EP0651139A1 - Turbomachine with means to control the tip clearance between rotor and stator - Google Patents

Abstract

The invention relates to a turbo machine including a shroud (2) consisting of a plurality of shroud elements (2a, 2b,...) in the form of circular sectors each one bearing stationary vanes (4) on one internal face, and a circular casing (1) surrounding the shroud. It is characterised in that it includes a support ring (6) comprising a plurality of circular ring sectors (6a, 6b,...) each one fixed to the casing and having a U-shaped cross-section, the opening of which U points towards the shroud, each shroud element including fastening means (9a) capable of being inserted into the opening of at least one ring sector in order to secure the said ring sector and the shroud element together. Application to aircraft engines. <IMAGE>

Description

Technical area

The present invention relates to a turbomachine comprising means for controlling the clearances between stator and rotor and, more precisely, between the stator and the top of the moving blades of the rotor.

It finds many applications in the field of aeronautics.

State of the art

The large temperature rises to which an aircraft engine turbomachine is generally caused thermal expansions which it is of the greatest interest to be able to control in order to avoid, in particular, gas leaks between the rotor and the structure of the stator which it is thus surrounds the yield losses, consecutive to these gas leaks.

Aircraft engines (particularly those used for propulsion of jet aircraft) must be able to operate under conditions which can vary rapidly. These variations in operating conditions can be runaway from the cold rotor, a throttle stroke, runaway from the hot rotor, or any other operating conditions well known to those skilled in the art.

Also, it is necessary to obtain a constant clearance between the ferrule of the stator and the rotor during variable operations such as those named above. It is in particular essential that the radial clearances between the external ends of the moving blades of the rotor and the internal shroud of the stator, which carries the fixed blades for rectifying the air flow between the moving blades, are as constant as possible. .

However, obtaining such constant clearances is relatively difficult due, on the one hand, to the expansion and variable mechanical construction of the rotor under the effect of speed variations and, on the other hand, to thermal growth. relative between the stator and the rotor due to a significant difference in thermal inertia, but necessary.

Various means are known for limiting the consequences of wear and tear on the stator shell due to a dilation of the movable blades greater than the dilation during so-called "normal" operation. A first means consists in building the ferrules with a coating of soft material at the point in front of which the movable blades pass; thus the possible friction of the end of the movable blades which could occur during a greater expansion of the latter would cause wear of the coating and a reshaping of the stator at this location.

Another means of obtaining a satisfactory result consists in constructing the stator in such a way that it is possible to circulate gas therein, taken for example from another location of the machine, at a temperature and at a flow rate which produce at will a heating or cooling capable of regulating the expansions of the ferrule and therefore its play with the movable blades.

Such a sending of air at variable temperature on the structure of the rectifier support allows, by a variation of the speed of expansion and contraction of the structure, to accommodate different engine operating conditions.

To ensure the expansion and contraction of the structure around the entire circumference of the casing, it is generally made in one piece; it is therefore a 360 ° circumference housing.

Documents FR-2 683 851, FR-2 516 980 and FR-2 482 661 describe turbomachinery whose stators include double-skin casings extending around the rotors on a complete circumference, the heating or cooling air circulating between the two skins of the casing. According to such turbomachines, the shell elements (or shell sectors) are directly linked to the casing. Also, during expansion or contraction of the casing, the shell elements can undergo displacements which harm the circularity of the structure.

In order to maintain perfect circularity of the shell elements and to ensure an immediate reaction of the structure to expansion and contraction, means for adapting the shell elements to the casing are known to those skilled in the art. Document GB-2 115 487 describes stator rings fitted by dovetail in supports. Document FR-2 482 662 describes a segmented stator ring pierced with orifices.

None of these adaptation means ensures a flexible connection of the shell elements relative to the casing.

Statement of the invention

The object of the present invention is precisely to remedy these drawbacks. To this end, she proposes a turbomachine comprising a stator whose casing of 360 ° circumference and the shell elements are linked by means of a fixed point and sliding bearings ensuring the shell a circumferential flexibility.

• une virole constituée d'une pluralité d'éléments de virole en forme de secteurs circulaires portant, chacun sur une face intérieure, des aubes fixes ; et
• un carter circulaire entourant la virole.

