Method of connecting a skirt to a thruster body casing

Abstract

The terminal portion of a prefabricated skirt is connected to a casing of a thruster body in the vicinity of an end wall thereof using a method including positioning the terminal portion of the skirt with circumferential clearance around the casing of the thruster body in the vicinity of the end wall; keeping the skirt in position relative to the casing of the thruster body; closing both ends of an annular space between the terminal portion of the skirt and the casing of the thruster body; injecting elastomer into the annular space; and curing the elastomer.

Claims

1. A method of connecting a terminal portion of a prefabricated skirt to a casing of a thruster body in the vicinity of an end wall thereof, the skirt having a free portion extending from the terminal portion so as to surround said end wall, at least in part, the method comprising: positioning the terminal portion of the skirt with a circumferential clearance around the casing of the thruster body in the vicinity of said end wall; positioning the skirt relative to the casing by means of a first annular removable tooling and a second annular removable tooling, said first annular removable tooling engaging without clearance in the free portion of the skirt so as to position the skirt radially relative to the casing in such a manner as to ensure the skirt and the casing have substantially the same axis, and said second annular removable tooling forming an abutment for the terminal portion for axially positioning the skirt relative to the casing; keeping the skirt in position relative to the casing of the thruster body; closing both ends of an annular space between the terminal portion of the skirt and the casing of the thruster body, said first annular removable tooling bearing against the end wall and said second annular removable tooling bearing against a shroud of the casing in order to close both ends of the annular space; injecting elastomer into said annular space; curing the elastomer, and after curing the elastomer, disengaging the first annular removable tooling and the second annular removable tooling.

2. A method according to claim 1, wherein the elastomer is injected at least in part through one of the first and second annular removable toolings.

3. A method according to claim 1, wherein the elastomer is injected at least in part through the terminal portion of the skirt.

4. A method according to claim 1, wherein the elastomer is injected while connecting the annular space to a vacuum source at least through one of the first and second annular removable toolings closing both ends of the annular space.

5. A method according to claim 1, wherein the elastomer is injected while connecting the annular space to a vacuum source at least through the terminal portion of the skirt.

6. A method according to claim 1, wherein the injecting is performed while keeping the casing of the thruster body substantially vertical.

7. A method according to claim 1, wherein the injecting is performed while keeping the casing of the thruster body substantially horizontal.

8. A method according to claim 1, further including depositing adhesive on facing faces of the terminal portion of the skirt and of the casing of the thruster body, prior to injecting the elastomer.

9. A method according to claim 1, wherein the elastomer is cured by means of a heater element arranged on the outside of the terminal portion of the skirt.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a view in axial half-section of a thruster body for a solid propellant engine; and

(2) FIGS. 2A, 2B, 2C, and 2D are highly diagrammatic fragmentary section views showing successive steps in an implementation of a method of the invention.

DETAILED DESCRIPTION OF AN EMBODIMENT OF THE INVENTION

(3) FIG. 1 shows a thruster body of a solid propellant engine, the body comprising a casing 10, front and rear skirts 22 and 24, and front and rear polar bases 32 and 34.

(4) The casing 10 is of axisymmetric shape about an axis A, and it comprises a substantially cylindrical central portion or shroud 12 and front and rear end walls 14 and 16. By way of example, the casing 10 is formed by filament winding and it defines the housing for the solid propellant. The inside surface of the casing 10 is provided with a thermal protection coating 18. It is also possible to provide a liner.

(5) The polar bases 32 and 34 are for mounting an igniter of the engine and a nozzle (not shown), and they contribute to facilitating the filament winding of the casing 10 at the end walls 12 and 14.

(6) As mentioned above, the skirts 22 and 24, of substantially annular shape, serve to connect the thruster body mechanically to other portions of the vehicle (e.g. a launcher or a missile) that is fitted with the engine. Each skirt has a terminal portion 22b, 24b secured with the casing 10 in the vicinity of the corresponding end wall, and a free portion 22a, 24a that extends from the terminal portion and that surrounds the end wall, at least in part. The term free portion is used herein to mean a portion that is not directly fastened to the casing.

(7) A thruster body as briefly described above and as shown in FIG. 1 is itself well known.

(8) With reference to FIGS. 2A to 2D, there follows a description of a particular implementation of the invention for making a connection between a thruster body casing and a skirt, such as the casing 10 and the front skirt 22 of FIG. 1.

