Fiber preform for a hollow turbine engine vane

Abstract

A fiber preform for a hollow turbine engine vane, the preform including a main fiber structure obtained by three-dimensional weaving and including at least one main part, wherein the main part extends from a first link strip, includes a first main longitudinal portion forming a pressure side wall of an airfoil, an U-turn bend portion forming a leading edge or a trailing edge of the airfoil, a second main longitudinal portion facing the first main longitudinal portion and forming a suction side wall of the airfoil, and terminating at a second link strip. The first and second link strips are secured to each other and form a link portion of the main fiber structure. The main longitudinal portions are spaced apart so as to form a gap between the main longitudinal portions forming a hollow in the airfoil.

Claims

1. A fiber preform for a hollow turbine engine vane, the preform comprising: a main fiber structure obtained by three-dimensional weaving and including a main part extending in a radial direction; and a second fiber structure obtained by weaving and configured to be fitted to an edge of the main fiber structure, wherein the main part presents a loop and includes, in order around the loop: a first link strip, a first main longitudinal portion suitable for forming essentially a pressure side wall of an airfoil, a U-turn bend portion suitable for forming essentially a leading edge or a trailing edge of the airfoil, a second main longitudinal portion facing the first main longitudinal portion and suitable for forming essentially a suction side wall of the airfoil, and a second link strip, wherein the first and second link strips are secured to each other and form a link portion of the main fiber structure, wherein the main longitudinal portions are spaced apart so as to form a gap between said main longitudinal portions suitable for forming a hollow in the airfoil, and wherein at least one of the fiber structures comprises a radial portion extending from a bottom edge or a top edge of the first main longitudinal portion or the second main longitudinal portion of the main part, the radial portion being suitable for forming a platform or a fastener flange.

2. The fiber preform according to claim 1, wherein the first and second link strips are woven together in interlinked manner.

3. The fiber preform according to claim 1, wherein at least one of the fiber structures includes an overlap portion that, when the fiber preform is flat, is situated upstream from at least part of the link portion of the main part, a gap being left between said overlap portion and the link portion.

4. The fiber preform according to claim 1, wherein at least one of a radially bottom end or a radially top end of the link portion of the main part presents a smaller width in a direction perpendicular to the radial direction than a middle of the link portion of the main part in the radial direction.

5. A hollow vane comprising a single piece of composite material from a fiber preform according to claim 1, said preform being shaped in a mold and embedded in a matrix.

6. The hollow vane according to claim 5, wherein the fiber preform is made with fibers of ceramic oxide, carbon, or carbide type.

7. The hollow vane according to claim 6, wherein the fiber preform is made with fibers of alumina, mullite, silica, zirconia, silicon carbide, or a mixture thereof.

8. The hollow vane according to claim 5, wherein the matrix is of ceramic oxide, carbide, or nitride type, or is organic of epoxy type.

9. The hollow vane according to claim 8, wherein the matrix is made of alumina, mullite, silica, zirconia, silicon nitride or carbide, or a mixture thereof.

10. A turbine engine, comprising a hollow vane according to claim 5.

11. A method of fabricating a hollow vane, the method including weaving a fiber preform according to claim 1.

12. The method according to claim 11, wherein the weaving is performed using a three-dimensional loom having a bundle of warp yarns and at least one shuttle suitable for inserting a weft yarn between the warp yarns; wherein the shuttle performs a succession of go-and-return movements in a first direction or a second direction, the first direction starting from a link zone, traveling within a first main longitudinal zone, performing a U-turn in a bend zone, traveling within a second main longitudinal zone facing the first main longitudinal zone, and returning to the link zone, the second direction being opposite the first direction; and wherein the weft yarn cooperates with the warp yarns to form a three-dimensional weave within the link zone, the first and second main longitudinal zones, and the bend zone.

13. The method according to claim 11, further comprising: cutting out the fiber preform; folding and shaping the fiber preform in a mold possessing the shape of a desired blank; placing an insert in the gap between the two main longitudinal portions; injecting and solidifying the matrix around the fiber preform in order to obtain the blank; removing the insert; and machining the link part of the blank corresponding to the link portion of the fiber preform in order to obtain the leading or trailing edge of the final part.

14. The method according to claim 13, wherein the machining the link part of the blank, corresponding to the link portion of the fiber preform, comprises tapering down said link part to obtain the trailing edge.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The accompanying drawings are diagrammatic and seek above all to illustrate the principles of the invention.

(2) FIG. 1 is a section view of a turbine engine of the invention.

(3) FIG. 2 is a perspective view of a set of turbine rear guide vanes.

