FR3084700A1 - SEAL AND SEALING SYSTEM FOR TURBOMACHINE - Google Patents

Abstract

The present disclosure relates to a gasket (23) for a turbomachine (11), configured to be disposed between a first shaft (13) and a second shaft (17), the first and second shafts (13, 17) being configured to rotating relative to each other about a main axis (AP), the seal (23) comprising a first cooperating element (29) configured to be mounted on the first shaft (13); a second cooperation element (31) configured to be mounted on the second shaft (17) and cooperating with the first cooperation element (29) at a cooperation zone; at least one lubricant passage configured to supply a lubricant to the cooperation zone, the lubricant passage being provided in at least one of the first and second cooperation elements (29, 31).

Description

FIELD OF THE INVENTION [1] The present disclosure relates to a gasket for a turbomachine, configured to be disposed between a first shaft and a second shaft. The present disclosure also relates to a sealing system for a turbomachine, comprising the seal. The invention also relates to a turbomachine comprising the seal or the sealing system.

TECHNOLOGICAL BACKGROUND [2] It is known from the prior art of seals for a turbomachine between two shafts which rotate relative to one another, for example inter-shaft seals having adjacent surfaces turning the one in relation to the other. However, when the shafts rotate at a significant relative speed, in particular when the shafts are counter-rotating, such seals may be subject to premature wear. Thus, when the relative speed between the two shafts is high, labyrinth type seals are used. For a better reliability, it is necessary to put the zone in which one does not wish that a liquid passes to a higher pressure than the zone containing the liquid. However, this type of sealing system entails the need for a high air flow to put the area in which it is not desired that a liquid pass under pressure, which requires additional equipment and significant energy costs. . There is therefore a need in this sense.

PRESENTATION OF THE INVENTION [3] For this purpose, the present disclosure relates to a gasket for a turbomachine, configured to be disposed between a first shaft and a second shaft, the first and second shafts being configured to rotate one by relative to each other around a main axis, the seal comprising:

- a first cooperation element configured to be mounted on the first shaft,

a second cooperation element configured to be mounted on the second shaft and cooperating with the first cooperation element at the level of a cooperation zone,

- At least one lubricant passage configured to bring a lubricant to the cooperation zone, the lubricant passage being formed in at least one of the first and second cooperation elements.

[4] It is understood that the term "tree" includes the tree itself and also, the rotating parts of the shaft, for example a journal.

[5] It is understood that the seal separates a first space and a second space, and provides a liquid sealing function between the first and second spaces.

[6] It is understood that the seal is configured to ensure at least relative tightness, that is to say limit the passage of liquid through the seal. In other words, it is possible that liquid can pass through the seal, in a very small amount.

[7] Thanks to these provisions, lubricant easily reaches the cooperation zone so as to lubricate it. Thus, the seal according to the present description makes it possible to prevent wear of the first and second cooperation elements and therefore to ensure the seal of the seal in a lasting manner.

[8] In addition, contrary to what could be expected, the fact of introducing a lubricant, which is a liquid within the meaning of the present description, in the cooperation zone, improves the performance of the seal, it is that is, limits the passage of liquid through the seal.

[9] The main axis is the axis of rotation of the first shaft and / or the second shaft of the turbomachine. An axial direction corresponds to the direction of the main axis and a radial direction is a direction perpendicular to this main axis and intersecting this main axis. Likewise, an axial plane is a plane containing the main axis and a radial plane is a plane perpendicular to this main axis. A circumference is understood as a circle belonging to a radial plane and whose center belongs to the main axis. A tangential or circumferential direction is a direction tangent to a circumference; it is perpendicular to the main axis but does not pass through the main axis.

[10] According to one aspect of this presentation, at least one of the first and second shafts is configured to rotate around the main axis.

[11] It is understood that the first and second shafts extend along the same main axis.

[12] According to one aspect of this presentation, the first and second shafts rotate around the main axis.

[13] Unless otherwise specified, the adjectives interior and exterior are used with reference to a radial direction so that the interior part of an element is, in a radial direction, closer to the main axis than the exterior part of the same element.

[14] According to one aspect of this presentation, the first tree rotates outside the second tree. We understand that the second tree guides the first tree. For example, the first and second trees have the general shape of a cylinder. For example, the first and second shafts are low-pressure and high-pressure transmission shafts for the turbomachine, respectively.

