FR3034130A1 - SOUFFLANTE BLADE DISASSEMBLY - Google Patents

Abstract

The invention relates to a rotary assembly for a turbomachine, comprising: - a disc (114) arranged around an axis (A), having an outer periphery having an alternation of cells (120) and teeth (118), - blades (124) extending radially from the disk and whose feet (126) are axially engaged and retained radially in the cavities of the disk, according to the invention, the cells (120) each have a radially internal bottom consisting of at least one upstream portion (122A) and one downstream portion (122B), each inclination substantially zero with respect to the axis, the upstream portions of the cell bottoms being formed radially further inwards than the downstream portions cell bottoms, and a shim (116), having an outer face (116A) which marries the blade root (126) and an inner face (116B) which matches the cell bottom (122A, 122B), is interposed between each pair of dawn and cell bottom

Description

The invention relates to a particular mounting of the fan blades of a turbomachine on the periphery of the rotary fan disc. According to the known technique, a fan disk, connected to a rotary shaft of the turbomachine, has at its periphery a circumferential alternation of cells and teeth of substantially axial orientations. Fan blades extend radially from the fan disk into the vein of the turbomachine, to the inner wall of an annular nacelle which delimits the same vein externally. In order to maintain the fan blades, the latter each have at their inner end a foot axially engaged in the cavities of the disk and retained radially by the teeth of the disk. A shim is interposed between each blade root and the corresponding cell bottom, for the purpose of maintaining and preventing premature wear of these elements. The blades are secured and retained upstream by an upstream cone connected to the disk. This same cone constitutes the internal and upstream limit of the vein of gas circulation of the turbomachine.

Conventionally, the assembly or disassembly of the blades at the disc periphery is performed when the cone is disassembled. After the shims have been removed, the vanes are simply slid, exclusively in the axial direction, into the alveoli of the disk until they are fully inserted or extracted from the upstream. Indeed, the cooperation surfaces between the blades and the cells are substantially parallel to the axis of the turbomachine. This mounting or dismounting technique is the most suitable and the most used in the prior art to this document, because it has always had a vein diameter, formed by the inner wall of the nacelle, just upstream of the disc, sufficient to allow the unobstructed movement of the blade upstream of the disk when a portion of the blade root 3034130 2 is already engaged in one of the cavities of the disc. However, in a continuous process of optimization of the aircraft engines, implemented by the applicant, the shape of the nacelle is modified, and in particular, the diameter of the vein portion situated just upstream of the fan disk has been decreased relative to its diameter at the blower disc. This is directly caused by a reduction in the thickness of the nacelle and its axial length at the inlet of the turbomachine, in order to improve the drag of the moving turbomachine, as well as its total mass.

Therefore, as it is expected that the radially outer ends of the fan blades are closer to the inner wall of the nacelle, in the mounted position, to avoid any flow that would not contribute to the thrust of the turbomachine, the decrease in the diameter of the vein upstream of the fan disk prevents the assembly or disassembly of the blades. Indeed, since the feet of the latter are provided to be moved exclusively axially along the cells, the outer ends of the blades would then abut against the inner wall of the nacelle, upstream of the disc. The assembly or disassembly of the fan blades is thus made impossible. The present invention provides a simple, effective and economical solution to the problem mentioned above. To this end, it proposes a rotary assembly for a turbomachine, comprising: a disk arranged around an axis (A), having an outer periphery having an alternation of cells and teeth, blades extending radially from the disc and whose feet are axially engaged and retained radially in the cavities of the disk, characterized in that the cells each have a radially internal bottom comprising at least one upstream portion and one downstream portion, each inclination substantially zero relative to the axis, the upstream portions of the cell bottoms being formed radially further inwards than the downstream parts of the cell bottoms, a shim, having an outer face which marries the blade root and one face internal which marries the bottom of cell, being interposed between each pair 5 of dawn and alveolus bottom. The upstream portion of the cell bottoms is offset radially relative to the downstream portion of the cell bottoms, and is located further inland. One can for example imagine that the upstream and downstream parts of the cell bottoms are connected by radial steps. It is known to form the cell bottoms and the teeth of the disk with a substantially zero inclination with respect to the axis of the rotary assembly, and therefore of the turbomachine, in order to balance the rotating disk, and improve its mechanical strength. Preferably, the cell bottoms are oriented strictly parallel to the axis of the rotating assembly.

