FR2791425A1 - Device for deconfining wall of rocket, missile, etc., comprises charges with explosive load, initiated by detonation relay linked to control unit - Google Patents

Abstract

Charge (10) has axis (12) slightly inclined relative to wall (5) of engine body with angle alpha smaller than or equals to 15 deg , and has explosive load (14) placed in envelope (15) where concave coating (16) is applied. Charge is initiated by detonation relay (17), initiated by detonator (18) linked to control unit (13). Charge is placed in area between floors (4) and is near bottom (8) of propeller. Jet from initiation of charge induces longitudinal cutting of wall and thermal protection (6).

Description

279-1425

  DEVICE FOR DECONFINING AN AMMUNITION BODY

  The technical field of the invention is that of devices for ensuring the deconfinement of a body.

  of ammunition, and more particularly of a wall of a rocket, missile or rocket propellant.

  A certain number of concepts are known which allow one or more cuts to be made in the wall of an ammunition body, for example to avoid an explosion which would be caused by a fire.10 Patent FR2608265 thus proposes using a cord of cut out to separate the base from the body of a bomb. The cord is initiated by a heat sensitive igniter. Thus, when the bomb is in a fire, the resulting rise in temperature automatically causes the base of the bomb to be cut. The explosive charge is no longer confined to the shell of the ammunition and any risk of explosion is avoided. Solutions using cutting lines are also used to ensure the destruction in flight of a missile propellant, in particular to minimize the risks caused by a loss of control of the missile. The destruction of the propellant ensures braking of the machine which limits the extent of the trajectory not

controlled.

  In this case, several cords are arranged longitudinally along the walls of the propellant body

  and they are initiated by a control system which is connected to a remote control operated from the ground.

  However, such a solution has drawbacks.

  Thus, the installation of the cutting cords is complex because long lengths of cords are

  necessary (about 10 m of cord for a missile whose propellant has a diameter of 2m and a length of 6m) .35 This results in mounting difficulties, resulting in additional cost and reliability problems.

  The assembly is made all the more complex as the cords must generally be placed outside the casing of the propellant in order to avoid their destruction or deterioration by the normal functioning of the propellant. 5 Furthermore the casing of the propellants of ballistic missiles is generally thick (greater than or equal to mm with internal thermal protection), which leads to the provision of strings of large diameter whose integration is even more delicate.10 Finally, the known solution only ensures the opening of the propellant body and does not destroy the contents of the propellant. The propellant charge risks retaining its propulsive regime, driving the machine on an uncontrolled trajectory. It is the aim of the present invention to propose a deconfinement device which does not have such drawbacks. Thus the device according to the invention makes it possible to ensure reliable deconfinement of a propellant body even of large

  dimensions while being inexpensive, compact and simple to implement.

  In addition, the device according to the invention not only ensures deconfinement but also the destruction of the propellant charge by the combustion of the latter. Thus the subject of the invention is a device for deconfining a body of ammunition, in particular of a propellant, by cutting a wall of this body, device characterized in that it comprises at least one shaped charge disposed in the vicinity of the wall of the body and 30 whose axis is coincident or slightly inclined relative to to this wall, a hollow charge, the initiation of which is caused by a control means and which is oriented so as to ensure a longitudinal cutting of the wall of the body. Advantageously, the axis of the load is inclined by

  relative to the wall by an angle less than or equal to 15.

  According to a particular embodiment, the load is arranged in the vicinity of a bottom of the body and has its axis oriented towards the outside of the body. The charge may have a diameter between 75 and 150 mm and may be a hollow charge or a charge generating a core. Advantageously, the device could comprise three charges regularly distributed angularly around the axis of the body.10 The control means could be associated with means making it possible to detect a loss of the radio link.

  ammunition guidance. The control means may be remotely controllable.

  The control means may be associated with means

  to detect a rise in temperature.

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

  embodiment, description made with reference to the accompanying drawings and in which: FIG. 1 schematically represents a ballistic missile as well as the location of the device for

  deconfinement according to the invention, FIG. 2 is a detail view of a particular embodiment of a deconfinement device according to

the invention.

  Referring to FIG. 1, a ballistic missile 1 includes a payload 2, for example an explosive warhead,

  and a propellant 3, separated by an inter-stage space 4, where the electronic guidance systems (not shown) are housed.

  The propellant body comprises a wall 5 made of filament wound and covered on its internal surface by

  thermal protection 6, for example rubber. The total thickness of the wall 5 and of the covering 6 is approximately 30 mm for a propellant body 2 m in diameter and 6 m long.

  A propellant charge 7 is disposed inside the propellant body, it is for example constituted by a

propellant block.

  The propellant body has a bottom 8 which separates it from the inter-stage space 4 and it ends in a nozzle 9 ensuring the ejection of the propellant gases. According to the invention, one or more formed charges are placed in the inter-stage space 4 10. If several charges are provided, they are regularly distributed around the axis 11 of the propellant and arranged substantially on the same circumference in the same plane perpendicular to the axis of the propellant. Each formed load 10 has its axis 12 slightly inclined

  relative to the wall 5 of the propellant body of an angle a which will be chosen less than or equal to 15.