[15] For example, each of the first and second shafts is intended to rotate at a determined speed. For example, the first and second trees are counter-rotating. Thus, for example, by adding the speeds of the first and second shafts, a relative speed of between 150 and 200 m / s is obtained. It is therefore advantageous to lubricate the seal so as not to cause premature wear of the seal at the level of the cooperation zone.

[16] According to one aspect of this presentation, the seal extends over the entire circumference between the first and second shafts, so as to seal between the first and second spaces. The first and second spaces can also be substantially annular.

[17] It is understood that the seal has a generally annular shape.

[18] According to one aspect of this presentation, the passage of lubricant communicates with a conduit formed in at least one of the first and second shafts.

[19] According to one aspect of this presentation, the seal comprises an indexing element disposed between the first cooperation element and the first shaft, and / or between the second cooperation element and the second shaft. The indexing element makes it possible to arrange the lubricant passage in front of the conduit so that they communicate.

[20] According to one aspect of this presentation, the indexing element is a rod embedded between the first cooperation element and the first shaft, and / or between the second cooperation element and the second tree.

[21] According to one aspect of this presentation, the lubricant passage comprises at least one segment which moves away from the main axis while approaching the cooperation zone.

[22] It is understood that the lubricant passage has an inclination relative to the main axis, towards the cooperation zone, so that the lubricant is directed towards the cooperation zone by means of a centrifugal force when the first and second trees rotate relative to each other.

[23] For example, the inclination between the main axis and the lubricant passage is between 5 ° and 90 ° angle (five and eighty ten degrees of angle), preferably between 45 ° and 90 ° (forty-five and ninety ten degrees of angle), more preferably between 75 ° and 90 ° (seventy-five and eighty ten degrees of angle). In other words, the direction of the lubricant passages has at least one radial component. The radial component can be dimensioned to have a height sufficient to generate a pressure conducive to flow under the effect of centrifugal acceleration.

[24] Thanks to these provisions, the centrifugal force facilitates the flow of the lubricant to the cooperation zone. Thus, the lubricant more easily reaches the cooperation zone, which improves the lubrication of the seal.

[25] For example, the lubricant comes from one of the first and second spaces.

[26] According to one aspect of this presentation, the lubricant is of the same nature as the liquid present in one of the first and second spaces.

[27] For example, the liquid is oil, for example of type I, typically with a viscosity of 3 centiStokes, or of type II, typically with a viscosity of 5 centiStokes.

[28] Alternatively or additionally, the lubricant of the seal can be taken from the supply of lubricant from the first and second shafts, for example.

[29] In one aspect of this discussion, the first and second elements of cooperation overlap.

[30] Thanks to these provisions, the overlap of the first and second cooperation elements makes it possible to limit the passage of liquid through the seal. The seal of the seal is improved.

[31] According to one aspect of this presentation, the first and second cooperation elements overlap radially and / or axially.

[32] Given the direction of the centrifugal force, it is preferable that the overlap is at least radial. Preferably, in order to facilitate the mounting of the seal, the overlap is conical.

[33] According to one aspect of this presentation, the axial play between the first and second cooperation elements is between 0.05 and 1 mm, preferably between 0.05 and 0.5 mm, and more preferably between 0.05 and 0.1 mm.

[34] According to one aspect of this presentation, the first and second cooperation elements are adjacent to each other.

[35] For example, the first and second elements of cooperation cooperate by complementarity of form.

[36] In one aspect of this disclosure, the seal includes a plurality of lubricant passages distributed along a circumference of at least one of the first and second cooperating elements.

[37] Thanks to these provisions, the lubrication of the seal's cooperation zone is better distributed, and therefore improved. These provisions therefore make it possible to further limit the passage of liquid through the seal, in other words, to improve the seal of the seal.

[38] According to one aspect of this presentation, each passage of lubricant communicates with a conduit formed in at least one of the first and second shafts.

[39] According to one aspect of this presentation, the indexing element makes it possible to arrange each passage of lubricant in front of a corresponding conduit.

[40] According to one aspect of this presentation, the lubricant passages are distributed regularly, that is to say equi-distributed along the circumference of at least one of the first and second cooperation elements.

[41] It is understood that the lubricant passages are angularly distributed along the circumference of at least one of the first and second cooperation elements.

[42] Thanks to these provisions, the lubrication of the seal's cooperation zone is improved. These provisions improve the tightness of the seal.