When the vanes are fully engaged in the disc's cells, in the operative position, they are supported both on the upstream parts and the downstream parts of the cell bottoms, via the wedges. In this functional position, the radially outer ends of the vanes will be as close as possible to the outer limit of the gas circulation duct of the turbomachine. The wedges marry the blade roots and the bottom of the cell in order to distribute a large part of the relative support and displacement constraints of the vanes with respect to the cells of the disc. Thus, by the term "embrace", we mean a complementary and intermediate shape, on the one hand with the dawning feet and on the other hand with the cell bottoms, in order to ensure between them the supports stable and without stress concentration that can cause mechanical deformations. When a blade is moved from the cell so as to be partially engaged by the upstream, and only radially facing the upstream portion of the cell bottom, and the wedge is also moved to the upstream so that it no longer radially fills the upstream portion of the cell bottom 3034130 4 inside the blade root, there then remains a radial space between the blade root portion remaining in the cell and the upstream part of the cell bottom. It is therefore possible to translate the blade radially inwards to fill this radial space, while the blade is still partially engaged in the cell. By this fact, it is possible to release an additional radial clearance between the radially outer ends of the vanes and the nacelle in which their mounting is provided, while the blades are not completely clear of the cells. This additional clearance makes it possible to disengage the vanes upstream of the cells without abutting the wall of the nacelle forming the outer limit of the vein. According to a particular embodiment, the rotary assembly constitutes a turbomachine fan stage, a turbomachine inlet cone being arranged upstream of the disk and retaining axially, from upstream, the blades. Input cone means the central and upstream member of a turbomachine, known to those skilled in the art, which forms the upstream and internal end of the gas flow stream. The entrance cone generally has a conical shape, but may also have a convex shape. According to another characteristic, the blade roots each have a radially inner surface substantially rectilinear depending on the orientation of the axis. This peculiarity gives the dawn feet a regular and relatively simple shape adapted to the complex manufacturing techniques of the blades. In addition, it ensures that the stresses generated by the wedge contacts are well distributed over all blade roots. Preferably, the blade roots each have a radially inner surface strictly rectilinear depending on the orientation of the axis.

Advantageously, the internal faces of the wedges protrude radially from the upstream portions of the cell bottoms, in order to fill the additional radial space created by the radial level difference between each downstream part and each part. upstream cell bottom, and therefore to marry properly each cell bottom. Preferably, the inner face of each of the wedges has at least two protruding ribs oriented substantially axially, and extending exclusively in radial vis-à-vis upstream portions of the cell bottoms. The shims and the blade roots may have substantially equal axial expanses to one another, and the axial ends of the shims and blade roots may further be substantially aligned. These characteristics both improve the role of damping and wedging wedges, and ensure a maximum distribution of constraints between the blade roots and the cell bottom. The invention further refers to a turbomachine input stage, comprising an annular nacelle whose inner wall surrounds the blades of the rotary assembly as described above. More particularly, at an axial distance upstream of the lower disc to the axial extent of the blade roots, the inner wall of the annular nacelle has a diameter smaller than the diameter of the rotating assembly as described above. The diameter of the rotary assembly is understood to mean the diameter of the circle including all the radially outer ends of the blades of the rotary assembly. In such a turbomachine inlet stage configuration, it is clearly understood that it is only possible to mount or dismount a blade in one of the cells by virtue of the particular characteristics of the invention. The invention also relates to a method of disassembly, downstream upstream, of a blade with respect to a disk, within a rotary assembly 30 of the aforementioned type or a turbomachine inlet stage also of the aforementioned type, with the particularities that : 3034130 6 - pulling parallel to the axis (A) of the disk, upstream, first the wedge alone, keeping the blade raised against the staves of said disk, - then the blade is lowered against the downstream part of the bottom of the cell considered, and is slid upstream, so that the blade is then placed in the bottom of said upstream portion of the bottom of the cell, - and then is slid l blade, parallel to said axis (A), upstream, to extract it completely from the cell . The invention also relates to a turbomachine fan disk having an axis of revolution and an outer periphery 10 having an alternation of cells and teeth of orientations substantially parallel to the axis of revolution, characterized in that the cells each have a radially inner bottom consisting of an upstream portion and a downstream portion, each inclination substantially zero with respect to the axis of revolution, the upstream portions of the cell bottoms 15 being formed radially further to interior than the downstream parts of the cell bottom. The invention finally relates to a turbomachine, such as a turbojet engine or a turboprop engine, comprising a rotary assembly as described in the present patent application.

