orifice through which the oil can be evacuated when the slide in cocking position. The piston is then driven in displacement, and at the end of the race, it releases a striker which initiates the means of priming the military charge. Such a system is in reality a micro-mechanism which requires very high precision in production, mounting and operation. It is therefore very sensitive to the external environment and of a high production cost.

 Document EP-0 205 956 describes a self-destruction system having a piston fitted with a secondary striker retained by a pin. After ejection of the submunition and passage of the slide in the cocking position, the pin creeps gradually to break after a determined time under the action of a spring. Such a system has the disadvantage of not being precise, since the delay is given by the creep time of the pin.

 The object of the invention is to design a system for self-destruction of ammunition which is simple, inexpensive and capable of acting with a delay which can be defined in a relatively precise manner compared with known systems.

 To this end, the invention provides a system for self-destruction of ammunition, of the aforementioned type and which is characterized in that the secondary striker is so lidary of a retaining element held in abutment on a seat under the loading of an arming spring, said seat being arranged inside the housing of the bucket grout, and in that the control device of the secondary striker comprises a corrosive agent intended to attack chemically the retaining element to release it from its seat, after said predetermined delay, and cause the secondary striker to move in the direction of the priming means under the thrust of the arming spring.

 For example, the retaining member is made of metal and the corrosive agent is an acid or, alternatively, the retaining member is made of a plastic material and the corrosive agent is a solvent.

 According to another characteristic of the invention, the secondary striker projects from one side of a piston mounted to slide inside the slide housing, the other side of the piston being extended by an axial rod which freely crosses an opening. a radial base forming said seat, and which is terminated by the retaining element such as a collar whose diameter is greater than the diameter of the opening of the base, a spring mounted between the piston and the base , urging the retaining element to bear on its seat.

 According to another characteristic of the invention, the corrosive agent is enclosed in an envelope mounted inside the housing of the slide being located at a distance from the retaining element, and there is provided a device for opening the envelope to bring the corrosive agent into contact with the retaining element.

 According to a first embodiment of the invention, the device for opening the envelope containing the corrosive agent comprises means for projecting the envelope in the direction of the fixed base which holds the retaining element and a perforation means advantageously constituted by the retaining element itself, the means for projecting the envelope being formed by a spring which is held in the banded state by a locking member which projects inside the grout bucket.

 According to a second embodiment of the invention, the device for opening the envelope containing the corrosive agent comprises a means for projecting the base in the direction of the envelope and a perforation means advantageously constituted by the retaining element itself, the projection means of the base being also formed of a spring which is held in the banded state by a locking member which projects inside the slide.

 In these two embodiments, when the locking member of the device for opening the envelope containing the corrosive agent is released, the envelope is perforated by the retaining element and the latter brought into contact with the corrosive agent is attacked chemically. As soon as the retaining element is no longer supported on its seat, after a certain delay, the secondary striker is released and pushed by its associated spring in the direction of the priming means such as a detonator primer. After percussion of the primer, the charge is initiated and the ammunition is destroyed.

 In general, the locking device of the device for opening the envelope containing the corrosive agent can be released during the passage of the slide in the arming position In this case, the functioning of the self-destruction system is subject to the passage of the slide in the cocking position.

By cons, we can consider the release of the locking device when the submunition is ejected from the cargo shell for example, so that the self-destruction system works regardless of the position of the slide. In the latter case and when the slide remains blocked in the safety position, there is not strictly speaking a self-destruction of the munit ion, but a neutralization of the latter by destruction of the detonator primer.

 The delay necessary for the corrosive agent to release the secondary striker must be calculated to be greater than the flight time in free fall of the munition before reaching the ground, to allow the main pyrotechnic chain, in normal operation, to initiate the charge of the submunition during its impact on the ground, the self-destruction system being designed to destroy the ammunition in the event of failure of the pyrotechnic chain after the impact on the ground of the submunition .

The invention applies in particular to a munition, in particular a submunition on board a cargo shell, which will be described later with a self-destruction system based on the second embodiment mentioned above.
With a self-destruction system according to the invention, it is possible to determine, in a relatively precise manner, the time of the chemical reaction which is necessary to release the secondary striker, depending on the nature of the corrosive agent, of the material constituting the retaining element and of the dimensions thereof.

 One of the advantages of the self-destruction system according to the invention lies in the fact that it is constituted by simple mechanical elements, easy to implement and of reliable operation.

