阅读说明：本技术 改进的叶片间平台密封件 (Improved platform seal between blades ) 是由 T·D·A·吉拉德 L·奥利亚克 J·古伊瓦尔克赫 J·P·P·埃迪纳克 达西尔 P·J·费 于 2020-01-03 设计创作，主要内容包括：本公开涉及一种用于叶片间平台的密封件(10),该密封件旨在绕轴线周向延伸并且安装在叶片间平台的两个轴向端部之间,该密封件包括至少第一部件(10a)和至少第二部件(10b),第一部件与第一叶片接触,该第一叶片与平台的第一周向端部相邻,第二部件与第二叶片接触,该第二叶片与平台的第二周向端部相邻,密封件(10)的第一部件(10a)和第二部件(10b)彼此固定,使得当密封件(10)的两个部件(10a、10b)彼此固定时,密封件(10)的两个部件(10a、10b)中的一个沿周向方向的位移引起密封件(10)的另一个部件(10a、10b)沿相同方向的位移。(The present disclosure relates to a seal (10) for an inter-blade platform, intended to extend circumferentially around an axis and to be mounted between two axial ends of the inter-blade platform, the seal comprises at least a first part (10a) and at least a second part (10b), the first part being in contact with the first blade, adjacent to a first circumferential end of the platform, a second part in contact with a second blade adjacent to a second circumferential end of the platform, the first part (10a) and the second part (10b) of the seal (10) being fixed to each other, such that when the two parts (10a, 10b) of the seal (10) are fixed to each other, a displacement of one of the two parts (10a, 10b) of the seal (10) in the circumferential direction causes a displacement of the other part (10a, 10b) of the seal (10) in the same direction.)

1. A seal (10) for an inter-blade platform, the seal being configured to extend circumferentially about an axis and to be mounted between two axial ends of the inter-blade platform (30), the seal (10) comprising at least a first component (10a) configured to be in contact with a first blade (20) circumferentially adjacent a first circumferential end (32a) of the platform (30) and at least a second component (10b) configured to be in contact with a second blade (20) circumferentially adjacent a second circumferential end (32b) of the platform (30), the first component (10a) and the second component (10b) of the seal (10) being configured to be fixed to each other such that when the first component (10a) and the second component (10b) of the seal (10) are fixed to each other, displacement of one of the first or second parts (10a, 10b) of the seal (10) in one circumferential direction causes displacement of the other of the first or second parts (10a, 10b) of the seal (10) in the same direction.

2. The seal (10) according to claim 1, wherein a first component (10a) of the seal (10) comprises a first contact portion (12a) made of elastomeric material, the first contact portion (12a) being configured to be in contact with the first circumferential end (32a) of the platform (30) and the first blade (20) adjacent to the first circumferential end (32a) of the platform (30), and the second component (10b) of the seal (10) comprises a second contact portion made of elastomeric material, the second contact portion (12b) being configured to be in contact with the second circumferential end (32b) of the platform (30) and the second blade (20) adjacent to the second circumferential end (30) of the platform (30).

3. The seal (10) of claim 1, wherein the first component (10a) of the seal (10) comprises a first structural portion (14a) and the second component (10a) of the seal (10) comprises a second structural portion (14b), the first and second structural portions (14a, 14b) being configured to be assembled to one another.

4. The seal (10) of claim 3 wherein each of the first and second structural portions (14a, 14b) comprises a metallic material.

5. The seal (10) of claim 3 wherein at least one of the first and second structural portions (14a, 14b) includes at least one circumferentially extending tab (140a, 140b), one circumferential end (141a, 141b) of the tab (140a, 140b) being configured to contact the other of the first and second structural portions (14a, 14 b).

6. The seal (10) of claim 5 wherein the first component (10a) of the seal includes at least a first attachment portion (16a) secured to a tab (140a) of the first structural portion (14a) and the second component (10b) of the seal (10) includes at least a second attachment portion (16b) secured to a tab (140b) of the second structural portion (14b), the first and second attachment portions (16a, 16b) configured to cooperate together to assemble the first component (10a) of the seal (10) to the second component (10b) of the seal (10).

7. An inter-blade platform (30), the inter-blade platform (30) comprising a seal (10) according to any one of the preceding claims, the first part (10a) of the seal (10) being fixed to the second part (10b) of the seal (10).

