FR2698405A1 - Variable orientation control for stator blades of turbine, - has orientation controlled by lever, which is operated by control ring. - Google Patents

Abstract

The turbine is formed around a static frame with stages of pivoting, non-rotating blades (5), each of which has a pivoting control lever (36). A single control ring (20) carries the pivot control levers by an articulated joint. The pivot control lever is connected at one end to the bush (7), which is arranged to pivot around the axis of the blade, causing the blade to pivot under the control of the lever (36). The other end of the lever is connected to the control ring (2) by means of the hollow pivot (37), which is arranged to rotate within the bearing (38). USE/ADVANTAGE - It provides a simple and practical method to provide different angles of pivot for the blades of each stage of the turbine.

Description

MULTI-STAGE TURBOMACHINE OF STATOR BLADES
WITH VARIABLE ORIENTATION.

DESCRIPTION
The invention relates to a turbomachine equipped with several stages of stator vanes with orientation or a ng the variable timing.

 Compressors and turbines are known of which the stages of fixed blades, linked to the stator, are capable of pivoting about a radial axis, which modifies the flow characteristics of the flow of compressed gases and thus improves the efficiency of The machine at certain speeds avoiding pumping.

This arrangement is found for single stages of blades or groups of stages: French patents 1,230,393, 1,238,098 and 1,990,020 give examples of embodiment of this second design family; it can be seen that a control ring concentric with the stator receives the ends of the control levers for the blades. The movements of the control ring in the direction of the axis of the machine or in rotation around this axis enter, cause the levers and rotate the blades.

 In a certain number of embodiments, the levers are articulated at fixed points on the control ring, which means that the latter can only be moved if all the stages of the blades are identical and in particular have levers of the same length; however it is often advantageous, in order to achieve a finer adjustment of the operating characteristics of the machine at all rotor rotation regimes, that the pivotings differ for the various stages concerned, which requires the use of length levers Such construction is kinematically possible if the levers are terminated by radial pivots which penetrate and slide in circumferential grooves of the control ring, which is chosen in some of the reported patents (where the blade stages are however identical), but the conditions of service would not be very good if we had to move some of the levers to orientations close to the longitudinal ones, because friction would be likely to jam the mechanism. This design is also possible only if the ring is movable in axial translation.

 The same reproach of risks of jamming can be addressed to systems where special control rings are used on each floor and united by return mechanisms: i Is complicated, heavy and unreliable under the conditions of normal La service machine where the high temperatures cause significant thermal expansions which increase the defects of adjustment and assembly of the elements.

 In designing the invention, we sought to achieve a simple and practical control system for several stages of blades undergoing pivoting at different angles for each stage, and we therefore retained the idea of using a ring of single control to which the levers are connected by articulations. The levers are now slidably mounted in the articulations for all the stages or, in a slightly different kind of embodiment, for all the stages except one, whose levers are connected to the articulations without being able to slide.

 The I e v i e rs can a i ns i a c qué r i r different lengths for each stage between the connection at dawn and the point of connection to the control ring.

 We have also sought to facilitate the mounting and dismounting of the elements, in particular with regard to the connections of at least some of the blades to the control ring by the levers c or li ssant s. The blades concerned are arranged so that they pivot around a journal provided with a hole occupied by one of the levers, the levers which occupy the holes comprising at least one narrowing of section; sockets comprising at least one recess engaged in the narrowing of the section surround the trunnions, the sockets being formed so that they are held blocked by the levers on the turrets by the engagement of portions of the sockets adjacent to the recesses in es narrowing section of the levers, thus preventing the levers from sliding in the holes, and that they can be released from the levers by deforming them by elastic zones of the sockets.

Various embodiments of the invention in accordance with this definition have been designed and will now be explained in detail by commenting on the following figures which are given for illustrative and nonlimiting purposes.
- Figure 1 partially illustrates a turbocharger in longitudinal section;
- Figures 2 and 3 are diagrams of an embodiment of the invention;
- Figures 4 and 5 illustrate a first embodiment of connection between a blade and a lever;
- Figures 6 and 7 illustrate a second embodiment of connection between a blade and a lever;
FIGS. 8 and 9 i Illustrate a third embodiment of connection between a blade and a lever, and
- Figure 10 shows a fourth embodiment of connection between a blade and a lever.

