Method for manufacturing a vane from a composite material with a fitted metal leading edge for a gas turbine

Abstract

A method for manufacturing a vane from a composite material with a fitted metal leading edge includes the successive draping, on a template of the leading edge of the vane to be manufactured, of a first layer of a base material and of a second layer of an adhesive material, the transfer of the first and second draped layers in the recess of a metal foil, the positioning of the foil including the first and second draped layers alongside the leading edge of a vane preform including a fiber reinforcement impregnated with a precursor of a matrix, the co-curing of the vane preform and of the first and second draped layers so as to obtain a vane made of composite material including on its leading edge a bonded metal foil.

Claims

1. A method for manufacturing a vane from a composite material with a fitted metal leading edge for an aeronautical gas turbine engine, the method comprising: successively draping, on a template of a leading edge of the vane to be manufactured, a first layer of a base material and a second layer of an adhesive material, transferring the first and second draped layers in a recess of a metal foil, positioning the foil comprising the first and second draped layers alongside a leading edge of a vane preform comprising a fiber reinforcement impregnated with a precursor of a matrix, co-curing the vane preform and the first and second draped layers so as to obtain said vane made of composite material including on the leading edge of the vane a bonded metal foil.

2. The method according to claim 1, wherein the step of transferring the first and second draped layers in the recess of the metal foil comprises the installation of the metal foil on the adhesive material layer and the removal of the assembly formed by the foil and the first and second layers from the template of the leading edge.

3. The method according to claim 2 further comprising, after installation of the metal foil on the adhesive material layer and before the removal of the assembly formed by the foil and the first and second draped layers, the cutting out of the portions of said first and second draped layers extending beyond the foil.

4. The method according to claim 1 further comprising, before the draping of the first and second layers on the template of the leading edge of the vane to be manufactured, depositing an anti-adhesive layer on the template.

5. The method according to claim 1, further comprising, before the draping of the first and second layers on the template of the leading edge of the vane to be manufactured, adjusting the foil on the template.

6. The method according to claim 1, wherein the base material of the first layer is chosen from glass fibers, bronze yarns and carbon fibers.

7. The method according to claim 1, wherein the adhesive material of the second layer is chosen from epoxy adhesive, reinforced epoxy adhesive, epoxy adhesive film and reinforced epoxy adhesive film.

8. A method comprising manufacturing a fan vane, an outlet guide vane, an inlet guide vane, or a variable stator vane with the method according to claim 1.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Other characteristics and advantages of the present invention will emerge from the description given below, with reference to the appended drawings which illustrate exemplary embodiments thereof without any limiting nature. In the figures:

(2) FIG. 1 is a schematic perspective view of an outlet guide vane according to one embodiment of the invention;

(3) FIG. 2 is a schematic perspective view showing the draping of a base layer and of an adhesive layer on a template;

(4) FIG. 3 is a schematic perspective view showing the positioning of a metal foil alongside the template of FIG. 2;

(5) FIG. 4 is a schematic perspective view showing the compaction of the base layer and of the adhesive layer with the metal foil;

(6) FIG. 5 is a schematic perspective view showing the cutting out of the portions of the base layer and of the adhesive layer which protrude from the metal foil;

(7) FIG. 6 is a schematic perspective view showing the removal of the metal foil provided with the base layer and with the adhesive layer from the template;

(8) FIG. 7 is a schematic perspective view showing the positioning of the metal foil provided with the base layer and with the adhesive layer alongside an outlet guide vane preform and then the molding of the assembly;

(9) FIG. 8 is a schematic view showing the co-curing of the vane preform of FIG. 7 with the metal foil provided with the base layer and with the adhesive layer in a mold.

DETAILED DESCRIPTION OF THE INVENTION

(10) The invention applies to the production of vanes made of composite material for an aeronautical gas turbine engine having a metal leading edge.

(11) Non-limiting examples of such vanes are in particular fan vanes, outlet guide vanes (called OGV), inlet guide vanes (called IGV), variable stator vanes (called VSV), etc.

(12) A method according to the invention will be described in relation to the manufacture of an outlet guide vane such as the vane 100 illustrated in FIG. 1 which comprises a vane body 110 extending along a longitudinal direction DL between an internal platform 120 and an external platform 130 and along a transverse direction DT between a leading edge 111 and a trailing edge 112. The vane body 110 also includes an intrados face 113 and an extrados face 114. A foil made of metal material 140 is further bonded to the vane body 120 at the leading edge 111.

(13) The method for manufacturing the vane 100 begins with the successive draping on a template of the leading edge of the vane to be manufactured, of a first layer of a base material and of a second layer of an adhesive material as illustrated in FIG. 2. More specifically, as represented in FIG. 2, a template 200 is used comprising at least one portion 211 reproducing the shape and the dimensions of the leading edge 111 of the vane 100 to be manufactured. The template 200 can be a part made especially for the implementation of the method of the invention or correspond to a rejected part or even correspond to a test part.

(14) Before the draping, the portion 211 of the template 200 is preferably covered with a layer 10 constituted of an anti-adhesive material, for example polytetrafluoroethylene (PTFE). A first base material layer 20 is first of all draped on the portion 211 covered or not with the layer 10. The first layer 20 can be a stratum or a bidirectional (2D-woven) ply made of a material chosen from one of the following materials: glass fibers, fine bronze yarns as used in the Bronze Mesh product manufactured by the company Lumicor®, carbon fibers. A second adhesive material layer 30 is then draped on the layer 20. The second layer 20 can be constituted of an epoxy-based adhesive, reinforced or not, or of an epoxy-based adhesive material film, reinforced or not. The adhesive material can for example correspond to the epoxy resin EA914 manufactured by the company Hysol®, to the adhesive film AF191 manufactured by the company 3M®, to the adhesive film FM300 manufactured by the company Cytec®, or to the epoxy resin EA9396 manufactured by the company Hysol®.