More specifically, the invention relates to a turbomachine comprising:

• a ferrule made up of a plurality of ferrule elements in the form of circular sectors, each carrying an inner face, fixed vanes; and
• a circular casing surrounding the ferrule.

This turbomachine is characterized in that each ferrule element is made integral with the casing by a fixed point means (10) and at least two sliding support means (11) located on either side of the fixed point means to provide the ferrule member with circumferential flexibility.

According to a first embodiment of the invention, the turbomachine comprises a support ring housed between the casing and the ferrule and comprising a plurality of circular ring sectors each fixed on the casing by means of fixed point and means d '' sliding supports and having a U-shaped section whose opening is directed towards the ferrule, each ferrule element comprising hooking means able to be introduced into the opening of at least one ring sector to secure said ring sector and the ferrule element.

According to this embodiment, each ring sector comprises an upstream wing and a downstream wing, each of said upstream and downstream wings comprising first recesses open radially towards the ferrule to provide circumferential flexibility to said ring sector. The upstream wing also has second recesses.

For this embodiment, the turbomachine comprises clamping means in support on either side of each ring sector to ensure that said ring sector is secured to the means for hooking the ferrule element.

These tightening means comprise a screw and a conical nut introduced inside the ring sector and able to move apart during the introduction of the screw, the base of said nut then being in abutment on the internal faces of the sector. ring.

The attachment means of each ferrule element constitute, with the ends of the upstream and downstream wings of the ring sector in which it is introduced, a dovetail assembly.

According to this embodiment, each fixed point means comprises a screw / nut system ensuring a connection without play of a ring sector with the casing, the nut being introduced inside the ring by the second recess and disposed in abutment on an internal face of the core of the ring sector.

The screw can be, for example, introduced into the ring sector with an inclination close to 45 ° relative to the radial direction. It can, according to another example, be introduced radially into the ring sector, the nut then having a conical shape whose base is directed towards the ferrule.

• une vis introduite dans le secteur d'anneau par une ouverture réalisée dans l'âme dudit secteur d'anneau ;
• une semelle surmontée d'une saillie qui est percée d'un trou comportant sur la paroi un pas de vis pour recevoir ladite vis et qui traverse l'ouverture de l'âme pour être en contact avec le carter ;
• deux pièces d'appui disposées de part et d'autre du trou de la semelle et fixées sur le secteur d'anneau de façon à permettre un glissement de la semelle sur les pièces d'appui.

According to this embodiment, each sliding support means comprises:

• a screw introduced into the ring sector through an opening made in the core of said ring sector;
• a sole surmounted by a projection which is pierced with a hole comprising on the wall a thread for receiving said screw and which passes through the opening of the core to be in contact with the casing;
• two support pieces arranged on either side of the hole in the sole and fixed to the ring sector so as to allow the sole to slide on the support pieces.

The screw is then introduced into the ring sector with a longitudinal inclination at an angle a, and the support pieces comprise a surface inclined at an angle α relative to the radial direction.

Advantageously, the first recesses of the downstream wing are closed by sealing plates. Each ring sector has, around the first recesses, grooves in which the sealing plates are positioned and fitted.

Each downstream wing of a ring sector can comprise, at one end, an extension tab and, at another end, a machining ensuring an interlocking with overlapping of said ring sector in the neighboring ring sectors.

According to a second embodiment of the invention, each sliding support means is positioned astride two ferrule elements to keep them integral with one another.

• deux vis (40a, 40b) traversant le carter ;
• une semelle (42a) située à la jonction des deux éléments de virole entre le carter et lesdits éléments de virole, percée de deux trous filetés (42d, 42e) pour recevoir les deux vis et comportant des pattes de glissement (42b, 42c) disposées de part et d'autre des trous ;
• deux pièces d'appuis (44b, 44c) situées de part et d'autre des trous de la semelle et fixées chacune sur un des éléments de virole de façon à glisser le long des pattes de glissement de la semelle.