[43] According to one aspect of this presentation, the first cooperation element comprises a first lateral element and a second lateral element, the first and second lateral elements extending in a radial direction relative to the main axis, and the second cooperating element comprises a central element extending in the radial direction relative to the main axis, the central element being disposed between the first and second lateral elements in an axial direction.

[44] It is understood that the first and second lateral elements of the first cooperation element are provided on either side of the central element of the second cooperation element.

[45] It is understood that the central element is adjacent to the first and second lateral elements.

[46] Thanks to these provisions, the overlap between the first element of cooperation and the second element of cooperation is achieved on two levels. In other words, the first and second cooperation elements overlap twice, namely once on the side of each lateral element. Thus, the seal of the seal is improved.

[47] For example, the first lateral element is arranged on the side of the first space, and the second lateral element is arranged on the side of the second space relative to the central element.

[48] According to one aspect of this presentation, the first cooperation element further comprises a junction element, connecting the first and second lateral elements.

[49] It is understood that the first element of cooperation has a general shape of U, in which the second element of cooperation can be inserted.

[50] According to one aspect, the second cooperation element may have a substantially rectangular or trapezoidal section.

[51] According to one aspect of this presentation, the joining element is adjacent to a first end portion of the central element of the second cooperation element in the radial direction, opposite to a second end portion of the central element, attached to the second shaft.

[52] It is understood that the cooperation area has a general shape of U.

[53] According to one aspect of this presentation, at least one lateral element among the first and second lateral elements comprises the at least one lubricant passage.

[54] In one aspect of the present disclosure, the at least one side member includes a plurality of lubricant passages.

[55] According to one aspect of this presentation, the lubricant passages are distributed regularly over the circumference of the lateral element. It is understood that the lubricant passages are distributed angularly along the circumference of the at least one lateral element.

[56] According to one aspect of this presentation, each of the first and second lateral elements comprises at least one lubricant passage.

[57] According to one aspect of this disclosure, each of the first and second side members includes a plurality of lubricant passages.

[58] According to one aspect of the present disclosure, the plurality of lubricant passages of the first lateral element and the plurality of lubricant passages of the second lateral element are distributed in an offset or alternating fashion along the circumference of the seal, according to a projection on a radial plane.

[59] According to one aspect of this presentation, the joining element comprises at least one lubricant passage.

[60] According to one aspect of this presentation, the central element comprises at least one lubricant passage.

[61] The present disclosure also relates to a sealing structure for a turbomachine intended to be disposed between a first space and a second space, comprising:

- the seal in accordance with any of the above aspects, and

- a secondary sealing system disposed between the seal and at least one of the first and second spaces.

[62] The secondary sealing system is configured to further limit the passage of liquid between the first and second spaces. The secondary sealing system makes it possible to prevent the lubricant, and / or possible liquid leaks from contaminating one or both of the first and second spaces, despite the presence of the seal. The seal between the first and second spaces is therefore improved.

[63] According to one aspect of this presentation, the secondary sealing system comprises a recovery passage configured to recover the lubricant which escapes from the cooperation zone.

[64] The term "recovering the lubricant" means preventing the lubricant from reaching at least one of the first and second spaces.

[65] Thanks to these provisions, the lubricant does not contaminate the first and / or second spaces. The seal between the first and second spaces is therefore improved.

[66] According to one aspect of this presentation, the recovery passage comprises at least one outer portion disposed radially outside the seal.

[67] It is understood that the recovery passage comprises at least a portion disposed at a greater distance from the main axis than the seal in the radial direction.

[68] Thus, the centrifugal force makes it possible to direct the lubricant towards said at least a portion of the recovery passage, thus the lubricant does not contaminate the first and / or second spaces. The seal between the first and second spaces is therefore improved.

[69] According to one aspect of this presentation, the lubricant recovery passage opens into one of the first and second spaces, designed to contain the liquid.

[70] According to one aspect of this discussion, the first space includes the liquid. The second space does not include the liquid.

[71] According to one aspect of this presentation, the lubricant recovery passage opens into the first space. Thus, when the lubricant leaves the side of the second space relative to the seal, that is to say in the recovery passage, it is recovered and reinserted in the first space in order to limit contamination of the second space.

[72] According to one aspect of this presentation, the secondary sealing system comprises a secondary seal, disposed between the seal and at least one of the first and second spaces, preferably in the axial direction.

[73] Thus, the risks of contamination of the second space by the lubricant are minimized and the seal between the first and second spaces is reinforced.

