FR2850454A1 - Method of assembly of aerospace rocket motor casing involves welding precharged tube and housing using spot welds to form continuous seam - Google Patents

Abstract

The method of assembly of a pyrotechnic separator (10) involves placing a loaded tube (12) including an envelope (13) containing a detonating cord, into an initiator housing (20). The precharged tube and housing are welded together using spot welds (40) which are placed to form a peripheral weld collar (42) which is continuous. A part of the charged tube can then be flattened.

Description

METHOD FOR ASSEMBLING A SEPARATION DEVICE

  PYROTECHNIQUE, AND DEVICE FOR SEPARATION

PYROTECHNIC OBTAINED BY THIS PROCESS

DESCRIPTION

TECHNICAL AREA

  The present invention relates to the field of pyrotechnic separation, in particular to the separation of two elements of aeronautical or spacecraft, such as, for example, the cap or protective panels of measuring devices of a rocket and the body of the rocket.

  It relates to a method of assembling a pyrotechnic separation device, and a pyrotechnic separation device obtained by the implementation of this assembly method.

STATE OF THE PRIOR ART

  WO 87/07006 discloses a pyrotechnic separation device which comprises at least one charged tube formed of an envelope containing a detonating cord along its entire length. The loaded tube is disposed between two machine elements which must be separated from each other, along a cutting zone between the two machine elements.

  The envelope is made of a deformable metal material, and has in a first operating configuration a flattened cross section, for example oblong or oval.

  It is filled with a flexible material within which the detonating cord is located.

  The separation device is held in place within a housing traversing the cutting zone. The wall of this housing has, distributed over its entire length, areas of weakness, which are areas where said wall is thinned.

  The firing of the detonating cord at at least one end of the separating device and the propagation of a subsequent shock wave inside the charged tube causes the deformation of the latter, step by step. Said loaded tube then tends to take a second operating configuration in which it has a circular cross section. This radial expansion of the loaded tube has the consequence that the zones 15 of weakening of the housing break, along the cutting zone between the two machine elements, which, step by step, separates these two elements. machine.

  WO-87/07006 does not provide any indication on the ends of the pyrotechnic separation device.

  A conventional pyrotechnic separation device of the prior art, seen at its ends, is illustrated in FIG. 5 in plan view. In a manner known per se, the separation device 110 comprises at each of its ends an initiation tip 120, which is connected on the one hand to one end of a charged tube 112 and on the other hand to a bead 180, itself connected to a firing device (not shown in Figure 5), through which is initiated the firing of the detonating cord, and which is remote from the separation device.

  The separation device 110 is received in a housing 106 which is continuous over the entire length corresponding to the loaded tube 112, and which has a discontinuity corresponding to the location of the initiation tip 120 associated with said end of the device. separation 110. This discontinuity results in an opening 108 made in the wall 109 of at least one of the two machine elements which must be separated.

  A major drawback of this configuration lies in the fact that, in the cutting zone, the edge of this opening 108 is a stress concentration zone 15. The stresses are all the greater the greater the length of this edge in the cutting plane, or in a plane substantially parallel to the cutting plane. It is recalled that the cutting plane is defined as being a median plane of the cutting zone between the two gear elements which must be separated.

  In a manner known per se, the two ends of the charged tube 112 are fired in order to avoid the possibility of a firing failure which would occur at one of these ends, which requires the presence two initiation tips 120 and two connections with a firing cord 180.

  In addition, when the cutting zone has substantially a closed contour as is the case for example for the separation between the cap and the body of a rocket, the positioning of the separation device 110 in the housing 106 is such that the two end pieces 120 are in close proximity to one another, which requires an opening 108 having a greater length in the cutting plane.

  Finally, in the case of closed-body structures of large diameter, for ease of implementation, it is known to those skilled in the art to have two separation devices 110, or three or more, placed end-to-end and each having an initiation tip at each end. This leads to two locations corresponding to the initiation tips 120 arranged to be substantially diametrically opposed (or three or more), and thus to two openings 108 (or three or more) formed in the wall 109 of the at least one of the elements that must be separated.

