DYNAMIC SEAL FOR A TURBOMACHINE COMPRISING A MULTI-LAYER ABRADABLE PART

Abstract

A dynamic seal for a turbomachine, including a fixed portion provided with at least one abradable wear part and a movable portion including at least one lip arranged to interact with the at least one wear part during the rotation of the movable portion. The wear part includes a structure forming cavities arranged in one or more series such that, in each series, the cavities of this series are superposed radially with respect to the central axis, the structure being configured to limit or prevent the circulation of gas between each pair of radially adjacent cavities. A method for the additive manufacture of the fixed portion of this dynamic seal is also described.

Claims

1. A dynamic seal for an aircraft turbomachine), comprising a stationary part provided with at least one abradable wear part and a part rotatably movable about a central axis, the movable part comprising at least one strip seal arranged to interact with the at least one wear part during rotation of the movable part about the central axis, wherein the at least one wear part includes a structure forming cavities arranged in one or more series so that in each series, the cavities of that series are radially superimposed with respect to the central axis, said structure being shaped at least to limit gas circulation between each pair of radially adjacent cavities, each cavity of the at least one wear part constituting a channel extending circumferentially with respect to the central axis over the whole circumferential dimension of the wear part.

2. The dynamic seal according to claim 1, wherein said structure of the at least one wear part forms, between each pair of radially adjacent cavities, a solid wall preventing any gas circulation from one of these cavities to the other.

3. The dynamic seal according to claim 1, wherein said structure of the at least one wear part forms, between each pair of radially adjacent cavities, an obstacle providing an opening between these cavities so as to limit gas circulation from one of these cavities to the other.

4. The dynamic seal according to claim 1, wherein the at least one wear part includes several series of cavities extending circumferentially with respect to the central axis.

5. The dynamic seal according to claim 1, wherein the stationary part is provided with a single wear part forming a ring centred on said central axis.

6. The dynamic seal according to claim 1, wherein the stationary part is provided with several wear parts arranged circumferentially end to end so as to form together a ring centred on said central axis.

7. An aircraft turbomachine, comprising a dynamic seal according to claim 1.

8. A method for manufacturing a dynamic seal according to claim 1, wherein said dynamic seal further comprises a step of additively manufacturing the at least one wear part.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0032] The following detailed description refers to the appended drawings in which:

[0033] FIG. 1 is a schematic axial cross-section view of an aircraft propulsion assembly comprising a turbomachine of the turbofan engine type;

[0034] FIG. 2 (already described) is a partial schematic axial cross-section half-view of a low-pressure turbine of a turbomachine, comprising a dynamic seal of prior art;

[0035] FIG. 3 is a partial schematic view of a dynamic seal according to the invention;

[0036] FIG. 4 is a partial schematic perspective view of a dynamic seal wear part according to a first embodiment;

[0037] FIG. 5 is a partial schematic axial cross-section view of a dynamic seal wear part according to a second embodiment;

[0038] FIG. 6 is a partial schematic view of the wear part of FIG. 5, showing the hexagonal shape of the cavities;

[0039] FIG. 7 is a partial schematic perspective view of a dynamic seal wear part according to a third embodiment in accordance with the invention;

[0040] FIG. 8 is a partial schematic axial cross-section view of the wear part of FIG. 7;

[0041] FIG. 9 is a partial schematic perspective view of a dynamic seal wear part according to a fourth embodiment in accordance with the invention;

[0042] FIG. 10 is a partial schematic axial cross-section view of the wear part of FIG. 9;

[0043] FIG. 11 is a partial schematic perspective view of a dynamic seal wear part according to a fifth embodiment in accordance with the invention;

[0044] FIG. 12 is a partial schematic axial cross-section view of the wear part of FIG. 11;

[0045] FIG. 13 is a partial schematic perspective view of a dynamic seal wear part according to a sixth embodiment in accordance with the invention;

[0046] FIG. 14 is a partial schematic axial cross-section view of the wear part of FIG. 13.

DETAILED DESCRIPTION OF EMBODIMENTS

[0047] The invention relates to a turbomachine, for example for an aircraft propulsion assembly 1 (not represented) as represented in FIG. 1. In this example, the turbomachine 10, which is housed in a nacelle 11 of the propulsion assembly 1, is a turbofan engine well known in the aeronautical field. Of course, the invention is not limited to such a turbomachine and can be applied to any type of turbomachine, such as a turboprop engine for example.

[0048] The turbomachine 10 has a central longitudinal axis A1 about which its various components extend, in this case, from upstream to downstream of the turbomachine 10, 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. The compressors 3 and 4, the combustion chamber 5 and the turbines 6 and 7 form a gas generator.

[0049] Conventionally, during operation of such a turbofan engine 10, an air flow 8 enters the propulsion assembly 1 through an air intake upstream of the nacelle 11, passes through the fan 2 and then splits into a central primary flux 8A and a secondary flux 8B. The primary flux 8A flows in a main stream 9A for circulating gases passing through the compressors 3 and 4, the combustion chamber 5 and the turbines 6 and 7. The secondary flux 8B in turn flows in a secondary stream 9B surrounding the gas generator of the turbojet engine 10 and radially outwardly delimited by the nacelle 11.