[74] According to one aspect of this presentation, the secondary seal is disposed between the recovery passage and the second space, for example in the axial direction.

[75] In one aspect of this discussion, the recovery passage is disposed between the seal and the secondary seal.

[76] According to one aspect of this presentation, the secondary seal is a “labyrinth” type seal. The secondary seal comprises a portion comprising a plurality of wipers, fixed to one of the first and second shafts and an abradable element, disposed on the other of the first and second shafts. The wipers are configured to dig into the abradable element so as to form a labyrinth-shaped cooperation zone, which limits the passage of liquid.

[77] According to one aspect of this presentation, when the turbomachine is in operation, the second space is subjected to a greater pressure than the first space. Thus, alternatively or in addition to the secondary sealing system, the pressure difference between the spaces limits the passage of fluid to the second space.

[78] According to one aspect of the present disclosure, the recovery passage comprises a first part extending substantially radially, and a second part extending substantially axially.

[79] According to one aspect of this presentation, the second part extends between the end of the first part and the first space. The outer portion is the portion of the first portion located outside relative to the seal.

[80] According to one aspect of this presentation, the first part, at its outer end, comprises at least one partition extending radially towards the main axis.

[81] The at least one partition makes it possible to force the lubricant to rotate at the same speed as the external shaft in order to optimize the centrifugation of the lubricant so that it can be reintroduced into the first space.

[82] According to one aspect of this presentation, the at least one partition is fixed to the second shaft.

[83] Preferably, the secondary sealing structure comprises two such partitions, diametrically opposite.

[84] The present disclosure further relates to a turbomachine comprising a seal in accordance with any of the foregoing aspects or a seal structure in accordance with any of the foregoing aspects.

[85] According to one aspect of this presentation, the turbomachine is a double body, comprising a high pressure body and a low pressure body.

[86] According to one aspect of this presentation, the first shaft forms a transmission shaft of the low pressure body.

[87] According to one aspect of this presentation, the second shaft forms a transmission shaft of the high pressure body.

BRIEF DESCRIPTION OF THE DRAWINGS [88] The invention and its advantages will be better understood on reading the detailed description which follows, of embodiments of the invention given by way of nonlimiting examples. This description refers to the accompanying drawings, in which:

- Figure 1 shows a sectional view along an axial plane of a portion of a turbomachine according to one embodiment of the present description;

FIG. 2 represents an enlargement of zone II of FIG. 1,

FIG. 3 represents a sectional view along the radial plane III-III of FIG. 2, of the first element of cooperation of the seal, connected to the first shaft,

- Figure 4 shows a sectional view along an axial plane of a portion of a turbomachine according to another embodiment of the present description.

DETAILED DESCRIPTION OF THE INVENTION [89] Figure 1 shows a rear portion of a turbomachine 11. The turbomachine 11 is dual-body. The turbomachine comprises a high pressure body and a low pressure body.

[90] The turbomachine 11 comprises a first shaft 13 configured to rotate around a main axis AP, the first shaft 13 here forms a transmission shaft of the high pressure body, sometimes more simply called the high pressure shaft. The turbomachine 11 comprises a second shaft 17 configured to rotate around the main axis AP also, the second shaft 17 here forming a low pressure transmission shaft, sometimes more simply called the low pressure shaft. The second shaft 17 here comprises an elongated main portion 17a and a journal 18. The journal 18 comprises a radial portion 18a extending from the elongated main portion 17a of the second shaft 17. The journal 18 is rotationally integral with the portion main elongate 17a of the second shaft 17. The first and second shafts 13, 17 are configured to rotate relative to each other around the main axis AP.

[91] The elongated main portion 17a of the second shaft 17 rotates inside the first shaft 13. The journal 18 is arranged around the first shaft 13 so that the first shaft 13 is wedged radially between the elongated main portion 17a of the second shaft 17 and the pin 18. The elongated main portion 17a of the second shaft 17 and the pin 18 guide the first shaft 13 radially.

[92] In one embodiment, each of the first and second shafts 13, 17 is configured to rotate at a determined speed. For example, the first and second shafts 13, 17 are counter-rotating. Thus, for example, by adding the speeds of the first and second shafts 13,17, a relative speed of between 150 and 200 m / s is obtained.

[93] The first and second shafts 13, 17 can move axially relative to each other.

[94] The turbomachine 11 comprises a sealing structure 21.