8. The inter-blade platform (30) of claim 7, comprising a case (32) bounded by a flowpath wall (34) to define an air flowpath, the case (32) including at least one lateral channel (38) configured to receive the tab (140a, 140b) of the first and/or second structural portion (14a, 14b) of the seal (10).

9. A rotor comprising a disc (40) at the outer periphery of which a plurality of blades (20) and a plurality of inter-blade platforms (30) according to claim 7 are mounted, each platform (30) being arranged between each pair of circumferentially adjacent blades (20).

10. A turbine (1) comprising a rotor according to claim 9.

Technical Field

The invention relates to an inter-blade platform seal. Such seals are disposed between the blades and inter-blade platforms separate from the blades and are intended to limit the circulation of air between the blades and the inter-blade platforms. Such seals are used particularly, but not exclusively, in turbine fans between the fan blades and the inter-blade platform.

Background

In a turbine, the blade platform of the fan must ensure several functions. Aerodynamically, these platforms have the primary function of defining an air flow path. Furthermore, these platforms must also be able to withstand large forces by deforming as little as possible and remaining fixed to the disks carrying them.

In order to meet these different requirements, some constructions have been proposed in which the platform has a first component, namely a flow path wall, which allows to define the air flow channel and ensure the retention of the platform when the engine is rotating, and a second component, namely a box, which allows to limit the deformation of the first component under the effect of centrifugal force and to maintain the platform in position when the engine is stopped.

A gap is disposed between the platform and the blade to allow limited displacement of the blade during various operating phases of the engine. However, the performance requirements of the turbine are reflected in a good control of the tightness at the blade root. To this end, the gap is plugged by a seal made of elastomeric material, which is fixed along the lateral edge of the platform and abuts against the adjacent blade.

The linear inter-blade platform seal described in document FR2987086 is known, having a length, comprising a linear base for fixing to the inter-blade platform and a linear lip extending from the linear base, said linear lip having a circumferential end configured to come into contact with a wall on the inner arc side of the blade or on the outer arc side of the blade. This type of seal extends along the inner or outer arc of the blade, including the leading and/or trailing edges.

In configurations where the blade is subject to large movements, particularly due to centrifugal forces, the seal must be designed and positioned finely to ensure permanent plating of the blade to maintain good sealing. However, it is difficult to find an optimal solution at any operating point. In fact, the seal must be both flexible enough to accompany the movement of the blade and yet stiff enough not to flip or tear. Materials that can meet these conditions can be expensive and involve complex shapes, and therefore complex implementations. Furthermore, in the case of large movements of the blade, known seals of this type may not be able to adapt correctly to the blade in sharp discontinuities or in areas with a small radius of curvature, such as near the leading or trailing edge of the blade, in some locations. As a result, air flows between the blades and the inter-blade platforms in these regions. Therefore, the sealing of the air (or gas) flow path is not optimal, which reduces the performance of the turbine.

Therefore, there is a need for an inter-blade platform seal that allows the above disadvantages to be at least partially overcome.

Disclosure of Invention

The present disclosure relates to a seal for an inter-blade platform intended to extend circumferentially around an axis and to be mounted between two axial ends of the inter-blade platform, the seal comprising at least a first component configured to be in contact with a first blade circumferentially adjacent to a first circumferential end of the platform, and at least a second component configured to be in contact with a second blade circumferentially adjacent to a second circumferential end of the platform; the first and second parts of the seal are configured to be connected to each other such that when the first and second parts of the seal are connected to each other, displacement of one of the first or second parts of the seal in one circumferential direction causes displacement of the other of the first or second parts of the seal in the same direction.

It should be understood that the seal extends in a preferred direction, i.e. the axial direction. The axial direction need not be rectilinear and is preferably configured to follow the profile of the blade, in particular in the vicinity of the discontinuity of the blade. The length of the seal is thus defined and measured parallel to the axial direction between the two axial ends of the platform. It is to be understood that the circumferential or lateral direction is a direction transverse to the axial direction. When the seal is mounted on a platform which in turn is mounted on the impeller of a turbomachine fan, the circumferential direction is a direction tangential to the impeller and perpendicular to the axis of rotation of the fan.