  Conventionally, the initiation tip 120 of the prior art is a substantially rectilinear tube segment, which has at one end an assembly opening 126 for its assembly with the envelope, and at the other end a firing orifice 124 for its connection with the firing bead 180. In a manner known per se, a method of manufacturing a conventional pyrotechnic separation device of the prior art takes place as follows: starting from an envelope, having a circular section, assembling an initiation nozzle 120 at each end of the envelope, by a conventional assembly method, for example by screwing into the assembly opening 126 of the initiation nozzle 120, - the sheath containing the detonating cord is then introduced through an insertion orifice 124 of the initiation nozzle 120, said insertion orifice 124 being for this purpose oriented such that way that its axis is parallel aligns with the longitudinal direction common to the initiation tip and the casing, then the sheath is slid from step by step inside the initiation tip and the envelope, - we connect a firing cord 180 to 15 each initiation nozzle 120, for example by screwing, into the firing orifice 124 of the initiation nozzle 120, the tube loaded with the flexible sheath containing the detonating cord, to bring it into its first operating configuration in which it has a flattened shape along its entire length, by a suitable method of deformation, for example by a pressing method or other calibrated crushing method.

  The shape of the initiation nozzle 120 is conditioned by the manufacturing process which has just been recalled. For reasons of convenience, the introduction orifice is coincident with the firing orifice 124.

  The firing orifice 124 and the assembly orifice 126 of the initiation nozzle 120 are aligned with each other in the longitudinal direction thereof, so that it is possible to introduce and slide the flexible sheath containing the detonating cord into the initiation tip 120 and then into the envelope, in the longitudinal direction common to the initiation tip 120 and to the envelope.

  The firing orifice 124 thus serves both to connect the firing cord to the initiation tip 120, and to introduce the flexible sheath 10 containing the detonating cord. This introduction function requires that the initiation tip has a certain length, designated D in Figure 5, to guide the flexible sheath.

  The connection between the initiation tip and the firing cord is made on a connecting portion, designated 140 in FIG. 5, which occupies a certain length D1, in the longitudinal direction of the end piece. initiation, which increases by the same length L, in the cutting plane, the opening 108 formed in said wall 109 of at least one of the two machine elements which must be separated.

  The deformation operation of the tube is done after its assembly with the initiation tip, otherwise it would not be possible, or in any case very difficult, to introduce the flexible sheath containing the detonating cord into an envelope already flattened. As a result, the loaded tube has a transient portion, designated 150 in FIG. 5, along which its section progressively passes from a substantially circular shape, close to the initiation tip, to a shape substantially flattened where it was deformed. This transient portion 150 occupies a certain length D2, which increases accordingly the length L, in the cutting plane, of the opening 108 formed in said wall 109 of at least one of the two machine elements.

  SUMMARY OF THE INVENTION An object of the present invention is to obtain a pyrotechnic separation device which retains the main advantage of the prior art separation device, namely to allow a proper separation of the elements, ie that is, the explosive residue remains inside the tube. Indeed, one of the two parts of machine to be separated is very often a compartment in which are sophisticated electronic equipment, fragile and expensive, which should not be polluted during the separation of the elements.

  Another object of the present invention is to minimize the stress on the edges of openings in the wall of at least one of the machine components to be separated. For this, it is necessary to reduce the length of these openings in the cutting plane.

  For this purpose, it is sought to reduce the length D of each initiation tip and / or the length D1 of the associated connection portion, and / or to reduce the length D2 of the associated transient portion.

  Now these three lengths D, D1, D2 are related to the method of manufacturing the pyrotechnic separation device of the prior art, which consists of assembling a rectilinear initiation tip on an empty envelope, then loading said envelope with the sheath. of flexible material containing the detonating cord by an end port of the initiation tip, and then deforming the resulting tube once it has been loaded and connected.

  To reduce these three lengths D, D1, D2, one solution consists in pre-loading a casing having a substantially circular cross-section with the flexible sheath containing the detonating cord, and then deforming the loaded tube to give its cross-section a flattened shape. over its entire length, and finally assemble the initiation tip on one end of said loaded tube, through the opening 15 of the assembly of the initiation tip. Therefore, the firing port of the initiation tip is only used to connect it with the firing cord, and is no longer used to introduce the flexible sheath containing the detonating cord.