[95] The sealing structure 21, shown in FIG. 2, comprises a seal 23. The sealing structure 21 is arranged between a first space 25 and a second space 27. The first space 25, here an enclosure lubrication, is able to contain a liquid, for example a lubricant such as oil. The first space 25 includes nozzles configured to project the liquid onto the elements to be lubricated. As a result, the first space 25 contains an atmosphere charged with lubricant, also called oiled air. The second space 27 does not normally include liquid.

[96] The seal 23 is disposed between the first shaft 13 and the pin 18.

[97] The seal 23 extends over the entire circumference between the first shaft 13 and the pin 18, so as to seal between the first and second spaces 25, 27. The seal 23 has a general annular shape.

[98] The seal 23 includes a first cooperation element 29, here a first ring, configured to be mounted on the first shaft 13.

[99] The seal 23 includes a second cooperation element 31, here a second ring, configured to be mounted on the second shaft 17, in particular against the journal 18. The second cooperation element 31 is intended to come in support against the journal

18. More particularly, the pin 18 comprises a mounting portion 20 against which the second cooperation element 31 is intended to come to bear. The mounting portion 20 comprises a chamfer 20a, configured to allow the mounting of the second cooperation element 31 on the mounting element 20.

[100] The second cooperation element 31 comprises at least one portion of carbon or steel.

[101] The main axis AP is also the axis of the first cooperation element 29 of the seal 23.

[102] The sealing structure and the seal are shown in close-up view in FIG. 2.

[103] The first and second cooperation elements 29, 31 cooperate at the level of a cooperation zone 33.

[104] There may be a radial clearance between the first and second cooperation elements 29, 31. This radial clearance makes it possible to absorb the radial movements between the first and second shafts 13,17.

[105] The first cooperation element 29 comprises a first lateral element 35, arranged on the side of the first space 25, and a second lateral element 37, arranged on the side of the second space 27. The first and second lateral elements 35, 37, here annular, extend in a radial direction DR with respect to the main axis AP. The first cooperation element 29 further comprises a junction element 39, here a spacer, connecting the first and second lateral elements 35, 37. The junction element 39 is arranged around the first shaft 13. The section of the first element cooperation 29, or of the first ring, therefore has a general shape of U. The first cooperation element 29 is fixed to the first shaft 13 along the horizontal bar of the U.

[106] The second cooperation element 31 comprises a central element 41. In this embodiment, the second cooperation element 31 comprises only this central element 41. The central element 41 also extends in the radial direction relative to the main axis AP, the central element 41 being disposed between the first and second lateral elements 35, 37 in an axial direction. The first and second lateral elements 35, 37 of the first cooperation element 29 are provided on either side of the central element 41. The central element 41 is therefore configured to fit into the general U shape of the first element of cooperation 29. Thus, the first and second elements of cooperation 29, 31 cooperate by complementarity of form.

[107] In this example, the central element 41 is a split ring allowing its expansion until contact with the pin 18. In the free state, the outside diameter of the central element 41 may be slightly larger than the bore of the journal 18, so that it is mounted prestressed.

[108] The first and second elements of cooperation 29, 31 overlap. The overlap of the first and second cooperation elements 29, 31 makes it possible to limit the passage of liquid through the seal 23. The seal between the first and second spaces 25, Tl is therefore improved. The first and second cooperation elements 29, 31 overlap radially, as illustrated in FIG. 2, and / or axially. The first and second cooperation elements 29, 31 are adjacent to each other.

[109] The axial play between the first and second cooperation elements 29, 31 can be between 0.05 mm and 0.1 mm.

[110] The joining element 39 is adjacent to a first end portion 41a of the central element 41 in the radial direction, opposite to a second end portion 41b of the central element 41, in radial contact with pin 18.

[111] Thus, the cooperation zone 33 also has a general shape of U. More generally, the cooperation area 33 is defined between the first and second cooperation elements 29, 31.

[112] Thus, when the turbomachine is in operation, the centrifugal force is added to the prestress due to the mounting of the central element 41 against the journal 18. The centrifugal force is predominant when the turbomachine is in operation . The coefficient of friction between the central element 41 and the pin 18 can be adapted to control the axial sliding between these two elements. One of the sides of the central element 41 may be in contact with the first or the second lateral element 35, 37, depending on the sign of the pressure difference on either side of the seal and of the relative axial displacements between the first and second shafts 13, 17. It is understood that friction is likely to appear between the central element 41 and one or the other of the first and second lateral elements 35, 37. Heat is then generated by friction on the surface of the first or second lateral element 35, 37 and of the central element 41. The thermal power released is maximum when the first cooperation element 29 pushes the second cooperation element 31 and moves it axially, and decreases when the first and second shafts 13 are again stabilized and the contact between the central element 41 and the lateral elements 35, 37 is minimized.