Other advantages, characteristics and details of the invention will emerge from the explanatory description which follows, made with reference to the attached drawings, given solely by way of example, and in which - Figure 1 is a schematic sectional view of princi
eg of a self-destruction system according to the invention, - Figure 2 is a partial axial sectional view of a
first embodiment of a car system
destruction according to the invention in its position
initial before operation, - Figure 3 and 4 are views similar to those of
Figure 2, but respectively representing the state of
system in an intermediate position and in its
final position at the end of operation, - Figure 5 is a partial axial sectional view of a
ammunition equipped with a self-destruction system according to
a second embodiment of the invention, the neck
strip in which the car system is housed
destruction being shown in the safety position, - and Figure 6 is an axial sectional view similar to
that of Figure 5, but with the slide represented
felt in the cocking position, - and Figure 7 is a sectional view along the line
VII-VII of figure 5.

 The principle of the invention is illustrated in FIG. 1 with the representation of a pyrotechnic chain 1 comprising a main striker 2, a priming device 3 and an explosive charge 4 for example. The priming device 3 is constituted by a slide 5 movable in translation which supports a detonator primer 6 intended to be struck by the main striker 2 to initiate the charge 4, in a manner known per se.

 The bucket grout 5 is movable between a safety position where the primer 6 is not aligned along the axis of the striker 2 and a cocking position where the primer 6 is located opposite the striker. This latter position is represented in FIG. 1. The priming device 3 thus forms a switch of the pyrotechnic chain 1, the load 4 can only be initiated if the slide 5 has passed into the arming position.

 Such a pyrotechnic chain 1 is in particular incorporated in a munition, in particular in a submunition of cargo shells, and for the reasons indicated in the preamble, such ammunition is equipped with a self-destruction system 10 linked to the device initiation 3 of the pyrotechnic chain 1, system which has the function of self-destroying the ammunition, after a predetermined delay, in the event of a malfunction of the pyrotechnic chain 1.

 Generally, the slide comprises two housings 5a and 5b separated from each other by an internal wall 11 pierced with a passage orifice 12. The housing 5a contains the detonator primer 6 and opens out at the outside by two diametrically opposite orifices 13a and 13b intended to be respectively opposite the main striker 2 and the load 4, when the slide 5 is in the cocking position. The housing 5b is intended to contain the self-destruction system 10.

 The self-destruction system 10 comprises a secondary striker 15 and a control device 16 which releases the striker 15 in the direction of the primer 6, after a predetermined delay.

 The secondary striker 15 is fixed to the front face of a piston 18 movable in translation inside the housing 5b of the slide 5. The other face of the piston 18 is extended by an axial rod 19 which freely crosses a central opening 20 a radial base 21 mounted inside the housing 5b, and which ends in a retaining element 25, such as a flange for example.

A spring 26 is mounted, in the banded state, around the rod 19 by taking respectively support on the base 21 and the piston 18, to apply the retaining element 25 around the opening 20 of the base 21 forming a seat 28.

 The control device 16 of the auxiliary striker 15 comprises a corrosive agent 30 enclosed in an envelope 31 and a device for opening this envelope 31 for bringing the corrosive agent 30 and the retaining element 25 into contact. opening of the envelope 31 comprises a projection means formed by a piston 32 movable in translation under the thrust of a spring 33, and a perforation means advantageously constituted by the retaining element 25. The envelope 31 is by example secured to the front face of the piston 32, for example by bonding, and the spring 33 respectively bears on the rear face of the piston 32 and on a disc 34 which closes the housing 5b of the slide 5.

 A locking member 35 projects radially inside the housing 5b to retain the piston 32 and keep the casing 31 away from the retaining element 25. The locking member 35, such as a pin, makes for example projecting into a groove 36 provided on the peripheral surface of the piston 32.

 Thus, when the locking member 35 is released from the groove 36 of the piston 32, the casing 31 is projected by the spring 33 onto the retaining element 25 and perforated by the latter. After a certain delay, the retaining element 25 chemically attacked by the corrosive agent 30 no longer has sufficient dimensions to remain in abutment on its seat 28, and the secondary striker 15 is released and pushed by the spring 26 to strike the primer 6 through the opening 12 of the wall 11 which separates the two housings 5a and 5b of the slide 5. The primer 6 initiates the charge 4 which destroys the ammunition.

 The self-destruction system 10 according to the first embodiment described above is shown in Figure 2, with certain elements which will be described in detail to give a concrete example of embodiment.

 The radial base 21 which forms the seat 28 for the retaining element 25 has a hollow axial central boss 40 whose bottom wall is pierced with the opening 20. The base 21 is for example fixed inside the housing 5b of the slide 5 by a crimping 21a for example.

 The envelope 31 which contains the corrosive agent 30 is a glass bulb for example, housed inside the piston 32 having the shape of a tubular element which supports towards one end an O-ring seal 42 held in place by a radially internal fold 32a provided at said end of the piston 32 and which presents towards its other end an internal annular boss 43, with the groove 36 which receives the locking member 35 situated at the level of this boss 43. The spring 33 which pushes the piston 32 rests on the one hand on the boss 43 and on the other hand on the disc 34.

