WO2011015767A1

WO2011015767A1 - Rectifier stage for a turbine engine

Info

Publication number: WO2011015767A1
Application number: PCT/FR2010/051587
Authority: WO
Inventors: Michel André BOURU; André Rémi Claude VERBRUGGE
Original assignee: Snecma
Priority date: 2009-08-06
Filing date: 2010-07-27
Publication date: 2011-02-10
Also published as: US20120128476A1; FR2948965B1; FR2948965A1

Abstract

The invention relates to a rectifier stage (10) for a turbine engine including two substantially cylindrical inner and outer shells (12, 14), respectively, between which extend blades (16) supported by a first of the shells (14), blades (18) supported by the second shell (12), and blades (20) forming struts connecting both shells together, the blades of the first and second shells being alternately arranged.

Description

Stator stage for a turbomachine

The present invention relates to a rectifier stage for a compressor or turbine of a turbomachine such as a turbojet engine or an airplane turboprop.

A rectifier stage of this type comprises two substantially cylindrical ferrules extending one inside the other and between which extend substantially radial vanes.

A rectifier stage is generally monobloc and can be made of foundry, by machining (for example by EDM machining), or by assembly and welding of each blade on the ferrules.

However, in this case, the manufacturing time of a rectifier stage is relatively long. In addition, when the rectifier stage has a high density of blades, that is to say that its blades are close to each other in the circumferential direction, the aforementioned manufacturing techniques are difficult or impossible to implement. Indeed, in the case where a tool is used to machine a stator blade or weld this blade to the ferrules, this tool must be passed between two consecutive blades of the floor, which is not always possible when the circumferential step between two consecutive blades is very small.

The invention aims in particular to provide a simple, effective and economical solution to these problems.

It relates to a rectifier stage, for example with a high blade density, which is more easily achievable than those of the prior art, and with simpler manufacturing techniques, faster and more economical.

It proposes for this purpose a rectifier stage for a turbomachine, comprising two substantially cylindrical ferrules, respectively internal and external, between which substantially radial vanes extend, characterized in that it comprises a first series of vanes carried by a first ferrules, a second series of vanes carried by the second ferrule, and connecting means connecting the two ferrules together, the blades of the first and second ferrules being arranged alternately.

Advantageously, the ferrule connecting means comprise spacer blades whose ends are fixed to the first and second ferrules, respectively.

The rectifier stage according to the invention therefore essentially comprises two series of vanes and connecting spacer blades: a first series of vanes connected to the first ferrule and which are independent of the second ferrule, a second series of connected vanes to the second ferrule, which are independent of the first ferrule and which each extend between two blades of the first shell, and spacer blades which are connected to the two ferrules and ensure the maintenance of all the parts of the floor rectifier.

Each ferrule thus carries approximately only half of the blades of the stage, which allows to double the pitch between blades and to facilitate access to these vanes by the aforementioned machining or welding tools, and thus to facilitate the manufacture of the rectifier stage.

The blades of each series are preferably substantially regularly distributed around the longitudinal axis of the stage.

The circumferential pitch between two consecutive blades of the first series is therefore substantially equal to the circumferential pitch between two consecutive blades of the second series and is substantially equal to twice the circumferential pitch of the blades of a rectifier stage having the same density of blades. the prior art. By way of example, the circumferential pitch between two consecutive blades borne by a ferrule may be approximately 27 mm and the circumferential pitch between two consecutive blades of the assembled stage may be approximately 13.5 mm.

According to another characteristic of the invention, the blades of the first series have free ends which are flush or are at short radial distance from the second shell, and the blades of the second series have free ends which are flush or are close to radial of the first ferrule. The radial distance between the free end of each blade of the second and third series and the corresponding ferrule is advantageously less than or equal to 0.05 mm, so as not to disturb the flow of air flow between the ferrules from the floor.

Each ferrule is preferably sectorized and comprises at least two annular sectors mounted end to end. Each annular sector of a ferrule may be formed in one piece with the blades carried by this ferrule sector, and be made for example of foundry or machining.

In a variant, the vanes carried by each annular sector of a ferrule are attached and fixed, for example by soldering or welding, to this ferrule sector.

According to another characteristic of the invention, the spacer blades are releasably connected to the ferrules. The radially outer end of each spacer blade may be threaded and be engaged in a radial orifice of the outer shell to receive a nut bearing on this outer shell.

The rectifier stage may further comprise an annular rail mounted on the inner ferrule and having an outer annular groove in which are engaged by circumferentially sliding an inner annular flange of each sector of the inner ferrule and the radially inner end of each dawn spacer.

Finally, the invention relates to a turbomachine, such as a turbojet engine or a turboprop engine, characterized in that it comprises at least one rectifier stage as described above.

The invention will be better understood and other characteristics, details and advantages thereof will appear more clearly on reading the description which follows, given by way of nonlimiting example and with reference to the accompanying drawings in which:

FIG. 1 is a partial schematic perspective view of a rectifier stage according to the invention; FIG. 2 is a schematic-partial-perspective view of the outer shell of the rectifier stage of FIG. 1;

FIG. 3 is a diagrammatic view in perspective and on a larger scale of the attachment of a spacer blade to the outer shell of FIG. 2; - Figures 4 and 5 are partial schematic views in perspective and on a larger scale of the rectifier stage according to the invention.