Other advantages and characteristics of the invention will appear on reading the following description given by way of nonlimiting example and with reference to the appended drawings, in which: FIG. 1 is a partial diagrammatic view in axial section of a turbomachine inlet stage according to the prior art; Figure 2 is a perspective view of a fan disk according to the invention; Figure 3 is an enlargement of Figure 2 at a cell of the disc; FIG. 4 is a view from above in perspective of a shim adapted for mounting in one of the cells shown in FIGS. 2 and 3, according to the invention; FIG. 5 is a bottom view in perspective of a shim adapted for mounting in one of the cells shown in FIGS. 2 and 3, according to the invention; FIGS. 6A-6D schematically represent different steps associated with the method of moving a blade with respect to a disk, according to the invention, and FIGS. 7 and 8 schematize the mounting of a lock that is useful for the frontal retention of a dawn, then a hold. Reference is first made to FIG. 1, which shows a turbomachine inlet stage 10 according to the prior art. The stage is arranged around an axis A of central revolution, around which are arranged the different elements constituting the stage 10. The upstream is located in the figure on the left (AM), meaning where the flow comes from. crosses the turbomachine in operation. In contrast, the downstream (AV) is on the right. A rotary drive shaft 12 is arranged radially inside the stage. This shaft is conventionally driven by a turbomachine turbine further downstream. The shaft 12 transmits the rotational movement to the rotating parts of the input stage 10. As a result, a disc 14 is arranged around the shaft 12, and is rotatably connected thereto through the intermediate shaft. example of 20 flutes 12A, 14A. The disk 14 comprises at its outer periphery a circumferential alternation of teeth 18 and cells 20 which extend substantially parallel to the axis A. The radially inner walls of the cells are called cell bottoms 22. The funds of FIG. cell 22 extend here continuously from upstream to downstream of each cell, with a zero inclination with respect to the axis A. Blades 24, whose feet 26 are engaged axially in the cells 20 and retained radially by the teeth 18, extending radially around the disc 14. The wedges 16 are arranged between the cell bottoms 22 and the blade roots 26. The radially outer faces 16A of the wedges 16 embrace the blade roots 26 while the radially inner faces 16B of the wedges 16 follow the cell bottoms 22. These wedges 16 are relatively flat and extend over the entire length of the cell bottoms 22. A wedge is thus interposed between each foot of the base 22. dawn and the bottom of alv ole corresponding, for the purpose of holding and preventing premature wear. Platforms 28 furthermore extend circumferentially between each pair of adjacent blades 24, from upstream to downstream of the vanes 24, so as to form the internal boundary of a gas flow vein 30. of the turbomachine. A nacelle 32 surrounds the radially outer ends of the blades 24. More particularly, an annular wall 34 of the nacelle 32 forms the outer limit of the vein 30, and extends with a slight clearance around the outer ends of the vanes 24, so that to prevent that gases can flow from upstream to downstream radially between the blades 24 and the nacelle 32. A cone 36 is arranged upstream of the shaft 12, the disk 14 and the blade roots 26. The cone 36 forms the internal and upstream limit of the vein 30. For axial retention of the vanes 24 in the cells 20 of the disk 14, means 37 upstream axial retention of these vanes are furthermore advantageously provided. As will be described in more detail below, the means 37 may comprise an annular flange 38 referred to as the hood rear ferrule head and latches 40 (only one of them and part of the flange have been shown in FIG. 3).

Each blade 24 must be displaceable upstream of the cells 20, when the cone 36, the locks 40 and the annular flange 38 are disassembled, in order to engage or disengage its foot 26 relative to one of the cells 20, as it is represented by the dawn 24 'in broken lines. Conventionally, the nacelle 32 has a structure which corresponds to the solid line 32. In this configuration, when one of the vanes 24 is upstream of the cells 22 according to the position 24 ', it does not intersect the nacelle 32 and can therefore be engaged or unobstructed. On the other hand, according to another structure of the nacelle which corresponds to the discontinuous line 32 ', the annular wall 34' is bent further inwards upstream of the disc 14, because the nacelle is here shortened longitudinally (parallel to the axis AT). In this configuration, when one of the vanes 24 is upstream of the cells 22 according to the position 24 ', it intersects the nacelle 32' and can not be engaged or disengaged. A particular solution to this problem which illustrates the invention is described below.

