FR3127019A1 - CMC distributor with improved sealing and associated turbomachine turbine - Google Patents

Abstract

The invention relates to an annular distributor (2) of a turbine (1) comprising a plurality of distributor sectors (20) made of composite material with a ceramic matrix forming a crown, each sector (20) of the crown comprising an inner platform (24) and an outer platform (26) having, in the circumferential direction (Dc), respectively first and second inner ends (241, 242) and first and second outer ends (261, 262), and at least one vane (28) extending radially between the inner and outer platforms (24, 26). For each sector (20), said first inner end (241) comprises a first inner shoulder (243) and said second inner end (242) comprises a second inner shoulder (244) shaped to cooperate by interlocking with the first inner shoulder (243 ) of an adjacent inner platform (24), and said first outer end (261) comprises a first outer shoulder (263) and said second outer end (262) comprises a second outer shoulder (264) shaped to cooperate by fitting with the first outer shoulder (263) of an adjacent inner platform (26). Figure for abstract: Fig. 3

Description

CMC distributor with improved sealing and associated turbomachine turbine

The invention relates to turbomachines, in particular aeronautical turbine engines or industrial turbines comprising a turbine nozzle made of composite material with a ceramic matrix or with a matrix at least partially in ceramic, hereinafter referred to as CMC material.

The field of application of the invention is in particular that of aeronautical gas turbine engines. The invention is however applicable to other turbomachines, for example industrial turbines.

Improving the performance of turbomachines and reducing their polluting emissions leads to considering increasingly high operating temperatures.

For elements of hot parts of turbomachines, it has therefore been proposed to use composite materials with a ceramic matrix denoted CMC hereafter.

CMC materials are typically formed of a fibrous reinforcement made of refractory fibers, such as carbon or ceramic fibers, densified by a ceramic or at least partially ceramic matrix.

These materials have remarkable thermo-structural properties, that is to say mechanical properties which make them suitable for constituting structural elements and the ability to retain these properties at high temperatures. In addition, CMC materials have a much lower density than that of the metallic materials traditionally used for elements of hot parts of turbomachines.

Thus, documents WO 2010/061140, WO 2010/116066 and WO 2011/080443 describe the production of impeller blades of CMC turbomachines with integrated platform and heel. The use of CMC materials for turbine distributors has also been proposed, in particular in documents WO 2010/146288, FR 2 979 662 and EP 2 443 318.

A traditional metallic turbine nozzle has a crown shape composed of several joined sectors, each sector comprising an inner platform, an outer platform and a plurality of blades extending between and attached to the inner and outer platforms. The juxtaposed inner platforms form an inner shroud and the juxtaposed outer platforms form an outer shroud. The inner and outer shrouds delimit the gas flow path in the distributor.

Introducing a distributor, for example a high pressure distributor, in CMC makes it possible to increase the maximum tolerated temperature compared to a metal distributor, and thus to reduce the quantity of cooling air used. This thus makes it possible to increase the performance of the turbomachine.

However, CMC, due to its different properties from metal, is more sensitive to certain mechanical stresses. Indeed, the CMC has greater rigidity and less expansion. It behaves better in compression, but its allowable tensile stresses are lower than those of metal.

Moreover, the integration in a metallic environment of a CMC part is tricky because of the differential thermal expansions between the CMC and the metal. This is all the more delicate in a turbomachine, and more particularly in a high-pressure part of the turbomachine, because the environment is hot, which exacerbates the differences in thermal expansion coefficients between the materials, the aerodynamic forces undergone by a high pressure distributor being further elevated in this turbine area.

Distributors made of CMC are known, such as for example a turbine distributor comprising an external supporting shroud integral with a casing, an internal supporting shroud, and a plurality of sectors of CMC distributors forming a ring extending between the shroud outer support and the inner support shell. Each distributor sector rests on the inner and outer support shells and comprises an inner platform, an outer platform, and at least one blade extending between the outer platform and the inner platform and fixed thereto.

However, there is a need to improve the known solutions with regard to the deterministic maintenance of the distributor sector in CMC with the inner shroud, in particular in terms of axial maintenance of the distributor sector and in terms of taking up aerodynamic forces.

Furthermore, a significant pressure differential is exerted on the housing radially under the distributor in the radial and axial directions. This casing is used to create a seal between the rotor and the stator. This pressure difference is the source of a force which, if it were exerted on the CMC, would be high given the allowable values of the material.

It is also known, in particular from document FR 3 061 928 and FR 2 973 435, a distributor as described above and further comprising a reinforcing mast extending radially inside the blades between the two platforms allowing the distributor to be held to the housing by the mast.

However, such a solution takes up, via the mast, both the forces relating to the pressure differential radially under the distributor and the aerodynamic forces on the CMC crown. In addition, for the reasons mentioned above relating to the different mechanical behavior between CMC and metallic material, it is difficult to position the CMC part on the metallic environment by clamping it.

