FR3107082A1 - Turbomachine wheel - Google Patents

Abstract

The invention relates to a turbine engine wheel (2) extending longitudinally along an axis X comprising a disc (4) having at its periphery substantially axial cells, blades (5) whose feet (9) are axially engaged and retained. radially in said cells and have stilts (8) for connecting the feet (9) to platforms (7) intended to define radially outwardly an annular flow stream of a gas flow, devices for 'sealing (20) mounted in inter-stilt cavities (19) delimited circumferentially between two stilts (8) of two adjacent blades (5) and axially by transverse walls (16, 17) connected at their peripheries radially external to the platforms. shapes (7), characterized in that at least one of the sealing devices (20) comprises an axial retaining tongue (23) bearing axially on at least one transverse sealing wall (17) so as to maintain axially in position the device sealing (20) relative to the base (9) of the corresponding blade (5). Figure to be published with the abstract: Figure 9

Description

Turbomachine wheel

Technical field of the invention

The invention relates to a turbine engine wheel for an aircraft, in particular a turbine wheel.

State of the prior art

A turbomachine conventionally comprises, from upstream to downstream in the direction of gas circulation within the turbomachine, a fan, a low pressure compressor, a high pressure compressor, a combustion chamber, a high pressure turbine, a low pressure turbine and a gas exhaust nozzle. The low pressure compressor is driven in rotation by the low pressure turbine, via a low pressure shaft, the assembly forming a low pressure body. The high-pressure compressor is driven in rotation by the high-pressure turbine, via a high-pressure shaft, the assembly forming a high-pressure body.

The low pressure turbine conventionally comprises a rotor connected to the high pressure shaft, said rotor comprising several stages each formed by a bladed wheel. Distributor stages are mounted axially between the wheels, the distributors belonging to the stator of the low pressure turbine.

The terms axial, radial and circumferential are defined with respect to the axis of the turbomachine.

A bladed wheel conventionally comprises an annular disk comprising cells or grooves regularly distributed at its radially outer periphery. The cells are circumferentially separated from each other by the teeth of the disc.

The wheel further comprises blades each comprising a blade root mounted in a cell of the disc and a blade connected to the root via a platform and a stilt.

In the assembly position, the platforms of the blades are arranged circumferentially one beside the other and surround the teeth of the disc. The longitudinal edges of the blade platforms are separated from each other in the circumferential direction by small clearances.

It is known, in particular from document FR 3072122 in the name of the Applicant, to mount between the stilts of the blades sealing devices which, in operation, are biased radially outwards by the centrifugal forces and come to bear radially on the radially inner faces of the platforms to limit gas leaks between the longitudinal edges of the platforms. These sealing devices can also dampen the vibrations to which the blades are subjected during operation.

In the current technique, these devices or sealing members, sometimes called "candies", are engaged in the side cavities of the blades, which are formed radially inside the platforms and which emerge in the circumferential direction. Each sealing device comprises a circumferential end part engaged in the side cavity of a blade and an opposite circumferential end part, engaged in the side cavity of an adjacent blade.

To limit the reintroduction of gas into the inter-blade or inter-stilt cavities, each stilt comprises a transverse wall at each of its upstream and downstream ends. These transverse walls extend transversely to the axis of rotation of the turbomachine but are not necessarily radial. The upstream transverse walls are thus arranged end to end and the same applies to the downstream transverse walls. It is understood that the shape of each device is imposed by the shape of the blade, more specifically by the geometry of the cavity.

The sealing devices are mounted with play in the inter-stilt cavities so that there is a risk of incorrect positioning, in particular axial, of the sealing devices in relation to the blades, which could affect their effectiveness.

Moreover, such sealing devices do not make it possible to ensure good sealing at the level of the interface zones between the transverse walls of two adjacent blades. Indeed, there is also a small clearance between the circumferential edges of the transverse walls, which can generate reintroduction of gas into the inter-stilt cavities.

We also know the use of an annular ring to achieve the axial stop of the blades in the cells of the disc. The ring has a radially inner periphery cooperating with the disc and a radially outer periphery engaged in hooks or grooves of the blades.

When the radially outer periphery of the rod is engaged in a groove of the platform, the rod is said to be high. In such a case, the rod can provide sealing at the interface zones between the transverse walls. However, the use of a high rod generates a significant centrifugal force at the level of the blade platforms as well as significant temperature gradients in the rods, which can cause premature deterioration of the blades and the rods. Moreover, such an embodiment has a large mass.

When the radially outer periphery of the ring is engaged in hooks extending from a radially median or inner zone of the transverse walls of the blade roots, the ring is said to be low. Such an embodiment, known for example from document FR 2971004 in the name of the Applicant, makes it possible to limit the mass and the mechanical stresses but cannot provide sealing at the level of the interface zones between the transverse walls of the blades.