The platform seal comprises two components that are different from each other. When the seal is mounted on the platform, the two parts of the seal are connected to each other such that the seal extends in a circumferential direction from a first circumferential end of the platform to a second circumferential end of the platform on either side of the platform. Thus, the first part ensures tightness between the platform and the inner arc of the blade, and the second part ensures tightness between the platform and the outer arc of the second blade, which is adjacent to the first blade. "connected to each other" or fixed to each other means that they are in contact with each other, i.e. communicate with each other, e.g. by being fixed to each other, such that a movement of one of the first and second components in the circumferential direction causes a displacement of the other of the first and second components by reaction. In other words, without movement of one of the first member and the second member in the circumferential direction, movement of the other of the first member and the second member in the circumferential direction cannot be performed.

Thus, during the movement of the blades, for example due to centrifugal forces, the first blade tends to press against the first part of the seal, ensuring tightness between said first blade and the platform. In addition, a second blade adjacent to the first blade and moving in the same direction as the first blade tends to move away from the platform. However, the force exerted by the first blade on the first part of the seal is transferred to the second part of the seal, so that the second part can follow the motion of the second blade. The second part of the seal is thus able to ensure sealing between the platform and the second blade. Thus, the seal of the present disclosure is able to follow the overall movement of the blade, thereby enabling improved tightness at the blade root, thereby improving the performance of the turbine.

In some embodiments, the first member of the seal includes a first contact portion made of an elastomeric material configured to contact the first circumferential end of the platform and a first blade adjacent the first circumferential end of the platform, and the second member of the seal includes a second contact portion made of an elastomeric material configured to contact the second circumferential end of the platform and a second blade adjacent the second circumferential end of the platform.

The first and second contact portions are configured to contact a platform and a blade adjacent to the platform. Thus, the first contact portion and the second contact portion are provided at the circumferential ends of the seal and are provided over the entire length of the seal in the axial direction. In the case where the first contact portion and the second contact portion are made of an elastomer material, the circumferential end portion of the seal is locally more flexible than the portion of the seal other than the contact portions. The contact portion enables a better adaptation of the profile of the blade, in particular in sharp, discontinuous areas or areas of small curvature radius of the blade.

In some embodiments, the first component of the seal comprises a first structural portion and the second component of the seal comprises a second structural portion, the first and second structural portions configured to be assembled to one another.

These structural portions allow the rigidity of the seal to be ensured, and also transmit the force exerted on the first contact portion at the circumferential end of the seal to the second contact portion at the other circumferential end of the seal.

Further, the first and second structural portions can be fixed to each other radially below a flowpath wall of the platform when the platform is installed in the turbine fan. The flow path walls of the platform are walls that allow for a flow path defining air entering the fan. By "radially below the flowpath wall of the platform" is meant that the structural portion is disposed on a radially inner surface of the flowpath wall of the platform when the platform is installed in a fan. Therefore, the structural portion is provided on the side of the flow path wall opposite to the side of the flow path wall through which the air flows. Thus, the fixing operation of the first structural portion and the second structural portion is performed radially below the flow path wall. According to this configuration, displacement of the first member of the seal generates displacement of the second member of the seal, and therefore, the seal moves in blocks by sliding radially under the flow path wall of the platform (moving in block).

In some embodiments, each of the first and second structural portions comprises a metallic material.

The fact that the first and second structural parts comprise a metallic material allows to improve the stiffness of the seal and also more effectively ensures circumferential displacement of the seal on either side of the platform. The first and second structure portions can be, for example, in the form of metal plates that slide radially under the flow path walls of the platform.

In some embodiments, the first contact portion and the second contact portion are secured to the first structural portion and the second structural portion, respectively, by bonding along the second structural portion.

Preferably, the first contact portion and the second contact portion are respectively joined over the entire length of the first structure portion and the second structure portion in the axial direction.

Alternatively, the first and second contact portions can comprise a groove extending along the portion in the axial direction, which groove can be nested with one end of the structural portion. The structural portion can also be embedded in the elastomer, such that the structural portion also includes the elastomer integral with the contact portion. These fixing modes allow a simple assembly of the different parts of the seal.

In some embodiments, in a cross-section parallel to the circumferential direction, the first contact portion and the second contact portion have a rectangular shape, one side of the rectangle being configured to contact an adjacent blade and the other side being configured to contact the platform.

The first contact portion and the second contact portion are preferably configured to be partially disposed radially below the flow path wall. The shape and arrangement of the first and second contact portions allows to facilitate their radial sliding under the flow path wall and thus the displacement of the seal on both sides of the platform.

