FR2928406A1 - Rotor disk for aeronautical turbomachine, has projections provided at downstream end of clamp of disk, where each projection axially cooperates with another projection of flange when clamp of flange is placed around clamp of disk - Google Patents

Abstract

The disk (4) has cells (10) that are axial and opened towards exterior, where each cell receives a root (12) of a vane (2). An annular clamp (14) extends towards upstream from a radial upstream face (16) of the disk, where a clamp (26) of an annular flange (22) maintaining the vane is placed around the clamp (14). Projections (38) are provided at a downstream end of the clamp (14) and radially extend towards the exterior, where each projection axially cooperates with another projection (40) of the flange when the clamp (26) of the flange is placed around the clamp (14). An independent claim is also included for a device for axially retaining vanes mounted on a rotor disk, comprising an annular flange.

Description

BACKGROUND OF THE INVENTION The present invention relates to the general field of turbomachine rotor disks provided at their periphery with cells in which blade roots are mounted. It is more specifically a device for effectively retaining blades mounted on such disks. In a manner known per se, the rotor disks of a turbomachine, such as the disks of the different stages of the low-pressure turbine, comprise at their periphery a plurality of substantially axial cells in which are fitted by fitting the blade roots. movable turbine. Each rotor disk also has an annular flange extending upstream from the upstream radial face of the disk. An annular flange is mounted on the flange of the rotor discs and provides ventilation of the disc cells and the axial retention of the blades in the cavities of the disc. The ventilation of the cells of the disk is necessary during operation of the turbomachine taking into account the high temperature of the gases flowing in the flow path of the low-pressure turbine. The cells of the disks which receive the blade roots being directly exposed to these gases, it is therefore essential to cool them to prevent damage to the disks. For this purpose, the flange of the rotor disk and the associated holding flange are arranged so as to form between them an annular space forming a cavity for diffusing the cooling air. This diffusion cavity is supplied with cooling air at its upstream end and opens at its downstream end into the bottom of each of the cells of the disc. The air flowing out of the flow passage of the turbine enters the diffusion cavity at its upstream end, diffuses into this cavity and then ventilates the cells of the disc to cool them.

Furthermore, the axial retention of the blades in the cavities of the disc is generally achieved by means of an annular stop ring interposed between the upstream radial face of the blade roots and the downstream end of the retaining flange. At its upstream end, the retaining flange is fixed to the flange of the rotor disc by means of bolted connections.

The main risk of such a configuration is to generate in operation a spill of the holding flange, that is to say a detachment of the downstream end of the retaining flange relative to the upstream radial face of the blade roots . However, the spill of the retaining flange causes a change in the ventilation of the cells of the disc leading to the risk of overheating of the disc and thus a reduction in the service life of the latter.

OBJECT AND SUMMARY OF THE INVENTION The present invention aims to remedy the aforementioned drawbacks by proposing to improve the axial retention of the blades on the rotor disk while ensuring efficient cooling of the disk cells. Thus, the subject of the invention is a turbomachine rotor disk, comprising, at its periphery, a plurality of substantially axial cells and open towards the outside, each cell being intended to receive the root of a blade, a flange annular extending upstream from an upstream radial face of the disk and around which is intended to be arranged a corresponding flange of an annular flange for holding the blades, characterized in that the flange of the disc comprises, at the level of its downstream end, a plurality of protrusions which extend radially outwards, each projection being intended to cooperate axially with a corresponding projection of the annular flange holding the blades when the flange of the flange is arranged around the disk flange . The invention also relates to an annular blade holding flange on a turbomachine rotor disk, comprising an annular hook intended to be mounted against an upstream radial face of the rotor blade blade roots and having at its outer end. a plurality of radially outwardly extending teeth each intended to cooperate axially with a corresponding tooth of the root of a blade, and an annular flange extending upstream from the hook and which is intended to be arranged around a corresponding flange of the rotor disc, characterized in that the hook of the flange further comprises at its inner end a plurality of projections which extend radially inwards and which are each intended to to cooperate axially with a corresponding projection of the flange of the disc when the flange of the flange is disposed around the disk flange. The invention also relates to an axial retention device for blades mounted on a turbomachine rotor disk, characterized in that it comprises a rotor disc as defined above, an annular flange holding the blades as defined previously, and a plurality of blades each comprising a foot mounted in a corresponding cell of the rotor disc, each blade root being provided at a radial upstream face of at least one tooth extending radially towards the inside.