During turbine operation, a large radial clearance is generated between the mast and the blade it passes through. More specifically, the expansion of the mast being greater than the expansion of the CMC blade, a radial play greater than 0.5 mm, or even greater than 1 mm, may appear between the mast and the blade through which it passes. This radial play generates an uncertainty on the position of the blade, the aerodynamic plating becoming random up or down according to the radial resultant of the aerodynamic force.

In an all-metal distributor, the distributors are usually foundry and several blades make up a single distributor (often doublets or triplets, i.e. two or three blades per ring sector). In this case the passage section is controlled and repeatable by the manufacturing process.

This is no longer the case when the blades are integrated in CMC material in a metallic environment, for several reasons. On the one hand, due to the lack of control of the tolerances on the CMC parts, due to the fact that the CMC material blade is not constrained in position to avoid damaging it, and due to the contact between the blade in CMC material and the metal mast which takes up the forces.

There is therefore a need to improve the deterministic maintenance of the distributor in CMC of this solution.

In addition, the use of CMC ring sectors increases the number of parts required for its integration on the turbine casing, which increases the cost and weight of the assembly and requires complex assembly operations (shrinking of bushings, fitting of pins, etc.) which can in particular affect the tightness of the ring.

It is known from document FR 2 979 573 of annular distributors comprising interlocking structures for platforms of circumferential blades. However, these interlocking structures can only be used for platforms with simple shapes. In addition, they have bulges, or ribs that disrupt fluid flow in the outflow vein.

The invention aims to overcome the disadvantages mentioned above and to overcome the difficulties mentioned above by proposing a turbomachine turbine comprising a turbine distributor at least partly made of CMC, the assembly of which is simplified and adapted to maintain its sectors distributor in a deterministic manner while allowing the sectors to deform independently of the metal parts at the interface, and guaranteeing satisfactory sealing between the ring sectors, in particular at the level of the interfaces between the sections of the platforms, both internal and external, in order to respect the level of stream air reintroduction admissible in these zones.

This object is achieved thanks to an annular turbine nozzle comprising a plurality of nozzle sectors made of ceramic matrix composite material forming a crown defining an axial direction, a radial direction and a circumferential direction, each sector of the crown comprising:
- an inner platform having, in the circumferential direction, a first inner end and a second inner end,
- an outer platform having, in the circumferential direction, a first outer end and a second outer end, and
- At least one blade extending radially between the inner and outer platforms.

According to a general characteristic of the invention, for each sector, said first inner end comprises a first machining forming a first inner shoulder and said second inner end comprises a second machining forming a second inner shoulder shaped to cooperate by interlocking with the first inner shoulder of an interior platform of an adjacent sector, and said first exterior end comprises a third machining forming a first exterior shoulder and said second exterior end comprises a fourth machining forming a second exterior shoulder shaped to cooperate by interlocking with the first exterior shoulder of an interior platform of an adjacent sector.

This architectural configuration of the ring sector platforms makes it possible to create, at each junction between two adjacent crown platforms, a baffle limiting the air flow between the sector outside the vein and the gas flow flow vein.

This architectural solution makes it easy to create interlocking blade structures in the circumferential direction even when the platform has a complex shape.

The invention thus makes it possible to improve the tightness between the different platforms of the distributor sectors, such as the sectors of a low pressure distributor, and therefore to control the level of pressurization of the internal cavities as well as the level of reintroduction of air coming from the vein.

In addition, the formation of the shoulders in the platforms of the ring sectors requires simplified machining of the interfaces compared to the machining of a slot for a tongue, for example.

In addition, the architectural solution can be adapted to any integration of distributor to be sectorized and for which a radial sealing between two sectorized parts must be ensured, and for any material in which the distributor is made.

According to a first embodiment of the distributor, the crown formed by the assembly of the sectors can comprise an inner shroud formed by the assembly of the inner platforms and an outer shroud formed by the assembly of the outer platforms, the inner shroud comprising a surface radially outer shell continues, and the outer shroud comprising a radially inner continuous surface facing the radially outer surface of the inner shroud, the shrouds being intended to delimit between them an air flow vein.

In other words, the platforms are formed in a plate of a certain thickness which is then machined on each of the circumferential ends to produce the shoulders without modifying the radial surfaces of the platforms.

According to a second embodiment of the distributor, the distributor may further comprise a sealing plate, which may be annular, arranged radially inside an inner shroud formed by the inner platforms of the sectors assembled to form the crown, and a radial spring arranged radially inside the sealing plate and pressing the sealing plate against the inner shroud.

The sealing plate and the radial spring which presses it against the inner shroud guarantee sealing at the level of the interlocking of the first and second inner shoulders.

According to a third embodiment of the dispenser, the inner platform of each sector may have circumferential ends having the shapes of broken lines in a plane comprising the circumferential direction and the axial direction.

