FR3052484A1 - ROTOR RESISTANT TO IMPACTS - Google Patents

Abstract

Rotor (10) comprising a disk (12) provided with cavities (14) at its outer periphery, vanes (20) attached to said disk (12), each blade (20) comprising a blade (22) and a foot of vane (24), the blade root (24) being engaged and retained in one of the cells (14), the rotor (10) comprising at least one support element (30) fixed to the disk (12), the element support member (30) being in contact with the blade (22) so as to absorb a portion of the impact energy on said blade (20).

Description

FIELD OF THE INVENTION

The present disclosure relates to a rotor comprising a disk and vanes attached to said disk, and more particularly to a fan rotor, for example for an aircraft turbojet engine.

TECHNOLOGICAL BACKGROUND

Aircraft turbojet engines are conventionally constituted, from upstream to downstream in the direction of the flow of gases, a fan, one or more stages of compressors, a combustion chamber, one or more stages of turbines and a gas exhaust nozzle. The fan comprises a stage of moving blades arranged regularly on the periphery of a disk driven by a shaft of the turbomachine. The blades are fixed to the disk by their foot and include a blade extending radially from the foot to the free end (or head) of the blade.

In flight condition, the fan blades are subjected to impacts of various projectiles such as ice or birds. The impact of a projectile on a dawn causes a deflection of the dawn and may damage the dawn. In order to counter the appearance of these damages, it is known to conceive the shape of the dawn so as to strengthen it. However, this consideration constrains the freedom of design and limits the performance of the fan blades.

There is therefore a need for a new type of rotor to limit damage to the blades while providing good performance.

PRESENTATION OF THE INVENTION To this end, the present disclosure relates to a rotor comprising a disk provided with cells at its outer periphery, blades attached to said disk, each blade having a blade and a blade root, the dawn foot being engaged and retained in one of the cells, the rotor comprising at least one support element attached to the disk, the support element being in contact with the blade so as to absorb a part of the impact energy on said blade.

In the present description, the term "axial direction" is the direction corresponding to the rotational speed of the rotor of the turbomachine. This axis of rotation is called "axis of the turbomachine" or "axis of the rotor". A radial direction is a direction perpendicular to the axis of the rotor and intersecting this axis. This direction corresponds to the rays of the rotor. Finally, the term "tangential direction", "circumferential" or "azimuthal" a direction perpendicular to the axis of the rotor and a radial direction, not intersecting the axis of the rotor. The support element is a separate piece of dawn. The support member is at least partially movable relative to the blade. Thus, the support member can absorb the impact energy resulting in a relative movement of the blade relative to the disk, typically in the form of elastic or plastic deformation of the support member. The support member may be attached to the disc directly or indirectly; in the case where the support element is attached indirectly to the disk, for example via another part, the attachment of the support element to the disk is not entirely integral with the blade.

In a rotor as defined above, the absorption function of the impact energy is at least partially offset from the blade to an element external to the blade, namely the support element. Thus, the impact energy can be absorbed efficiently while allowing greater freedom of blade design, whereby the rotor performance can be improved.

In some embodiments, the support member supports the blade in a circumferential direction. In one example, the support member may take the form of a cradle on which the blade bears in the circumferential direction. The support member may fit at least in part the shape of the blade on the part with which it is in contact.

In some embodiments, the blade comprises a platform extending transversely to the blade and the support member is in contact with the blade between the blade root and the platform, in particular only between the blade root and the platform. The platform is placed on the blade, between the blade root and the dawn head, that is to say between the proximal and distal ends of the blade in the radial direction. The platform allows, in a manner known per se, in cooperation with the platforms of the adjacent blades, to define an air passage called aerodynamic vein radially outside the platform. By positioning the support element between the blade root and the platform, that is to say radially inside the platform, that is to say still outside the aerodynamic vein, it avoids disrupt the flow of air in the vein.

In some embodiments, the support member is in contact with the upper surface of the blade. Thus, the support element supports the extrados part. The support element is configured to absorb a portion of the impact energy on the blade when said impacts apply on the blade a force directed towards its upper surface. In particular, the fan blades are generally strongly inclined at their distal end, so that in almost all cases, the impacts of projectiles apply on the blade a force directed towards the extrados. Such positioning of the support element thus makes it possible to effectively manage most of the impacts to which the blade is subjected.