(4) FIG. 3 is a section view of a hollow vane.

(5) FIG. 4 is a perspective view of the main part of a first preform example.

(6) FIG. 5 is a diagram showing the weaving path for this main part of the preform.

(7) FIG. 6 shows an example weaving path for this main part.

(8) FIG. 7 is a view of a part of the first example preform when flat.

(9) FIG. 8 shows the same preform after it has been shaped.

(10) FIG. 9 is a detail view of the trailing edge of the preform after shaping.

(11) FIG. 10 is a perspective view of the blank obtained from the preform

(12) FIG. 11 is a perspective view of the final hollow vane obtained after machining the blank.

(13) FIG. 12 is a view of a part of a second example preform when flat.

DETAILED DESCRIPTION OF EMBODIMENTS

(14) In order to make the invention more concrete, an example preform and an example method of fabrication are described in detail below with reference to the accompanying drawings. It should not be forgotten that the invention is not limited to these examples.

(15) FIG. 1 is a view of a bypass turbojet 1 of the invention in section on a vertical plane containing its main axis A. From upstream to downstream in the flow direction of the air stream it comprises: a fan 2; a low pressure compressor 3; a high pressure compressor 4; a combustion chamber 5; a high pressure turbine 6; and a low pressure turbine 7. At its downstream end it also includes a set 10 of turbine rear guide vanes that is inserted in the primary air passage at the outlet from the low pressure turbine 7.

(16) FIG. 2 is a perspective view of such a set 10 of turbine rear guide vanes. This set comprises an inner hub 11 and an outer shroud 12 that are radially connected together by guide vanes 20, commonly referred to as TRVs.

(17) FIG. 11 is a perspective view of an example vane 20 of the present invention, specifically a TRV. Such a vane comprises an airfoil 21, a bottom platform 22, a top platform 23, and bottom and top fastener flanges 24 and 25. The airfoil portion 21 serves mainly to provide the aerodynamic function of the vane 20; the platforms 22 and 23 serve to constitute inner and outer walls for the air passage that are smooth and aerodynamic; the fastener flanges 24 and 25 serve to enable the vane 20 to be fastened to the inner hub 11 and to the outer shroud 12, respectively.

(18) The airfoil 21 of such a TRV 20 is shown in section in FIG. 3. It comprises a pressure side wall 26 and a suction side wall 27 that are joined together at one end via a leading edge 28 and at the opposite end via a trailing edge 29: these pressure side and suction side walls 26 and 27 define an internal void 30 forming a vane hollow. In this example, the vane hollow 30 is to remain empty in order to reduce the weight of the guide vane set. Nevertheless, in other examples, in particular for other types of part, such a vane hollow could be used for passing services or a flow of air. It should also be observed that the leading edge 28 and the trailing edge 29 serve to define a chord plane P.

(19) FIG. 4 is a diagram showing the main part 41 of a fiber preform 40 once it has been woven, which preform serves to obtain such a vane 20. In these figures, the weft weaving direction is represented by arrow T, i.e. from right to left in the figures, while the warp direction is represented by arrow C. Nevertheless, it is possible to imagine configurations in which weaving is performed from the other end and in the opposite direction.

(20) In this embodiment, the preform 40 is made by three-dimensionally weaving fibers of alumina in a 3D interlock weave.

(21) This main part 41 of the preform 40 essentially comprises a fiber structure in the form of a loop comprising, one after another around the loop: a link portion 44, a first main longitudinal portion 46, a U-turn bend portion 45, and a second main longitudinal portion 47. It can thus be understood that the main longitudinal portions 46 and 47 serve to form the pressure side and suction side walls 26 and 27 of the airfoil 21, that the U-turn bend portion 45 serves to form the leading edge 28, and the link portion 44 is used for forming the trailing edge 29.

(22) FIGS. 5 and 6 serve to explain how this main part 41 of the preform 40 is woven. Such a preform may be woven on a three-dimensional loom having at least one shuttle pulling a weft yarn and capable of navigating freely between the warp yarns. In such a loop, the shuttle is directed so as to form a go-and-return path U between a said link zone 44a in which the link portion 44 is formed, and a said bend zone 45a in which the bend portion 45 is formed.

(23) Thus, on each go-and-return movement, the shuttle starts from the link zone 44a, passes through a first main longitudinal zone 46a in which the first main longitudinal portion 46 is formed, then through the bend zone 45a where it performs a U-turn and returns to the link zone 44a by passing through the second main longitudinal zone 47a in which the second main longitudinal portion 47 is formed.