We distinguish in Figure 1 a stator 1 and a rotor 2 concentric, the latter being surrounded by this one. The rotor 2 carries movable vanes 3 which are rigidly connected to it and therefore rotate around its axis X of rotation. The movable blades 3 are responsible for the compression of the gases flowing in an annular stream 4 which corresponds to the interval between the rotor 2 and the stator 1, and they are arranged obliquely so as to push the gases towards the end of exit from the annular vein 4, at
the right of FIG. 1. The stator 1 carries pivoting vanes 5 which also extend in the annular vein 4. All the vanes 3 and 5 are distributed in stages where they are arranged according to the circumferences of the machine, and the movable blade stages 3 alternate with the pivoting blade stages 5 in the longitudinal direction.

The pivoting vanes 5 are vanes of
straightening of the gas flow and extend in principle substantially longitudinally, but it appears that slight adjustments of their orientation lead to a better performance of the machine at certain speeds of rotation of the rotor 2. This is why
their end 6 pressed into the stator 1 is, in this kind of design, composed of a journal 7 of radial Y axis which is engaged in a bearing 8 of the stator 1 and of a lever 9 which ends at one end with the journal 7 to which it is rigidly linked, as will be seen below, and by its other end to a control ring 20 movable and rotating around the axis X.

The means which drive it can be mechanical or pneumatic but are conventional and are not shown here. We now refer to Figure 2.

 The control ring 20 of Figures 2 and 3 has three rings 31, 32 and 39 to which the levers of two stages of pivoting vanes 5 are connected. However, a distinction must be made between the levers 33 of the crown 31, which are conventionally provided with a handle 34 in the form of a radial pivot engaged in recesses 35 in the crown 31 and which are screwed by their other ends to the link towers 7, levers 36 associated with crowns 32 and 39, which slide in holes in hollowed-out pivots 37 capable of rotating around radial axes in cylindrical housings 38 of crowns 32 and 39. This arrangement remains ineffectually admissible if stages of blades with c levers similar to the levers 33 (of the same length, of the same orientation and articulated without sliding to the control ring 20) or if we add stages of blades with articulated levers by sliding to the control ring 20, like the levers 36. The orientations and the lengths of the levers of these stages can be freely chosen and differ from one stage to another, which implies that the rotations of the blades 5 associated with the 36 levers will also be different.

 It is also possible to use the sliding levers 36 for all the stages of blades 5 controlled by the ring 20. It can be seen in FIG. 3, where the representation of the crown 39 is omitted, that a hollow imprint 29 is formed on the crown 32 at each hollowed-out pivot 37 so that the levers 36 rotate without being hindered by the material of the crown 32.

 We now refer to Figures 4 and 5.

The levers 36 are connected to the towers 7 in a manner which enables them to be disassembled and reassembled quickly. They are first of all inserted into a bore 40 of the pins 7 which extends perpendicular to the axis of rotation of the pivoting vanes 5 and in the extension of the bore of the hollow pivots 37. They are provided with two narrowing of section: a groove 41 and a thinning end 42 obtained by turning, which are located at the outcrops of the levers 36 at the ends of the bore 40.

 Note that the pins 7 associated with the levers 36 are cylindrical up to their end distant from the voting vanes 5, while the pins 7 associated with the conventional levers 33 are of a more complex constitution, with a square section e around which a flange 80, which has a central hole of the same shape, is engaged in order to ensure the rotation of the pin 7, and a threaded end which receives a nut 81 retaining the lever 33 by blocking the flange 80. The connection of the levers 36 to the pins 7 is produced for each of them by a sleeve 43 engaged around the swirl 7.

It is a ring terminated at the bottom by a flange 44 for bearing or abutting against a smooth bearing 45 around which the pin 7 pivots. The sleeve 43 further comprises two longitudinal grooves 46 (oriented in the axis of the journal 7 when the sleeve 43 is mounted on it) and diametrically opposite, which divide it into two similar lobes 47 and open out at the end of the sleeve 43 opposite the flange 44. The longitudinal grooves 46 are narrower than the section of any place of the lever 36, except at their lower end, which forms a widening 48 p wider than the narrowing of the section of the lever 36 but always narrower than the section of the lever 36 elsewhere.