 The envelope 31 is housed in the piston 32 between the boss 43 and the seal 42, being fixed by gluing for example.

 For example, the retaining element 25 is made of a metallic material and the corrosive agent 30 is an acid, such as hydrochloric acid, or alternatively, the retaining element 25 is made of a plastic material and the corrosive agent 30 is a solvent, such as acetone.

 When the locking member 35 is released from the slide 5, the spring 33 pushes the piston 32 and projects the casing 31 onto the retaining element 25 by perforating the latter, as illustrated in FIG. 3. corrosive agent 30 is then in contact with the retaining element 25, and the seal 42 bearing on the base 21 prevents the corrosive agent from spreading outside the casing 31, this ci not being exploded but only perforated by the retaining element 25 in the example considered here.

 Following the chemical attack by the corrosive agent 30, the retaining element 25 is destroyed, and the secondary striker is released and pushed by the spring 26, as is schematically illustrated in FIG. 4.

 Referring to Figures 5 to 7, there is partially shown an ammunition, in particular a submunition 50 on board a cargo shell, as described in more detail in US Patent 4,488,488, and equipped with a system of self-destruction 10 according to a second embodiment.

 Generally, the submunition 50 comprises an envelope in which the explosive charge is housed, and this envelope is surmounted by an arming security device 51 which notably comprises the main striker 2 and the initiation device 3 consisting of the slide 5 which supports the detonator primer 6.

 For reasons of simplification and clarity, the representation of the submunition 50 has been deliberately limited to its armament security device 51 in which the self-destruction system 10 is mounted.

 Referring to Figure 5, the slider 5 is slidably mounted inside a housing 52 of the body 53 of the armament security device 51, and it is in particular maintained in the security position by the main striker 2 which projects into a radial opening 54 of the slide 5. The main striker 2 is, in a manner known per se, screwed into a nut 55 integral in rotation with the body 53. The slide cooperates with two springs 57, being bandaged, located on either side of the slide 5 to pass it into the cocking position (Figure 7).

 In the self-destruction system 10 housed inside the slide 5, the base 21 which forms the seat 28 for the retaining element 25 is mobile and the casing 31 which contains the corrosive agent 30 is fixed .

As can be seen in FIG. 7, the base 21 is extended at the front by two wings 21a which project by lateral openings 58 outside the slide 5.

The two springs 57 are supported on the two wings 21a, so that the envelope opening device 31 comprises a projection means constituted by the base 21 movable in translation under the thrust of the springs 57, and a means of perforation always advantageously constituted by the retaining element 25.

 The locking member which keeps the base 21 away from the casing 31 as long as the self-destruction system 10 is not actuated, consists of a ball 60 interposed between the base 21 and the piston 32 Pressed by the springs 57 which bear on one side against washers 57a crimped on the body 53 and on the other side on the base 21, the ball 60 rests on a bottom plate 61 through an opening 62 produced in the slide 5. The piston 32 has a conical fold 32a intended on the one hand to maintain the seal 42 and on the other hand to promote the ejection of the ball 60, as will be explained below.

 In a first phase of ejection, following the firing of the cargo shell in which the submunition 50 is loaded, the latter is ejected from the cargo shell.

 In a second arming phase, a stabilizing tape for example (not shown) fixed to the main striker 2 is deployed when the munition 50 falls. The stabilizing tape, under the effect of its aerodynamic drag combined with a rotational movement of the submunition 50 causes partial unscrewing of the main striker 2 screwed into the nut 55.

 The main striker 2 then emerges from the opening 54 of the slide 5 which, by the relaxation of the arming springs 57 which are associated with it, is moved in translation towards its arming position illustrated in FIG. 6.

 In the first phase of its travel, the bucket grout 5 translates under the thrust of the arming springs 57, by means of the base 21 bearing against the ball 60 itself bearing against the piston 32 which is now attached to the slide 5.

In the second phase of its stroke, the bucket grout 5 protrudes outside the housing 52 of the body 53 of the armament security device 51, which has the effect of matching the opening 62 of the slider 5 with a clearance 63 produced in the bottom plate 61 by which the ball 60 is ejected. The ejection is favored by the particular conical profile of the fold 32a of the piston 32. The springs 57 then project the base 21 onto the casing 31 and the retaining element 25 pierces the latter.

 At the end of the race, the bucket grout 5 by means of the lateral wings 21a of the base 21 against which the springs 57 bear, abuts against an internal annular abutment surface 63 provided in the housing 52. The slide 5 is then moved into the cocking position, as illustrated in FIG. 6.