According to this embodiment, each sliding support means comprises:

• two screws (40a, 40b) passing through the casing;
• a sole (42a) situated at the junction of the two ferrule elements between the casing and said ferrule elements, pierced with two threaded holes (42d, 42e) to receive the two screws and comprising sliding tabs (42b, 42c) arranged on either side of the holes;
• two support pieces (44b, 44c) located on either side of the holes in the sole and each fixed on one of the shell elements so as to slide along the sliding tabs of the sole.

Brief description of the drawings

• FIG. 1 represents a high pressure compressor equipped with means for controlling the clearances between rotor and stator according to the first embodiment of the invention;
• FIG. 2 represents a diametral section of the turbomachine according to the first embodiment, showing the angular distribution of the shell elements and of the ring sectors inside the casing;
• Figure 3 shows a perspective view of a ring sector of Figure 2;
• FIG. 4 represents a partial view of the downstream wing and of the upstream wing of a ring sector of FIG. 2;
• FIG. 5 represents, in an axial section, the clamping means ensuring the joining of the ring sectors and of the shell elements in accordance with the first embodiment;
• Figure 6 shows, in an axial section, a fixed point according to the first embodiment;
• Figure 7 shows, in axial section, a variant of the clamping means and sealing means of the first embodiment;
• FIG. 8 represents, in axial section, a sliding support connecting the ring sector and the casing according to the first embodiment;
• Figure 9 shows, in a perspective view, the support parts and the sole forming the sliding support of Figure 8;
• Figure 10 shows a perspective view of the joint between two ring sectors of Figure 2;
• FIG. 11 represents a partial view of the means for controlling the clearances between rotor and stator according to the second embodiment of the invention;
• Figure 12 shows a perspective view of a sliding point according to the embodiment of Figure 11; and
• Figures 13 and 14 show a partial axial section of a sliding point of Figure 11 according to two mounting modes.

Detailed description of embodiments

In Figure 1, there is shown, in axial section, a high pressure compressor having an outer casing 1 of 360 ° in circumference and means for controlling the clearances according to the first embodiment of the invention. This casing 1 comprises two envelopes (or two skins) concentric, slightly conical, separated by a volume (shown hatched in Figure 1) in which circulates the heating or cooling air. This two-skin housing is of the type described in the document FR-2 683 851 cited above; it will therefore not be described in more detail.

This casing 1 surrounds a plurality of shell elements 2 which are substantially conical. These ferrule elements 2 are arranged end to end and assembled by interlocking seals 3 to form a single continuous ferrule and substantially parallel to the casing 1.

Each ferrule element 2 carries a stage of stationary vanes 4 of stator, also called rectifier stage. A stage of movable rotor blades 5 extends between each pair of stages of fixed blades 4.

In FIG. 1, the rings 6 according to the first embodiment of the invention are also shown, these rings allowing appreciable displacements of the shell elements 2 as a function of the expansions and contractions of the casing 1. These rings 6 each comprise a plurality of sectors of rings arranged end to end and nested one inside the other to produce continuous rings.

This figure 1 shows the section of a ring 6. As can be seen in the figure, each ring 6 has a U-shaped section, the open side of the U being directed towards the ferrule 2.

Each ferrule element 2 comprises on its external face, that is to say on the face not carrying the fixed vanes 4, hooking means 9 of the ring 6. According to a preferred embodiment of the invention, these attachment means 9 consist of a dovetail pin 9a capable of being introduced into the opening of the ring 6. The ends of the upstream 7 and downstream 8 wings of the ring 6 form a mortise 9b suitable for receiving the post 9a. The mortise 9b and the tenon 9a thus form a dovetail assembly. Clamping means, not shown in this figure 1, ensure a pinching on either side of the wings upstream 7 and downstream 8 of the ring 6 to ensure that said ring 6 is secured to the ferrule 2.

Each ring sector 6 is fixed to the casing by means of a fixed point 10 which will be described in more detail through the following figures. Each ring sector is also fixed to the casing by means of sliding supports not shown in this FIG. 1 but described in more detail in the following description.

FIG. 2, as well as the following figures 3 to 10 show in detail the elements constituting the first embodiment of the control means shown in FIG. 1.