In some embodiments, the support member is removably mounted relative to the disk. Thus, the support member can be easily replaced if it is damaged, for example following an impact.

In some embodiments, the blade has a deformation tolerance below which the blade can remain in service on the disk despite the deformations it undergoes, and the support member has an elastic behavior in the range. energy impacts that would induce, in the absence of said support element, deformations of the blade less than said tolerance. Thus, if the impact is not likely to call into question the use of the blade on the disk, the support element absorbs said impact elastically.

Alternatively or in addition, the support element has a plastic behavior in the energy range of the impacts which would induce, in the absence of said support element, deformations of the blade greater than or equal to said tolerance. Thus, if the impact is likely to call into question the use of the blade on the disk, the support element absorbs said impact plastically. After the impact, we observe a permanent deformation on the support element, which deformation was used to protect the dawn of the impact.

In some embodiments, the breaking limit of the support member is less than the breaking limit of the portions of the disk on which the support member is attached.

In some embodiments, the support member comprises a band whose ends each include a clip for securing the disk support member. A first of the fasteners may be attached to the front side of the disc (leading edge side), while a second of the fasteners may be attached to the rear side of the disc (trailing edge side).

More generally, in some embodiments, movement of the blade toward the support member induces tension on the support member. The support element is then subjected to tensile stresses.

In some embodiments, the material of the support member is prestressed. Thanks to the prestressing, the support element is maintained in the desired position.

The present disclosure also relates to a turbomachine blower or a turbomachine comprising a rotor as previously described.

BRIEF DESCRIPTION OF THE DRAWINGS The invention and its advantages will be better understood on reading the following detailed description of embodiments of the invention given as non-limiting examples. This description refers to the accompanying drawings, in which: - Figure 1 shows an axial half-section of a turbomachine according to one embodiment; - Figure 2 shows in perspective, in the axial direction, a rotor portion according to one embodiment.

DETAILED DESCRIPTION OF THE INVENTION The overall architecture of a turbomachine that can incorporate an embodiment of the invention will be described with reference to FIG. 1, which has an axial half-section of a turbomachine 100. Upstream, the turbomachine 100 comprises a fan 200 for the admission of air. At the outlet of the fan 200, the air flow separates in two. A first portion of the air flow is sent into a low-pressure compressor 300 and then a high-pressure compressor 400. This first portion of the air flow is then injected into a combustion chamber 500, at the exit of which it drives a turbine. 600. A second portion of the air flow, at the outlet of the blower 200, is sent into a rectifier 250 to be rectified and then mixed with the gases leaving the turbine 600. The second part of the air flow can be used, in part, the cooling of the turbomachine 100.

The fan 200 has a rotor axis X which is here coincident with the axis of the turbomachine. The X axis defines the axial direction. The blower 200 comprises a rotor 10 described with reference to FIG. 2. In FIG. 2, in addition to the axial direction X, there is shown a radial direction R and a tangential or circumferential direction T corresponding to the radius along which the line extends. dawn 20.

In a conventional manner and known per se, the rotor 10 comprises a disc 12 provided with cavities 14 at its outer periphery. The rotor 10 comprises at least one blade 20 attached to said disk 12. The blade 20 itself comprises a blade 22 and a blade root 24. The blade 22 comprises the aerodynamically active part of the blade 20, while the blade 20 comprises blade root 24 includes the part of the blade 20 which allows its connection with the disk 12. In fact, as indicated above, the blade root 24 is engaged and retained in one of the cells 14. The engagement of the foot blade 24 is generally permitted by correspondence of at least partial shape with the cell 14, for example by means of so-called dovetail or fir tree forms, well known to those skilled in the art. The retention of the blade root 24 in the corresponding cell 14 can be achieved in particular by means of a lock 50, attached to the blade root 24 on the leading edge side of the blade 20. The principle of retention by such a lock 50 is known per se and therefore will not be described. Note that in Figure 2, the blade root 24 is hidden behind the latch 50 in the axial direction.

Although only one blade 20 is shown in FIG. 2, the rotor 10 generally comprises a plurality of blades, each having its foot engaged in a cavity 14. The rotor 10 can comprise as many blades 20 as the disk 12 comprises of cells 14.