[113] The seal 23 includes a plurality of lubricant passages 43 configured to bring a lubricant to the cooperation zone 33. For example, the lubricant comes from the first space 25. In fact, the liquid present in the first space 25 can be a lubricant. The lubricant of the seal 23 can alternatively or additionally be taken from the supply of lubricant to the first and second shafts 13, 17. Preferably, the lubricant comes from a supply to the roller bearing 28. The path of the lubricant is illustrated in FIG. 1 by the arrow F1, from the roller bearing 28 towards the seal 23. A cover 24 makes it possible to radially hold the first cooperation element 29 of the seal 23 against a shoulder 26 of the first shaft 13 The cover 24 also makes it possible to guide the lubricant from the roller bearing 28 towards the seal 23. The lubricant can also come from possible leaks of lubricant outside the first space 25. In this case, a passage 30 allows the reintroduction of the lubricant into the first space 25, as illustrated by the arrow F2. The lubricant is then reintroduced radially inside the cover 24 so as to be guided towards the seal 23.

[114] In the embodiment shown, the lubricant passages 43 are formed in the first cooperation element 29, and more particularly in each of the first and second lateral elements 35, 37. In this embodiment, each of the first and second lateral elements comprises eight passages of lubricant 43.

[115] Each lubricant passage 43 includes at least one segment 43a which moves away from the main axis while approaching the cooperation zone 33. Each lubricant passage segment 43a 43 has an inclination relative to the axis main AP, so that the lubricant is directed towards the cooperation zone 33 thanks to a centrifugal force when the turbomachine 11 is in operation.

[116] The inclination between the main axis AP and the segments of the lubricant passages 43 is between 5 ° and 90 ° angle (five and eighty ten degrees of angle), here the inclination is 90 ° angle. In other words, the direction of the lubricant passages 43 has at least one radial component. In this way, the centrifugal force allows the lubricant to flow to the cooperation zone 33.

[117] The lubricant passages 43 are here equi-distributed along a circumference of each of the first and second lateral elements 35, 37 of the first cooperation element 29.

[118] In addition, the first and second lateral elements 35, 37 are arranged relative to each other so that, in projection along a radial plane, the lubricant passages 43 of the first and second lateral elements 35, 37 are evenly distributed along the circumference of the first cooperation element 29.

[119] The lubricant passages 43 open on one side into the cooperation zone 33. The lubricant passages 43 make it possible to directly supply lubricant to the cooperation zone 33, and thus limit the contact between the first and second cooperation elements 29, 31. On the other side, the lubricant passages 43 communicate with conduits 45, here lunulas, formed in the first shaft 13. The first shaft 13 thus comprises sixteen conduits 45 equi-distributed along the circumference of the first shaft 13. The conduits 45 open into the first space 25.

[120] In order to ensure the correct positioning of the conduits 45 opposite the lubricant passages 43, an indexing element 47 may be disposed between the first cooperation element 29 and the first shaft 13, as shown in FIG. 3. In the embodiment shown, the indexing element 47 is a rod embedded between leather and flesh, that is to say a rod placed astride two cylindrical parts fitted to prevent relative angular displacement, here between the first cooperation element 29 and the first tree 13.

[121] The sealing structure 21 further comprises a secondary sealing system 49 disposed between the seal 23 and the second space 27. The secondary sealing system makes it possible to prevent leakage of liquid. reach the second space 27.

[122] The secondary sealing system 49 comprises a recovery passage 51 configured to recover the lubricant which escapes from the cooperation zone 33.

[123] The recovery passage 51 comprises a first part 53 extending in the radial direction, and a second part 55 extending in the axial direction. The first part 53 comprises an inner portion 53a adjacent to the seal 23, and an outer portion 53b extending outside of the seal 23 and being partly delimited by the pin 18. At its end outer, that is to say against the pin 18, the first part 53 communicates with the second part 55. The second part 55 of the recovery passage 51 comprises, in this embodiment, two axial conduits 56, diametrically opposed, spindle pin 18. There could be one or more conduits.