In another object of the invention, there is proposed a turbomachine turbine comprising a casing, an outer metal support shroud integral with the casing and defining an axial direction, a radial direction and a circumferential direction, an inner support shroud made of metal, an annular turbine distributor as defined above forming a crown extending between the outer support shroud and the inner support shroud.

According to a first embodiment of the turbine, said at least one blade of each sector may have a hollow profile defining an internal housing extending radially, and the turbine may further comprise, for each sector, at least one mast integral with the metal shroud and radially crossing the sector via the housing of a blade.

The invention thus proposes a solution for controlling the passage section of the stream flow in a distributor comprising an assembly of hollow CMC blades crossed by metal masts despite being held in an unconstrained position.

The configuration thus proposed makes it possible to control the passage section of the hollow blade in CMC material positioned on a metal mast despite holding it in an unconstrained position

According to a second embodiment of the turbine, the masts and the outer metal shroud can be made in one piece.

This makes it possible to limit as much as possible the leaks that would be present in the case of a sectorized shell or masts attached to the outer shell.

According to a third embodiment of the turbine, the mast can be hollow.

The mast thus makes it possible to bring air into the cavity radially inside the internal shroud in order to pressurize it and thus prevent the air circulating in the vein extending between the internal and external platforms of the sectors of distributor is reintroduced out of this vein and thus reduces the performance and increases the risk of overheating of the parts.

The invention also relates to a turbomachine comprising an assembly as defined previously.

The invention also relates to an aircraft comprising at least one turbomachine as defined above.

There is a schematic sectional view of a sector of a turbine according to one embodiment of the invention.

There shows a schematic perspective view of a single nozzle sector of the turbine of the .

There is a schematic perspective front view of three adjacent sectors of the nozzle of the turbine of the .

There schematically represents an exploded perspective view of a portion of the turbine sector of the .

There schematically represents a radial spring of the distributor of the .

Claims (10)

Annular distributor (2) of turbine (1) comprising a plurality of distributor sectors (20) made of composite material with a ceramic matrix forming a crown defining an axial direction (D _A ), a radial direction (D _R ) and a circumferential direction ( D _C ), each sector (20) of the crown comprising:
- an inner platform (24) having in the circumferential direction (D _c ) a first inner end (241) and a second inner end (242),
- an outer platform (26) having, in the circumferential direction (D _c ), a first outer end (261) and a second outer end (262), and
- at least one blade (28) extending radially between the inner and outer platforms (24, 26),
characterized in that , for each sector (20), said first inner end (241) comprises a first machining forming a first inner shoulder (243) and said second inner end (242) comprises a second machining forming a second inner shoulder (244 ) shaped to cooperate by interlocking with the first inner shoulder (243) of an inner platform (24) of a circumferentially adjacent sector (20), and said first outer end (261) comprises a third machining forming a first outer shoulder ( 263) and said second outer end (262) comprises a fourth machining forming a second outer shoulder (264) shaped to cooperate by interlocking with the first outer shoulder (263) of an inner platform (26) of a circumferentially adjacent sector ( 20). Distributor (2) according to claim 1, in which the ring formed by the assembly of the sectors (20) comprises an inner ring formed by the assembly of the inner platforms (24) and an outer ring formed by the assembly of the outer platforms (26), the inner shroud having a continuous radially outer surface, and the outer shroud having a radially inner surface opposite the radially outer surface of the inner shroud, the shrouds being intended to delimit between them a flow vein of air. Distributor (2) according to one of Claims 1 or 2, further comprising a sealing plate (7) disposed radially inside an inner shroud formed by the inner platforms (24) of the sectors (20) assembled to form the crown, and a radial spring (8) disposed radially inside the sealing plate (7) and pressing the sealing plate (7) against the inner shroud. Distributor (2) according to one of Claims 1 to 3, in which the internal platform (24) of each sector (20) has circumferential ends having the shape of broken lines in a plane comprising the circumferential direction (D _C ) and the axial direction (D _A ). Turbine (1) of a turbomachine comprising a casing, an outer metal support shroud (9) secured to the casing and defining an axial direction (D _A ), a radial direction (D _R ) and a circumferential direction (D _C ), a inner support shroud (5) made of metal, an annular turbine nozzle (2) according to one of claims 1 to 4 forming a crown extending between the outer support shroud (9) and the inner support shroud (5 ). Turbine (1) according to Claim 5, in which the said at least one blade (28) of each sector (20) has a hollow profile defining an internal housing (280) extending radially, and the turbine (1) further comprising , for each sector (20), at least one mast (6) secured to the metal shroud (9) and radially crossing the sector (20) via the housing (280) of a blade (28). Turbine (1) according to Claim 6, in which the masts (6) and the outer metal shroud (9) are made in one piece. Turbine (1) according to any one of claims 6 or 7, in which the mast (6) is hollow. Turbomachine comprising a turbine (1) according to one of Claims 5 to 8. Aircraft comprising at least one turbomachine according to claim 9.