At its hook mounted against the upstream radial face of the blade roots, the retaining flange is held axially by a double clutch, namely by the axial engagement of the teeth of the hook against the teeth of the blade roots and by the axial engagement of the protrusions of the disc flange against the protrusions of the hook. Thus, the blades are perfectly retained on the rotor disk and any risk of spillage of the holding flange is avoided. In addition, this solution avoids the use of an annular ring stop which is a gain in weight and facilitates the assembly of parts.

In an advantageous arrangement, each projection of the flange of the disc is angularly disposed facing a tooth of the disc and extends in a circumferential direction to a width less than that of the tooth so as not to interfere with the ventilation of the cells. According to another advantageous arrangement, the flange of the retaining flange is arranged around the flange of the rotor disc so as to arrange therewith an annular space forming a diffusion cavity, said diffusion cavity opening at its downstream end in the bottom of each of the disk cells at the upstream end thereof, and a plurality of air intake ports opening into the diffusion cavity at the upstream end thereof. Thus, the ventilation of the disc cells from the cooling air diffusion cavity is not affected by this arrangement. The invention also relates to a turbomachine comprising at least one axial blade retainer mounted on a rotor disk as defined above.

BRIEF DESCRIPTION OF THE DRAWINGS Other features and advantages of the present invention will emerge from the description given below, with reference to the accompanying drawings which illustrate an embodiment having no limiting character. In the figures: - Figure 1 is a partial view in longitudinal section of a low-pressure turbomachine turbine equipped with a device according to one embodiment of the invention; Figure 2 is a perspective and exploded view of the device of Figure 1; and - Figures 3 and 4 are perspective views of the device of Figure 1 showing its mounting.

DETAILED DESCRIPTION OF AN EMBODIMENT FIG. 1 partially shows in longitudinal section a low pressure turbine of an aeronautical turbine engine equipped with a device according to one embodiment of the invention. Of course, the present invention applies to any other turbomachine assembly (aeronautical or terrestrial) provided with a rotor disc having cells in which are axially mounted blade roots. Figure 1 shows more precisely the first two stages of the low-pressure turbine. The first stage consists of a movable wheel formed of a plurality of blades 2 axially mounted on a rotor disk 4. The second stage consists of a distributor formed of a plurality of vanes fixed 6 and a movable wheel placed behind the distributor and formed of a plurality of blades 2 'axially mounted on a rotor disc 4'. The rotor disks 4, 4 'of the first and second stages of the turbine are centered on the longitudinal axis XX of the turbomachine and are fixed to each other by means of bolted connections 8 regularly distributed around this axis. axis XX. Each disk 4, 4 'has at its periphery a plurality of substantially axial cells 10, 10', open towards the outside of the disk and regularly distributed around the axis of rotation of the disks (this axis of rotation coincides with the longitudinal axis XX of the turbomachine). The cells are intended to receive each foot 12, 12 '(for example fir-shaped) of a blade 2, 2' (for example by fitting). Each cell is delimited circumferentially by two teeth 11 of the disk (Figures 2 to 4). Each disc 4, 4 'further comprises an annular flange 14, 14' which extends axially upstream from the upstream radial face 16, 16 'of the disc. This flange 14, 14 'is extended by a plurality of substantially radial tabs 15, 15'.

The disc 4 of the first stage of the turbine also comprises another annular flange 18 which extends axially downstream from the downstream radial face 20 of the disc. This other flange 18 serves for fixing the disc 4 on the disc 4 'of the second stage of the turbine through the bolted connections 8 as indicated above.