The invention aims to remedy in a simple, reliable and inexpensive way to all or part of the aforementioned problems.

Presentation of the invention

To this end, the invention relates to a turbine engine wheel extending longitudinally along an axis X comprising a disk having at its periphery substantially axial cells, blades whose roots are engaged axially and retained radially in said cells and have stilts for connecting the feet to platforms intended to delimit radially outwardly an annular vein for the flow of a gas flow, sealing devices mounted in inter-stilt cavities circumferentially delimited between two stilts of two adjacent blades and axially by transverse walls connected at their radially outer peripheries to the platforms, characterized in that at least one of the sealing devices comprises an axial retaining tongue bearing axially on at least one transverse sealing wall so as to maintaining the sealing device in position axially with respect to the root of the corresponding blade.

The axial retention of the sealing device makes it possible to guarantee its correct positioning in the corresponding inter-stilt cavity despite the mounting clearances between said sealing device and the surfaces delimiting said cavity. This ensures good sealing at the interface between the circumferential ends of the platforms and the transverse walls.

The wheel is for example a turbine wheel.

The tongue may comprise a part extending axially upstream or downstream and extending through an opening or a slot in the transverse wall upstream or respectively downstream of at least one blade.

The axial part can extend upstream or downstream from a main part of the sealing device housed in the inter-stilt cavity.

The axially extending part of the tongue can pass through two openings or slots made in the upstream or respectively downstream transverse walls of two adjacent blades, the two openings or slots being located radially opposite each other and extending circumferentially in the extension of one another.

Each vane may comprise an upstream or downstream transverse wall comprising a first opening slot extending circumferentially over part of the circumferential dimension or width of the transverse wall and emerging circumferentially at the level of a first end or circumferential edge of the transverse wall, and a second slot or opening extending circumferentially over part of the circumferential dimension or width of the transverse wall and opening circumferentially at a second end or circumferential edge of the transverse wall.

Each slot or opening may extend a distance between 10 and 45% of the circumferential dimension or width of the transverse wall.

In other words, for a pair of adjacent blades, the upstream or downstream transverse walls of the blades comprise slots or openings opening out facing each other so as to form a continuous overall opening or slot s straddling the two adjacent blades. The axial portion of the tab extends through the overall slot or opening.

The axial dimension of the axial part of the tab is substantially equal to the axial dimension or thickness of the corresponding transverse wall(s).

The tongue may comprise a part extending radially and bearing on the upstream or downstream transverse wall of at least one blade.

The radial part of the tongue can bear on the upstream or downstream transverse walls of two adjacent blades and on the interface zone between said transverse walls.

In this way, the radial part of the tongue contributes to sealing at the level of said interface zone.

The circumferential dimension of the radial part can be substantially equal to the circumferential dimension of the axial part. In other words, the tab can have a constant circumferential dimension from one end of the tab to the other.

The axial part of the tongue may comprise a first end connected to a main part of the sealing device housed in the inter-stilt cavity and a second end opposite the first end, the radial part of the tongue extending axially towards the outside from the second end of the axial part.

The radial part and the axial part can be planar.

The radial part and the axial part can extend along perpendicular planes.

The radial part and the axial part can be rectangular in shape.

The sealing device may comprise a main part housed in the inter-stilt cavity, the main part being in the form of a hollow shell open radially inwards and comprising upstream and downstream walls able to bear against the upstream and downstream transverse walls of the blade, side walls capable of bearing against the stilts of adjacent blades and a radially outer wall capable of bearing against the platforms of said blades, the tongue extending from the wall upstream or downstream of the main part.

At least one of the side walls may comprise at least one recess of a shape complementary to a projecting zone provided at the level of the stilt of one of the two adjacent blades.

The wheel may comprise an annular ring for axially stopping the blades, comprising a radially inner periphery cooperating with the disc and a radially outer periphery engaged in the hooks of the blades, the said hooks extending from the upstream or downstream transverse walls of the blades, the tongues extending radially outside the rod.

In this way, it is possible to use a so-called low ring, the radially outer periphery of which has a relatively small diameter, so as to limit the centrifugal forces applied to the blades, as well as the mass of the wheel as well as the risks of cracking.

The invention also relates to a turbine comprising a wheel of the aforementioned type.

The invention also comprises a turbine engine characterized in that it comprises a wheel of the aforementioned type.

The invention relates to an aircraft, characterized in that it comprises at least one turbomachine of the aforementioned type.