(15) By draping the layers 20 and 30 on the template 200, they are conformed following a geometry corresponding exactly to that of the leading edge of the vane to be made.

(16) Once the first and second layers 20 and 30 are draped on the portion 211 of the template 200, a foil made of metal material 140 is placed on the second adhesive material layer 30 as illustrated in FIG. 3. The foil 140 can be made for example of stainless steel. The foil 140 has a shape and dimensions corresponding to the trailing edge of the vane to be manufactured. The foil 140 has a spout shape which defines a recess 141 on the wall 141a of which the first and second draped layers 20 and 30 will be fixed.

(17) Before the draping of the first and second layers 20 and 30 on the template 200, the foil 140 can be adjusted on the template 200. The adjustment of the foil 140 on the template 200 can correspond to an adjustment of the dimensions of the foil, for example its length, and/or of the shape of the foil, for example its curvature or its twisting. The thickness of the metal foil being very small and its conformation on the template is produced by manual pressures.

(18) The first and second layers 20 and 30 can be compacted by applying a compaction pressure P.sub.C to the foil 140 as represented in FIG. 4. For this purpose, the template 200 provided with the first and second layers 20 and 30 and with the foil 140 are disposed in a tooling (not represented in FIG. 4) able to exert the compaction pressure P.sub.C on the foil 140.

(19) As represented in FIG. 5, the portions of the first and second layers 20 and 30 which extend outside of the foil 140 are then cut out, the edges 140a and 140b of the foil being used to mark the cut line on the template 200. This operation is optional and, according to a variant of implementation, the first and second layers 20 and 30 of the foil 140 are allowed to protrude.

(20) The assembly formed by the foil 140 and the first and second layers 20 and 30 fixed to the surface 141a of the recess 141 of the foil is removed from the template 200 (FIG. 6). This assembly is then positioned alongside the leading edge 311 of an outlet guide vane preform 300 (FIG. 7). The layers 20 and 30 having been conformed to the exact shape of the trailing edge of the vane to be manufactured and transferred from the template in the recess 141 of the foil 140, a continuous fixing interface is ensured between the foil 140 and the leading edge 311 of the preform 300.

(21) The composite material vane is obtained from a fiber reinforcement densified by a matrix. In this case, it is manufactured from a fibrous preform that can be obtained in different ways known to those skilled in the art. Typically, the preform can be obtained directly by three-dimensional (3D) weaving of yarns (formed for example of carbon fibers) or by draping of two-dimensional fibrous fabrics. The manufacture of an outlet guide vane from a composite material obtained from a fiber reinforcement produced by three-dimensional weaving and densified by a matrix is in particular described in document WO2013088040. In the example described here, the outlet guide vane preform 300 is obtained from a plurality of two-dimensional (2D fabric) strata or plies made of pre-impregnated and draped carbon fibers. The outlet guide vane preform can also be obtained from a fiber reinforcement made of carbon fibers produced by three-dimensional weaving, the reinforcement having been impregnated with a thermosetting resin, for example an epoxy-type resin.

(22) Alternatively, these composite material vanes can be obtained directly by injection into a mold of a thermoplastic resin (TP) reinforced by short, long loads, etc. In this case, the resin is not completely transformed (polymerized) in order to allow its co-curing with the assembly formed by the foil and the first and second layers fixed to the surface of the foil recess.

(23) The vane manufacturing method continues by placing in a curing mold 50 the preform 300 and the assembly formed by the foil 140 and the first and second layers 20 and 30, positioned on the leading edge 311 of the preform 300. In a known manner, the curing mold 50 comprises two shells 51 and 52 each including respectively a cavity 510 and 520, the cavities 510 and 520 forming, once joined (i.e. after the closing of the mold), a mold recess 530 corresponding to the shape of the vane to be manufactured (FIG. 8).

(24) The mold 50 is then heated to a temperature making it possible to obtain the co-curing of the preform 300 with the assembly formed by the foil 140 and the first and second layers 20 and 30. The different layers, namely the pre-impregnated preform and the second layer (adhesive layer), have compatible curing cycles allowing the polymerization of the elements at the same time. The mold can be heated via the plates of the press, in an autoclave, or be provided with heating means, the heating being carried out according to a temperature ramp defined up to a temperature allowing the polymerization of the various polymers, a pressure being applied during this temperature rise in order to control the creep. A polymerization level is then applied followed by a drop in temperature following a new defined ramp. The polymerization of the layers 20 and 30 takes place at the same time as the polymerization of the resin of the preform 300. The resins being compatible, the layers 20, 30 and the preform 300 become secured to each other during the curing.

(25) After co-curing, the vane is removed from the mold. It can possibly undergo a post-curing cycle to improve its thermomechanical characteristics (increase in the glass transition temperature). No machining is necessary since, the part being molded, it meets the required dimensions. The vane 100 illustrated in FIG. 1 is then obtained, which comprises a vane body 110 provided with internal 120 and external 130 platforms made of composite material with the metal foil 140 bonded to the leading edge 111 of the vane 100.

(26) The method of the invention also applies in particular to the manufacture of blades with or without platforms such as fan vanes and variable stator vanes used on unducted engines (“open rotor”).