An annular holding flange 22, 22 'is mounted against the upstream radial face 16, 16' of each disk 4, 4 '. More specifically, each retaining flange 22, 22 'comprises a substantially radial annular hook 24, 24' which is mounted against the upstream radial faces of the disk and the blade roots. It also comprises an annular flange 26, 26 'which extends axially upstream from the hook and which is arranged around the corresponding flange 14, 14' of the disc. At its upstream end, the flange 26, 26 'of the holding plate ends with a plurality of substantially radial tabs 27, 27'.

The holding flange 22 of the first stage of the turbine is fixed on the flange 14 of the disc 4 by means of bolted connections 28 clamping their respective lugs 15, 27. As for the holding flange 22 'of the second stage, it is fixed on the flange 14 'of the disc 4' by means of the bolted connections 8 for fixing the discs 4, 4 '.

During the operation of the turbine, the cells 10, 10 'of the discs which receive the feet of the blades 2, 2' being directly exposed to the hot gases flowing in the vein of the low-pressure turbine, it is necessary to cool them by means of a cooling circuit to prevent damage to the discs 4, 4 '. For the sake of convenience, only the circuit for cooling the cells 10 of the disc 4 of the first stage of the turbine is described. Of course, the cooling circuit of the cells 10 'of the disk 4' of the second stage of the turbine is perfectly similar to that of the first stage. The flange 26 of the holding flange 22 is disposed around the flange 14 of the disc so as to form therewith an annular space 30 forming a cavity for diffusing the cooling air. The diffusion cavity 30 opens at its downstream end into the bottom of each of the cells 10 of the disc 4 at the upstream end thereof. At its upstream end, the diffusion cavity is closed by clamping the bolted connections 28 between the respective tabs 15, 27 of the flange and the retaining flange. Furthermore, the diffusion cavity 30 is fed by a plurality of air intake orifices 32 (FIG. 2) which are regularly distributed around the longitudinal axis XX and which open into the diffusion cavity at the upstream end of it. In the embodiment of Figure 2, these air intake ports 32 are formed by machining in a substantially radial direction of the flange 14 of the disc 4. Of course, these orifices could equally well be obtained by machining flange 26 of the holding flange. There is also provided an axial retention device of the blades 2, 2 'mounted on the discs 4, 4'. For reasons of convenience, only the axial retention of the blades 2 of the first stage of the turbine is described, the retention of the blades 2 'of the second stage of the turbine being perfectly similar to that of the first stage. According to the invention, the blades 2 are held axially on the disc 4 by means of a double connection by interconnection with the retaining flange 22. On the one hand, the hook 24 of the retaining flange comprises at its outer end ( that is to say at its end farthest from the axis XX) a plurality of teeth 34 (or crenellations) which extend radially outwards and which are regularly distributed around the axis XX. Each blade root 12 is provided at an upstream radial face with at least one tooth 36 (or slot) extending radially inwards (that is to say towards the axis XX), this tooth 36 being intended to cooperate axially with a corresponding tooth 34 of the hook of the retaining flange (the teeth of the blade roots and those of the hook of the retaining flange extend over a substantially equal angular distance).

On the other hand, the flange 14 of the disk 4 comprises at its downstream end a plurality of projections 38 (or crenels) which extend radially outwards. The hook 24 of the retaining flange 22 comprises at its inner end (that is to say at its end closest to the axis XX) a plurality of projections 40 (or crenels) which extend radially inwards, these projections being each intended to cooperate axially with a corresponding projection 38 of the disk flange (the projections of the flange of the disc and those of the hook of the holding flange extend over a substantially equal angular distance) .

