FR3105981A1 - Turbomachine assembly ring - Google Patents

Abstract

The invention relates to an assembly ring (2) extending circumferentially around an axis (X), said ring (2) being intended for the rotational coupling of a first part (3) and a second part. (4) of a turbomachine, characterized in that the ring (2) comprises a first part (8) cooperating by interlocking with the first part (3), and a second part (9) cooperating by interlocking with the second part ( 4), so as to ensure the rotational coupling of the first part (3) relative to the second part (4), said ring (2) being elastically deformable between an operating position in which said ring (2) has a first diameter and an assembly or disassembly position in which said ring (2) has a second diameter, smaller or greater than the first diameter, the ring (2) having a median axial plane (P) and comprising at least one hollow region ( 14) which extends circumferentially on either side of the median axial plane (P). Figure to be published with the abstract: Figure 4

Description

Assembly ring for turbomachine

Technical field of the invention

The invention relates to an assembly ring intended for the rotational coupling of a first part and a second part of a turbomachine.

State of the prior art

In the rest of the description, the terms upstream and downstream are defined with respect to the direction of circulation of the gases within the turbomachine. Furthermore, the terms axial, radial and circumferential are defined with respect to the axis of the turbomachine.

As illustrated in Figure 1, document FR 2873161, in the name of the Applicant, discloses a turbine A1 comprising a high pressure turbine rotor A2, located directly downstream of the combustion chamber A3 and comprising a disc A4 equipped with blades AT 5. The gases from the combustion chamber A3 drive the rotor blades A5 in rotation. Disc A4 is attached to a pin A6, located downstream of disc A4. Furthermore, the rotor A2 is integral with an upstream drum A7, itself connected to the high pressure compressor. This assembly forms a high-pressure body of the turbomachine and is supported by two bearings, respectively upstream and downstream. The downstream bearing has an internal ring A8 shrunk on the pin A6. The inner ring and the trunnion may comprise complementary teeth, interposed with respect to each other and making it possible to couple in rotation by dog clutching the inner ring and the trunnion. An annular ring is mounted in a groove of the inner ring, so as to ensure axial retention of the inner ring on the pin.

During assembly, the ring is deformed so as to fit into the groove of the inner ring by snap-fastening. During this deformation, the rod can be subjected to high mechanical stresses resulting in its plasticization and therefore its degradation. There is therefore a need to provide a rod which is less subject to this type of degradation. It is also desired to provide such a rod which has a reduced mass.

Furthermore, there is also the need to provide a rod structure that is simple.

The invention aims to meet these needs in a simple, reliable and inexpensive manner.

Presentation of the invention

To this end, the invention proposes an assembly rod extending circumferentially around an axis, said rod being intended for the coupling in rotation of a first part and a second part of a turbomachine, characterized in that that the rod comprises a first coupling part cooperating by interlocking with the first part, and a second coupling part cooperating by interlocking with the second part, so as to ensure the coupling in rotation of the first part with respect to the second part, said ring being elastically deformable between an operating position in which said ring has a first diameter and an assembly or disassembly position in which said ring has a second diameter, less or greater than the first diameter, the ring having an axial plane median and comprising at least one hollow zone which extends circumferentially on either side of the median axial plane.

The hollow zone makes it possible to increase the deformation capacity of the bead, so as to reduce the effort necessary to ensure its deformation during the assembly or disassembly phase of the bead. In this way, it is possible to facilitate its installation by an operator. The mechanical stresses in the rod are then limited during assembly or disassembly, which avoids the risk of plastic deformation and damage to the rod. The latter can then be reused after assembly and disassembly.

For example, it is possible to reduce the maximum stresses within the ring by a factor of 2.5 and to reduce by a factor of 10 the effort required to ensure assembly and disassembly of the ring around the axis.

Improving the deformation capacity of the rod also makes it possible to reduce the dimensional manufacturing tolerances, and thus limit the manufacturing costs of such a rod.

Furthermore, the hollow zone makes it possible to limit the mass of the bead.

The median axial plane is the plane passing through the center of the rod and extending along the axis of the rod.

The mass of the rod can for example be reduced by 10 to 20% compared to the prior art.

The hollow zone may extend circumferentially over at least 50% of the circumferential extension of the rod.

In the case where the rod has several hollow zones, it is the sum of the circumferential extensions of said hollow zones which may extend circumferentially over at least 50% of the circumferential extension of the rod.

The hollow zone, or all of the hollow zones, may extend over at least 180°.

The hollow zone can emerge axially on either side of the rod.

Thus, at the level of the hollow zone, the rod comprises a radially outer part and a radially inner part, radially separated from each other by the hollow zone.

As a variant, the hollow zone opens axially on only one side of the rod. The hollow zone is then said to be blind.