FIG. 2 shows the angular distribution of the shell elements 2 and of the ring sectors 6 inside the casing 1. The shell 2 therefore comprises a plurality of shell elements, three of which are shown in FIG. 2 and referenced 2a , 2b and 2c. Likewise, the ring 6 comprises a plurality of ring sectors, four of which are shown in this FIG. 2 and referenced 6a, 6b, 6c and 6d. According to the embodiment represented in this FIG. 2, each ring sector has a size equivalent to approximately two shell elements.

However, it should be noted that the size of a ferrule element and the size of a ring sector are entirely independent of each other.

• deux appuis glissants répartis de part et d'autre du point fixe ; et
• deux appuis glissants situés chacun à une extrémité d'un secteur d'anneau.

Each ring sector 6a, 6b, 6c and 6d is linked to the casing 1 by a fixed point referenced, respectively, 10a, 10b, 10c and 10d. Each ring sector 6a, 6b, 6c and 6d is, moreover, linked to the casing by sliding supports. These sliding supports are at number of four per ring sector distributed as follows:

• two sliding supports distributed on either side of the fixed point; and
• two sliding supports each located at one end of a ring sector.

According to the embodiment shown in FIG. 2, the ring sector 6a comprises two sliding supports 11a and 11b on either side of the fixed point 10a and two sliding supports 11c and 11d at each of its ends.

All of these sliding supports ensure, for each ring sector, an immediate circumferential movement (represented by the arrows in FIG. 2) of the ring sector, and therefore of the shell elements connected to this ring sector, relative to the displacement of the housing.

In addition, schematically shown in this Figure 2, the recesses of the upstream wing of the ring sector 6a. Each ring sector has, in fact, a plurality of recesses, namely the recesses 12 only on the upstream wing and the recesses 13 on the upstream wing and on the downstream wing, these recesses ensuring circumferential flexibility at the ring area. The ring sectors 6a, 6b, ... are assembled with the neighboring ring sectors at the center of a recess 12.

FIG. 3 represents a perspective view of the ring sector 6a of FIG. 2. This figure therefore shows the ring sector 6a cut at a recess 13, the casing 1 on which the ring sector is fixed 6a, as well as the ferrule 2 with its tenon 9a in dovetail around which fits the ends in dovetail 9b of the upstream wings 7 and downstream 8. More precisely, the ring sector 6a is connected to the casing 1 via the fixed point 10a and several sliding supports, three of which are shown in this figure and referenced 11a, 11b and 11c.

There is shown in this figure, the recesses 12 of the upstream wing as well as the recesses 13 with their radial slot, these recesses 13 also being present on the downstream wing 8, but not visible in this perspective view of the sector of ring 6a.

Also, FIG. 4 shows, in part A, a portion of the upstream wing 7 of the ring sector 6a and, in part B, a portion of the downstream wing 8 of this same ring sector 6a .

More precisely, part A of FIG. 4 shows the external face of the upstream wing 7 of the ring sector 6a. This part A therefore shows the recesses 12 of the upstream wing 7 as well as the recesses 13 of this same upstream wing 7. As explained above, these recesses 13 have a radial opening 13a, or radial slot, starting from the internal part of the sector. ring (that is to say the part of smaller diameter) and ending in the recess 13. These radial slots give the ring 6 a circumferential flexibility.

The recesses 12, produced in the upstream wing 7, make it possible to reduce the amount of material necessary for the production of this ring; this therefore results in a reduction in the ring. In addition, these recesses 12 ensure a reduction in the heat exchanges between the ambient medium and the ring 6.

This part A of FIG. 4 also shows the nuts 14 of the clamping means.

Part B of FIG. 4 shows the internal face of the downstream wing 8 of the ring sector 6a. This downstream wing 8 comprises the recesses 13 with their radial slots 13a as well as screws 15 which pass through the ring sector right through and are fixed in the nuts 14 of the upstream wing 7. Each screw 15 associated with a nut 14 constitutes the clamping means which ensure the clamping of the ring sector around the dovetail tenon of the ferrule.

