FR3093131A1 - Turbomachine assembly - Google Patents

Abstract

The present invention relates to an assembly for a turbomachine comprising: A rotor disc (1) provided with a cell (10), A blade (12) having a dawn (120), said dawn (120) being housed within the cell (10), A retaining ring (2): Being configured to prevent axial movement of the blade root (120) within the socket (10), and Introducing: A radially internal part (20) provided with a first anti-rotation member (200), and A radially outer part (22), A retaining ring (3), said retaining ring (3): Extending around a longitudinal axis (X-X) of a turbomachine, Being configured to prevent axial movement of the retaining ring (2), and Including a retaining ring anti-rotation member (300) configured to cooperate with the first anti-rotation member (200), so as to prevent rotation of the retaining ring (2) about the longitudinal axis ( XX). Figure for the abstract: Fig. 2

Description

Turbomachine Kit

The present invention relates to an assembly for a turbomachine.

The invention relates more specifically to the axial retention of a rotor disk blade of a turbomachine.

Referring to Figure 1, a known assembly for a turbomachine comprises:
a low-pressure turbine rotor disk 1 of a turbomachine, said rotor disk 1 extending around a longitudinal axis XX of the turbomachine and comprising:
a cell 10,
a blade 12 having a blade root 120, said blade root 120 being housed within the cell 10,
a retaining ring 2 configured to prevent axial movement of the blade root 120 within the cell 10.

As seen in Figure 1, the rotor disc 1 comprises a retaining hook 14 within which is formed an annular groove 140, the retaining ring 2 being housed, at least partially, within the annular groove 140. way, the radial retention of the retaining ring 2 is ensured.

As also visible in Figure 1, the assembly further comprises a retaining ring 3 configured to ensure the axial retention of the retaining ring 2.

Such an assembly has many drawbacks.

In particular, the retaining ring 2 is subjected to a strong thermal gradient which generates additional stresses. This thermal gradient is established in the retaining ring 2 because the radially internal part of the retaining ring 2 extends in a cold air circulation zone, the cold air circulating in this zone so as to cool the cell 10, while the radially outer part of the retaining ring 2 extends in a zone close to the hot air flow path.

Thus, such an assembly is complex to design.

There is therefore a need to overcome at least one of the drawbacks of the state of the art.

An object of the invention is to ensure the axial retention of a rotor disk blade root.

Another object of the invention is to ensure the sealing of a cell of a rotor disk.

Another object of the invention is to limit the thermal gradient established within a rotor disk blade root axial retaining ring.

Another object of the invention is to ensure the anti-rotation of the rotor disk blade root axial retaining ring.

Another object of the invention is to ensure a better distribution of the stresses within the rotor disk blade root axial retaining ring.

Another object of the invention is to facilitate the integration of a retaining ring within existing turbomachines.

To this end, it is proposed, according to a first aspect of the invention, an assembly for a turbomachine comprising:
a rotor disk, said rotor disk:
extending around a longitudinal axis, and
being provided with a cell,
a blade having a blade root, said blade root being housed within the cell,
a retaining ring, said retaining ring:
extending around the longitudinal axis,
being configured to prevent axial movement of the blade root within the cell, and
presenting:
a radially internal part provided with a first anti-rotation member, and
a radially outer part,
a retaining ring, said retaining ring:
extending around the longitudinal axis,
being configured to prevent axial movement of the retaining ring, and
comprising a retaining ring anti-rotation member configured to cooperate with the first anti-rotation member, so as to prevent rotation of the retaining ring relative to the retaining ring about the longitudinal axis.

In such an assembly, the radial sectoring of the retaining ring into parts, one radially internal, and the other radially external, makes it possible to limit the thermal gradient within the retaining ring, while maintaining at this -last its functions of axial retention of the blade root within the cell and limitation of leaks from the flow stream. By limiting the thermal gradient, the level of radial stresses within the retaining ring is lowered. In addition, the anti-rotation member being offset towards the radially internal part of the retaining ring, it extends into a zone of lower temperature, which limits the tangential expansion of the retaining ring, and the corresponding constraints. This limitation of the stresses at the level of the anti-rotation member is all the more important since the mechanical stresses generated by the presence of such an anti-rotation member are generally high. Finally, the functions of radial restraint and tangential restraint of the retaining ring are no longer performed in the same zone of the assembly, which limits the stresses within the retaining ring accordingly.