 The sleeve 43 is made of elastic metal and can be deformed without damage by spreading the lobes 47 to open the longitudinal grooves 46 and allow the lever 36 to slide in the enlargements 48, which have been enlarged, to mount or dismount it. Ears 49 are provided at the upper edge of the lobes 47 to protrude from the pins 7 and allow to spread by a tool such as pliers.

When the lobes 47 are released, the sleeve 43 returns to its original state and the narrowing of the lever 36 is retained in the enlargements 48.

 In the embodiment of FIGS. 6 and 7, the single socket 43 is replaced by a double socket composed of an internal socket 50 and an external socket 51 concentric and stacked around the end of the journal 7. The internal socket 50 carries a lower flange 52 identical in nature and in function to the previous flange 44, but it is devoid of longitudinal grooves, has only two circular recesses 53 crossed by the lever 36 and of larger diameter, so that the passage of the lever 36 does not cause any deformation. The retention of the lever 36 introduced into the bore 40 and the recesses 53 is ensured by the external sleeve 51, which is a ring with a discontinuous contour cut by a single longitudinal groove 54 which extends from one end to the other of the external sleeve 51. The external sleeve 51 further comprises a recess 55 diametrically opposite the longitudinal groove 54 and two ears 56 at right angles to the longitudinal groove 54 and the recess 55, which consist of longitudinal bulges towards the outside. of the material of the outer sleeve 51.

 When the sockets 50 and 51 are mounted together, the recess 55 is in front of one of the recesses 53 and the lever 36 passes through it. The ears 56 are in front of longitudinal grooves 57 formed on the outer surface of an upper flange 58. The branches of a tool I such as a clamp can be slipped into the hollows formed by the grooves 57 and the ears 58. can then move aside the outer sleeve 51 by opening the longitudinal groove 54, which releases it from the groove 41 of the lever 36, into which its edges penetrate when the outer sleeve 51 grips the outer sleeve 50, after which the outer sleeve 51 is removed by passing it around the upper flange 58. It is then possible to remove the lever 36 then the internal sleeve 50. This latter has the essential purpose of retaining the external sleeve 51 between the two flanges 52 and 58, the last of which is a longitudinal stop means.

 The embodiment of FIGS. 8 and 9 also comprises an internal sleeve 60 and an external sleeve 61 which are concentric and successively engaged on the end of the pin 7. The internal sleeve 60, which is further terminated by a flange 62 of abutment on the bearing smooth 45, here has two circumferential and diametrically opposite grooves 63 each of which is composed of a thin portion 64 and an enlargement 65 at one end. To carry out the mounting of the lever 36, it is made to slide in the bore 40 and the enlargements 65, after which the internal sleeve 60 is rotated so that the thin portions 64 come to enclose the narrowing of the section; they are just wide enough to contain them but narrower than the other sections of the lever 36, so that the lever 36 can no longer be removed.

 The external sleeve 61 is intended to maintain the mounting of the lever 36 by opposing an opposite and accidental rotation of the internal sleeve 60. It therefore includes two longitudinal notches 67 diametrically opposite at its lower end, intended to overlap the lever 36 and, at the bottom of its internal face, a locking groove 68 which is intended to snap into place by elastic deformation when mounted on a flange 69 of the internal sleeve 60. It is therefore necessary to press on the external sleeve 61 to secure it to the internal sleeve 60 in the longitudinal direction. No accidental loosening is therefore possible. It is preferable to conform the outer sleeve 61 in the form of a cabochon, that is to say with a flat upper face 70 on which the pressing is exerted without damage. The upper face 70 however has a central bore 71 through which one can introduce from below the upper face 70 a tool for tearing off the outer sleeve 61, which is made of soft elastic material such as plastic, while the inner sleeve 60 is made of metal.

 Flats 72 are provided on the internal face of the external sleeve 61 and 66 on the external face of the flange 62. They come face to face with the mounting of the external sleeve 61 and oppose any rotation of the latter. The narrowing of the section of the lever 36 therefore remains maintained in the intersections of the longitudinal notches 67 and of the thin ions port 64 of the circumferential grooves 63. The flats 66 of the internal sleeve 60 also serve to facilitate the rotation of the latter on the pin 7 .