The elements presented in the following figures, in connection with the invention, have reference numerals corresponding to those of their structural equivalents of FIG. 1, plus one hundred. With respect to the disk 14 described in FIG. 1, FIGS. 2 and 3 propose a disk 114, each cell bottom 122 of which consists of two axially-extending portions 122A and 122B, each of which is substantially zero in relation to the disk 14. to the axis A, similarly to the prior art. The upstream portion 122A of the cell bottom is however formed radially further inland than the downstream portion 122B of the cell bottom. The downstream portion 122B of the cell bottom corresponds in fact to the original cell bottom 15 of the disk, as has been described with reference to FIG. 1, and which is formed continuously at the side walls of the cell 120, and at the sidewalls 118a, 118b of adjacent teeth 118, also called spans or flanks. The upstream portion 122A of the cell bottom then corresponds to a recess of the cell bottom 122 which opens on the upstream face of the disk 114. Between the upstream portions 122A and downstream 122B of the cell bottoms, each of parallel inclination Axis A but offset radially relative to each other, radial steps 122C therefore appear. To maintain the blades 124 in the cells 120, a longitudinal shim 116 has been inserted upstream between each cell bottom and the corresponding blade root, thus stabilizing the position of the blade, radially. The means 37 upstream axial retention of the blades 124 in the cells 120 are furthermore advantageously present. In particular, the upstream ends of the cells are here closed on the one hand by the annular flange 38 and on the other hand individually by the respective latches 40. The annular flange 38 is assembled by screws 42 to the disc 3034130 10 or rim 114. Notches 128A, 128B may be provided in the side walls, respectively 118A, 118B, of the teeth 118 to hold the latches 40. It is shown in FIGS. Figures 4 and 5 a shim 116 adapted to the disk shown in Figures 2 and 3. The shim 116 is elongated 5 along a longitudinal axis 116C. It has a radially outer face 116A similar to what can be found in the prior art. This outer face 116A is flat so as to marry a blade root. On the other hand, the radially inner face 116B of the shim differs in that it has locally a protuberance formed of two ribs 138. The radially inner face 116B thus marries one of the cell bottoms 122, since the ribs 138 fill the gap. or the upstream part of the cell bottom 122A, when the shim 116 is placed on the cell bottom 122 and the non-protruding part of the inner face 116B matches the downstream part 122B of the cell bottom. The ribs 138 are then oriented along the axis A.

Thus, when a blade, similar to that of the prior art shown in FIG. 1, is arranged in one of the cells 120, the spacer effectively performs its maintenance and damping function: it relies homogeneously on the entire blade root and the entire cell bottom 122. Its shape is also there to prevent a loss of dawn. In fact, the wedge presents here favorably a section in an arc of a circle in order to follow the shape of the blade root and to move with it for example following a bird ingestion, which may have the consequence to generate significant efforts in the dawn foot in contact with the staves, in the cell. Figure 6 illustrates the reason why a rotating assembly consisting of disc 114, shims 116 and blades 124, according to the invention, solves the problem. It describes the different stages of disengagement of one of the blades 116 from upstream relative to one of the cells 120 of the disk 114. These steps can be reversed, so as to describe the engagement of the blade in the cell.

In a first step 6A, the blade 124 is in the state mounted in the cell 120 of the disk 114, by its foot 126, the wedge 116 being interposed between the blade and the cell bottom 122 as previously described. In order to achieve this state, the blade root concerned was held against the bearing surfaces (aforementioned lateral flanks of the adjacent teeth), then the corresponding shim 116 which thus came to block, or at least limit, the radial clearance of the blade root in the cell 120. In the following steps 6B to 6D disassembly is drawn parallel to the axis A, upstream, first the wedge 116 alone, maintaining the dawn raised against litters 118A, 118B. Then the blade is lowered against the downstream portion 122B and is slid upstream. The blade 124 is thus lowered so that it is then placed in the bottom of the upstream portion 122A, then it is slid upstream, still parallel to the axis A, to extract it completely from the cell. With the arrangement provided, a radial space has been released between the inner wall 116B of the wedge and the upstream portion 122A of the cell bottom.

