Method for demoulding a composite material with an organic matrix

Abstract

An injection tooling is configured to inject a polymer resin into a fiber preform for fabricating a part in the form of a body of revolution out of composite material, the part having an internal cavity with back-draft. In order to enable the part to be unmolded after the polymer resin has been injected and polymerized, the tooling includes, arranged at least in the internal cavity, firstly a sectorized ring made up of at least three mutually touching inserts including one forming a keystone, the ring having an outside surface that matches the internal cavity with back-draft and an inside surface that presents natural draft, and secondly a conical drum secured to the inside surface of the sectorized ring to support it and that is withdrawn, once separated from the sectorized ring, relying on the natural draft created by the inside surface of the sectorized ring.

Claims

1. An injection tooling for injecting a polymer resin into a fiber preform for fabricating a part in the form of a body of revolution out of composite material, the part having an internal cavity with back-draft, wherein, in order to enable said part to be unmolded after said polymer resin has been injected and polymerized, the tooling includes, arranged at least in said internal cavity, firstly a sectorized ring made up of at least three mutually touching inserts including one forming a keystone, the sectorized ring having an outside surface that matches said internal cavity with back-draft and an inside surface that presents natural draft, and secondly a conical drum secured to said inside surface of said sectorized ring to support it and that is withdrawn, once separated from said sectorized ring, relying on said natural draft created by said inside surface of said sectorized ring.

2. The injection tooling according to claim 1, wherein said sectorized ring comprises at least three inserts, said keystone-forming insert occupying an angle lying in the range 20? to 40?.

3. The injection tooling according to claim 2, wherein said sectorized ring comprises four inserts, three inserts each occupying an angle of 110?, and a keystone-forming fourth insert occupying the remaining angle of 30?.

4. The injection tooling according to claim 1, wherein said inserts are secured to said conical drum by screw-fastening.

5. The injection tooling according to claim 1, wherein, in order to center said insert angularly relative to said conical drum, mutual centering elements are arranged facing one another respectively on said insert and on said conical drum.

6. The injection tooling according to claim 5, wherein, in order to center said inserts angularly relative to said conical drum, annular slopes are arranged at one of the ends of said inserts.

7. The injection tooling according to claim 1, wherein said inserts include handling members to enable them to be extracted by a hoist or any analogous lifting system.

8. The injection tooling according to claim 1, wherein said inserts are made of a metal material having mechanical properties and dimensional stability that facilitates expansion during polymerization by heating.

9. The injection tooling according to claim 1, wherein said inserts are made of metal sheet including weight-reducing blind holes between stiffeners on the face that is to come into contact with said conical drum.

10. The injection tooling according to claim 1, wherein said body of revolution made out of composite material is a fan casing.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Other characteristics and advantages of the invention appear from the following description of particular embodiments of the invention, given as non-limiting examples and with reference to the accompanying drawings, in which:

(2) FIG. 1 is a perspective view of an aeroengine having a fan casing obtained using injection tooling in accordance with the invention;

(3) FIG. 2 is a half-view in axial section of the injection tooling enabling the FIG. 1 fan casing to be fabricated; and

(4) FIGS. 3A to 3F show the successive steps performed in the FIG. 2 injection tooling for unmolding the FIG. 1 fan casing.

DETAILED DESCRIPTION OF EMBODIMENTS

(5) The invention applies in general manner to any gas turbine part made of polymer matrix composite material. Nevertheless, the invention is described below in the context of its application to a fan casing for a gas turbine aeroengine.

(6) FIG. 1 is a diagram showing such a gas turbine aeroengine comprising, from upstream to downstream in the flow direction of the gas stream: a fan 10 arranged at the inlet of the engine; a compressor 12; a combustion chamber 14; a high pressure turbine 16; and a low pressure turbine 18. The engine has successive casings corresponding to various elements of the engine and of inside surface defining the air inlet passage of the engine. Thus, the fan 10 is surrounded by a fan casing 20 in the form of a body of revolution and made out of fiber reinforcement, e.g. using carbon, glass, aramid, or ceramic fibers, densified by a polymer matrix, e.g. an epoxy, bismaleimide, or polyimide matrix. The fiber reinforcement is obtained in known manner by three-dimensional or multilayer weaving, e.g. by weaving an interlock weave, and the matrix is obtained by a liquid technique using known injection methods such as the RTM molding method.

(7) The fan casing 20 has outwardly-directed flanges 22 and 24 at its upstream and downstream ends in order to enable it to be mounted and connected to other elements of the engine. Between its upstream and downstream ends, the fan casing has an intermediate portion (internal cavity 20A presenting back-draft) that has a diameter that is greater than the diameters of the end portions connecting progressively therewith, which intermediate portion makes it impossible to have recourse to standard RTM injection tooling.

(8) In the invention, it is thus proposed to resolve the problem posed by unmolding a body of revolution having an internal cavity with back-draft by adding an additional piece to the upstream drum supporting the part being molded on either side of this cavity so as to enable that part to be unmolded from the upstream end of the casing, which additional piece is added between the fiber preform that receives the injection and the upstream drum, thereby recreating natural draft that makes unmolding possible once more.

(9) FIG. 2 is a section of the injection tooling of the invention supporting the fan casing 20 and omitting the sectorized outer half on the outside that conventionally closes the mold.