In some embodiments, at least one of the first and second structural portions comprises at least one tab extending in a circumferential direction, one circumferential end of the tab being configured to contact the other of the first and second structural portions.

"tab" refers to a plate having a dimension in the circumferential direction that is greater than the dimension in the axial direction. In other words, the tabs of the first and/or second structure portions do not extend in the axial direction over the entire length of the seal. When the first and second parts of the seal are assembled, the circumferential ends of the tabs of the first structural part are, for example, in contact with the second structural part. The force exerted by the vane at the circumferential end of the seal is then transferred via the tabs to the other end of the seal.

For example, the first structural portion can also include two or more tabs, each tab having a circumferential end in contact with the second structural portion. Thus, when the first and second parts of the seal are assembled, the seal is in the form of a plate comprising a window. The structure of the structural portions comprising the tabs allows to facilitate the assembly of the two parts of the seal, in particular the insertion of each structural portion under the wall of the flow path. Furthermore, the shape and number of tabs are not limited and can be adjusted depending on the configuration of the platform on which the seal is mounted.

In some embodiments, each of the first and second structural portions includes at least one tab extending in a circumferential direction, a circumferential end of the tab configured to contact a circumferential end of the tab of the other of the first and second structural portions.

Preferably, each of the first and second structural portions comprises the same number of tabs. Each tab of the first or second structural portion is disposed to face a tab of the other of the first or second structural portion when the first and second components of the seal are assembled. Thus, when the first and second parts of the seal are assembled, the axial ends of each of these tabs are in contact with each other.

In some embodiments, the first component of the seal includes at least a first attachment portion secured to the tab of the first structural portion and the second component of the seal includes at least a second attachment portion secured to the tab of the second structural portion, the first and second attachment portions configured to cooperate together to assemble the first component of the seal to the second component of the seal.

Preferably, the first and second attachment portions are fixed below the tabs of the first and second structural portions, respectively, i.e. on the radially inner surfaces of these structural portions, when the seal is mounted on the platform and the platform itself is mounted on the turbine fan. The attachment portion can be fixed by being added to the tab, for example by welding, or molded or machined in the same material as the first and second structural parts into a block.

The first and second attachment portions allow the first and second components of the seal to be assembled and secured such that the first and second components of the seal are connected to each other. The first attachment portion can be, for example, a female attachment portion, and the second attachment portion can be a male attachment portion that is secured to the female attachment portion, for example, by clamping.

There can be as many attachments as tabs. More specifically, when each of the first and second structural portions includes two tabs, the first tab of the first structural portion can include a first attachment portion and the first tab of the second structural portion can include a second attachment portion configured to be secured to the first attachment portion. Similarly, the second tab of the first structural portion can include a first attachment portion, and the second tab of the second structural portion can include a second attachment portion configured to be assembled to the first attachment portion.

In some embodiments, the assembly between the first and second attachments is reversible. This therefore provides the possibility of easily separating the first and second parts of the seal to service or replace the latter.

The present disclosure also relates to an inter-blade platform comprising a seal according to any of the preceding embodiments, the first part of the seal being fixed to the second part of the seal.

In some embodiments, the platform includes a box bounded by flow path walls to define an air flow path, the box including at least one lateral channel configured to receive a tab of the first and/or second structural portions of the seal.

The case allows the flow path wall to be maintained in position under the action of centrifugal force, and also restricts deformation of the flow path wall. The case also includes a bottom surface that can be supported on the fan tray. The channels present in the box are orifices disposed radially below the flow path wall, preferably adjacent thereto, and sized to allow the passage of the tab(s) of the structural portion of the seal. The presence of these channels allows the assembly of the first and second parts of the seal and makes possible the communication of the first and second parts of the seal via the tabs and thus the displacement of the seal extending in the circumferential direction on either side of the platform radially below the flow path wall.

The present disclosure also relates to a rotor comprising a disc, at the periphery of which a plurality of blades and a plurality of inter-blade platforms are mounted according to any of the preceding embodiments, each platform being arranged between each pair of adjacent blades.

The present disclosure also relates to a turbomachine and in particular to a turbojet comprising a rotor according to the previous embodiments.