Advantageously, but optionally, the assembly according to the invention can comprise one of the following characteristics, taken alone, or according to any combination:
in such a set:
the radially inner portion includes a first retaining sub-ring extending around the longitudinal axis at a first radial distance from the longitudinal axis, and
the radially outer part comprises a second retaining sub-ring extending around the longitudinal axis at a second radial distance from the longitudinal axis, the second radial distance being greater than the first radial distance,
one of the first anti-rotation member or the retaining ring anti-rotation member comprises a pin, and the other of the first anti-rotation member or the retaining ring anti-rotation member comprises a bore, the pin and the bore being configured to cooperate so as to prevent rotation of the retaining ring relative to the retaining ring around the longitudinal axis,
the radially inner part comprises a plurality of first ring sectors distributed circumferentially around the longitudinal axis, the first ring sectors being separated from each other by first spaces allowing tangential expansion of the first ring sectors,
the radially outer part comprises a plurality of second ring sectors distributed circumferentially around the longitudinal axis, the second ring sectors being separated from each other by second spaces allowing tangential expansion of the second ring sectors,
it further comprises an annular seal disposed between the retaining ring and the rotor disc,
in such a set:
the radially internal part comprises a second anti-rotation member, and
the radially outer part comprises an outer anti-rotation member, the outer anti-rotation member being configured to cooperate with the second anti-rotation member so as to prevent rotation of the radially inner part relative to the radially outer part around the longitudinal axis,
one of the second anti-rotation member or the outer anti-rotation member includes a pin, and the other of the second anti-rotation member or the outer anti-rotation member includes a bore, the pin and the the bore being configured to cooperate so as to prevent rotation of the radially inner part with respect to the radially outer part around the longitudinal axis,
in such a set:
an outer radial edge of the radially inner part has a first shoulder, and
an internal radial edge of the radially external part has a second shoulder, the second shoulder cooperating with the first shoulder so as to ensure the axial support of the radially external part on the radially internal part,
the cooperation of the second shoulder with the first shoulder consists of a fitting of the second shoulder with the first shoulder, for example according to a Z-shaped junction zone, and
the rotor disc comprises a retaining hook, the retaining hook comprising an annular groove, the radially outer part being housed within the annular groove.

According to a second aspect of the invention, there is proposed a retaining ring for a turbomachine, said retaining ring:
extending around a longitudinal axis of the turbomachine,
being configured to prevent axial movement of the blade root within the cavity of an assembly as previously described, and
having a radially internal part provided with a first anti-rotation member, said first anti-rotation member being configured to cooperate with the anti-rotation member of the retaining ring of an assembly as previously described, so as to prevent a rotation of the retaining ring around the longitudinal axis.

According to a third aspect of the invention, there is proposed a turbomachine turbine comprising an assembly as previously described.

According to a fourth aspect of the invention, there is proposed a turbomachine comprising an assembly as previously described.

Other characteristics, objects and advantages of the invention will emerge from the description which follows, which is purely illustrative and not limiting, and which must be read in conjunction with the appended drawings in which:

Figure 1, already described, schematically illustrates an assembly for a turbomachine known from the prior art,

Figure 2 is a sectional view of an embodiment of an assembly for a turbomachine according to the invention, and

Figure 3 is a front view of an embodiment of a retaining ring according to the invention.

With reference to Figures 2 and 3, a turbomachine assembly and a retaining ring 2 will now be described.

In the present application, upstream and downstream are defined with respect to the general direction of gas flow through a turbine engine in operation. Furthermore, an axial direction designates a direction parallel to a longitudinal axis XX of the turbomachine, a radial direction is a direction perpendicular to this longitudinal axis XX, and passing through this longitudinal axis XX, while a tangential or circumferential direction, is a direction orthogonal to both an axial direction and a radial direction, typically in a plane orthogonal to the longitudinal axis XX. Unless otherwise specified, internal (or interior) and external (or exterior), respectively, are used with reference to a radial direction so that the internal (i.e. radially internal) part or face of an element is closer to the longitudinal axis XX, that the outer part or face (ie radially outer) of the same element.

Turbomachine Kit

Referring to Figure 2, the turbomachine assembly comprises:
a rotor disk 1, said rotor disk 1:
extending around the longitudinal axis XX, and
being provided with a cell 10,
a blade 12 having a blade root 120, said blade root 120 being housed within the cell 10,
a retaining ring 2 extending around the longitudinal axis XX, and
a retaining ring 3 extending around the longitudinal axis XX.

In one embodiment, the rotor disk 1 is a rotor disk of a turbomachine turbine, for example a turbomachine low-pressure turbine. However, this is not limiting, since the turbomachine assembly can also be used within a high pressure turbine, or even a turbomachine compressor.