On this part B, the screws of the fixed point 10a and of the sliding support 11a are also represented. These screws are shown in dotted lines because they are not visible on the internal face of the downstream wing 8. The screw 16a of the fixed point 10a is inserted in the casing 1 and the downstream wing 8 is fixed in the nut 16b which is in contact with the internal face of the downstream wing 8. This nut 16b is fixed to the downstream wing 8 by means of two rivets 17a and 17b.

This fixed point will be described in more detail in the following description.

The sliding support 11a is also shown in this part B of FIG. 4. The screw 18a of the sliding support is inserted into a sole 18b surmounted by a projection pierced with a hole on the wall of which a pitch of screws has been realized. This sole 18b is supported on support pieces 19a and 19b arranged on either side of said hole in the sole 18b. These support pieces 19a and 19b are crossed by the screws 15, which secures said support pieces on the downstream wing 8. An opening 21 is, moreover, made in the core 20 of the ring sector; the sole 18b has, with the projection which surmounts it, a form of "pick" capable of passing partly into the opening 21 of the core 20 of the ring sector 6a so as to be in direct contact with the internal wall of the casing 1. The parties lateral of the sole 18b can therefore slide on these support pieces 19a and 19b thus creating a circumferential clearance of the ring segment 6a relative to the casing 1.

According to one embodiment, this sole 18b is a double-bearing nut.

According to a preferred embodiment of the invention, the support pieces 19a and 19b form an angle of approximately 45 ° relative to the downstream wing 8 so as to ensure better sliding of the sole 18b.

This sliding support will be described in more detail with reference to Figures 8 and 9 of the description.

This part B of FIG. 4 also shows a sealing plate 25 which can be introduced into grooves (or slots) machined around the recesses 13 of the downstream wing 8. These grooves, referenced 26, are shown in dotted lines in the figure because they are produced on the external face of the downstream wing 8. The sealing plate 25 has returns (in dotted lines) capable of being introduced into the grooves 26 to ensure the positioning and fitting of said plates 25 in the downstream wing 8. The positioning of such sealing plates in front of the recesses 13 in the downstream wing 8 of the ring sector 6a is intended to prevent possible reintroductions of downstream gases upstream of the ring.

According to another embodiment of the invention, represented in FIG. 7, the sealing of the downstream wing of each ring sector is carried out by means of an annular seal 38 bearing on the downstream part of the dovetail assembly.

In Figure 5, there is shown the clamping means in axial section. As briefly described above, these clamping means comprise a screw 15 inserted in the downstream wing 8 of the ring 6 and passing through said ring right through. This screw 15 is fixed in a nut 14 bearing on the external face of the upstream wing 7. These tightening means thus make it possible to compress the mortise 9b produced by the wings 7 and 8 of the ring 6 against the tenon 9a. dovetail of the ferrule 2.

In Figure 6, there is shown a fixed point in axial section. This fixed point 10 consists of a screw / nut system introduced into the casing 1 and into the ring 6 to secure them. More precisely, this screw / nut system comprises a screw 16a introduced into the casing 1 and into the core 20 of the ring 6 by a breakthrough. A nut 16b introduced into the ring 6 through one of the recesses 12 of the upstream wing 7 secures the screw 16a. The screw 16a thus fixed in the nut 16b secures the ring 6 by its core 20 against the internal wall of the casing 1.

According to one embodiment of the invention, the nut 16b is of the tab nut type, the tabs of which are fixed to the ring 6 by the rivets referenced 17a and 17b in FIG. 4.

According to the preferred embodiment of the invention, that is to say the embodiment shown in FIG. 6, the screw 16a is introduced into the casing 1 and the ring 6 with a longitudinal inclination, the nut 16b having a shape adapted to receive the screw 16a thus inclined while having a solid support against the internal face of the core 20 of the ring 6.

According to another embodiment of the invention, shown in FIG. 7, the means for hooking the ferrule 2 with the ring 6 consist of a mortise 30b produced in each ferrule element 2 and a tenon 30a produced by the inner ends of the downstream 8 and upstream 7 wings of the ring sectors. Also, the connection without play of each ring sector with the housing 1 is achieved by means of a domed screw 32 inserted radially in the housing 1 and in the ring. This screw is introduced into a nut 34 of conical shape, the base of which, directed towards the ferrule, is in contact with the internal faces of the upstream and downstream wings. A lunule 36 is machined on the external face of each ferrule element. Also, when the screw 32 is tightened, its curved end is supported in the lunula 36, the nut 34 rises and, by its conicity, spreads the ring sector thus realizing the connection without play between the ferrule element 2 and the ring sector 6.