  It results firstly that the transient portion is removed, since the deformation of the loaded tube is along its entire length. The length D2 can thus be deleted. On the other hand, it is no longer necessary to place the firing orifice so that it is aligned with the assembly opening in the longitudinal direction of the loaded tube. The length D1 can thus be deleted. It finally follows that the initiation tip can be shortened, and its length D decreased, since it no longer has the role of guiding the flexible sheath containing the detonating cord for its introduction into the envelope.

  The removal of the transient portion also has the advantage of reducing the manufacturing costs of the separation device.

  Another object of the present invention is to ensure that the assembly between the loaded tube and the initiation tip ensures good sealing conditions to preserve the detonating cord from the humidity of the ambient air.

  Therefore, for the manufacture of a pyrotechnic separation device, the following dual problem is encountered: - use a pre-loaded tube 15 having a flattened cross section, before assembling it with an initiation tip to at least one of its ends, - guarantee the tightness of this assembly between the initiation tip and said end of the tube 20 previously loaded and previously deformed.

  This double problem can be solved by means of a welding assembly.

  But a derivative problem then occurs.

  The heating of the parts during welding must not cause the ignition rod or the destruction of the detonating cord which is already inside the casing at the time of assembly to be ignited.

  The present invention therefore proposes a method of assembling a pyrotechnic separation device by which at least one initiation tip is directly connected to one end of a previously loaded and deformed tube, said initiation tip having a longitudinal dimension. reduced compared to the initiation tips of the prior art, and said assembly method ensuring the tightness of the assembly. It also proposes a pyrotechnic separation device obtained by this method.

  According to a first aspect of the invention, the method of assembling a pyrotechnic separation device comprises: a step during which a charged tube is fitted, comprising an envelope containing a detonating cord, in a nozzle of initiation, a step during which said charged tube and said initiation tip are bonded together by fusion welding, producing successive weld points which overlap so as to form at least one peripheral weld bead, continuous and closed.

  Preferably, the method comprises a prior step during which the loaded tube has been deformed to give its cross-section a flattened shape along its entire length.

  Preferably, said flattened cross section has an oblong or oval or elliptical shape.

  Preferably, the method comprises an initial step in which a casing having a substantially circular cross-section with a flexible material and a detonating cord is loaded, said flexible material forming a sheath for said detonating cord.

  If the separating device comprises more than one initiation tip, the sequence of steps above mentioned is repeated for each assembly of an initiation tip with a tube end previously loaded and deformed.

  Preferably, said weld bead is made between a thinned peripheral zone of an assembly wall surrounding an assembly opening of the initiation tip and the envelope. Said weld points pass through the thinned peripheral zone of the assembly wall and penetrate into the envelope without passing through it.

  Preferably, this spot welding is performed by means of a pulsed YAG laser laser welding apparatus. Its operating parameters are adjusted in such a way that the temperature rise at the detonating cord is perfectly controlled.

  According to a second aspect of the invention, the pyrotechnic separation device comprises at least one tube loaded with a detonating cord and at least one initiation tip assembled on said tube 25 charged by the implementation of an assembly method according to the first aspect of the invention.

  Preferably, the initiation tip is provided with an assembly orifice delimited by an assembly wall which comprises a thinned peripheral zone.

  Preferably, the initiation tip has a bent shape, forming for example substantially a right angle.

BRIEF DESCRIPTION OF THE DRAWINGS

  Other features and advantages of the assembly method and the pyrotechnic separation device will become apparent on reading the following detailed description of an exemplary embodiment of the invention, provided for purely illustrative and nonlimiting purposes, in 1 is a perspective view of a portion of a cutting zone between two machine elements, showing two initiation tips assembled on two respective ends placed end to end of two tubes loaded with a pyrotechnic separation device; - Figure 2 illustrates in longitudinal section an initiation tip assembled on one end of a tube loaded with a pyrotechnic separation device; - Figure 3 is an enlarged partial view illustrating the assembly by welding between the initiation tip and the charged tube of Figure 2; and - Figure 4 is a close-up view of a weld spot to illustrate its shape and dimensions; FIG. 5, already described, is a view from above of a part of a cutting zone between two machine elements, showing two initiation tips assembled on two end-to-end ends of a loaded tube. a pyrotechnic separation device of the prior art.