Wedge 116 advanced to disengage the ribs 138 axially, it was therefore easy to translate the blade 124 radially inwardly by a distance J. In the last step 6D, after pulling the shim 116 towards Upstream, parallel to the axis A, the blade 124 has been thus displaced, so that these elements are then completely disengaged from the cell 120. As at the end of the displacement, the blade 124 is a distance J radially further inward than its mounted and functional position, the outer end of the blade 124 is no longer likely to abut against a nacelle 32 ', such as that of FIG. 1. The mounting or dismounting from dawn to 25 was made possible and safe. In FIGS. 7 and 8, a part of the assembly of one of the wedges 116 and of the corresponding lock 40 has been detailed. In Figure 7, we can assume a blade that has been put in place in its cell. The blade concerned here extends downwards, since the bottom of the cell 122 in question is at the top in both figures. When the time comes, before sliding the wedge 116 in parallel with the axis A, radially, the inside (INT) is slid radially from the inside (INT) to the latch 40 in the notches 128A, 128B (arrow 130, FIG. 7). The radial engagement is sufficient to leave an axial access opening 132 opposite the upstream portion 122A of the cell bottom free. This axial access opening 132 is adapted to allow the shim 116 concerned to pass through. longitudinally (axis 116C). In FIG. 8, lock 40 still in place in its notches, the wedge 116 has been slid frontally from the upstream (AM) and parallel to the axis A in the bottom of the cell 122 in question. It may be noted that the shim 116 has a frontal protrusion 116D which remains outside the cell and which serves in particular to lock the latch 40 radially inwards. In the embodiment provided, the frontal protrusion 116D, which here extends along the axis 116C, is even radially opposite one or more (here two) end protrusions 40A, 40B of the latch 40, parallel to the axis A, so as to increase the contact surfaces (radial retention) of the lock.

The subsequent front mounting of the annular flange 38 stabilizes all the shims, blocking them in their axial sliding. Disassembly takes place in reverse.

Claims (9)

REVENDICATIONS1. Rotary assembly for a turbomachine, comprising: - a disc (114) arranged around an axis (A), having an outer periphery having an alternation of cells (120) and teeth (118), - blades (124) s extending radially from the disk and whose feet (126) are axially engaged and retained radially in the cavities of the disk, characterized in that the cells (120) each have a radially internal bottom (122) comprising at least one upstream part ( 122A) and a downstream part (122B), each inclination substantially zero with respect to the axis, the upstream portions of the cell bottoms being formed radially further inwards than the downstream parts of the cell bottoms, a wedge (116), having an outer face (116A) which marries the blade root (126) and an inner face (116B) which marries the cell bottom (122A, 122B), being interposed between each pair of dawn and cell bottom. 2. Rotary assembly according to claim 1, characterized in that it constitutes a turbomachine fan stage, and comprises means (37) upstream axial retention of the blades (124) in the cells arranged upstream of the disk (114). and retaining axially from upstream said vanes (124). 3. Rotary assembly according to one of claims 1 or 2, characterized in that the blade roots (126) each have a radially inner surface substantially rectilinear according to the orientation of the axis (A). 4. Rotary assembly according to one of the preceding claims, characterized in that the inner face (116B) of each of the wedges (116) has at least two ribs (138) protruding oriented 3034130 14 substantially axially, and extending exclusively into vis-à-vis the radial upstream portions (122A) of the cell bottoms. 5. Rotary assembly according to one of the preceding claims, characterized in that the wedges (116) and the blade roots (126) 5 have axial extents substantially equal to one another. 6. Turbomachine inlet stage (10), comprising an annular nacelle (32 ') whose inner wall (34') surrounds the vanes (124) of the rotary assembly according to one of the preceding claims. 7. Turbomachine inlet stage according to claim 6, characterized in that, at an axial distance upstream of the disc (114) below the axial extent of the feet (126) of the blades (124), the inner wall (34 ') of the ring nacelle has a diameter smaller than the diameter of the rotary assembly according to one of claims 1 to 5. 8. A method of disassembling, downstream upstream, a blade (124) with respect to a disk (114), within a rotary assembly according to one of claims 1 to 5 or a turbomachine inlet stage according to one of claims 6 or 7, characterized in that: - the axis (A) is drawn parallel to the upstream direction, firstly the wedge (116) alone, in now the dawn lifted against spans (118A, 118B) 20 of the disc (114), - then the blade is lowered against the downstream portion (122B) of the bottom (122) of the cell (120) considered, and slide it upstream, so that the blade (124) is then placed in the bottom of said upstream portion (122A) of the bottom (122) of the cell, and then the blade is slid, parallel to the axis (A), upstream, to extract it completely from the cell. 9. Disk (114) of turbomachine blower, having an axis of revolution (A) and an outer periphery having an alternation of cells (120) and teeth (118) of orientations substantially parallel to the axis of revolution , characterized in that the cells each have a bottom (122) radially internal consisting of an upstream portion 3034130 (122A) and a downstream portion (122B), each inclination substantially zero with respect to the axis of revolution, the upstream portions (122A) of the cell bottoms being formed radially further inland than the downstream portions (122B) of the cell bottoms.