FR2724979A1 - Exhaust nozzle firing guide for sea-launched missile - Google Patents

Abstract

A temporary tubular insert (20) is located in the interior of the divergent portion (12b) of the missile engine exhaust nozzle, defining a cylindrical outlet passage for the driving exhaust gas flow. The insert extends over at least half of the length of the divergent portion of the nozzle. The insert is constructed of material of low resistance to the temperature and pressure of the exhaust combustion gases, such that it is destroyed shortly after firing the missile engine. Alternatively the insert may be constructed of stronger material and attached to the interior of the nozzle by connectors ruptured at a predetermined interval after firing.

Description

 The present invention relates to missiles which are lads in immersion, in particular missiles driven from submarines while diving, and which are fired before or at the time of their exit from the water.

 Failures have been reported during missile launches of this type, in the "TRIDENT 2 DS ICBM" category by the United States Navy.

The search for the cause of these failures made it possible to highlight the so-called "water plug" effect. This occurs when, upon firing the missile engine, a body of water is present at the end of the nozzle and completely or largely obstructs the outlet of the nozzle. Such a body of water forms a plug which, before being expelled by the combustion gases, causes a brief but significant increase in pressure in the diverging part of the nozzle. This rise in pressure results in the application of an intense axial force, in the downstream direction, capable of damaging organs located at the rear part of the missile.

 This phenomenon is illustrated by FIG. 1. In this figure is schematically represented the rear part of a missile 1 with a nozzle 2 having a neck 2a and a divergent 2b. The nozzle is connected by a hinge 4 to the body 5 of the missile or of the first stage thereof, in the case of a multi-stage missile. The articulation 4 makes it possible to rotate the nozzle under the control of actuators 6 in order to control the orientation of the thrust vector. In a manner known per se, the articulation 4 can be formed by a flexible laminated stop constituted by a stack of layers alternately of metal and of rubber adhering to each other. It will be noted that the laminated stopper is arranged so as to be normally stressed in compression under the effect of the gases generated in the combustion chamber of the engine, upstream from the neck 2a dc the nozzle 2.The articulation 4 is connected to the nozzle 2 via a base 7 and to the body 5 via a bottom 8. Such an articulated nozzle is well known in itself.

 In FIG. 1, the reference 9 designates a water plug which is situated in the end part of the divergent 3 and obstructs the outlet of the nozzle 2. This water may have been sucked up during the path of the missile between its point of launch and water surface.

 When the missile engine or its first stage is fired in the presence of the water plug 9, the pressure increase in the divergent, before the expulsion of the water plug, results in the application, on the internal wall of the divergent, forces whose resultant has an axial component FAX directed from downstream to upstream of the nozzle. Tests on a 1/10 scale model carried out by the applicant have shown that the axial component FAX thus briefly generated has an intensity equal to more than three times that exerted in the upstream-downstream direction during the normal operation of the wetness.

 The FAX component is transmitted to the body 5 by the articulation 4 and the actuators 6, as well as by the base 7 and the bottom 8. When the articulation 4 is a laminated flexible stop, the latter is then stressed in traction, that is to say under the conditions where it has the least mechanical resistance. This may result in damage to the flexible stop such that the missile can no longer be operated. Damage can also be caused to the actuators 6 as well as to the base 7 and to the bottom 8, damage which can also lead to the loss of the missile.

To solve the problem posed by the water plug effect, it has been proposed, for the "TRIDENT" missiles mentioned above, to install an inflatable bladder which fits between the nozzle and the rear part of the missile, outer side and which, when inflated, blocks the nozzle so as to stiffen the nozzle-rear part of the missile. We can refer to article dc
Edward H. Kolcum titled "Three Successful Launches Verify Design Fixes to
Trident 2D5 ICBM "and published in the publication" Aviation Week & Space
Technology "January 8, 1990. The downstream-upstream axial force resulting from the possible presence of a water plug is transmitted from the nozzle to the bitter part of the missile via the inflated bladder, without risk of damage to the articulation of the nozzle and the thrust orientation actuators.

 However, this solution makes it possible to neutralize the water plug effect only for the elements of orientation of the nozzle, but not for the other constituents of the rear part of the missile, in particular the base and the bottom. However, these constituents are not normally intended to withstand an intense force exerted from downstream to upstream.

 In addition, the launch phase is made more delicate and more complex since it is necessary, first, to inflate the bladder before or during the firing of the missile, in any case before firing, and then to ensure quickly and completely emptying the bladder, after firing and once the time necessary for the expulsion of a possible water plug has elapsed, to regain complete freedom to control the orientation of the thrust . Rapid emptying of the bladder requires pyrotechnic means and appropriate control of the latter.