  DESCRIPTION OF THE SIZE OF A PARTICULAR MODE OF REALIZATION Referring to FIG. 1, a first machine element 2 and a second machine element 4 intended to be separated are placed side by side along each other. a cutting area. Figure 1 illustrates only a part of the two elements 2, 4, each having a substantially circular overall ring shape. This cutting zone is traversed by a peripheral housing 6 which comprises, in the illustrated example, a wall 62 belonging to the gear element 2 and a wall 64 belonging to the gear element 4.

  Said peripheral housing 6 receives pyrotechnic separation devices 10. These are, in this example, two in number and arranged end to end. They each comprise a loaded tube 12 and two initiation tips 20. Due to the substantially circular configuration of the cutting zone of the present example, it has two substantially diametrically opposed locations, in which there are two end pieces. each of these locations, the gear element 4 has openings 8 for accommodating the initiation tips 10 and firing cords 80. (represented by dashed lines in FIG. 1) which connect the initiation tips 20 to a firing device (not shown) which is remote from the cutting zone.

  FIG. 2 illustrates, in longitudinal section, an end of a pyrotechnic separation device 10, which comprises a charged tube 12 and an initiation tip 20.

  The loaded tube 12 comprises a metal casing 13, preferably of stainless steel. It is equipped throughout its length with a detonating cord 14 constituting a core of said charged tube 12, and a flexible sheath 16 which fills the space between the envelope 13 and the detonating cord 14. The charged tube 12 was obtained by introducing into the casing 13 a flexible material containing the detonating cord 14, said flexible material forming a sheath 16 for said detonating cord 14. Said flexible sheath 16 is made of a damping material, such as silicone.

  The loaded tube 12 has been previously deformed over its entire length. It has a cross section of flattened shape, for example oblong, oval or elliptical. Firing the detonating cord will cause radial expansion of the charged tube 12 which will tend to assume a configuration in which it will have a substantially circular cross section.

  The initiation tip 20 is a metal tip, preferably of vacuum-refined stainless steel, which has a length D in its longitudinal direction which is also the longitudinal direction of the loaded tube 12. It comprises 30 - a tip body 22, - a firing orifice 24 for connection with a firing cord 80 (shown by dashed lines in Figure 1), which is in the example illustrated a screw-type connection, and - an orifice assembly 26 for its assembly with the loaded tube 12.

  The tip body 22 preferably has a bent shape. The firing orifice 24 and the assembly orifice 26 have axes which intersect by forming, in the example illustrated, an angle substantially equal to 900.

  The assembly opening 26 has a cross section whose shape and dimensions are adapted to those of the cross section of the end of the loaded tube 12. It is delimited by an assembly wall 28 which is part of the body 22. The assembly wall 28 has a thinned peripheral zone 30 and terminates in a reinforcing ring 32.

  The thinned peripheral zone 30 is shown on a larger scale in FIG. 3, which illustrates the actual assembly of the initiation tip 20 on the loaded tube 12.

  The assembly method of the separation device 10 comprises a step of interlocking the end of the loaded tube 12 in the assembly opening 26, and a step of joining by welding the thinned peripheral zone 30 to 30 flattened envelope 13.

  These two steps may be preceded by a step of loading the envelope 13 with the detonating cord 14 surrounded by its flexible sheath 16, and / or by a deformation step of the cross section of the loaded tube 12. This deformation is carried out over the entire length of the loaded tube 12, and tends to flatten its cross section, to give it an oblong shape, or oval, or elliptical, or other flattened shape.

  The welding is a metal fusion welding, which is carried out by means of a pulsed YAG laser laser welding apparatus, whose operating parameters are adjusted, so that the temperature generated at the detonating cord does not does not exceed a maximum value TM. Preferably, this maximum value TM is set at 1000C. The main operating parameters are the welding speed, the welding energy, the duration of the pulses, the laser beam pulse frequency, the focal length of the objective, and the firing distance.

  The welding process influences the choice of material constituting the initiation tip. In fact, a vacuum-refined stainless steel has the advantage over a stainless steel which is not refined under vacuum, a lower sensitivity to cracking that sometimes occurs during a laser welding, because of fast solidification of the melted zones.

  The welding step consists in producing successive soldering points 40 on the thinned peripheral zone 30, by overlapping the soldering points 40 along the periphery of the thinned peripheral zone 30, so as to form one or more welding cord (s) 42 peripheral (s) and continuous (s).