  Furthermore, each charge formed is positioned radially with respect to the axis of the missile so that its axis 12 intersects the bottom 8 at a point A which is located at a distance d20 from the external cylindrical wall of the propellant which is substantially equal to the total thickness of the wall 5 and of the thermal protection 6. Such a choice of the angle and of the positioning of the load makes it possible to ensure that the jet generated by the load will perform a longitudinal cutting of the wall 5 as well as thermal protection of the body along a sufficient length L (at least equal to 1 m). The inclination of the load also ensures such a longitudinal cut to a suitable length while allowing positioning of the loads entirely.

  inside the inter-floor space.

  The charges formed are connected to a control means 13 which is intended to cause their initiation at a given time. This control means can advantageously be

  consisting of part of the missile's control / guidance electronics.

  The initiation of the charge (s) 10 will be caused on the trajectory of the missile at a given time. This initiation

  can advantageously be remotely controlled from the ground in the event of detection of a serious event (failure of the missile, 5 rocking, exit of a given perimeter ...).

  The prompt may also be triggered automatically by the missile's electronics in the event of loss of the ground link (loss of guidance and / or control). Finally, the deconfinement also making it possible to avoid an explosion of the propellant, it is possible to provide a temperature sensor connected to a specific control means in order to

  trigger loads in the event of an abnormal rise in temperature (in the event of a fire in a storage area, for example) .15 Figure 2 shows more precisely the structure and arrangement of a load formed from deconfinement 10.

  This charge comprises an explosive charge 14 placed in an envelope 15 and to which a concave, for example conical, coating 16 is applied. The explosive charge is initiated by a detonation relay 17, itself initiated by a detonator 18 connected to the

  control means 13. The load is placed in the inter-stage space 4 and in the vicinity of the bottom 8 of the propellant.

  Thus its axis 12 cuts the bottom 8, crosses the thermal protective coating 6 and part of the load

  propellant 7. It emerges from the propellant body at a distance L from the bottom 8 which is approximately 1 m for an angle of inclination a of the axis 12 of the order of 15.

  The jet generated by the initiation of the charge 10 will therefore cause a longitudinal cutting of the wall 5 of the body as well as that of the protective coating 6. This cutting will ensure rapid deconfinement of the propellant body. In addition, the thermal energy of the charge jet formed will cause the combustion of the propellant charge 7 without detonation thanks to the deconfinement which is ensured.

  at the same time. This results in destruction of the propellant charge which does not fall to the ground with the missile.

  The device according to the invention therefore allows, with a simple structure, compact and easy to integrate into space

  inter stages, to ensure on the one hand the deconfinement of the propellant body and on the other hand the safe destruction of the propellant charge. The efficiency of the device is therefore greater than that of existing devices and at a lower cost.

  By way of example, three charges 10 with a diameter of 100 mm and a length of 120 mm may be used, comprising a conical coating of copper 1 mm thick. Alternatively, a number of different charges may be adopted or the the charges in the vicinity of the nozzle. One could also use core-generating charges. The loads can also be arranged not regularly distributed over a circumference coaxial with the propellant but on a propeller coaxial with the propellant. This will result in different distances between each charge and the bottom of the propellant. We can also give different angles of inclination for each load. Such arrangements will make it possible to cut a greater number of fibers of the filament wound up constituting the casing of the propellant, each cutting attacking different fibers of the propellant body. Alternatively, the loads can also be arranged with their axes parallel to the axis of the propellant (a = 0). In this case the loads will be positioned so that their axes are merged with the envelope of the

  propellant. Such a variant also ensures a longitudinal cutting of the envelope, it is however more difficult to integrate into the inter-stage space of the missile because of the bulk of the charges 10.

Claims (7)

  1- Device for deconfining a body of an ammunition, in particular of a propellant, by cutting a wall of this body, characterized in that it comprises at least one shaped charge5 (10) disposed in the vicinity of the wall (5) of the body and whose axis (12) is coincident or slightly inclined by   relative to this wall (5), hollow charge, the initiation of which is caused by a control means (13) and which is oriented so as to ensure a longitudinal cutting of the wall (5) of the body.   2- Device according to claim 1, characterized in that the axis (12) of the load (10) is inclined relative to the wall (5) by an angle less than or equal to 15. 3- Device according to claim 1, characterized in that   that the load (10) is disposed in the vicinity of a bottom (8) of the body and has its axis (12) oriented towards the outside of the body.   4- Device according to one of claims 1 to 3, characterized in that the load (10) has a diameter included   between 75 and 150 mm. 20 5-Device according to claim 4, characterized in that the load (10) is a hollow load.   6-Device according to claim 4, characterized in that the load is a core-generating load.   7-Device according to one of claims 1 to 6, charac-   terized in that it comprises three charges (10) regularly distributed angularly around the axis (11) of the body.   8-Device according to one of claims 1 to 7, characterized in that the control means (13) is associated with   means for detecting a loss of the radio guidance link of the ammunition.   9-Device according to one of claims 1 to 8, characterized in that the control means is remotely controllable.   -Device according to one of claims 1 to 9, characterized in that the control means is associated with   means for detecting a rise in temperature.