 In a third phase which corresponds to the end of the fall to the ground of the submunition 50, the explosive charge 4 is initiated, in normal operation, following the percussion of the detonator initiator 6 by the main striker 2 which s 'is suddenly displaced by the deceleration movement caused by the impact of the submunition on contact with a target or the ground.

 In the event of malfunction of the main striker 2 for example, the submunition 50 is not initiated, and the self-destruction system 10 takes over to initiate the detonator primer 6 and detonate the submunition 50 after a predetermined delay calculated to be greater than the fall time of the submunition 50 towards the ground. This delay corresponds to the time taken by the corrosive agent 30 to destroy the retaining element 25 which retains the secondary striker 25.

 In this case, however, if the slider 5 has not passed into the arming position, the self-destruction system is inoperative.

 Thus, as a variant, it is possible to provide for a release of the pin 35 or of the locking ball 60 following the ejection of the submunition 50 from the cargo shell, and not following the passage of the slider 5 in position of weapons. I1 will suffice for this to have the locking pin 35 for example in a radial direction relative to the axis of the submunition 50 in a housing such that the pin 35 is ejected by the centrifugal force of inertia, whatever or the position of the slide 5. The advantage of such an arrangement is that it allows the neutralization of the submunition 50 by destruction of the primer 6 at the end of a certain delay, and this even if the slide 5 is not in the armed position.

 Of course, the invention is in no way limited to the two preceding embodiments described only by way of example. In particular, the choice of the nature of the corrosive agent and of the material which constitutes the retaining element may be different from the examples given. Finally, the retaining element constituted by a flange at the end of the rod 19 can be formed by an independent element fixed to the rod or by machining the end of the rod.

Claims (10)

 1. Self-destruction system of an ammunition, in particular of a submunition of cargo shells, the ammunition being provided with a military charge initiated by a pyrotechnic charge comprising a main striker and a priming device consisting of a slide movable between a safety position and an arming position, and which carries a means of initiating the load, the system being of the type comprising a secondary striker mounted inside a housing of the slide and movable between a safety position and a percussion position of the priming means, and an actuating device for releasing the secondary striker after a predetermined delay, characterized in that the secondary striker (15) is integral with an element retaining (25) held in abutment on a seat (28) under the bias of an arming spring (26), said seat (28) being disposed inside the housing (5b) of the slide (5), and in that the dispositi f control (16) of the secondary striker (15) comprises a corrosive agent (30) intended to attack chemically the retaining element (25) to release it from its seat (28), after said predetermined delay, and cause displacement of the secondary striker (15) in the direction of the priming means (6) under the thrust of the arming spring (26).  2. System according to Claim 1, characterized in that the secondary striker (15) projects on one face of a piston (18) slidably mounted inside the housing (5b) of the slide (5), the other face of the piston (18) extending by an axial rod (19) which freely passes through an opening (20) of a radial base (21) forming said seat (28), and which is terminated by the retaining element ( 25) consisting of a collar whose diameter is greater than the diameter of the opening (20) of the base (21), the arming spring (26) associated with the retaining element (25) being mounted between the piston (18) and the base (21).  3. System according to Claim 1 or 2, characterized in that the corrosive agent (30) is contained in an envelope (31) located at a distance from the retaining element (25), said envelope (31) being associated with a device for opening the latter in order to bring the corrosive agent (30) into contact with the retaining element (25).  4. System according to Claim 3, characterized in that the opening device comprises a means of projection (33) of the envelope (31) in the direction of the retaining element (25) and a means of perforation formed by the latter, the projection means being constituted by a spring (33) which is held in the bandaged state by a locking member (35) which projects inside the slide (5).  5. System according to Claim 4, characterized in that the envelope (31) is supported by a piston (32) movable in translation under the thrust of the spring (33).  6. System according to Claim 5, characterized in that the opening device comprises a projection means (57) of the base (21) integral with the retaining element (25) in the direction of the envelope (31 ) fixed, and a means for perforating the envelope (31) formed by the retaining element (26).  7. System according to Claim 6, characterized in that the projection means (57) consists of springs (57) held in the bandaged state by a locking ball (60) which projects inside the slide (5).  8. System according to Claim 9, characterized in that the base (21) comprises two lateral wings (21a) which project outside the slide (5) and under which the springs (57) also used for move the slide (5) to the cocking position.  9. System according to Claim 1, characterized in that the retaining element (25) is made of metal, and in that the corrosive agent (30) is an acid.  10. System according to Claim 1, characterized in that the retaining element (25) consists of a plastic material, and in that the corrosive agent (30) is a solvent.