Optionally, the blade 20 may comprise a platform 40. The platform 40 may be an integral part of the blade 20 and formed with the blade 20 in one piece, or, as is the case in the embodiment shown in Figure 2, a platform 40 separate and independent of the blade 20 and reported on the blade 20. A platform 40 may extend transversely to the blade 22 and be placed between two adjacent blades 20. Thus, as indicated above, the platform 40 contributes to creating, radially outside the platform 40 and between the blades 20, an air passage comprising as few elements that can disturb the flow as possible. The portion of the blade 22 located radially between the blade root 24 and the platform 40 is sometimes called stilt.

In particular in the case where it is not fixed to the blade 20, the platform 40 can be fixed to the disk 12, for example by means of flanges 42. In the present embodiment, the disk 12 comprises, at its outer periphery, lugs 16 located between the cells 14. As illustrated in Figure 2, the lugs 16 comprise circumferential grooves retaining the flanges 42. However, the platforms 40 could be fixed to the disk 12 by other means. Furthermore, the disc ears 16 may comprise axial bores which allow a connection, for example bolted, with a downstream collar placed at the rear of the disc.

As indicated above, the rotor 10 comprises at least one support element 30 fixed to the disk 12, the support element 30 being in contact with the blade 22 so as to absorb a part of the impact energy on the dawn 20. It is understood that the rotor may comprise several support elements 30 for the same blade 20, a blade support member 30 or one or more support elements 30 for only some blades 20.

In the present embodiment, the support member 30 is in the form of a strip 32 whose ends each comprise a clip 34, 36 for fixing the support member 30 to the disc 12. The strip 32 is contact with the extrados 22a of the blade 22. In this case, the band 32 matches the shape of the extrados 22a substantially from the leading edge to the trailing edge of the blade 22. Thus, the element support 30 supports the blade 22 in the circumferential direction T.

As can be seen in Figure 2, the support member 30 is in contact with the blade 22 between the blade root 24 and the platform 40. The assembly of the support element 30, here the band 32 and the clips 34, 36, is arranged radially inside the platform 40. The strip 32 may be in contact with the stalk of the blade 20. The support member 30 may be attached to the disk 12 in various ways. In the present embodiment, the fasteners 34, 36 take the form of eyelets intended to cooperate with fixed hooks relative to the disk 12. The positions of the hooks and eyelets could however be exchanged between the disc 12 and the element support 30.

In the embodiment of Figure 2, an attachment member 52 complementary to the fastener 34 of the support member 30 is attached to the latch 50. The fastener 52 comprises a hook 52a configured for engage in the eyelet of the fastener 34 and hold it. Furthermore, a fastening element 18 complementary to the fastener 36 of the support element 30 is attached to an ear 16. The fastening element 18 comprises a hook 18a configured to engage in the eyelet of the fastener 36 and hold it. In one example, the shape of the hook 18a may be a shape extending in a main plane, said plane being preferably perpendicular to a main plane of the hole of the fastener 36. In one example, the shape of the hook 52a may be a shape extending in a main plane, said plane being preferably perpendicular to a main plane of the hole of the fastener 34.

Thanks to the simple engagement of the hooks 18a, 52a in the eyelets 36, 34, the support element 30 can be easily mounted and disassembled from the disk 12. In the embodiment of FIG. 2, the mounting of the element support 30 can be performed in the following manner: - the clip 36 and the hook 18a of the disc are assembled; - The blade 20 is installed in its cell 14; - Lock 50 is installed to lock the blade 20 in the cell 14; the fastener 34 and the hook 52a of the lock are assembled.

According to one example, the disassembly of the support element 30 can be achieved by the same steps, performed in the reverse order.

In addition, other attachment means or other positions of these means may be provided. However, the structure presented above has the advantage of modifying at least the existing parts, which facilitates the integration of the support element 30 in the design of the rotors. In particular, as has been seen, the parts such as the disk 12 and the latch 50 only require the addition of respective fastener elements 18, 52, and not modifications involving a new definition of the parts.

If necessary, the support element 30 can be held in position by virtue of a prestressing of the material constituting said support element 30. This prestressing can be applied during the assembly of the second fastener (fastener 34) on the second hook ( fastening element 52 of the latch 50). The support element 30 may be made of polymer, for example elastomer, that is to say of a material that deforms only elastically before rupture. In any event, the material of the support member 30 must be sufficiently ductile to deform. The use of an elastomeric strip 32 makes it possible, thanks to its flexibility, to install the strip 32 and to apply prestressing as indicated previously.