  Preferably, the weld points 40 of the same weld bead 42 are evenly distributed over the entire circumference of the thinned peripheral zone 30, so that said weld bead 42 is closed.

  As can be seen clearly in FIG. 3, the soldering points 40 pass through the thinned peripheral zone 30 of the assembly wall 28 and penetrate into the envelope 13 without passing through it.

  The assembly of the initiation nozzle 20 on the end of the loaded tube 12 is obtained as soon as a peripheral and continuous weld bead 42 has been produced. In order to improve the mechanical strength and the tightness of the assembly, it is preferred to produce several peripheral and continuous welding beads 42 which are substantially parallel to each other.

  The number of weld beads 42 is limited by the width of the thinned peripheral zone 30. It is preferably between two and six, and even more preferably equal to four. Said width of the thinned peripheral zone is denoted a.

  According to an alternative embodiment, the weld beads 42 are spaced apart from each other in the direction of the width a of the thinned peripheral zone 30. According to another preferred variant, illustrated in FIG. 3, the weld beads 42 are joined along the direction of the width a of the thinned peripheral zone 30.

  The height of the thinned peripheral zone is denoted hi, the axial distance between two adjacent weld seams 42 is denoted c, the distance between each end weld seam 42 and each edge of the thinned peripheral zone 30 is denoted b, and the total welding width is denoted 1.

  In FIG. 4 is illustrated in section and in enlarged manner a weld spot 40. It has a base portion 44 which opens out to the surface of the thinned peripheral zone 30, and a foot portion 46 which penetrates in the envelope 13.

  The base 44 has a substantially domed shape and the foot 46 has a substantially cylindrical shape or a frustoconical shape tapering away from the base 44. The end of the foot 46 penetrating the casing 13 ends with a tip 47 substantially rounded. The surface of the base 44 which opens to the outside has a recess 45. The junction between the base 44 and the foot 46 has substantially a funnel-shaped profile. The base 44 has a diameter d1 and its recess 45 has a height e. The foot 46 has a diameter d2. When the foot 46 has a substantially frustoconical shape, its diameter d2 is axially variable. D2p denotes the diameter d2 at the joint plane between the thinned peripheral zone 30 and the envelope 13. The weld point 40 has a total height h2 which is the sum of a through height hi equal to the height the thinned peripheral zone 30 traversed by the weld points 40 and a penetrating height h3 which corresponds to the penetration height of the weld points 40 in the envelope 13.

Example

  An initiation tip 20 made of EZ2 CN 18-10 type stainless steel, hyper-tempered and vacuum-refined, having an assembly wall 28 having a thinned peripheral zone 30 having a width a = 6.2 mm, was used. and a height hl = 0.95 mm.

  A cylindrical casing 13 made of Z2 CN 18-10 type stainless steel was also used, which had been hypertreated and not refined under vacuum.

  The casing 13 was loaded with a silicone sheath 13 containing a detonating cord 14. The loaded tube 15 thus formed was crushed to have an oblong cross section, with two straight portions and two rounded portions.

  A pulsed YAG laser welding process was used with a microwelding center known as LASAG PM 300.

  Its operating parameters were adjusted in the following way: - welding speed on the straight parts 45 mm / minute - welding speed on the rounded parts 540 degrees / minute - impulse energy: 18 joules - duration of the pulses: 6 milliseconds frequency pulses: 3 hertz - focal length of the objective: 150 millimeters - firing distance: 125.6 millimeters Gas protection was applied by means of a flow of nitrogen having a flow rate of 10 liters / minute.

  The temperature generated at the detonating cord remained below 800C.

  Seams 40 overlapping in the circumferential direction were made to form four peripheral, continuous, and closed weld seams. The welding beads 42 were joined. The axial distance between two adjacent weld seams 42 was c = 0.9 mm. The distance between each outermost weld bead and the corresponding edge of the thinned peripheral zone was b = 1.75 mm. The total welding width was 1 = 4.2 mm.

  The weld points 40 had the following dimensions: - total height: h2 = 1.2 to 1.4 mm, - through height h1 = 0.95 mm, - penetrating height: h3 = h2 - h1 = 0.25 to 0 , 45 mm, 20 - base diameter: 1.2 mm <dl <1.6 mm, - average height of the depression in the base: e <0.2 mm, foot diameter at the joint plane between the zone thinned device 30 and the envelope 13 d2p 2 0.4 mm.