Also at each sector end, a conical nut 34 is positioned astride two sectors, thus allowing the sectors to slide relative to the rings as a function of thermal variations.

In Figure 8, there is shown a sliding support in axial section. This sliding support 11 consists of a screw / nut system in which the nut can move on support parts. More precisely, this screw / nut system comprises a screw 18a inserted in the casing 1 and in the projection of the sole 18b. This sole consists of a base and the projection located in the middle of the base. An opening 21 is made in the core 20 of the ring 6, large enough to allow the passage of the projection of the sole 18b which can thus be in contact with the internal wall of the casing 1.

A nut 18c secures the screw 18a in the sole 18b. The base of the sole 18b is supported on two support pieces, of which only the support piece 19a is visible in this figure 8. The projection of the sole 18b passing through the opening 21 of the core 20 and the base of said sole 18b being able to slide on the support pieces, a circumferential clearance of the ring 6 relative to the casing 1 is then possible. Such sliding supports 11 thus allow the movement of the ring 6 and therefore of the shell 2 as a function of thermal variations.

According to the preferred embodiment of the invention, the support piece 19a, as well as all the support pieces in the ring 6, are held integral with the ring by the clamping means 14, 15 which pass through the said pieces. supporting parts at their outer ends.

FIG. 9 represents a perspective view of the support pieces and of the sole of a sliding support. We therefore see, in this figure 9, the support pieces 19a and 19b having a wall, inclined at 45 ° relative to the radial direction, on which slides the base 18b 'of the sole 18b.

In this FIG. 9, we can clearly see the projection 18b '' of the sole 18b introduced into the opening 21. An arrow shows the clearance between the projection 18b '' and the core 20 of the ring 6. We have shown, in addition, schematically, the screw 18a inserted in the projection 18b '' and fixed by the nut 18c.

Figure 10 shows a perspective view of the joint between two ring sectors 6a and 6b. This joint is made in the middle of an opening 21 machined partly in the core 20 of the ring sector 6a and partly in the core 20 of the ring sector 6b.

In addition, the downstream wing 8 of the ring sector 6b has an extension tab 22b machined in said downstream wing 8; the downstream wing 8 of the ring sector 6a has an extension tab 22a symmetrical to the tab 22b; the legs 22a and 22b being complementary so as to fit into each other. Such a joining of the ring sectors ensures, by the covering produced on the downstream wings, a sealing of the ring.

In FIGS. 11 to 14, means for controlling the clearances between the stator and the rotor are shown in accordance with a second embodiment of the invention.

The means for controlling games in accordance with this second embodiment being mounted on a casing which is substantially identical to that on which the means for controlling the first embodiment are mounted, it was not considered necessary to append another view. of the high pressure compressor. Reference is therefore made to FIG. 1 for the general description of the casing 1 and of the shell elements 2 of the compressor.

FIG. 11 therefore shows a partial view of this casing 1 and of the shell 2 made integral by a fixed point and sliding supports. More specifically, this FIG. 11 shows a portion of casing 1 and a ferrule element 2d attached to its two neighboring ferrule elements 2e and 2f. This figure 11 shows, in addition, the means for controlling the clearances between the rotor and the stator. These means consist of a combination of a fixed point 10d and sliding supports 11e and 11f making it possible to make each ferrule element 2d, 2e or 2f integral with the casing 1 while providing it with circumferential flexibility.

The ferrule element 2d like all of the compressor ferrule elements is therefore fixed, in its center, to the casing 1 by a fixed point 10d constituted, as for the fixed point in FIG. 6, of a screw system / nut. More specifically, this screw / nut system comprises a screw 16d introduced into the casing 1 by a breakthrough. A nut 16e introduced between the ferrule element 2d and the casing 1 and fixed on said ferrule element 2d ensures the fixing of the screw 16d. The screw 16d thus fixed in the nut 16e ensures a fastening without play of the ferrule element 2d against the internal wall of the casing 1.