 The object of the invention is to provide a simpler and more reliable solution to the problem posed by the water plug effect, offering effective protection not only of the orientation elements (articulation and actuators) but also of the other constituents of the rear part of the missile.

 This object is achieved by the fact that, in accordance with the invention, a temporary structure is arranged inside the diverging so as to transform the diverging vein thereof into a substantially cylindrical vein, over at least most of the length of the divergent and ephemeral after the firing of the missile. In this way, it is avoided that an increase in pressure in the divergent flow due to the accidental presence of a water plug at its end at the time of firing induces on the nozzle and of the constituents of the rear part of the missile a force, the result of which has a damaging axial component, directed from downstream to upstream of the nozzle, before the expulsion of the water plug.

 The shape and arrangement of the provisional structure are preferably chosen so that the downstream-upstream axial component is as small as possible, in any case incapable of damaging the organs of the rear part of the missile.

 The temporary structure must be able to fulfill its function for the time necessary, after ignition, for the expulsion of a water plug which may be present, but must then be eliminated as quickly as possible to restore the configuration normal of the divergent. In practice, the ephemeral nature of the temporary structure, after firing, means a duration preferably less than 1 s, of the order of a few 1/10 of a second.

 The temporary structure is preferably made of one or more materials having an ephemeral resistance to the combustion gases produced by the firing of the missile. Thus, the elimination of the provisional structure does not require any particular intervention. This same advantage can be obtained by fixing the temporary structure to the divergent by connecting means having an ephemeral resistance to these combustion gases, so that the temporary structure can be expelled from the nozzle within the desired time after firing.

 According to another embodiment, the temporary structure can be fixed to the divergent by connecting means with which means, for example pyrotechnic means, are used to control the rupture of the connecting means for a determined time after the firing of the missile.

 Advantageously, the provisional structure comprises a rigid tubular part defining the cylindrical vein and fixed to the wall of the divergent. A filling material is then preferably placed between the tubular part and the internal wall of the divergent.

The invention will be better understood on reading the description given below, by way of indication but not limitation, with reference to the attached drawings in which:
- Figure 1, already described, illustrates the water plug effect on an unprotected nozzle;
- Figure 2 is a very schematic view, in section, illustrating a first embodiment of a device according to the invention; and
- Figures 3 and 4 are very schematic sectional views illustrating two alternative embodiments of the device of Figure 2.

 Figure 2 illustrates very schematically the rear part of a missile 1 1 intended to be launched in immersion. The missile comprises a nozzle 12 having a neck 12a extended towards the end of the nozzle by a divergent 12b. Upstream of the neck 12a, the nozzle 12 has a converging part 12c which communicates with the combustion chamber 13 of the missile or of the first stage thereof, in the case of a multi-stage missile.

 The external surface of the convergent 12c, which faces towards the rear of the missile, is supported on a flexible stop 14 by means of an annular base 17. The stop 14 is connected to the body 15 of the missile or of the first stage of the latter by a bottom 18. The stop 14 is a laminated stop which comprises alternating layers of metal 14a and rubber 14b adhering to each other.

The layers 14a and 14b have the shape of spherical rings with the same center so that, by the deformation capacity of the rubber layers, the stopper 14 constitutes an articulation allowing the nozzle 12 to pivot relative to the body 15. The pivoting of the nozzle 12 and, thereby, the orientation of the thrust vector during the flight of the missile, are controlled by means of actuators 16 articulated respectively on the bottom 18 and on the nozzle 12, outside the nozzle .

The nozzle 12, the bottom 18 and the body 15 are provided with internal thermal protections 10.

 According to the invention, a temporary structure 20 is introduced into the divergent 12b of the nozzle 12. This temporary structure 20 transforms the divergent vein into a cylindrical vein over the greater part of the length of the divergent.

 The structure 20 comprises a rigid tubular part 20a, which defines the cylindrical vein, and a filling 20b which occupies the space between the tubular part 20a and the internal wall of the divergent. The constituent materials of the tubular part 20a and of the filling 20b are chosen so as to be eliminated, for example sublimed, by the gases coming from the combustion chamber shortly after the firing of the missile. By way of example, the rigid tubular part 20a can be made of a composite material of the resin type reinforced with fibers, such as glass fibers, or of an easily sublimable metal, such as aluminum. The filling 20b is made of a relatively light material resistant to compression, for example in an expanded polymer, such as a polyurethane foam. The tubular part 20a is glued to the block 20b of filling material and is fixed to the divergent 12b by bonding of block 20b on the internal wall of the divergent. At its base, the block 20b can be provided with a rear covering 20c, for example of the same kind as the tubular part 20a and glued to the block 20b.