At its hook 24, the holding flange 22 is thus held axially by a double clutch, namely by the axial engagement of the teeth 34 of the hook against the teeth 36 of the feet 12 of the blades and by the axial engagement of the projections 38 of the flange 14 of the disc against the projections 40 of the hook. Thus, the blades 2 are perfectly retained on the disk 4 and any risk of spillage of the holding flange is avoided. Figures 3 and 4 illustrate the mounting of the holding flange 22 against the upstream radial face 16 of the disc. In FIG. 3, the flange 22 is brought against the upstream radial face 16 of the disc so that, on the one hand, each of the teeth 34 of the hook 24 of the flange comes axially between two adjacent teeth 36 of the feet 12 of the blades. and, on the other hand, each of the projections 40 of the hook of the flange comes to be positioned axially between two adjacent projections 38 of the flange 14 of the disc.

The holding flange 22 is then pivoted about the longitudinal axis of the turbomachine in the direction of the arrow F until the teeth 34 of its hook come into axial contact with the corresponding teeth 36 of the blade roots and the protrusions 40 come into axial contact with the projections 38 of the flange 14 of the disc (see FIG. 4). The bolted connections 28 between the respective tabs 15, 27 of the holding flange and the flange of the disc are then tightened to ensure attachment and anti-rotation of the retaining flange. Preferably, each projection 38 of the flange 14 of the disc is angularly disposed facing a tooth 11 of the disc and extends in a circumferential direction to a width less than that of said tooth.

This advantageous arrangement makes it possible not to hinder the ventilation of the cells 10, 10 '.

Claims (6)

1. A turbomachine rotor disc (4), comprising: at its periphery, a plurality of substantially axial cells and (10) open towards the outside, each cell being intended to receive the foot (12) of a blade ( 2) and being delimited circumferentially by two teeth (11); an annular flange (14) extending upstream from an upstream radial face (16) of the disk and around which is intended to be arranged a corresponding flange (26) of an annular flange (22) for holding the blades; characterized in that the flange of the disk comprises, at its downstream end, a plurality of projections (38) which extend radially outwards, each projection being intended to cooperate axially with a corresponding projection (40) of the flange annular blade holding when the flange of the flange is disposed around the disk flange. 2. Annular flange (22) for maintaining blades on a turbomachine rotor disc, comprising: an annular hook (24) intended to be mounted against an upstream radial face of the feet (12) of the blades (2) of the disc rotor (4) and having at its outer end a plurality of teeth (34) which extend radially outwardly and which are each intended to cooperate axially with a corresponding tooth (36) of the root of a blade; and an annular flange (26) which extends upstream from the hook and which is intended to be arranged around a corresponding flange (14) of the rotor disc; Characterized in that the hook of the flange has at its inner end a plurality of projections (40) which extend radially inwards and which are each intended to cooperate axially with a corresponding projection (38) of the flange. of the disk when the flange of the flange is arranged around the disk flange. 35 3. Device for axially retaining blades mounted on a turbomachine rotor disk, characterized in that it comprises: a rotor disk (4) according to claim 1; an annular flange (22) for holding the blades according to claim 2; and a plurality of blades (2) each comprising a foot (12) mounted in a corresponding cell of the rotor disc, each blade root being provided at an upstream radial face of at least one tooth (36). extending radially inward. 4. Device according to claim 3, wherein each projection (38) of the flange (14) of the disc is disposed angularly facing a tooth (11) of the disc and extends in a circumferential direction to a width less than that of the tooth so as not to interfere with the ventilation of the cells (10, 10 '). 5. Device according to one of claims 3 and 4, wherein the flange (26) of the retaining flange (22) is arranged around the flange (14) of the rotor disc (4) so as to arrange with that- ci an annular space forming a diffusion cavity (30), said diffusion cavity opening at its downstream end in the bottom of each of the cells (10) of the disc at the upstream end thereof, and a plurality of orifices air inlet (32) opening into the diffusion cavity at the upstream end thereof. 6. Turbomachine characterized in that it comprises at least one axial retaining device of vanes mounted on a rotor disk according to any one of claims 3 to 5.