The rod can extend circumferentially on either side of a median axial plane.

The rod can be at least partly symmetrical with respect to the median axial plane.

The first part and the second part of the rod can be located at the level of the median axial plane.

The first part and the second part of the rod can be crossed by the median axial plane

The circumferential ends of the rod can include gripping zones.

The gripping zones make it easier to grip the ring with a view to deforming it during assembly or disassembly.

Each gripping zone can comprise at least one hole or a housing, intended for the insertion of a gripping tool.

Each circumferential end of the rod may comprise a balancing part connected to the first and second parts of the rod by a connecting part, the cross section of each balancing part being greater than the cross section of the corresponding connecting part.

The cross section of the rod can be taken in an axial plane of the rod.

Each balancing part is thus a solid part, capable of balancing the first and second parts in particular of the rod, so as to limit the vibrations in operation, in particular in the case where the rod is mounted on a rotor of the turbomachine.

The grip zones can be formed in the balancing parts of the ring.

The first part and/or the second part of the bead may have protruding or recessed areas. The first part and/or the second part of the rod can extend axially or radially.

The balancing parts can extend in a radial plane and/or in an axial plane. The balancing parts can be curved and extend circumferentially with respect to the axis of the rod.

The invention also relates to an assembly for a turbomachine comprising a first part and a second part coupled in rotation with respect to each other via an assembly ring of the aforementioned type.

The first part and the second part can belong to a turbomachine rotor, for example at the level of the turbine, in particular of the high pressure turbine.

The rod can be immobilized axially in position with respect to the first part and/or with respect to the second part.

The rod can be housed, at least in part, in a groove of the first part and/or in a groove of the second part.

The invention also relates to a turbomachine comprising at least one assembly of the aforementioned type.

The turbomachine may be a turbojet engine or an aircraft turbomachine.

The invention may also relate to an aircraft comprising at least one turbomachine of the aforementioned type.

Brief description of figures

is a sectional view of part of a prior art turbomachine,

is a detail view in section of part of an assembly according to a first embodiment of the invention,

is a perspective view of part of the assembly,

is a front view of the rod in the context of the first embodiment of the invention,

is a detail view of part of Figure 4,

is a perspective view of part of the rod,

is a detail view in section of part of an assembly according to a second embodiment of the invention,

is a perspective view of part of the assembly,

is a perspective view of the rod,

is a detail view of part of Figure 9.

Detailed description of the invention

Figures 2 to 6 illustrate an assembly 1 and a rod 2 according to a first embodiment of the invention.

The assembly 1 comprises a first part 3 and a second part 4 of the turbomachine, formed for example by a journal 3 and by a bearing nut 4 of a high pressure turbine. The parts 3, 4 are annular and extend along the axis X of the turbomachine, the second part 4 being located radially outside the first part 3.

The first part 3 comprises teeth 5 extending axially downstream and regularly distributed over the circumference.

The second part 4 comprises teeth 6 extending axially downstream and regularly distributed over the circumference. A groove 7 is formed at the radially inner surface of the teeth 6.

The assembly 1 further comprises an annular ring 2 extending around an axis over part of the circumference, for example over an angular range of less than 340°, like a split ring.

The rod 2 is symmetrical with respect to a median axial plane P (FIG. 4) and comprises a first projecting part 8 which is inserted between the teeth 5 of the first part 3 and a second projecting part 9 which is inserted between the teeth 6 of the second part 4. The first part 8 and the second part 9 are located at the level of a median zone 10 of the rod 2, in particular in the median plane of symmetry P of the rod 2. The first part 8 s extends radially inwards from the middle zone 10 of the rod 2. The second part 9 extends axially, here upstream, from the middle zone 10 of the rod 2.

Of course, each part 8, 9 can be housed in any type of housing, whether between two adjacent teeth 5, 6 of parts 3, 4 or in a single housing of each part, the dimensions and shape of the housing being then complementary to the corresponding part 8, 9 of the rod 2.

The middle zone 10 is connected to a first balancing part 11 and to a second balancing part 11, respectively via a first connecting zone 12 and a second connecting zone 12. each balancing part 11 being greater than the section of the corresponding connecting part 12. Each balancing part 11 extends circumferentially over an angular range greater than 10° for example. Each balancing part 11 is substantially planar and extends in a radial plane. Each balancing part 11 has a gripping hole 13. Each gripping hole 13 passes axially through the balancing part in which it is formed.

Each connecting part 12 extends circumferentially between a balancing part and the median plane P of the rod. Each connecting part 12 comprises a hollow zone 14 extending circumferentially from the middle zone 10 over the entire connecting part 12 and projecting over part of the balancing part 11. Each hollow zone 14 thus extends for example over an angular range greater than 180° for example. Each hollow zone has a width, that is to say a radial dimension greater than 1 mm for example. Each hollow zone 14 opens axially on either side of the rod 2. The two hollow zones 14 are separated circumferentially. from each other by the middle zone 10. The circumferential ends 15 of the recessed zones 14 can be rounded so as to limit the stress concentrations.