[0050] Throughout this description, the terms “upstream” and “downstream” are defined in relation to a main direction D1 of gas flow through the propulsion assembly 1 along the axial direction X. The terms “inner” and “outer” refer respectively to a relative proximity, and a relative distance, of an element with respect to the central axis A1. The axial direction X is a direction parallel to the longitudinal central axis A1 of the turbomachine 10; the radial direction R is, at any point, a direction orthogonal to and passing through the central axis A1; and the circumferential or tangential direction C is, at any point, a direction orthogonal to the radial direction R and to the central axis A1.

[0051] FIG. 2, already described, represents in more details part of a turbine 90 of prior art. Such a turbine typically constitutes the low pressure turbine 6 of a turbojet engine of a propulsion assembly of the type represented in FIG. 1.

[0052] The invention is more specifically concerned with a dynamic seal, which may especially replace the dynamic seals 94, 97 and/or 98 of the turbine 90 of FIG. 2.

[0053] A dynamic seal 20 is partially represented in FIG. 3. This seal 20 consists of a stationary part 21 and a movable part 22.

[0054] The stationary part 21 of the seal 20 is to be connected to a turbomachine stator, for example to the stator of the compressor 3 or 4, or of the turbine 6 or 7 of the turbomachine 10. With reference to the known configuration of FIG. 2, the stationary part 21 of the seal 20 can thus be fixed to the radially inner face of the inner annular wall 93 of the stationary vane 91 of the turbine 90.

[0055] More precisely, the stationary part 21 of the seal 20 comprises a wear part 23 and a support element 24 for holding the wear part 23 fixedly relative to the movable part 22. Still referring to the known configuration of FIG. 2, attaching the stationary part 21 of the seal 20 to the inner annular wall 93 may here be achieved by attaching the support element 24 to said radially inner face of this wall 93.

[0056] In this example, the wear part 23 is located radially inwardly of the support element 24.

[0057] The movable part 22 of the seal 20 is to be connected to a turbomachine rotor, for example to the rotor of the compressor 3 or 4, or of the turbine 6 or 7 of the turbomachine 10. With reference to the known configuration of FIG. 2, the movable part 22 of the seal 20 may be connected to the annular flange 99 connecting the movable vanes 92. The movable part 22 of the seal 20 can thus be secured to the rotor, rotating about the central axis A1 of the turbomachine 10.

[0058] In the example shown in FIG. 3, the movable part 22 of the seal 20 comprises two annular strip seals 25 arranged to interact with the wear part 23 during rotation of the movable part 22 about the central axis A1.

[0059] Each strip seal 25 comprises a machining end 26 arranged facing and at a short distance from the wear part 23, in order to limit as much as possible the gas flow between the stationary part 21 and the movable part 22 of the seal 20, in the manner of a sealing labyrinth.

[0060] In a manner known per se, the strip seals 25 and the wear part 23 are made of respective materials allowing the strip seals 25 to machine the wear part 23 with their machining end 26 during rotation of the rotor. In other words, the wear part 23 is abradable.

[0061] The invention is more specifically characterised by the structure of the wear part 23, several embodiments of which are illustrated in FIGS. 7 to 14.

[0062] FIGS. 4 to 6 show other embodiments of a wear part 23 which are not part of the invention.

[0063] In each of the embodiments in FIGS. 4 to 14, the wear part 23 has a structure forming multiple layers of cavities.

[0064] More specifically, with reference to the embodiment in FIG. 4, the wear part 23 comprises several layers of cavities spaced apart along the radial direction R.

[0065] In this example, for each layer, the cavities extend both axially, that is along the axial direction X, and circumferentially, that is along the circumferential direction C.

[0066] In other words, the cavities of the wear part 23 are arranged in several series so that, in each series, the cavities of that series are superimposed radially with respect to the central axis A1.

[0067] The wear part 23 is shaped to limit or prevent gas circulation between each pair of radially adjacent cavities, that is to limit or prevent gas circulation from a first cavity belonging to one of the layers to a radially adjacent second cavity, that is belonging to a layer adjacent to the layer including the first cavity.

[0068] In the embodiments in FIGS. 4 to 6, each layer has a honeycomb structure, the wear part 23 thus forming a structure including a superimposition of honeycomb-type cell cores. The cavities of each series respectively consist of respective cells of the cell cores.

[0069] In the example in FIG. 4, the wear part 23 comprises five cores A41-A45 separated in twos by walls 231. The walls 231 comprise holes 232 each forming an opening between two radially adjacent cavities. The holes 232 have a diamond-shaped cross-section in this example and are for discharging powder (see below). The holes 232 are sized to allow such powder discharge while limiting the flow rate of gas that may pass from one cavity to the other. Of course, depending on the manufacturing method used, such holes 232 may be unnecessary so that, in embodiments not represented, the walls 231 may be solid and completely plugs the cavities with respect to each other.