  An initiation tip 20 was used whose length D in the longitudinal direction of the loaded tube was substantially between 30 and 35 millimeters, more precisely substantially equal to 32.7 millimeters, whereas according to the prior art it would have been used an initiation tip having a firing and insertion port axially aligned with the assembly port, and having a length D of 58.4 mm.

  The length L, in the cutting plane, of the opening in the wall of the machine element has been reduced to 116 millimeters, whereas with a separation device of the prior art it would be necessary to make an opening with a length L of 230 mm.

  The invention is not limited to the embodiment and to the example which have just been described.

  It encompasses modifications and adaptations that are within the reach of those skilled in the art.

Claims (22)

REVENDI CATIONS   1. A method of assembling a pyrotechnic separation device (10), characterized in that it comprises: - a step during which a charged tube (12) is fitted, comprising a casing (13) containing a cord detonator (14), in an initiation tip (20), a step during which said pre-loaded tube (12) and said initiation tip (20) are joined by fusion welding, by producing successive welding (40) which overlap to form at least one peripheral, continuous, and closed weld seam (42).   2. Method according to claim 1, characterized in that it comprises a prior step during which the deformed tube is deformed. 20 3. Method according to claim 2, characterized in that the deformed tube (12) to give its cross section a flattened shape over its entire length. 25 4. Method according to any one of claims 1 to 3, characterized in that said loaded tube (12) has a cross section having an oblong or oval or elliptical shape.   5. Method according to any one of claims 1 to 4, characterized in that it comprises an initial step during which the envelope is loaded with a flexible material containing the detonating cord so as to form said charged tube.   6. Method according to any one of claims 1 to 5, characterized in that said weld bead (42) is formed between the casing 10 (13) and a thinned peripheral zone (30) of an assembly wall (28) surrounding an assembly port (26) of the initiation tip (20).   7. Method according to claim 6, characterized in that the solder points (40) pass through the thinned peripheral zone (30) of the assembly wall (28) and penetrate into the envelope (13).   8. A method according to any one of claims 1 to 7, characterized in that one carries welds (42) substantially parallel, the number is between two and six.   9. The method of claim 8, characterized in that one carries out four weld seams (42).   10. Method according to any one of claims 1 to 9, characterized in that when making more than one weld bead (42), these weld beads (42) are spaced apart from each other.   11. Method according to any one of claims 1 to 9, characterized in that when making more than one weld bead (42), these weld seams (42) are joined.   12. Method according to any one of claims 1 to 11, characterized in that the welding is carried out by means of a pulsed YAG laser whose operating parameters are adjusted so that the temperature generated at the level of the detonating cord does not exceeds a maximum temperature value (TM).   13. Process according to claim 12, characterized in that the maximum temperature value (TM) is set at 1000 ° C. Pyrotechnic separation device (10), comprising an initiation tip (20) and a charged tube (12) with a detonating cord (14), characterized in that said initiation tip (20) is assembled on said charged tube (12), by implementing an assembly method according to any one of Claims 1 to 13.   15. Device (10) according to claim 14, characterized in that the loaded tube (12) is formed of a casing (13) into which has been introduced a flexible sheath (16) containing the detonating cord (14).   16. Device (10) according to claim 14 5 or 15, characterized in that said loaded tube (12) has a cross section having a flattened shape.   17. Device (10) according to any one of claims 14 to 16, characterized in that said loaded tube (12) has a cross section having an oblong or oval or elliptical shape.   18. Device (10) according to any one of claims 14 to 17, characterized in that the casing (13) and the initiation tip (20) are both made of stainless steel.   19. Device (10) according to any one of claims 14 to 18, characterized in that the casing (13) is made of stainless steel type Z2 CN 18-10, hypertrempé.   20. Device (10) according to any one of claims 14 to 19, characterized in that the initiation tip (20) is made of vacuum-refined stainless steel. type EZ2 CN 18-10, hyper-tempered and refined under vacuum.   21. Device (10) according to any one of claims 14 to 20, characterized in that the initiation tip (20) is provided with an assembly hole (26) surrounded by an assembly wall (28) which has a thinned peripheral zone (30).   22. Device (10) according to any one of claims 14 to 21, characterized in that the initiation tip (20) has a bent shape.