According to one embodiment of the invention, the nut 16e is of the tab nut type, the tabs of which are fixed to the ferrule element 2d by the rivets.

The sliding supports 11f and 11e are located symmetrically with respect to the fixed point 10d. They are above all located each at the junction of two shell elements. This embodiment has the advantage of ensuring that the ferrule 2 is circumferentially flexible relative to the casing 1 obtained by using the clearances between the different ferrule elements 2.

It can therefore be seen, in FIG. 11, that the sliding support 11f is positioned astride the ferrule elements 2d and 2f and the sliding support 11e is positioned astride the ferrule elements 2e and 2d.

More specifically, the sliding support 11f comprises two screws 40a and 40b introduced into the casing 1 by two separate holes and coming to be fixed in a double floating nut 42. This floating nut 42 comprises a sole 42a having two threaded holes in which the two screws 40a and 40b are screwed. This sole 42a is provided with two lateral sliding tabs 42b and 42c each supported by a respective support piece 44b and 44c.

In Figure 12, there is shown, in a perspective view, the double floating nut 42 with its sole 42a provided with sliding tabs 42b and 42c. In this figure, we can see the two threaded holes 42d and 42e in which the screws 40a and 40b are introduced.

This figure also shows the support parts 44b and 44c each comprising a notch 44a supporting the sliding tabs 42b and 42c. Each of these support pieces is integral with one of the shell elements. They can be attached to it, for example, by stirring.

As can be seen in this figure 12, these sliding tabs 42b and 42c have a slightly curved shape at their free end so as to prevent them from dislodging from the notches 44a.

Thus, when the ferrule elements expand, following thermal effects, the sliding parts integral with these ferrule elements slide along the sliding tabs of the floating nut, modifying the play between the ferrule elements.

It is specified all the same that, just as in the first embodiment of the invention, the screws of the fixed points, as well as the screws of the supports sliders are positioned at an angle of about 45 ° to the surface of the housing 1.

In Figure 13, there is shown a part of the sole 42a of a double floating nut 42 to show the mounting operation of the sliding support 11f.

In this FIG. 13, a part of the ferrule element 2f has also been shown on which a positioning support 46 is fixed. According to the embodiment shown in FIG. 13, this support 46 is a V in brazed sheet metal on the ferrule element 2f.

This support 46 is used for mounting the sliding support. For this, a tool screw 45 is introduced into the hole 42e, that is to say a headless screw shorter than the final screw 40b. This tool screw 45 is therefore introduced into the hole 42e until it is in abutment against the support 46 so as to keep the floating nut 42 fixed relative to the ferrule element. This screw 45 is then embedded in the sole 42a, which makes it possible to position the casing 1 around the shell without being hindered by the presence of the screw heads such as those of the screws 40a and 40b.

When the casing 1 is correctly positioned, the screw 40a is introduced into the second hole 42d of the sole 42a to maintain the casing in the chosen position.

The tool screw 45 can then be removed and replaced by the final screw 40b.

In FIG. 14, a second embodiment of the sliding support 11f has been shown, in which the sole 42a is held in a fixed position relative to to the ferrule element 2f by means of a clip 47. This clip 47 is fixed by its end 47 ′ to the radial wall 2f ′ of the ferrule element and partially surrounds the sole 42a so as to keep it fixedly against this wall 2f '.

In addition, except for the method of holding the floating nut on the ferrule, the second technique for mounting the sliding support remains identical to the first technique shown in FIG. 13 and described previously. It will therefore not be described again.

The second embodiment of the invention as just described provides circumferential flexibility to the shell by sliding of the shell elements relative to the casing 1 thanks to the sliding supports.

In addition, it allows relatively easy and rapid assembly, as well as reliable disassembly without risk of jamming since the nuts are momentarily fixed.