(10) More precisely, in known manner, the tooling 30 comprises an upstream drum 32 and a downstream drum 34 together with an upstream cheek plate 36 and a downstream cheek plate 38. The upstream and downstream drums touch each other via a reentrant diameter (in general the smallest diameter of the air passage) so as to make unmolding possible relying on the natural draft of the passage on either side of this junction, and they are secured to each other at the junction by connection means such as bolts (see axis lines given reference 33). The upstream and downstream cheek plates for molding the outwardly-directed flanges 22 and 24 are also secured to the upstream and downstream drums respectively, e.g. by screw-fastening (see axis lines given references 35 and 37). It should be observed that the upstream cheek plate and the upstream drum may comprise a single piece, and the same applies to the downstream cheek plate and the downstream drum.

(11) In accordance with the invention, this tooling further includes an additional piece made up of a sectorized ring 40 having at least three touching inserts and typically four such inserts 40A-40D, e.g. screw-fastened (see axis lines given reference 41) to the upstream drum 32 supporting the fiber preform in the internal cavity with back-draft and on either side thereof, and having a slightly conical shape in order to facilitate unmolding in the upstream direction. Preferably, the screw-fastening is located as close as possible to the free end of the upstream drum 32 in order to facilitate access thereto when the drum is to be removed. In addition, in order to ensure that the inserts 40 are angularly centered on the upstream drum 32 and the downstream drum 34, mutual centering elements 32A and 42 are advantageously arranged on each of these pieces.

(12) More precisely, the sectorized ring of outside surface matching the internal cavity with back-draft (and its upstream and downstream approaches) presents an inside surface with natural draft (i.e. an angle of inclination of a few degrees sufficient to make unmolding possible in the manner that applies to a prior art air passage). Annular slopes 44 are provided at one of its ends in order to provide annular (axial and radial) centering both on the upstream drum 32 and on the downstream drum 34. The ring is made of a metal material having mechanical properties and dimensional stability that facilitate managing expansion during polymerization by heating, e.g. steel sheets of thickness that lies in the range 50 millimeters (mm) to 80 mm, for example, and including blind holes 46 for weight-reducing purposes between stiffeners 48 on the face that comes into contact with the upstream drum. The drums and the inserts are preferably made of the same material.

(13) In order to enable them to be removed, when the sectorized ring is made of up four inserts, three of these inserts are designed to cover respective angles of 110?, while the fourth insert covers the remaining angle of 30? and forms a kind of keystone for the additional part. Nevertheless, depending on the total number of inserts (which may lie in the range three to five, for example), and depending on their dimensions, the keystone fourth insert may cover an angle possibly lying in the range 20? to 40?. The inserts need to be a good fit with the upstream drum since the resin is injected under pressure after generating a vacuum inside the mold. The mechanical properties and the dimensional stability of the material constituting the ring facilitate successful injection. Naturally, conventional gaskets (not shown) also need to be provided between the various pieces of the mold in order to guarantee that it is indeed leaktight.

(14) During the molding stage, the injection process is no different from the conventional RTM injection process, with the fiber preform being placed inside the mold that is closed in leaktight manner. Thereafter, low viscosity liquid thermosetting resin is injected into the mold in order to impregnate the entire fiber portion of the preform. Polymerization is then performed, generally by heating the mold in one or more consecutive cycles in order to achieve the desired degree of densification. Once injection and polymerization have been completed, the part as finally obtained can then be unmolded using steps that are now different from the steps performed in the conventional process, because of the way the tooling is modified.

(15) The unmolding steps are shown sequentially in FIGS. 3A to 3F. FIG. 3A shows the mold at the end of the polymerization step, the outer half having been removed in a first unmolding step and the outside surface of the final part thus has the outside shape of the casing that is to be made. The second step shown in FIG. 3B consists in unscrewing the fasteners 35 and removing the upstream cheek plate 36 so as to release the upstream drum 32 which, once separated from the upstream drum 34 by unscrewing the fasteners 33, can then itself be withdrawn in a following step shown in FIG. 3C (naturally, the fasteners 41 of the inserts are removed beforehand). Withdrawal of the upstream drum 32 and withdrawal of the downstream drum 34 can then take place simultaneously, instead of being performed one after the other.

(16) This withdrawal of the upstream drum 32 makes it possible to release the inserts 40A-40D that can be removed, beginning with the keystone insert 40A (new step shown in FIG. 3D) prior to removing the remaining other inserts 40B-40D, as shown in FIG. 3E. Finally, in a last step shown in FIG. 3F, the final part can at least be extracted in turn from the mold, of which there then remains only the downstream drum 34 and the downstream cheek plate 38. This final part is then trimmed in order to remove excess resin and obtain the fan casing 20.

(17) For all of these steps, given their dimensions (diameter of several meters) and their weights (several (metric) tonnes), all of these parts need to be handled with precaution, and they are therefore preferably withdrawn by means of a hoist or any other similar lifting system, each of the mold parts then including the members needed to enable to them to be moved. By way of example, these handling members may comprise fastener holes 50 that can have docking rings 52 (see FIG. 2) mounted on the heads of bolts screwed therein, or any other hole for connection purposes, e.g. with a handling frame 54 (see FIG. 3D) itself having docking rings that co-operate by engaging hooks associated with a hoist. In general manner, the technique for handling and fastening large parts by means of systems for handling loads that are heavy and/or bulky, by using docking rings screwed into said loads, is of known type.

(18) It should be observed that in order to avoid any damage to the final part during the final withdrawal step, this step should preferably be performed by using a handling ring, a sling, or any other equivalent means for handling large bodies of revolution. The final casing part does not have any specific member for handling purposes, so this ensures it does not run any risk of being damaged during such handling.