Brief description of figures

is a schematic half-view, in axial section, of a turbine of a turbomachine of the prior art,

is a perspective view of part of a prior art blade,

is a side view of part of a prior art blade,

is a perspective view of part of a blade according to the invention,

is a perspective view of part of the blade of Figure 4,

is a perspective view of a sealing device according to the invention,

is a perspective view of a sealing device of Figure 6,

is a side view of part of a blade and the sealing device,

is a perspective view of part of a blade and the sealing device,

is a downstream view, illustrating an assembly formed by two adjacent blades and a sealing device according to the invention,

is a view, radially from the inside, of said assembly,

is a perspective view of said assembly.

Detailed description of the invention

Figure 1 illustrates a low pressure turbine 1 of axis X comprising a rotor comprising several stages each formed by a bladed wheel 2.

The wheels 2 are assembled axially to each other by annular flanges 3 and each comprising a disc 4 carrying individual blades 5. As is best seen in Figures 2 and 3, these blades 5 each comprise a blade 6 connected by a platform 7 and a stilt 8 to a foot 9 which is for example dovetail or the like, and which is engaged in a longitudinal cell formed at the outer periphery of the corresponding disk 4. The cavities or housing grooves of the blade roots 9 define between them teeth which are arranged radially opposite the platforms 7 of the blades 5. The rotor is connected to the turbine shaft via of a driving cone 10 (FIG. 1). Between the wheels 2 are distributors 11 forming annular rows of vanes 12 fixed which are mounted by suitable means at their radially outer ends on a casing 13 of the low-pressure turbine 1. The fixed vanes 12 of each row are joined together at their radially inner ends by annular sectors placed circumferentially end to end. Upstream and downstream circumferential plates or flanges 14 are formed axially projecting from the annular sectors, and form baffles with other upstream and downstream circumferential spoilers or flanges 15 of the platforms 7 of the rotor blades 5, to limit the passage combustion gases, coming from the combustion chamber upstream of the turbine 1, radially from the outside inwards. The term "radially" in relation to the terms "internal" and "external" are to be interpreted with regard to the axis of the moving wheel or axis of rotation of the turbomachine. The terms “upstream” and “downstream” are to be interpreted in relation to the direction of flow of the air through a wheel 2 when the latter is integrated into a turbomachine.

Each blade 5 also comprises an upstream transverse wall 16 (FIGS. 2 and 3) formed at the upstream end of the stilt 8 and a downstream transverse wall 17 formed at the downstream end of the stilt 8. As can be seen on FIGS. 2 and 3, these upstream 16 and downstream 17 transverse walls are connected radially outwards to the upstream and downstream edges, respectively, of the platform 7. The circumferential edges 18 of the transverse walls 16, 17 are arranged end to end. end, that is to say juxtaposed circumferentially, in order to limit the reintroduction of hot gases into the inter-stilt cavities 19 delimited by two consecutive or circumferentially adjacent stilts 8.

As can be seen in FIG. 3, these inter-stilt cavities 19 each house a sealing device 20 mounted for one part in a cavity 19 of a blade 5 and for the other part in a cavity 19 of an adjacent blade. 5. These sealing members 20 allow, by radial support on the internal faces 21 of the platforms 7, to limit the reintroduction of hot gases between the interstices at the junction between two consecutive platforms 7.

A hook 22 extends radially inwards from the radially median zone of each downstream transverse wall 17, each hook 22 being intended to cooperate with the radially outer periphery of an annular ring, not shown. The radially inner periphery of the ring also cooperates with the disk 4 so that the ring makes it possible to hold the roots 9 of the blades 5 axially in the cells of the disk 4.

As indicated previously, the sealing devices 20 are mounted with play in the inter-stilt cavities 19 so that there is a risk of poor positioning, in particular axial, of the sealing devices 20 with respect to the blades 5, which may affect their effectiveness.

Furthermore, such sealing devices 20 do not make it possible to ensure good sealing at the level of the interface zones between the transverse walls 16, 17 of two adjacent blades 5 . Such tightness at the level of these interface zones is moreover not ensured by means of the bead, the latter not extending over the entire radial dimension of the interface zones.

Figures 4 to 12 illustrate an embodiment of the invention, which differs from the prior art described with reference to Figures 1 to 3 in that each sealing member 20 includes a tongue 23 extending from the radial face downstream 24 of a main part 25 of the sealing member 20. The main part 25 is defined as the part housed in the inter-stilt cavity 19. In particular, the tongue 23 comprises a part 23a extending axially towards the downstream comprising a first end connected to the downstream radial face 24 of the main part 25 and a second end opposite the first end.

As is best seen in Figures 6 and 7, the main part 25 is in the form of a hollow shell open radially inwards and comprising downstream and upstream walls 25a, 25b capable of coming to rest on the downstream transverse walls 17 and upstream 16 of the blade 5, side walls 25c able to come to rest on the stilts 8 of the adjacent blades 5 and a radially outer wall 25d able to come to rest on the platforms 7 of said blades 5.

