The present invention relates to a labyrinth sealing joint for a turbomachine, in particular an aircraft.
The prior art includes documents EP-A1-1413712, US-A1-2018/010467 and US-A1-2014/072415.
It is known to equip a turbomachine with labyrinth sealing joints, which are sealing joints, the dynamic sealing of which is ensured by rotating lips. As shown in
The abradable elements 18 are intended to protect the lips 12 from wear by contact with the stator element 16 surrounding them. The contact with the abradable elements 18 can be avoided or, on the contrary, can be sought, for example, to minimize the radial clearances J around the lips. The types of abradable elements 18 and lips 12 can be adapted accordingly.
This technology can be used to ensure a sealing of the tops of the blades of a rotor wheel, these blades carry annular, possibly sectorized lips, which are surrounded by abradable elements carried by a stator housing (see in particular FR-A1-3 001 759). It can also be used to provide a sealing between a portion of the shaft or trunnion and a stator of the turbomachine. The number and dimensions of the lips depend in particular on the radial space available between the elements to be sealed.
During operation, as shown in
At the level of each lip 12 to be crossed, the gas stream is disturbed a first time when it impacts the body of the lip (arrow F1). The gas stream crosses the gap between the top of the lip 12 and the abradable element 18 surrounding it, this stream being reduced by the value J thanks to the disturbance created by the lip, then is disturbed a second time (arrow F2) following the sudden increase in the passage section after crossing the lip. The greater the number of lips 12, the more turbulence is generated in the gas stream, and the better the sealing joint is improved.
The present invention proposes an improvement to this technology to improve the sealing of the sealing joint in a simple, efficient and economical way.
The invention provides a labyrinth sealing joint for a turbomachine, in particular of an aircraft, comprising a rotor element extending around an axis, and a stator element extending around the rotor element, the rotor element comprising two annular lips extending radially outwards and surrounded by at least one abradable element carried by said stator element, characterized in that a plurality gas passage cavities are arranged circumferentially next to one another between the two lips which are interconnected by connecting partitions, and in that at least one of said lips has at least one axial gas passage opening that leads into at least some of said cavities.
The present invention can use only two lips to ensure sealing between a rotor and a stator. These lips can replace a multitude of adjacent annular lips of the prior art, which is advantageous.
The air passage cavities are located between the lips (or between two annular walls, respectively upstream and downstream, of the lip when it is considered unique) and are arranged circumferentially. They open radially outwards, facing the abradable element and are internally delimited by a bottom or an annular surface extending between the lips and which is preferably cylindrical.
These cavities define or are part of “bathtubs” in which gas streams can circulate and are advantageously disturbed or pressurized.
At the level of each lip to be crossed, the gas stream is disturbed a first time when it impacts the body of the upstream lip. The gas stream crosses the radial clearance at the top of the upstream lip and penetrates and circulates in the cavities where it is disturbed a second time and can undergo various phenomena (disturbances, pressurization, vortices, etc.). These phenomena create turbulence which improves the performance of the sealing joint. The gas stream continues its course and is then disturbed a third time, due in particular to the increase in the passage section after crossing the downstream lip.
The invention thus makes it possible to significantly increase the sealing level of the sealing joint.
In accordance with the invention, said partitions can extend substantially axially between the lips and define therebetween sectors of spaces for gas passage, said sectors of spaces being divided by separation walls to form said cavities.
The sealing joint according to the invention may comprise one or more of the following features, taken in isolation from each other or in combination with each other:
The present invention also concerns a turbomachine, characterized in that it comprises at least one sealing joint as described above.
The invention will be better understood and other details, characteristics and advantages of the invention will appear more clearly when reading the following description made as a non-limitative example and with reference to the appended drawings in which:
The sealing joint 100 comprises a rotor element 114 rotating around an axis of rotation, which is not visible and which will be designated by A, and a stator element 116 extending around the rotor element 114.
In the example shown, the stator element 116 is a turbine nozzle that comprises two annular shrouds between which an annular row of stator blades 120 extends. Only the radially inner shroud 122 is visible here. This shroud is generally cylindrical or frustoconical in shape and carries on its internal periphery an abradable annular element 118 which surrounds the rotor element 114 with a small radial clearance J.