[0070] In the example in FIGS. 5 and 6, the wear part 23 comprises three cores A51-A53 separated in twos by walls 231. In this example, the walls 231 comprise hexagonal cross-section holes 232 each forming an opening between two radially adjacent cavities. The function of these holes is similar to that of the holes in the embodiment of FIG. 4 (see above).

[0071] In the embodiments in FIGS. 7 to 14 in accordance with the invention, each cavity forms a channel extending circumferentially with respect to the central axis A1, over the whole circumferential dimension of the wear part 23.

[0072] In the embodiment in FIGS. 7 and 8, the wear part 23 comprises circumferential bars 233. Each bar 233 comprises a central portion 234 and radially spaced apart branches 235 so as to define cavities C1-C4 open onto each other. The branches 235 form air flow cross-section restrictions between radially adjacent cavities (see FIG. 8). In the example illustrated, each branch 235 is fir tree shaped.

[0073] In other words, the branches 235 form an obstacle between each pair of radially adjacent cavities, providing an opening between these cavities so as limit the gas circulation from one of these cavities to the other.

[0074] The openings provided between radially adjacent cavities have a dimension D1 capable of significantly limiting the gas circulation between these cavities, given their own dimensions. Of course, these openings can also be used to discharge powder, in particular when the wear part 23 is annular and manufactured by an additive manufacturing method by powder bed laser melting (see below).

[0075] In the embodiment of FIGS. 9 and 10, the wear part 23 has walls 236 axially delimiting the cavities and walls 237 radially delimiting the cavities.

[0076] In this example, the walls 236 and 237 are solid and therefore prevent any gas circulation between adjacent cavities.

[0077] In one embodiment not represented, the walls 237 may comprise holes or openings between radially adjacent cavities for de-powdering (see later).

[0078] With reference to FIG. 10, the cavities of this wear part 23 have a substantially rectangular cross-section, the walls 236 and 237 being substantially straight along the radial R and axial X direction respectively.

[0079] The embodiment of FIGS. 11 and 12 is distinguished from that of FIGS. 9 and 10 by the shape of the walls 237: each wall 237 radially delimiting two adjacent cavities comprises two parts 2371 and 2372 each extending both along the axial direction X and along the radial direction R, so that the cavities have a “V”-shaped axial cross-section.

[0080] Of course, the walls 236 and 237 of these different embodiments may have different shapes and hence the cavities of the wear part 23 may have a cross-section of any shape imparting the capacity to perform its function to the wear part 23.

[0081] In the embodiment of FIGS. 13 and 14, the wear part 23 has walls 238 and 239 that are substantially straight in the plane X-R and perpendicular to each other, each extending along both the axial direction X and along the radial direction R, so that the cavities each have a substantially square cross-section.

[0082] In this example, most of the cavities are each radially adjacent to at least three other cavities. For example, cavity C5 is adjacent to cavities C6, C7 and C8. Cavities C5 and C8 are delimited by a node N1 formed by the intersection of two walls 238 and 239. Cavity C5 is separated from cavity C6 by a wall 238, and from cavity C7 by a wall 239.

[0083] The walls 238 and 239 are solid and therefore prevent any gas circulation between adjacent cavities.

[0084] The axial dimension of the wear part 23 especially depends on the number and dimension of the strip seals 25.

[0085] The circumferential dimension of the wear part 23 may vary depending on whether the stationary part 21 is provided with a single or several wear parts 23. In the first case, the wear part 23 typically forms a ring centred on the central axis A1, in which case its circumferential dimension is equal to 360°. In the second case, the stationary part 21 may comprise several wear parts 23 circumferentially arranged end to end so as to together form a ring centred on said central axis A1, in which case the circumferential dimension of each of the wear parts 23 is less than 360°. This applies regardless of the embodiment described above.

[0086] Regarding the manufacture of the wear part 23, this may be carried out by additive manufacturing, in particular by means of a method of selectively laser melting metal powder layers.

[0087] After the wear part 23 has been manufactured, the cavities are likely to contain residual powder which has to be discharged before implementing the dynamic seal.

[0088] The powder can be discharged: [0089] in the examples of FIGS. 4 to 6, through holes 232, [0090] in the example of FIGS. 7 and 8, through the openings formed by the branches 235 and/or the circumferential ends of the cavities if the wear part 23 does not form a closed ring, [0091] in the examples of FIGS. 9 to 14, through the circumferential ends of the cavities if the wear part 23 does not form a closed ring, and/or through openings (not represented) between adjacent cavities.

[0092] The cavities or openings for powder discharge may be of any shape in cross-section, for example diamond, square, round, triangle, or hexagon, provided that they are small enough to limit gas circulation between radially adjacent cavities.

[0093] In order to improve abradability of the wear part 23, both the wear part 23 and the support element 24 of the stationary part 21 may be manufactured as a single piece, using an additive manufacturing method.

[0094] The examples just described are by no means limiting.

[0095] By way of example, the walls defining two adjacent cavities may have a thickness in the order of 0.08 mm and the cavities may have a radial dimension of between 0.8 mm and 2 mm.