(9) The casing 10 and the skirt 22 are made separately. The casing 10 may be made by filament winding on a mandrel fitted with the polar bases of the thruster body, using a filament, e.g. made of carbon preimpregnated with a resin, e.g. epoxy resin, followed by polymerising the resin, it being understood that other known fabrication techniques could also be adopted.

(10) The skirt 22 may be made of composite material or of metal. A skirt made of composite material may be obtained by draping plies and/or winding filaments on a mandrel, e.g. made of carbon fibers or of Kevlar fibers, impregnated with a resin, e.g. epoxy resin, which is subsequently polymerised. The skirt 22 presents an inside diameter that is greater than the outside diameter of the shroud 12 of the casing 10.

(11) The skirt 22 is placed around the corresponding end wall of the casing 10, in this example the front end 14 (FIG. 2A), and it is then positioned relative to the casing 10 by means of annular tooling 42, 44 formed by removable rings (FIG. 2B). The front tooling 42 engages without clearance in the free portion 22a of the skirt 22 so as to position the skirt 22 radially relative to the casing 10 in such a manner as to ensure they have substantially the same axis. The rear tooling 44 forms an abutment for axially positioning the skirt 22 relative to the casing 10. Clearance j is thus arranged between the terminal portion 22b of the skirt 22 and the shroud 12 in the vicinity of the end wall 14. The size of the clearance j may lie in the range 1 mm to a few millimeters as a function in particular of the diameter of the thruster body, e.g. in the range 2 mm to 5 mm.

(12) The front tooling 42 bears against the end wall 14, and the rear tooling 44 bears against the shroud 12 in order to close an annular space 46 between the terminal portion 22b of the skirt 22 and the casing 10 in the vicinity of the end wall 14. With the skirt 22 held in position relative to the casing 10, an elastomer is injected into the space 46 (FIG. 2C), e.g. with the axis A being substantially vertical. Injection may be performed through the front tooling 42 via one, or preferably several, passages (not shown) that are formed for this purpose. Simultaneously, the annular space 46 is connected to a vacuum source via one, or preferably several, passages (not shown) formed in the rear tooling 44. In a variant, injection may be performed through the rear tooling 44 and a connection with a vacuum source may be established through the front tooling 42. By way of example, the elastomer may be selected from the silicone, polyurethane, and polyisoprene families.

(13) In another implementation, elastomer may be injected while the axis A is in a substantially horizontal position. Injection into and suction from the space 46 are then preferably performed through a plurality of injection and suction passages formed through the tooling 42 and 44.

(14) In the description above, elastomer injection into the space 46 and suction from that space are performed through passages formed in the tooling 42 and 44. In a variant, or in addition, injection and suction may be performed through perforations formed in the terminal portion 22b of the skirt 22. It is also possible to perform injection through one or more passages formed in at least one of the pieces of tooling 42 and 44 and to perform suction through one or more perforations formed in the terminal portion 22b of the skirt 22, or vice versa.

(15) Once the space 46 has been filled with an elastomer, the elastomer is cured. Depending on the nature of the elastomer, curing may be performed at ambient temperature or at a higher temperature, either because that is necessary, or because that is preferred. Under such circumstances, an annular heater muffle 48 (FIG. 2D) is placed against the outside of the terminal portion 22b of the skirt 22. In a variant, it is possible to arrange one or more heater strips around the terminal portion 22b of the skirt 22.

(16) It should be observed that a layer of adhesive, or of adhesion primer, may be deposited on the facing faces of the casing 10 and of the terminal portion 22b of the skirt 22 prior to putting the skirt into position, with the deposited layer then being cured during the heat treatment for curing the elastomer.

(17) A connection is thus obtained between the terminal portion 22b of the skirt and the casing 10 via an elastomer spacer 50 that is formed in situ, with intimate contact with the elastomer spacer over the entire length in the axial direction of the connection zone, and in spite of potential geometrical defects of the connected-together parts. This provides an effective connection between the coaxial skirt 22 and casing 10 without requiring any over-winding on the outside face of the terminal portion 22b of the skirt 22. The length of the connection zone in the axial direction may lie in the range from a few tens of millimeters to more than 100 mm, as a function in particular of the size of the thruster body, e.g. lying in the range 50 mm to 150 mm.

(18) The connection between the casing 10 and a rear skirt may be made in similar manner. Naturally, the method can also be used when the thruster body is provided with only one skirt.