FIG. 1 represents a portion of a rectifier stage 10 according to the invention, comprising two coaxial ferrules 12, 14, respectively internal and external, between which substantially radial vanes 16, 18 and 20 extend, the ferrules 12 and 14 and vanes 16, 18 and 20 being described in more detail in the following with reference to Figures 2 to 5.

This rectifier stage 10 is part of a turbomachine turbine or compressor. It forms a stator element of the turbine or compressor and is disposed between two rotor stages of this turbine or compressor, which are each formed of a mobile wheel having an annular array of vanes.

In the example shown, the rectifier stage 10 is in two annular parts each extending over approximately 180 ° (only one of which is shown), these two parts being arranged circumferentially end to end and fixed to one another. by appropriate means, for example of the screw-nut type.

The illustrated portion of the rectifier stage 10 comprises an annular sector 15 of the outer shell 14 (extending over approximately 180 °) and three annular sectors 13 of the inner shell 12 (each extending approximately 55-60 °) which are arranged circumferentially end to end. Figure 2 is a schematic perspective view of the sector 15 of the outer shell 14.

This sector 15 carries a first series of blades 16 which are connected by their radially external ends to a cylindrical wall 22 of the sector.

These blades 16 are regularly distributed around the longitudinal axis of the rectifier stage and are at a circumferential pitch K each other. The vanes 16 carried by the sector 15 are for example 30 in number.

The blades 16 may be formed integrally with the sector 15 or be attached and fixed by their radially outer ends to the cylindrical wall 22 of the sector 15.

The ferrule sector 15 further comprises an annular wall 24 extending radially outwardly for mounting the rectifier stage 10 in the turbine or compressor of the turbomachine.

The cylindrical wall 22 of the ferrule sector 15 comprises substantially radial orifices 28 in which are engaged the radially outer ends of vanes 20 forming spacers which firmly connect the two ferrules 12, 14 between them.

In the example shown in Figure 1, these spacer blades 20 are 4 in number and are regularly distributed around the longitudinal axis of the stage. Of these four spacer blades 20, two are located at the circumferential ends of the ferrule sector 15. The two other blades 20 of the ferrule sector 15, located at a distance from the circumferential ends of this sector, are each arranged between two consecutive blades 16 borne by that sector.

The attachment of a blade 20 is shown on a larger scale in FIG.

The blade 20 comprises at its radially outer end a cylindrical tail 26 which is engaged in an orifice 28 of the cylindrical wall 22 of the ferrule sector 15 and whose radially outer end portion is threaded and receives from the outside a nut 30 intended to bear directly or via a washer 32 on the outer surface of the wall 22 of the ferrule sector 15.

The blade 20 comprises at its radially inner end a platform 34 connected to a foot 36 which has in section (in a plane passing through the longitudinal axis of the stage) a shape substantially I. Each blade 20 is mounted on the ferrule sector 15 by radial translation from the inside to the outside until its tail 26 is engaged in one of the orifices 28 of the ferrule sector 15. The nut 30 is then screwed on the threaded part of this tail and is clamped on the ferrule sector so as to immobilize the blade 20 radially on the ferrule sector 15.

FIGS. 4 and 5 show another step of mounting the rectifier stage 10 according to the invention, in which each sector 13 of the inner shell 12 is arranged between two platforms 34 of spacer blades 20.

Each sector 13 of the inner shell carries a series of blades 18, which extend radially outwardly from a cylindrical outer surface of the sector. Each sector 13 carries nine blades 18 in the example shown.

Each of these blades 18 is disposed between two consecutive blades 16 of the sector 15 of the outer shell or between one of these blades 16 and a spacer blade 20.

The blades 18 may be formed in one piece with the corresponding ferrule sector 13 or be reported and fixed by their radially inner ends on this sector.

The mounting of each inner ferrule sector 13 on the outer ferrule takes place as follows. The sector 13 is aligned with the outer ferrule sector 15 and disposed at an axial distance therefrom and then is displaced in axial translation towards the sector 15, until the blades 18 of the sector 13 are between the blades 16 of the sector 15.

In this position, the circumferential pitch between a blade 18 of the sector 13 and a blade 16 of the sector 15 is equal to K / 2.

The free ends of the blades 18 are flush or are at a short radial distance from the ferrule sector 15, and the free ends of the blades 16 are flush or are at a short radial distance from the ferrule sector 13. These distances are preferably less than or equal to 0 , 05 mm. Each The inner ring sector 13 is circumferentially aligned with the platforms 34 of the adjacent spacer blades 20 and has in section (in a plane passing through the longitudinal axis of the stage) a shape identical to that of the platforms 34. and feet 36 of the spacer blades 20.

An annular rail 40 (shown in Figures 1, 4 and 5) extending over

Approximately 180 ° makes it possible to firmly connect the sectors 13 of the inner shell 12 to the spacer vanes 20.