Drawings

The invention and its advantages will be better understood by reading the following detailed description of various embodiments of the invention, given as non-limiting examples. The description makes reference to the pages of the drawings in which:

figure 1 shows a schematic cross-section of a turbojet engine according to the invention,

figure 2 shows a schematic view along the direction II of the fan of figure 1,

figure 3 shows a partial cross-sectional view of a part of a fan according to the prior art,

figures 4A-4B figure 4A schematically shows a bottom view of a seal according to the invention when the first and second parts of the seal are joined, figure 4B shows a bottom view of a seal according to the invention when the first and second parts of the seal are disengaged,

FIGS. 5A-5C FIGS. 5A shows a perspective view of the first and second attachment portions with the seal in a locked position according to the present invention, FIG. 5B shows a perspective view of the first and second attachment portions with the seal in an unlocked position according to the present invention, and FIG. 5C shows a front view of the first and second attachment portions with the seal in a locked position according to another example of the present invention,

figures 6A-6B figure 6A shows a perspective view of the platform according to the invention, figure 6B shows a cross-sectional view of the platform of figure 6A taken according to the section VIB-VIB,

fig. 7 shows a cross-section along a plane parallel to the circumferential direction of a platform according to the invention.

Detailed Description

In the present disclosure, the term "axial" and its derivatives are defined with respect to the main direction of the seal and the platform in question; the term "circumferential" and its derivatives are defined with respect to a direction extending about an axial direction; the terms "radial", "inner", "outer" and derivatives thereof are defined with respect to the main axis of the turbine when the platform is mounted on a disk which in turn is mounted in the turbine; finally, the terms "above", "below", "lower", "upper" and derivatives thereof are defined with respect to a radial direction facing an axis about which the turbine extends. Moreover, unless otherwise indicated, like reference numerals in different drawings refer to like features.

Fig. 1 shows a schematic longitudinal section through a bypass turbine 1, which bypass turbine 1 is centered on an axis a about which the turbine extends. It comprises, from upstream to downstream: a fan 2, a low pressure compressor 3, a high pressure compressor 4, a combustor 5, a high pressure turbine 6 and a low pressure turbine 7.

Fig. 2 shows a schematic view of the fan 2 of fig. 1 along direction II. The fan 2 includes a fan disk 40, and a plurality of grooves 42 are formed at the outer circumference of the fan disk 40. These grooves 42 are rectilinear and extend axially from upstream to downstream along the entire disc 40. They are also evenly distributed about the axis a of the disk 40. In this manner, each groove 42 defines, with its adjacent grooves, a tooth 44 that also extends axially from upstream to downstream along the entire disk 40. In an equivalent manner, the groove 42 is delimited by two circumferentially adjacent teeth 44.

The fan 2 also includes a plurality of curved-profile blades 20 (only four blades 20 are shown in FIG. 2). Each blade 20 has a root 20a, which root 20a is mounted in a corresponding recess 42 of the fan disk 40. To this end, the roots 20a of the blades 20 can have a fir tree or dovetail shape adapted to the geometry of the grooves 42, each root 20a having a shape at least partially complementary to the shape of the groove 42 in which it is mounted.

Finally, the fan 2 comprises a plurality of additional platforms 30, each platform 30 being mounted at a spacing extending circumferentially between two adjacent fan blades 20 in the vicinity of the root 20a thereof so as to define on the inside an annular flow path for air entering the fan 2, which flow path is defined on the outside by a fan casing (not shown).

As shown in fig. 3, according to the prior art, each edge or circumferential end 32a, 32b of each platform 30, facing respectively the inner 22a and outer 22b sides of the blade 20, is fitted with a seal 100 and a seal 100', respectively, which extend in the axial direction along said circumferential ends 32a, 32 b. In this example, seal 100 is configured to cooperate with blades 20 on the inner arc 22a side, while seal 100' is configured to cooperate with blades 20 on the outer arc 22b side. Movement of the first blade 20 (the left blade in fig. 3) in the circumferential direction Y tends to exert pressure on the seal 100. Conversely, movement of the second vane 20 (the right vane in fig. 3) in the same circumferential direction Y tends to move that vane 20 away from the seal 100' (the arrow in fig. 3).