(24) Each go-and-return movement U may be performed in the same direction or in opposite directions, i.e. alternating between traveling clockwise and traveling counterclockwise.

(25) The succession of these go-and-return movements U serves to form a main part 41 of the preform 40 that has a given thickness of layers, which thickness is naturally greater in the link portion 44, given that the shuttle passes more frequently through the link zone 44a. For this purpose, it may be considered that the link portion 44 is made up of a first link strip 44p and a second link strip 44q lying one against the other and woven together in linked manner. Nevertheless, this is merely a mental concept, since there is no physical boundary that actually lies between these two strips, the link portion 44 as a whole forming a unit that is uniformly interlinked by a three-dimensional weave.

(26) FIG. 6 shows an example of a path V that the shuttle may follow in order to make such a main part 41 of the preform 40. In this example, the shuttle travels three go-and-return movements alternating its travel direction on each occasion. It should also be observed that the shuttle causes layers at the junction between the link portion 44 and the main longitudinal portions 46 and 47 to cross. In this example, a main part 41 of the preform 40 is thus obtained having a thickness of three weft yarns and a thickness of six layers in its link portion 44.

(27) It can naturally be understood that FIGS. 5 and 6 show the path followed by the shuttle in one given plane of the preform, however the preform is woven in analogous manner in the other plane of the preform so as to form three-dimensional weaves, and in particular weaves of the 3D interlock type, with the local positioning of the yarns nevertheless changing between each of the weave planes. Each weave plane may thus have its own shuttle, with the various planes of the preform then being woven in parallel; otherwise, in another configuration, a single shuttle weaves each plane in full one after another.

(28) Thus, after a single weaving step, a main preform part 41 is obtained in a single piece that has a three-dimensional weave in each of its portions, including in its link portion, and that possesses a bend portion 45 of shape that, immediately after the weaving step, is appropriate for corresponding substantially to the shape desired for the leading edge.

(29) FIG. 7 shows part of the preform 40 laid out flat after being cut out. FIG. 8 shows the same preform 40 after it has been shaped. In these figures, for reasons of readability, only the front sheets of the preform 40 as cut out are shown: it should nevertheless be remembered that the preform 40 has other sheets that lie behind the sheets that are shown and that possess shapes that are substantially analogous.

(30) In the preform 40, there can be seen the main part 41 with its first main longitudinal portion 46 between the link portion 44 and the bend portion 45 that extend respective all along the upstream and downstream ends of the first main longitudinal portion 46.

(31) The preform 40 also has a top front sheet 48s and a bottom front sheet 48i that are woven independently and that are fitted respectively to the top edge and to the bottom edge of the main part 41, essentially via the first main longitudinal portion 46. In this example, these secondary fiber structures 48s and 48i are secured to the main part 41 by stitching. It would also be possible to place these sheets in a mold and to secure them to the main part by co-injection followed by sintering.

(32) The bottom front sheet 48i has a portion 52 referred to as the bottom radial portion that extends from the bottom edge of the main longitudinal portion 46 to the bottom edge of the preform 40. This bottom radial portion 52 also has an upstream overlap portion 52m that goes around and extends in part upstream of the link portion 44. The bottom radial portion 52 also has a downstream overlap portion 52v that passes around and extends in part downstream from the bend portion 45.

(33) While the preform 40 is being shaped, this radial portion 52 is folded into a radial position so as to form the pressure side portion of the bottom platform 22.

(34) This radial portion 52 is also extended upstream by an upstream secondary longitudinal portion 54m and downstream by a downstream secondary longitudinal portion 54v. These portions are suitable for being folded longitudinally so as to form the bottom fastener flanges 24.

(35) In analogous manner, the top front sheet 48s has a portion 53 referred to as the top radial portion that extends from the top edge of the main longitudinal portion 46 to the top edge of the preform 40. This top radial portion 53 has upstream and downstream overlap portions 53m and 53v. This top radial portion 53 is suitable for being folded into a radial position so as to form the pressure side part of the top platform 23.

(36) This top radial portion 53 is also extended downstream by a succession of intermediate portions 59 leading to a downstream secondary longitudinal portion 55v, and upstream by an upstream secondary longitudinal portion 55m. These portions are suitable for being folded longitudinally so as to form the top fastener flanges 25.

(37) The preform 40 may be moistened in order to soften it and make it easier to move the fibers out of register. It is then inserted into a forming mold having its inside space matching the shape desired for the preform 40.