In one embodiment, the rotor disk 1 comprises a plurality of cells 10 and a plurality of blades 12 is distributed circumferentially around the longitudinal axis XX, each of the blades 12 having a blade root 120, said blade root blade 120 being housed within a corresponding cell 10 of the rotor disc 1.

In one embodiment, for example illustrated in FIG. 2, the rotor disk 1 comprises a retaining hook 14, the retaining hook 14 comprising an annular groove 140. The retaining ring 2 is thus housed, at least partially at the within the annular groove 140. The annular groove 140 advantageously ensures the radial retention of the retaining ring 2.

In operation, the rotor disc 1 is rotated around the longitudinal axis XX and the blade 12 is bathed in a flow of hot air within a flow path 16. To limit the heating of the disc of rotor 1, the cell 10 can be cooled by a ventilation circuit 18 provided for this purpose.

The retaining ring 2 is thus configured to prevent axial movement of the blade root 120 within the cell 10, but also to limit leaks between the ventilation circuit 18 and the flow path 16. In other words, the retaining ring 2 ensures the axial retention of the blade root 120 within the cell 10. The retaining ring 3 is, for its part, configured to prevent an axial movement of the ring retaining ring 2. More specifically, the retaining ring 3 ensures the axial retention of the retaining ring 2.

In one embodiment, also illustrated in Figure 2, the assembly comprises an annular seal 4, extending around the longitudinal axis XX, and disposed between the retaining ring 2 and the rotor disc 1 The seal 4 is configured to prevent air leaks from the ventilation circuit 18, towards the flow path 16, and vice versa.

Retaining ring 2

Referring to Figures 2 and 3, the retaining ring 2 is sectorized radially. In other words, retaining ring 2 has:
a radially inner part 20, and
a radially outer part 22.

Thanks to this radial sectoring, the thermal gradient established in each part 20, 22 is less than the thermal gradient which would be established within the retaining ring 2 if it were in one piece. In this way, it is possible to reduce the thermal stress in each of the two parts 20, 22, and thus to improve their respective mechanical strength by reducing the level of the radial stresses within the retaining ring 2. This effect is moreover obtained by retaining the functions of the retaining ring 2 for axial retention of the blade root 120 within the cell 120.

In one embodiment, for example illustrated in Figure 2:
an outer radial rim of radially inner part 20 has a first shoulder 2000, and
an inner radial rim of radially outer part 22 has a second shoulder 2200.

As seen in Figure 2, the second shoulder 2200 cooperates with the first shoulder 2000 so as to ensure the axial support of the radially outer part 22 on the radially inner part 20. Advantageously, the cooperation of the second shoulder 2200 with the first shoulder 2000 consists of a nesting of the second shoulder 2200 with the first shoulder 2000. In addition, in this embodiment, the retaining ring 3 exerts an axial retaining force on the radially outer part 22 through the contact between the shoulders 2000, 2200, even though the retaining ring 3 is itself in contact only with the radially inner part 20.

The shape of the shoulders 2000, 2200 illustrated in FIG. 2 is however not limiting. It is indeed possible to envisage that each of the outer radial rim of the radially inner part 20 and of the radially inner rim of the radially outer part 22 has a surface inclined with respect to the longitudinal axis. The shoulders 2000, 2200 then do not have the substantially “L” shape of FIG. 2, but rather a beveled shape. Advantageously, the interlocking of the shoulders 2000, 2200 is produced along a Z-shaped junction zone, visible in FIG. 2. More specifically, in the section plane of FIG. 3, the retaining ring 2 is divided into sectors Z, and the shoulders 2000, 2200 define the axial ends of the Z-shaped junction zone between the radially inner part 20 and the radially outer part 22 of the retaining ring 2.

Referring to Figure 2, the radially inner part 20 comprises a first anti-rotation member 200. In addition, the retaining ring 3 comprises a retaining ring anti-rotation member 300. As shown in Figure 2, the retaining ring anti-rotation member 300 is configured to cooperate with the first anti-rotation member 200 so as to prevent a rotation, for example a circumferential rotation, of the retaining ring 2 with respect to the ring holding 3 around the longitudinal axis XX. In an advantageous variant where the assembly further comprises the seal 4, the cooperation of the retaining ring anti-rotation member 300 with the first anti-rotation member 200 prevents the deterioration of said seal 4 by tangential sliding of the retaining ring 2. In this advantageous variant, the radially outer part 22 can, for its part, remain free to move tangentially. Indeed, the radially outer part 22 is then not in contact with the seal 4.