The tab 23 further comprises a part 23b extending radially outwards from the second end of the axial part 23a. The radial part 23b is substantially parallel to the downstream face 24 of the main part 25 and is separated from the latter by an axial distance d corresponding substantially to the axial dimension or thickness e of the downstream transverse wall 17 of each blade 5.

Furthermore, each downstream transverse wall 17 of the blade 5 comprises two openings or slots 26, extending circumferentially over part of the circumferential dimension or width l of the downstream transverse wall 17 and opening out at one end or edge circumferential 18 of the downstream transverse wall 17. Each slot 26 can extend over a distance of between 10 and 45% of the circumferential dimension or width l of the downstream transverse wall 17.

The slots 26 of two adjacent blades 5 are located radially opposite one another, that is to say are located on the same implantation radius.

The axial part 23a of the tongue 23 of each sealing device 20 passes through two adjacent slots 26 belonging to two adjacent blades 5. A first zone of the axial part 23a is thus engaged in the slot 26 of a blade 5, a second zone of the axial part 23a being engaged in the slot 26 of an adjacent blade 5, said slots 26 emerging opposite one another at the same interface between the two downstream transverse walls 17 concerned.

The radial part 23b of the tongue 23 bears against the downstream faces of the two adjacent downstream transverse walls 17 and covers the radially outer part of the interface zone, that is to say the clearance between the two transverse walls 17 , so as to improve sealing in the area not covered by the bead.

Furthermore, the radial part 23b makes it possible to form an axial stop preventing the axial displacement of the sealing device 23 within the cavity 19.

Claims (10)

Turbomachine wheel (2) extending longitudinally along an axis X comprising a disk (4) having at its periphery substantially axial cells, blades (5) whose roots (9) are engaged axially and retained radially in said cells and have stilts (8) for connecting the feet (9) to the platforms (7) intended to delimit radially outwardly an annular vein for the flow of a flow of gas, sealing devices (20) mounted in inter-stilt cavities (19) delimited circumferentially between two stilts (8) of two adjacent blades (5) and axially by transverse walls (16, 17) connected at their radially outer peripheries to the platforms (7), characterized in that at least one of the sealing devices (20) comprises an axial holding tongue (23) bearing axially on at least one transverse sealing wall (17) so as to hold the sealing device axially in position sealing (20) relative to the root (9) of the corresponding blade (5). Wheel according to Claim 1, characterized in that the tongue (23) comprises a part (23a) extending axially upstream or downstream and extending through an opening or a slot ( 26) of the upstream (16) or respectively downstream (17) transverse wall of at least one blade (5). Wheel according to Claim 2, characterized in that the part extending axially (23a) of the tongue (23) passes through two openings or slots (26) made in the upstream (16) or respectively downstream (17) transverse walls of two adjacent blades (5), the two openings or slots (26) being located radially opposite one another and extending circumferentially in the extension of one another. Wheel according to one of Claims 1 to 3, characterized in that the tongue (23) comprises a part (23b) extending radially and bearing on the upstream (16) or downstream (17) transverse wall of at least minus one dawn (5). Wheel according to Claim 4, characterized in that the radial part (23b) of the tongue (23) comes to bear on the upstream (16) or downstream (17) transverse walls of two adjacent blades (5) and on the zone of interface between said transverse walls (17). Wheel according to Claim 4 or 5 and according to Claim 2 or 3, characterized in that the axial part (23a) of the tongue (23) has a first end connected to a main part (25) of the sealing device (20 ) housed in the inter-stilt cavity (19) and a second end opposite the first end, the radial part (23b) of the tongue (23) extending axially outwards from the second end of the axial part ( 23a). Wheel according to one of Claims 1 to 6, characterized in that the sealing device (20) comprises a main part (25) housed in the inter-stilt cavity (19), the main part (25) being the shape of a hollow shell open radially inwards and comprising upstream (25b) and downstream (25a) walls able to bear against the upstream (16) and downstream (17) transverse walls of the blade (5) , side walls (25c) capable of coming to bear on the stilts (8) of the adjacent blades (5) and a radially outer wall (25d) capable of coming to bear on the platforms (7) of the said blades (5) , the tongue (23) extending from the upstream (25b) or downstream (25a) wall of the main part (25). Wheel according to one of Claims 1 to 7, characterized in that it comprises an annular ring for axially stopping the blades (5), comprising a radially inner periphery cooperating with the disc and a radially outer periphery engaged in hooks ( 22) of the blades (5), said hooks (22) extending from the upstream (16) or downstream (17) transverse walls of the blades (5), the tongues (23) extending radially outside the . Turbomachine characterized in that it comprises a wheel (2) according to one of claims 1 to 8. Aircraft, characterized in that it comprises at least one turbomachine according to claim 9.