Each connecting part 12 comprises a radially outer part 12a and a radially outer part 12b radially separated from each other by the corresponding hollow zone 14.

The radially outer edge of the connecting parts 12 and the balancing parts 11 is engaged in the groove 7 of the second part 4, in the assembly position.

The ring 2 makes it possible to lock the second part 4, in this case the nut 4, in rotation with respect to the first part 3, in this case the journal 3, by engagement of the first part 8 between the teeth 5 of the first part 3 and by engagement of the second part 9 between the teeth 5 of the second part 4.

The ring 2 is also elastically deformable between an operating position, illustrated in the figures, in which the ring 2 has a first diameter, and an assembly or disassembly position in which the ring 2 is constrained and has a second diameter, less to the first diameter, so as to allow its assembly or its disassembly out of the groove 7, by axial translation, once constrained in this position.

For this, an operator inserts a tool into the gripping holes 13 of the balancing parts 11 and constrains the rod 2 by bringing the balancing parts 13 or circumferential ends closer together.

Figures 7 to 10 illustrate an assembly 1 and a rod 2 according to a second embodiment of the invention. In this embodiment, the rod 2 ensures a rotational coupling between a sleeve 3 and a journal 4 of a turbine rotor. The rod 2 comprising a first radially internal part 8, extending axially upstream and engaged between teeth 5 of the sheath 3. The rod 2 further comprises a second radially external part 9, extending axially downstream and engaged in a housing 6a (FIG. 8) of pin 4, housing 6a being formed by a notch made in a radial rim 6 of pin 4.

The radial dimension of each part 8, 9 can vary depending on the applications and the balancing constraints, for example.

In this embodiment, the rod has only one hollow zone 14 extending on either side of the median radial plane P, over an angular range greater than 180°.

Furthermore, each balancing part 11 extends circumferentially but also axially, on one side or on either side of the connecting parts 12 of the rod 2. The gripping holes 13 formed in the balancing parts 11 are radially oriented.

The radii of the curved end zones 15 are also greater than in the case of the embodiment described with reference to FIGS. 2 to 6.

As indicated above, in each of the embodiments described above, the presence of recessed areas 14 makes it possible to limit the mechanical stresses in the rod 2 and to facilitate its deformation during the assembly and disassembly steps of the rod 2.

Improving the deformation capacity of the rod 2 also makes it possible to reduce the dimensional manufacturing tolerances, and thus limit the manufacturing costs of such a rod 2.

Furthermore, the recessed areas 14 make it possible to limit the mass of the rod 2.

Claims (9)

Assembly ring (2) extending circumferentially around an axis (X), said ring (2) being intended for coupling in rotation of a first part (3) and a second part (4) of a turbomachine, characterized in that the rod (2) comprises a first coupling part (8) cooperating by interlocking with the first part (3), and a second coupling part (9) cooperating by interlocking with the second part (4), so as to ensure the rotational coupling of the first part (3) with respect to the second part (4), said rod (2) being elastically deformable between an operating position in which said rod (2) has a first diameter and an assembly or disassembly position in which said ring (2) has a second diameter, smaller or greater than the first diameter, the ring (2) having a median axial plane (P) and comprising at least one hollow zone (14) which extends circumferentially on either side of the median axial plane (P). Ring (2) according to Claim 1, characterized in that the hollow zone (14) extends circumferentially over at least 50% of the circumferential extension of the ring (2) around the axis (X). Ring (2) according to Claim 1 or 2, characterized in that the hollow zone (14) opens out axially on either side of the ring (2). Ring (2) according to Claim 3, characterized in that the ring (2) is at least partly symmetrical with respect to the median axial plane (P). Ring (2) according to Claim 3 or 4, characterized in that the first part (8) and the second part (9) of the ring (2) are traversed by the median axial plane (P). Ring (2) according to one of Claims 1 to 5, characterized in that the circumferential ends of the ring (2) have gripping zones (11, 13). Ring (2) according to Claim 6, characterized in that each gripping zone (11) comprises at least one hole (13) or a housing, intended for the insertion of a gripping tool. Ring (2) according to one of Claims 1 to 7, characterized in that each circumferential end of the ring (2) comprises a balancing part (11) connected to the first and second parts (8, 9) of the ring (2 ) by a connecting part (12), the cross section of each balancing part (11) being greater than the cross section of the corresponding connecting part (12). Assembly (1) for a turbomachine comprising a first part (3) and a second part (4) coupled in rotation with respect to each other via an assembly ring (2) according to one of claims 1 to 8.