 When, upon firing the missile, a water plug 19 is present at the end of the nozzle 12, a significant pressure is generated in the divergent until the water plug is expelled. This pressure results in the application of normal forces to the wall of the divergent vein. Due to the present temporary structure 20, the vein is cylindrical over a large part of the length of the nozzle, so that the result of the forces applied to the internal wall of this vein does not have a significant axial component directed from downstream upstream of the nozzle. It will be noted that the internal diameter of the provisional structure 20 is preferably greater than that of the neck 12a so that this structure does not occupy too large a volume in the divergent 12b and leaves only a too narrow central vein. the pressure which applies to the upper part of the diverging part, directly on the wall of the latter, can result in a non-zero residual downstream-upstream axial force. This is however much lower than the value it would take in the absence of the temporary structure 20. wire suffice to choose the internal diameter of the structure 20 so that the residual downstream-upstream axial force is low enough to avoid any risk of damage to the organs of the rear part of the missile.

 The time required to expel a possible water plug, after ignition, is normally less than 1 s, of the order of a few 1/10 of a second. It therefore suffices to make the provisional structure 20 so that it retains its integrity only during this period.

 The embodiment of FIG. 3 differs in particular from that of FIG. 2 in that the provisional structure 20 is fixed inside the divergent by connection means 21 having an ephemeral resistance to the combustion gases produced by the setting missile fire. The connection means 21 consist, in the example illustrated, of an annular strip which is glued to the cylindrical internal wall of the structure 20, at the upper part of the latter, and to the internal wall of the divergent 12b, also at the top of it. The annular strip 21 may be made of a composite material, for example of resin reinforced with fibers, such as glass fibers, or of metal, for example of aluminum. The elimination of the temporary structure 20 results from the destruction of the connecting means. 21, within the time required after the firing, followed by the expulsion of the provisional structure.

This can then be made of different materials which cannot necessarily be eliminated by the combustion gases.

 FIG. 4 illustrates an alternative embodiment of the device of FIG. 3 in which the provisional structure 20 is fixed to the divergent not by connection means having an ephemeral resistance to combustion gases, but by connection means 22, the rupture of which can be ordered. The temporary structure 20 extends to the end of the divergent part and is fixed to the latter by means of explosive bolts 22 at the periphery of the divergent part. The rupture of the bolts 22 is controlled for a determined time after the firing of the missile to allow the expulsion of the temporary structure 20 immediately after that of a water plug possibly present at the firing.

Claims (9)

1. Device for protection against the water plug effect during the firing of a missile launched in immersion and having a nozzle (12) ending, at the rear of the missile, by a divergent (12b), characterized in that a temporary structure (20) is arranged inside the diverging part (12b) so as to transform the diverging vein thereof into a substantially cylindrical vein, over at least most of the length of the divergent and ephemeral after firing the missile, so that an increase in pressure in the divergent due to the accidental presence of a water plug (19) at its end at the time of firing n 'not induce on the nozzle and the constituents of the rear part of the missile an effort the result of which has a damaging axial component, directed from downstream to upstream of the nozzle, before the expulsion of the water plug. 2. Device according to claim 1, characterized in that the temporary structure (20) is made of one or more materials having an ephemeral resistance to the combustion gases produced by the firing of the missile. 3. Device according to claim 1, characterized in that the provisional structure (20) is fixed to the divergent by connecting means (21) having an ephemeral resistance to the combustion gases produced by the firing of the missile. 4. Device according to claim 1, characterized in that the temporary structure is fixed to the divergent (12b) by connecting means (22) and in that means are provided for controlling the rupture of the connecting means for a determined time after firing the missile. 5. Device according to any one of claims 1 to 4, characterized in that the temporary structure (20) comprises a rigid tubular part (20a) defining the cylindrical vein and fixed to the wall of the divergent. 6. Device according to claim 5, characterized in that the rigid tubular part (20a) is made of a fiber-reinforced resin. 7. Device according to any one of claims 5 and 6, characterized in that the provisional structure further comprises a filling material (20b) between the tubular part (20a) and the internal wall of the divergent (12b). 8. Device according to claim 7, characterized in that the filling material (20b) is an expanded polymer. 9. Device according to any one of claims 7 and 8, characterized in that the tubular part (20a) adheres to the filling material (20b) and the latter is bonded to the internal wall of the divergent (12b).