Fig. 4A and 4B schematically illustrate a bottom view of the seal 10 according to the present invention, when the first and second parts of the seal are joined (fig. 4A) and disconnected (fig. 4B). Axis X represents the axial direction and axis Y represents the circumferential direction. When the seal 10 is mounted on the platform 30, which in turn is mounted on the fan disc, the axis X is substantially parallel to the central axis a of the turbojet engine. In these figures, the circumferential end of the seal 10 has a linear shape in the axial direction X. The illustration is schematic, wherein the seal 10 is not limited to this shape. Conversely, the circumferential ends of the seal 10 may have a curved shape to conform to the shape of the profile of the blades with which they contact when the seal 10 is installed on a fan platform. Further, the surface of the seal 10 shown in fig. 4A and 4B is the surface facing the axis of the fan when the seal 10 is mounted on the fan platform in this bottom view, in other words, the radially inner surface of the seal 10.

The seal 10 comprises a first part 10a and a second part 10b separate from the first part 10 a. The first component 10a includes a first contact portion 12a and a first structural portion 14a that are secured to one another, such as by bonding. Similarly, the second component 10b includes a second contact portion 12b and a second structure portion 14b secured to each other, such as by bonding. The contact portions 12a, 12b each comprise an elastomeric material and are arranged to be in contact with the circumferential end 32a of the platform 30 and the blade adjacent to said circumferential end 32a, and with the circumferential end 32b of the platform 30 and the blade adjacent to said circumferential end 32b, respectively.

The structural portions 14a, 14b each comprise a metallic material, such as an aluminum alloy, and can also comprise a carbon composite. Alternatively, the structural part can comprise an elastomer with an embedded part made of an aluminum alloy or of an entirely metallic, aluminum or titanium alloy. In the example shown in fig. 4A and 4B, the first structural portion 14A includes three tabs 140a and the second structural portion 14B also includes three tabs 140B. When the first and second components 10a, 10b of the seal are assembled, the circumferential ends 141a of the tabs 140a of the first structural portion 14a are configured to contact the circumferential ends 141b of the tabs 140b of the second structural portion 14 b. According to this embodiment, the tabs 140a of the first structure part 14a are shorter in the circumferential direction than the tabs 140b of the second structure part 14 b. However, the seal 10 is not limited to this structure. The tabs 140a, 140b may, for example, be of equal length. Similarly, the dimension of the tab along the axial direction X is given as an illustration in fig. 4A, 4B and can vary depending on the configuration of the platform 30 on which the seal 10 is mounted. The number of these tabs can also vary and can be less or more than three for each structural part 14a, 14b, each tab 140a of the first structural part 14a having to face the tab 140b of the second structural part 14b in the circumferential direction Y.

Further, the seal 10 includes a first attachment 16a secured to the tab 140a of the first structural portion 14a and a second attachment 16b secured to the tab 140b of the second structural portion 14 b. These attachment portions 16a, 16b are secured to the radially inner surface of the seal 10 when the seal 10 is mounted on the fan platform 30. In fig. 4A, a single pair of attachment portions 16a, 16b is shown. However, the first attachment 16a can be provided on two or each tab 140a of the first structure portion 14 a. Similarly, the second attachment 16b can be provided on two or each tab 140b of the second structural portion 14 b.

Fig. 5A and 5B show perspective views of the first attachment portion 16a and the second attachment portion 16B of the seal 10 according to the present invention, respectively, when they are in the locked position and the unlocked position, respectively. The first attachment portion 16a includes: a first attachment portion 161a and a first pin portion 162a, the first attachment portion 161a being fixed to the tab 140a, for example by welding, and the first pin portion 162a including a first branch 162a1 extending in a circumferential direction from the fixed portion 161a, and a second branch 162a2 extending from a circumferential end of the first branch 162a1 toward the attachment portion 161 a. The second attachment portion 16a includes: a second fixing portion 161b and a second pin portion 162b, the second fixing portion 161b being fixed to the tab 140b, for example by welding, and the second pin portion 162b including a first branch 162b1 extending from the fixing portion 161b in the circumferential direction, and a hook 162b2 extending from the first branch 162b1 such that an end of the hook 162b2 is directed toward the fixing portion 161 b.