Claims (17)

Turbomachine comprising: - a ferrule (2) consisting of a plurality of ferrule elements (2a, 2b, ...) in the form of circular sectors each carrying on an inner face of the fixed vanes (4); and - a circular casing (1) surrounding the ferrule,
characterized in that each ferrule element is made integral with the casing by a fixed point means (10) and at least two sliding support means (11) located on either side of the fixed point means to ensure that the 'ferrule element circumferential flexibility. Turbomachine according to claim 1, characterized in that it comprises a support ring (6) housed between the casing and the shell and comprising a plurality of circular ring sectors (6a, 6b, ...) each fixed on the casing by means of a fixed point and sliding support means and having a U-shaped section whose opening is directed towards the ferrule, each ferrule element comprising hooking means (9a) capable of fitting together in at least one ring sector to secure said ring sector and the ferrule element. Turbomachine according to claim 2, characterized in that, each ring sector comprising an upstream wing (8) and a downstream wing (7), each of said upstream and downstream wings comprises first recesses (13) open radially towards the shell for providing circumferential flexibility to said ring sector. Turbomachine according to any one of claims 2 and 3, characterized in that each ring sector comprising an upstream wing (8) and a downstream wing (7), said upstream wing comprises second recesses (12). Turbomachine according to any one of claims 2 to 4, characterized in that it comprises clamping means (14, 15) bearing on either side of each ring sector to ensure that said sector is secured ring with the means for attaching the ferrule element. Turbomachine according to claim 5, characterized in that the clamping means comprise a screw (32) and a conical nut (34) inserted inside the ring sector and able to move apart during the introduction of the screw, the base of said nut then being in abutment on the internal faces of the ring sector. Turbomachine according to any one of claims 3 to 6, characterized in that the attachment means of each ferrule element constitute, with the ends of the upstream and downstream wings of the ring sector into which it is introduced, an assembly in dovetail. Turbomachine according to claim 4, characterized in that each fixed point means comprises a screw / nut system (16a, 16b) ensuring a play-free connection of a ring sector with the casing, the nut being introduced at the inside the ring by the second recess and placed in abutment on an internal face of the core (20) of the ring sector. Turbomachine according to claim 8, characterized in that the screw is introduced into the ring sector with an inclination close to 45 ° relative to the radial direction. Turbomachine according to claim 8, characterized in that the screw is introduced radially in the ring sector and the nut has a conical shape, the base of which is directed towards the ferrule. Turbomachine according to any one of Claims 2 to 10, characterized in that each sliding support means comprises: - A screw (18a) surmounted by a projection (18b '') which is introduced into the ring sector by an opening (21) made in the core of said ring sector; - a sole (18b) surmounted by a projection (18b '') which is pierced with a hole comprising on the wall a thread for receiving said screw and which crosses at least partially the opening of the core for be in contact with the housing; - Two support pieces (19a, 19b) arranged on either side of the hole in the sole and fixed to the ring sector so as to allow the sole to slide on the support pieces. Turbomachine according to claim 11, characterized in that the screw being introduced into the ring sector with a longitudinal inclination of angle α, the support pieces comprise a surface inclined at an angle α relative to the radial direction. Turbomachine according to any one of claims 3 to 12, characterized in that the first recesses of the downstream wing are closed by sealing plates (25). Turbomachine according to claim 13, characterized in that the downstream wing of each ring sector comprises, around the first recesses, grooves (26) in which the sealing plates are positioned and fitted. Turbomachine according to any one of Claims 3 to 14, characterized in that each downstream wing of a ring sector comprises, at one end, an extension tab (22a) and, at another end, a complementary extension tab (22b) ensuring an interlocking with overlap of said ring sector in the sectors of neighboring rings. Turbomachine according to claim 1, characterized in that each sliding support means is positioned astride two ferrule elements to keep them integral with one another. Turbomachine according to claim 16, characterized in that each sliding support means comprises: - two screws (40a, 40b) passing through the casing; - a sole (42a) located at the junction of the two ferrule elements between the casing and said ferrule elements, pierced with two threaded holes (42d, 42e) to receive the two screws and comprising sliding tabs (42b, 42c) arranged on either side of the holes; - Two support pieces (44b, 44c) located on either side of the holes in the sole and each fixed on one of the shell elements so as to slide along the sliding tabs of the sole.

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