This rail 40 has an outer annular groove 42 having in section a shape substantially complementary to that of the feet 36 of the blades 20 and the ferrule sectors 13. The blade roots 20 cooperate with the side walls of the groove 42 of the rail to prevent the rotation of the blades about their axes and are retained radially by annular flanges 44 oriented towards one another of the side walls of the groove 42.

The feet 36 of the blades 20 and each sector 13 are engaged by circumferentially sliding in the annular groove 42 of the rail, by displacing the rail 40 in the circumferential direction on the sectors 13 of the inner shell 12 and on the feet 36 of the blades 20. For this, the root 36 of a blade 20 disposed at one of the circumferential ends of the ferrule sector 15 is engaged in a circumferential end of the groove 42 of the rail 40 and the rail is then slid in the circumferential direction on the sectors 13. of the inner ferrule, until the circumferential ends of the rail are substantially aligned radially with the circumferential ends of the ferrule sector 15.

The rail 40 may carry at its inner periphery an annular element 46 of abradable material intended to cooperate by friction with annular wipers carried by the rotor of the turbine or the compressor, so as to form a labyrinth type seal.

The first and second parts of the rectifier stage are identical and assembled in the same way. These two parts are then arranged end to end and then fixedly connected to each other to form the rectifier stage.

In the example of the drawings, the illustrated portion of the rectifier stage 10 comprises 30 blades 16 of the first series, (3 * 9) = 27 blades 18 of the second series, and 4 spacer blades 20. The second part not shown of this stage 10 is identical.

It is advantageous to interpose a corrugated leaf 48 with spring effect between the underside of the foot 36 of the blade 20, the base of the sector 13 and the bottom 50 of the groove 42 of the rail 40 (FIG. 5) to ensure permanent contact of the foot 36 of the blade 20 and the corresponding portion of each sector 13 on the flanges 44 of the groove 42 of the rail 40.

The radial heights of the flanges 44 of the groove 42 of the rail are determined with respect to the radial dimensions of the connections of the feet 36 of the blades 20 to their platforms 34 for a fitting fitting of the blade roots 20 in the groove 42 of the rail, and similarly for the corresponding parts of the sectors 13. Thus, the outer faces of the platforms 34 of the blades 20 and the corresponding parts of the sectors 13 are precisely at the same level, which ensures the continuity of the internal surface delimiting the fluid stream which goes into the rectifier stage.

Claims

1. Stator stage (10) for a turbomachine, comprising two substantially cylindrical ferrules (12, 14), respectively internal and external, between which extend substantially radial vanes (16, 18, 20), characterized in that comprises a first series of blades (16) borne by a first of the ferrules (14), a second series of vanes (18) carried by the second ferrule (12), and connecting means connecting the two ferrules together, the blades of the first ferrule being alternating with the vanes of the second ferrule.

2. Rectifier stage according to claim 1, characterized in that the blades (16, 18) of each series are substantially evenly distributed around the longitudinal axis of the stage.

3. Stage rectifier according to claim 1 or 2, characterized in that the connecting means of the ferrules comprise spacer blades (20) whose ends are fixed to the first ferrule and the second ferrule, respectively.

4. Stator stage according to one of the preceding claims, characterized in that each shell (12, 14) is sectored and comprises at least two annular sectors (13, 15) mounted end to end.

5. Rectifier stage according to the set of claims 3 and 4, characterized in that it comprises an annular rail (40) mounted on the inner ring (12) and having an outer annular groove (42) in which are engaged by sliding in the circumferential direction an inner annular flange of each sector of the inner shell and the radially inner end (36) of each spacer blade (20).

6. Rectifier stage according to claim 5, characterized in that waved blades (48) forming a spring are interposed between the bottom of the annular groove (42) of the rail (40), on the one hand, and the sectors (13). the inner ferrule and the feet (36) of the spacer blades, on the other hand.

7. Stage rectifier according to one of the preceding claims, characterized in that the blades (16) of the first series have free ends which are flush or are at short radial distance from the second ferrule (12), and the blades (18). ) of the second series have free ends which are flush or are at short radial distance from the first ferrule (14).

8. Rectifier stage according to claim 7, characterized in that the radial distance between the free end of each vane (16, 18) of the first and the second series and the corresponding ferrule (12, 14) is less than or equal to at 0.05mm.

9. Rectifier stage according to claim 4, characterized in that each annular sector (13, 15) of a ferrule is formed in one piece with the vanes (16, 18) carried by this ferrule sector, for example of foundry or by machining.

10. Rectifier stage according to claim 4, characterized in that the blades (16, 18) carried by each annular sector (13, 15) of a ferrule are attached and fixed, for example by brazing or welding, on this sector of ferrule.

11. Stage rectifier according to claim 3, characterized in that the spacer blades (20) are removably connected to the ferrules (12, 14).

12. Rectifier stage according to claim 3 or 11, characterized in that the radially outer end (26) of each spacer blade (20) is threaded and is engaged in a radial orifice (28) of the outer shell (14) and receives a nut (30) bearing on this outer shell.

13. Turbomachine, such as a turbojet or an airplane turboprop, characterized in that it comprises at least one rectifier stage (10) according to one of the preceding claims.