As the first and second members 10a, 10b of seal 10 come closer to one another, second branch 162a2 of first pin portion 162a slides along hook 162b2 of second pin portion 162b by elastic deformation, thereby coming closer to first branch 162a 1. When the first and second components 10a, 10b of the seal 10 are brought closer to one another such that the circumferential ends 141a and 141b of the tabs 140a, 140b abut one another along the contact surface 141, the end of the second branch 162a2 of the first pin portion 162a passes over the hook end 162b2 by moving away from the first branch 162a1 again as the first pin portion 162a returns to its original shape. Thus, the first and second attaching portions 16a and 16b are in the locked position, and then the first and second members 10a and 10b are coupled to each other. The two parts 10a, 10b can also be separated from each other by exerting a force on the first part 10a in the axial direction X so as to release the second branch 162a2 from the hook 162b 2.

Fig. 5C shows a perspective view of the first attachment portion 17a and the second attachment portion 17b of the seal 10 according to an alternative example of the invention in a locked position. The first attachment portion 17a includes a first attachment portion 171a fixed to the tab 140a, for example, by welding, and a first notch portion 172a extending from the fixed portion 171a in the circumferential direction, the first notch portion 172a including a first step 172a1 extending perpendicular to the circumferential direction. The second attachment portion 17b includes a second fixing portion 171b fixed to the tab 140b, for example, by welding, and a second notched portion 172b extending from the fixing portion 171b in the circumferential direction, the second notched portion 172b including a second step 172b1 extending perpendicular to the circumferential direction.

When the first part 10a and the second part 10b of the seal 10 are closer to each other, the inclined wall of the first notch portion 172a slides along the inclined wall of the second notch portion 172b by elastic deformation of both. When the first and second parts 10a, 10b of the seal 10 are brought closer to each other so that the circumferential ends 141a, 141b of the tabs 140a, 140b abut against each other according to the contact surface 141, the first step 172a1 passes over the second step 172b1 so that the first and second notched portions hook into each other. Therefore, the first and second attaching portions 17a and 17b are in the locking position, and then the first and second members 10a and 10b are coupled to each other.

Fig. 6A shows a top perspective view of a platform 30 according to the invention on which the seal 10 is mounted, and fig. 6B shows a side cross-sectional view of the platform of fig. 6A taken along the section VIB-VIB. The platform 30 includes a box 32, the box 32 serving to maintain the flow path walls 34 in place under centrifugal force and also to limit deformation of the flow path walls 34. The case 32 also includes a bottom surface 36, the bottom surface 36 being capable of abutting the teeth 44 of the fan's disk 40. The case 32 includes a lateral passage 38 radially outward of the flow path wall 34 and radially downward thereof. Each structural portion 14a, 14b includes as many tabs 140a, 140b as channels 38. When the seal 10 is installed on the platform 30, the first component 10a is inserted radially from the circumferential end 32a of the platform 30 below the flowpath wall 34 by passing the tabs 140a through the channels 38. Similarly, the second component 10b is inserted radially from the other circumferential end 32b of the platform 30 below the flow path wall 34 by passing the tab 140b through the channel 38 until the lateral ends 141a, 141b contact each other along the contact surface 141 and the first and second attachments 16a, 16b are in the locked position.

Fig. 7 shows a cross-sectional view at the channel 38 along a plane parallel to the circumferential direction of the platform 30. According to this embodiment, the contact portions 12a, 12b have a rectangular cross section. However, this shape is not limiting, and other shapes that allow the contact portions 12a, 12b to partially slide radially under the flow path wall 34 are contemplated. As shown in fig. 3, the contact portion can for example have a shape that flares towards the area of contact with the blade, or substantially T-shaped. When the blade 20 (not shown in fig. 7) moves in the direction of the arrow in fig. 7, the blade 20 exerts a force on the contact portion 12a and thus on the structure portion 14 a. This force is transmitted to the structural part 14b via the contact surface 141 at the end of the tab. Thus, displacement of the entire seal 10 occurs, and the seal 10 slides under the flow path wall 34 by passing through the passage 38. Thus, the displacement of the contact portion 12b in the direction of the arrow in fig. 7 allows compensating the movement of the blade 20 in the same direction and thus allows maintaining the sealing function of the contact portion 12b between the circumferential end 32b of the platform and the blade 20.

Although the present invention has been described with reference to specific exemplary embodiments, it will be apparent that modifications and variations can be made to these examples without departing from the general scope of the invention as defined in the claims. In particular, various features of the various illustrated/referenced embodiments can be combined in further embodiments. The specification and drawings are, accordingly, to be regarded in an illustrative rather than a restrictive sense.