Advantageously, one of the first anti-rotation member 200 or of the retaining ring anti-rotation member 300 comprises a pin, and the other of the first anti-rotation member 200 or of the anti-rotation member of retaining ring 300 comprises a bore, the pin and the bore being configured to cooperate so as to prevent the rotation, preferably circumferential, of the retaining ring 2 relative to the retaining ring 3 around the longitudinal axis XX. In the embodiment illustrated in FIG. 2, it is the first anti-rotation member 200 which comprises a pin 200, said pin 200 cooperating with a bore 300 of the retaining ring anti-rotation member 300, the bore 300 being arranged opposite pin 200.

By transferring the anti-rotation devices 200, 300 of the retaining ring 2 to the level of the radially internal part 20 of the retaining ring 2, the expansion of the retaining ring 2 is limited, since this zone is at a lower temperature. In fact, the stresses induced in the retaining ring 2 are less significant, despite the discontinuity introduced by the geometry of the anti-rotation members 200, 300. In any event, sufficient radial play is provided between the retaining ring retainer 2 and retaining ring 3 in order to ensure radial contact between these two elements 2, 3.

In an advantageous variant where the rotor disc 1 comprises a retaining hook 14, the radially outer part 22 is housed within the annular groove 140. In this way, the functions of radial stop and tangential stop of the ring retaining ring 2 are distributed, respectively, between the retaining hook 14 and the anti-rotation members 200, 300. The stress is thus better distributed within the retaining ring 2.

In one embodiment illustrated in Figure 2:
the radially internal part 20 comprises a second anti-rotation member 210, and
the radially outer part 22 comprises an outer anti-rotation member 220.

The outer anti-rotation member 220 is then configured to cooperate with the second anti-rotation member 210 so as to prevent a rotation, preferably a circumferential rotation, of the radially inner part 20 with respect to the radially outer part 22 around the longitudinal axis XX.

In an advantageous variant, one of the second anti-rotation member 210 or of the external anti-rotation member 220 comprises a pin, and the other of the second anti-rotation member 210 or of the external anti-rotation member 220 comprises a bore, the pin and the bore being configured to cooperate so as to prevent the rotation, preferably circumferential, of the radially inner part 20 with respect to the radially outer part 22 around the longitudinal axis XX. In the embodiment illustrated in FIG. 2, it is the second anti-rotation member 210 which comprises a pin 210, said pin 210 cooperating with a bore 220 of the external anti-rotation member 220, the bore 220 being arranged facing the pin 210. In any case, the bore is made taking care to provide sufficient clearance so as not to place too much stress on the assembly of the radially inner part 20 with the radially outer part 22.

In one embodiment illustrated in Figures 2 and 3:
the radially inner part 20 comprises a first retaining sub-ring extending around the longitudinal axis XX at a first radial distance D1 from the longitudinal axis XX, and
the radially outer part 22 comprises a second retaining sub-ring also extending around the longitudinal axis XX, at a second radial distance D2 from the longitudinal axis XX.

As can be seen in particular in FIG. 3, the second radial distance D2 is greater than the first radial distance D1. Thus, the first retaining sub-ring 20, and the second retaining sub-ring 22, are concentric and coplanar.

Referring to Figure 3, in a first variant of this embodiment, the radially inner part 20 is sectorized tangentially. In other words, the radially inner part 20 comprises a plurality of first ring sectors 201, 202, 203, 204, 205, 206 distributed circumferentially around the longitudinal axis, the first ring sectors 201, 202, 203, 204, 205, 206 being separated from each other by first spaces 211, 212, 213, 214, 215, 216. The first spaces 211, 212, 213, 214, 215, 216 thus allow a tangential expansion of the first ring sectors 201, 202, 203, 204, 205, 206. Thus, each of the first ring sectors 201, 202, 203, 204, 205, 206 is subjected to lower tangential stresses, which improves the behavior mechanism of the retaining ring 2. In an advantageous variant, the presence of the seal 3 makes it possible to limit the leaks associated with this tangential sectorization. To do this, as for example visible in Figure 2, the seal 3 is arranged between the first retaining sub-ring 20 and the rotor disc 1.

Referring to Figure 3, in a second variant of this embodiment, which can be complementary or alternative to the first variant of this embodiment, the radially outer part 22 is sectorized tangentially. In other words, the radially outer part 22 comprises a plurality of second ring sectors 221, 222, 223, 224, 205, 226 distributed circumferentially around the longitudinal axis, the second ring sectors 221, 222, 223, 224, 205, 226 being separated from each other by second spaces 231, 232, 233, 234, 235, 236. The second spaces 211, 212, 213, 214, 215, 216 thus allow a tangential expansion of the seconds ring sectors 201, 221, 222, 223, 224, 205, 226. Thus, each of the second ring sectors 221, 222, 223, 224, 205, 226 is subjected to lower tangential stresses, which improves the mechanical strength of the retaining ring 2.