This rotor element 114 is here a rotor disc which can be monobloc, i.e. it extends continuously over 360° around its axis A. It comprises an annular wall 114a extending around the axis with an opening in the center. As can be seen in
The wall 114a is connected at its outer periphery to two annular flanges, respectively upstream 114b and downstream 114c. The upstream flange 114b has in axial section a general curved shape, the concavity of which is oriented radially outwards with respect to the axis A. The flange 114b has a downstream end connected to the outer periphery of the wall 114a and a free upstream end which can be attached to a rotor wheel located upstream of the element 114. The downstream flange 114b also has a generally curved shape in axial section with the concavity facing radially outward from the axis A. The flange 114c has an upstream end connected to the outer periphery of the wall 114a and a free downstream end that can be attached to a rotor wheel located downstream of the element 114.
The outer periphery of the wall 114a is thickened both radially and axially in the example shown to define a radially outer cylindrical surface 122. This surface 122 here has an axial dimension L greater than the minimum axial thickness of the wall 114a and substantially equal to the maximum axial thickness of this wall (
Two annular lips 112a, 112b are protruding from the surface 122 and extend radially outwards. They are substantially parallel to each other and to a plane perpendicular to the axis A. They are located respectively at the axial ends of the surface 122. The upstream lip 112a has an upstream radial face 112aa which is radially aligned with an upstream radial face 122a of the outer periphery of the wall 114a. The downstream lip 112b has a downstream radial face 112ba that is radially aligned with a downstream radial face 122b of the outer periphery of the wall 114a.
The radially outer tops or ends of the lips are separated by the clearance J located between the rotor element 116 and the abradable element 118.
The lips 112a, 112b define between them an annular space 124 which is sectorized and formed by several sectors of space 124a, 124b, etc. isolated and arranged circumferentially next to one another around the axis A.
The lips 112a, 112b are connected to each other by partitions 126 which are here parallel to each other and oriented axially, i.e. parallel to the axis A. As can be seen in
In the example shown, the lips 112a, 112b and the partitions 126 have the same height H1 or radial dimension, measured here from the cylindrical surface 122. The partitions 126 thus have their tops separated by the clearance J of the abradable element 118.
The partitions 126 can be connected to the lips 112a, 112b as well as to the surface 122 by fillets 126a (
A sector of space 124a, 124b is thus delimited on the one hand by axially aligned portions of lips 112a, 112b and on the other hand by two adjacent partitions 126 extending between these portions. Each sector of space thus has the shape of a “bathtub”.
In the embodiment of
The openings 128, 130 are here formed by radial notches extending from the tops of the lips over approximately all their heights. The openings 128, 130 are not aligned axially but are on the contrary offset from each other in the circumferential direction, as shown in
The opening 128 allows the gas passage in operation, from the upstream to the downstream, following the arrow F4, i.e. from the upstream of the upstream lip 112a to the sector of space 124a, 124b. The opening 130 allows the gas passage in operation, from upstream to the downstream, following the arrow F5, thus from the sector of space 124a, 124b to the downstream of the downstream lip 112b.
Within the sector of space 124a, 124b, the separation walls 132 are provided. In the example shown, each sector of space comprises a wall 132 which has a generally corrugated shape and comprises an upstream end connected to the downstream radial face of the upstream lip 112a and a downstream end connected to the upstream radial face facing the downstream lip 112b. The wall 132 is located substantially in the middle of the sector of space, in the circumferential direction, and comprises a through hole 134 oriented here in a substantially circumferential direction.
The wall 132 has here a radial height H2, measured from the surface 122, which is less than that of H1 of the lips 112a, 112b and partitions 126. The wall 132 separates the space into two cavities 132a, 132b in fluid communication via the bore 134.
The shapes and dimensions of the wall 132 and the bore 134 are determined to control the disturbance of the incoming and outgoing gas stream in each sector of space.
The openings 128, 130 are advantageously calibrated. The cavities 132a, 132b could lose their curvilinear side or reduce in spacing in places in order to increase the pressure between two shapes to expel a more compressed gas stream between the rotor and the stator. The shapes can be aerodynamic or on the contrary tapered to smooth the stream in some places or amplify the disturbance to others (depending on upstream/downstream needs).
At the level of the lip 112a, the gas stream is disturbed a first time when it impacts the lip (arrow F1). A first part of the gas stream crosses the radial clearance at the top of the lips 112a, 112b (arrow F3) then is disturbed a second time following the increase of the passage section downstream of the lips (arrow F2). On the other hand, a second part of the gas stream enters sectors of space 124a, 124b (arrow F4) and circulates there being disturbed, which generates turbulence and impacts the first part of the gas stream, whose flow rate is reduced.
Number | Date | Country | Kind |
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1855418 | Jun 2018 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FR2019/051400 | 6/11/2019 | WO | 00 |