[124] At the outer end of the first part 53, the recovery passage 51 comprises partitions 58, for example two partitions 58, extending radially towards the main axis AP from the outer end of the first part 23 The partitions 58 are therefore fixed to the pin 18. In this example, the two partitions 58 are diametrically opposite. These partitions 58 make it possible to force the lubricant to rotate at the same speed as the pin 18 in order to optimize the centrifugation of the lubricant so that it can be reintroduced into the second part 55 of the recovery passage 51.

[125] Each partition 58 is arranged axially in line with a conduit 56 so as to allow the lubricant to be introduced directly into the conduit 56.

[126] For example, each partition 58 is arranged after the corresponding conduit 56 in the direction of rotation of the second shaft 17.

[127] In another embodiment shown in Figure 4, the secondary sealing system 49 further comprises a secondary seal 57, disposed between the recovery passage 51 and the second space 27 in the axial direction. The secondary seal 57 makes it possible to reinforce the seal between the first and second spaces 25, 27. The recovery passage 51 is therefore disposed between the seal 23 and the secondary seal 57.

[128] The secondary seal 57 is a “labyrinth” type seal. The secondary seal 57 comprises a first portion 57a, fixed to the first shaft 13, and comprising a plurality of wipers. The secondary seal 57 also comprises a second abradable portion 57b, fixed to the pin 18. The wipers are configured to dig into the abradable element so as to form a cooperation zone in the form of a labyrinth, which limits the passage of liquid.

[129] In addition, to further strengthen the seal, when the turbomachine is in operation, the second space 27 may be subjected to a greater pressure than the first space 25. For this, oiled air is that is to say containing vaporized oil, is evacuated from the first space 25 by an evacuation duct 59.

[130] Although the present invention has been described with reference to specific exemplary embodiments, modifications can be made to these examples without departing from the general scope of the invention as defined by the claims. In particular, individual features of the various illustrated / mentioned embodiments can be combined in additional embodiments. Therefore, the description and the drawings should be considered in an illustrative rather than restrictive sense.

Claims (11)

1. Gasket for a turbomachine (11), configured to be disposed between a first shaft (13) and a second shaft (17), the first and second shafts (13, 17) being configured to rotate one relative to the other around a main axis (AP), the seal (23) comprising: - a first cooperation element (29) configured to be mounted on the first shaft (13), - a second cooperation element (31) configured to be mounted on the second shaft (17) and cooperating with the first cooperation element (29) at a cooperation zone (33), - at least one lubricant passage (35) configured to bring a lubricant to the cooperation zone (33), the lubricant passage (35) being provided in at least one of the first and second cooperation elements (29, 31 ). 2. A seal according to claim 1, in which the lubricant passage (35) comprises at least one segment (43a) which moves away from the main axis (AP) while approaching the cooperation zone (33 ). 3. Seal according to one of claims 1 or 2, wherein the first and second cooperation elements (29, 31) overlap. 4. Seal according to one of the preceding claims comprising a plurality of lubricant passages (35) distributed along a circumference of at least one of the first and second cooperation elements (29, 31). 5. Seal according to one of the preceding claims, in which the first cooperation element (29) comprises a first lateral element (35) and a second lateral element (37), the first and second lateral elements (35, 37) extending in a radial direction relative to the main axis (AP), and the second cooperation element (31) comprises a central element (41) extending in the radial direction relative to the main axis (AP), the central element (41) being disposed between the first and second lateral elements (35, 37) in an axial direction. 6. Joint according to claim 5, wherein at least one lateral element among the first and second lateral elements (35, 37) comprises the at least one lubricant passage (43). 7. Sealing structure for a turbomachine intended to be disposed between a first space (25) and a second space (27), comprising: - the seal (23) according to any one of the preceding claims, and - a secondary sealing system (49) disposed between the seal (23) and at least one of the first and second spaces (25, 27). 8. A sealing structure according to claim 7, in which the secondary sealing system (49) comprises a recovery passage (51) configured to recover the lubricant which escapes from the cooperation zone (33). 9. A sealing structure according to claim 8, in which the recovery passage (51) comprises at least one outer portion (53b) disposed radially outside the seal (23). 10. Sealing structure according to one of claims 7 to 9, wherein the secondary sealing system (49) comprises a secondary seal (57), disposed between the seal (23) and at least the one of the first and second spaces (25, 27), preferably in the axial direction. 11. A turbomachine comprising a seal (23) according to any one of claims 1 to 6 or a sealing structure (21) according to any one of claims 7 to 10.