(38) The shaping of the trailing edge of the preform 40 is described in greater detail with reference to FIG. 9. This figure shows in superposition the shape of the preform 40 in dashed lines and the shape of the final part 20 in bold lines. During shaping, the main longitudinal portions 46 and 47 are spaced apart from each other so as to leave a gap 50. An insert is then inserted into the gap 50 so that the matrix does not fill it during injection and setting, thus making it possible to obtain the hollow 30 in the airfoil.

(39) At the trailing edge 29, the main longitudinal portions 46 and 47 converge in regular manner towards the link portion 44. Shaping is performed in such a manner that the trailing edge 29 of the final part 20 lies on the midplane 44 of the link portion 44.

(40) Once shaping has been performed with the help of the forming mold, the preform 40 is dried so that it stiffens, thus holding it in the shape imposed during shaping. The preform 40 is then placed in an injection mold having the dimensions of the desired vane blank 60 and a matrix is injected into the mold, specifically a porous alumina matrix. By way of example, such injection may be performed by the LCM method. At the end of this step, after drying and removal of the insert, a vane blank 60 is obtained that is made of composite material comprising a preform 40 woven using alumina fibers and embedded in an alumina matrix.

(41) In FIG. 10, it can be seen that the vane blank 60 already has the leading edge 28, the platforms 22 and 23, and the fastener flanges 24 and 25 as desired. In contrast, the airfoil 61 of the blank 60 possesses a protuberance 64 resulting from the distal end of the link part derived from the link portion 44. This protuberance, which is also visible in FIG. 9, needs to be machined away in order to obtain the final vane 21. The machining includes cutting off the protuberance 64 and tapering down the trailing edge on either side of the midplane 44 of the link portion 44.

(42) In order to facilitate machining of the junctions between the airfoil 21 and the platforms 22 and 23 and in order to avoid weakening the structure of the vane in so doing, the link portion 44 possesses small width, equal to about 5 millimeters (mm) at its top and bottom ends; in the middle of the airfoil 21, its width is greater, being equal to about 10 mm.

(43) Other finishing steps, in particular machining steps, may possibly be used in addition in order to finish off the vane 20.

(44) FIG. 12 shows another example preform 140 in which large portions of the top and bottom front sheets 48s and 48i of the above-described example are woven simultaneously with the main part 141 of the preform during a common weaving step.

(45) The need to cause the shuttle to perform a U-turn in the bend zone in order to make a suitable shape for the leading edge during the weaving step means that it is not possible during the same step to weave portions of the preform that are located strictly downstream from the bend zone. Nevertheless, above and beneath this bend zone, the shuttle is free to perform its U-turn further downstream in order to weave a larger portion of the top and bottom sheets during the same step.

(46) Thus, in this second example, the main weaving step ends up forming a main fiber structure as a single piece comprising a main part 141 with its first and second main longitudinal portions 146 between the link portion 144 and the bend portion 145, a bottom radial portion 152, a top radial portion 153, and upstream secondary longitudinal portions 154m and 155m that are analogous to the portions of the same types in the first example.

(47) The main fiber structure of the preform 140 also has bottom and top downstream portions 157i and 157s that extend downstream from the bend portion 145, respectively downstream and above it. It should be recalled that only the front sheets are shown in FIG. 12, but it should be observed that the rear sheets could likewise include such portions, in which case the shuttle may for example weave the front portions on its go path and the rear portions on its return path.

(48) Bottom and top downstream sheets 158i and 158s are also woven separately and secured, by stitching, to the top edges of the bottom downstream portions 157i and the bottom edges of the top downstream portions 157s, respectively. Because of these added-on fiber structures, the preform 140 has downstream secondary longitudinal portions 154v and 155v that are analogous to those in the first example.

(49) It should also be observed that the main fiber structure of the preform 140 also includes upstream overlap portions 152m and 153m that go round the link portion 144, respectively from below and from above, and that extend in part upstream therefrom, with a gap 149 that is cut out in the fiber structure separating these overlap portions 152m and 153m from the link portion 144. The cutting that forms the gap 149 may be performed in particular by a jet of water under pressure or by a laser beam.

(50) The embodiments or implementations described in the present description are given by way of non-limiting illustration, it being easy for a person skilled in the art to modify these embodiments and implementations or to envisage others in the light of this description, and while remaining within the ambit of the invention.

(51) Furthermore, the various characteristics of these embodiments or implementations may be used on their own or in combination with one another. When they are combined, these characteristics may be combined as described above or in other ways, the invention not being limited to the specific combinations described in the present description. In particular, unless specified to the contrary, a characteristic described with reference to one particular embodiment or implementation may be applied in analogous manner to some other embodiment or implementation.