 A final embodiment is given in FIG. 10. It involves only a single socket 75 comprising a lower flange 76 and two diametrically opposite recesses 77. A helical groove 78 winds on the wall of the sleeve 75 and the notch between the collar 76 and the recesses 77. This region forms an elastically compressible zone of the sleeve 75. The sleeve 75 is made of metal and elastic. It is of sufficient diameter to slide around the pin 7 with play. When the flange 76 abuts against the plain bearing 45, the sleeve 75 is pressed so that the recesses 77 come in front of the bore 40 by flattening the sleeve 75 to the location of the helical groove 78.

 The lever 36 is then slid into the bore 40 and the recesses 77 until the section narrowing comes in front of the latter. The sleeve 75 is then released; the lower edges 79 of the recesses 77 engage in the section narrowing, which blocks the lever 36 in its location. A new pressure on the sleeve 75 is necessary to unlock the lever 36.

 It is understood from these examples that many other embodiments can be envisaged for connecting the levers 36 to the pins 7 so as to allow quick and easy disassembly and reassembly, according to the same principle consisting in using a sleeve or a set of threaded sleeves around a trunnion to lock the lever passing through recesses of the sockets by engaging portions of the sockets adjacent to the recesses in narrowing of the section of the lever, while preventing the disjunction of the sockets and the lever unless d '' apply voluntary efforts on the bushings to deform them elastically in an appropriate manner by opening or moving the recesses.

Indeed, the portions engaged in the narrowing of the lever prevent it from sliding, and the lever locks the sockets on the pin.

Claims (10)

CLAIMS.  1. Turbomachine comprising a stator (1) with several stages of pivoting vanes (5) each having a pivoting control lever, a single control ring (20) to which the levers are connected by articulations (37), characterized in that the levers (36) are slidably mounted in the joints.  2. Turbomachine comprising a stator (1) with several stages of pivoting vanes (5) each having a pivoting control lever, a single control ring (20) to which the levers are connected by articulations (34, 37), the levers (33) of one of the blade stages (31) being connected to the articulations (34) without being able to slide, characterized in that the levers (36) of the other blade stages are mounted to slide in the articulations (37 ).  3. Turbomachine according to any one of  Claims 1 or 2, characterized in that at least some of the blades pivot around a pin (7) provided with a hole (40) occupied by one of the levers, the levers (36) which occupy the holes (40) comprising at least one section narrowing (41, 42), and in that sockets comprising at least one recess (48, 5 4, 64, 77) surround the pins (7), the sockets being constructed so that they are kept b locked by the levers (36) on the pins (7) by the engagement of portions of the sockets adjacent to the recesses in the narrowing of the sections of the levers, thus preventing the levers (36) from sliding in the bores (40), and that they can be released from the levers by deforming them by elastic zones (47, 54, 68, 78).  4. Turbomachine according to claim 3, characterized in that the recesses consist of longitudinal grooves (46, 54) extending to one end of the sockets (43, 51).  5. Turbomachine according to claim 4,  characterized in that the grooves (46) have widenings (48) which can be opened by deforming the bushings so as to release the cross-sectional narrowing (41, 42) of the levers (36).  6. Tu r bom ac hi ne according to I has claim 4, characterized in that it comprises internal sockets (50) engaged on the touri lIons (7), surrounded by the sockets (51) having the longitudinal grooves (54 ) and provided with recesses (53) for passage of the levers (36) and abutment means (58) retaining the sockets (51) co comprising the longitudinal grooves (54)  7.Turbomachine according to claim 3, characterized in that the recesses consist of circumferential grooves (63) provided with enlargements (65) for passage of the levers (36) and narrowing (64) limited by the engaging portions in the narrowing of the section of the levers, in that external sockets (61) provided with longitudinal grooves (67) are engaged on the sockets comprising the reconcferential grooves, the levers (36) passing through the longitudinal grooves, the sockets ( 60, 61) being provided with means for mutual maintenance in angular position (66, 72) and for maintenance in longitudinal position by snap-fastening (68, 69).  8. Turbomachine according to claim 3, characterized in that the sockets (75) have a bearing end (76) and an elastic zone between the recesses (77) and the bearing end (76), deformable by compression longitudinal of the sleeve (75).  9. Turbomachine according to claim 8, characterized in that the elastic zone is constituted by a helical groove (78).  10. Turbomachine according to any one of claims 1 to 9, characterized in that the levers (33, 36) have different lengths between the blades (5) and the control ring (20).