Claims (13)

Turbomachine assembly comprising:
a rotor disk (1), said rotor disk (1):
extending around a longitudinal axis (XX), and
being provided with a cell (10),
a blade (12) having a blade root (120), said blade root (120) being housed within the cell (10),
a retaining ring (2), said retaining ring (2):
extending around the longitudinal axis (XX),
being configured to prevent axial movement of the blade root (120) within the cell (10), and
presenting:
a radially internal part (20) provided with a first anti-rotation member (200), and
a radially outer part (22),
a retaining ring (3), said retaining ring (3):
extending around the longitudinal axis (XX),
being configured to prevent axial movement of the retaining ring (2), and
comprising a retaining ring anti-rotation member (300) configured to cooperate with the first anti-rotation member (200), so as to prevent rotation of the retaining ring (2) relative to the maintenance (3) around the longitudinal axis (XX). Assembly according to claim 1, in which:
the radially inner part (20) comprises a first retaining sub-ring extending around the longitudinal axis (XX) at a first radial distance (D1) from the longitudinal axis (XX), and
the radially outer portion (22) includes a second retaining sub-ring extending around the longitudinal axis (XX) at a second radial distance (D2) from the longitudinal axis (XX), the second radial distance (D2 ) being greater than the first radial distance (D1). Assembly according to one of Claims 1 and 2, in which one of the first anti-rotation member (200) or of the retaining ring anti-rotation member (300) comprises a pin, and the other of the first anti-rotation member (200) or retaining ring anti-rotation member (300) includes a bore, wherein the pin and the bore are configured to cooperate to prevent rotation of the retaining ring (2) relative to the retaining ring (3) around the longitudinal axis (XX). Assembly according to one of Claims 1 to 3, in which the radially internal part (20) comprises a plurality of first sectors of rings (201, 202, 203, 204, 205, 206) distributed circumferentially around the longitudinal axis (XX), the first ring sectors (201, 202, 203, 204, 205, 206) being separated from each other by first spaces (211, 212, 213, 214, 215, 216) allowing tangential expansion first ring sectors (201, 202, 203, 204, 205, 206). Assembly according to one of Claims 1 to 4, in which the radially outer part (22) comprises a plurality of second sectors of rings (221, 222, 223, 224, 225, 226) distributed circumferentially around the longitudinal axis (XX), the second ring sectors (221, 222, 223, 224, 225, 226) being separated from each other by second spaces (231, 232, 233, 234, 235, 236) allowing tangential expansion second ring sectors (221, 222, 223, 224, 225, 226). Assembly according to one of Claims 1 to 5, further comprising an annular seal (4) arranged between the retaining ring (2) and the rotor disc (1). Assembly according to one of Claims 1 to 6, in which:
the radially internal part (20) comprises a second anti-rotation member (210), and
the radially outer part (22) comprises an outer anti-rotation member (220), the outer anti-rotation member (220) being configured to cooperate with the second anti-rotation member (210) so as to prevent rotation of the radially inner part (20) with respect to the radially outer part (22) around the longitudinal axis (XX). Assembly according to claim 7, in which one of the second anti-rotation member (210) or of the external anti-rotation member (220) comprises a peg, and the other of the second anti-rotation member (210) or of the external anti-rotation member (220) comprises a bore, the pin and the bore being configured to cooperate so as to prevent the rotation of the radially internal part (20) with respect to the radially external part (22) around of the longitudinal axis (XX). Assembly according to one of Claims 1 to 8, in which:
an outer radial edge of the radially inner part (20) has a first shoulder (2000), and
an inner radial edge of the radially outer part (22) has a second shoulder (2200), the second shoulder (2200) cooperating with the first shoulder (2000) so as to ensure the axial support of the radially outer part (22) on the radially inner part (20). Assembly according to claim 9, in which the cooperation of the second shoulder (2200) with the first shoulder (2000) consists of an interlocking of the second shoulder (2200) with the first shoulder (2000), preferably according to a junction zone in the form by Z. Assembly according to one of Claims 1 to 10, in which the rotor disc (1) comprises a retaining hook (14), the retaining hook (14) comprising an annular groove (140), the radially outer part (22) being housed within the annular groove (140). Turbomachine turbine comprising an assembly according to one of claims 1 to 11. Turbomachine comprising an assembly according to one of claims 1 to 11.