The respective attachment elements 18, 52 of the disc 12 and the latch 50 may be made of metal alloy such as titanium or llnconel (trademark). The support element 30 is mounted on the rotor 10 so as to be biased in tension during an impact on the intrados 22b of the blade 22 and tending to move the blade 22 towards its upper surface 22a, that is to say to say in the direction -T. The blade 20 has a deformation tolerance below which the blade 20 can remain in service on the disc 12 despite the deformations it undergoes. The deformation tolerance is defined as a function of the technical characteristics of the blade 20 and the disk 12. In the case of a blade 20 made of composite material, the deformation tolerance and the damage threshold are defined by means of a test. bird ingestion. This criterion can be applied for other types of blades. The support element 30 is arranged to absorb a portion of the impact energy on the blade, it reduces the internal energy that must dissipate the blade 20 itself. The dissipation of energy by the support element 30 results in an elastoplastic deformation of the support element 30. The support element 30 has an elastic behavior when subjected to relatively low forces, a plastic behavior when subjected to average forces exceeding its yield strength and breaks when subjected to relatively high forces exceeding its ultimate limit. Preferably, those skilled in the art can take care of dimensioning the support element 30 so that it has an elastic behavior in a range of energy impacts that would induce, in the absence of said support member 30, deformations dawn 20 below the deflection tolerance of the blade 20, and / or so that it has a plastic behavior in a range of energy impacts that would induce, in the absence of said support member 30, deformations of the blade greater than or equal to said deformation tolerance. This dimensioning can be carried out on the basis of the observed or simulated deflections of the blade 20 as a function of impacts of different energies.

Thus, the support element 30 protects the blade by deforming in its place during impacts on the blade 20. In addition, the support element 30 is much easier and much cheaper to replace than the dawn. Such a rotor 10 thus has an increased life.

In the embodiment described, the behavior of the support element 30 can be modulated by acting on the material of the support element 30, or on the thickness or width of the strip 32.

Although a rotor 10 according to an embodiment of the invention has been described as an aircraft turbomachine fan rotor, a rotor according to the invention could be used in other fields, for example in other types of turbomachines.

Although the present invention has been described with reference to specific exemplary embodiments, modifications can be made to these examples without departing from the general scope of the invention as defined by the claims. In particular, individual features of the various embodiments illustrated / mentioned can be combined in additional embodiments. Therefore, the description and drawings should be considered in an illustrative rather than restrictive sense.

Claims (10)

1. Rotor (10) comprising a disk (12) provided with cells (14) at its outer periphery, blades (20) attached to said disk (12), each blade (20) having a blade (22) and a foot blade (24), the blade root (24) being engaged and retained in one of the cells (14), the rotor (10) comprising at least one support element (30) fixed to the disk (12), support member (30) being in contact with the blade (22) to absorb a portion of the impact energy on said blade (20). The rotor (10) of claim 1, wherein the support member (30) supports the blade (22) in a circumferential direction. The rotor (10) according to claim 1 or 2, wherein the blade (20) comprises a platform (40) extending transversely to the blade (22) and the support member (30) is in contact with the blade (22) between the blade root (24) and the platform (40). 4. Rotor (10) according to any one of claims 1 to 3, wherein the support member (30) is in contact with the extrados (22a) of the blade (22). 5. Rotor (10) according to any one of claims 1 to 4, wherein the support member (30) is mounted removable from the disc (12). The rotor (10) according to any one of claims 1 to 5, wherein the blade (20) has a deformation tolerance below which the blade (20) can remain in service on the disk (12). ) despite the deformations that it undergoes, and the support element (30) has an elastic behavior in a range of energy impacts that would induce, in the absence of said support member (30), deformations of the blade (20) less than said tolerance. The rotor (10) according to any one of claims 1 to 6, wherein the blade (20) has a deformation tolerance below which the blade (20) can remain in service on the disk (12). ) despite the deformations that it undergoes, and the support element (30) has a plastic behavior in a range of energy impacts that would induce, in the absence of said support member (30), deformations of the blade (20) greater than or equal to said tolerance. The rotor (10) according to any one of claims 1 to 7, wherein the support member (30) comprises a band (32) each end of which comprises a clip (34, 36) for securing the clip. support member (30) to the disk. 9. Rotor (10) according to any one of claims 1 to 8, wherein the material of the support member (30) is prestressed. 10. A turbomachine blower (200) comprising a rotor (10) according to any one of claims 1 to 9.