FR3069572B1 - ROTOR DARK FOR AN AIRCRAFT TURBOMACHINE - Google Patents

Abstract

A rotor blade (10) for an aircraft turbomachine, comprising a foot (12), a heel (14) and a blade (16) extending between the foot and the heel, said foot including a bulb (18) and a platform, said bulb being configured to be engaged in a cell of complementary shape of a rotor disk (32), and said platform being configured to partially delimit a stream of air flow in the turbomachine, characterized in that said bulb and said platform are connected together by connecting means (24) which are configured, when the blade is in the free state without stress, to: - allow an angular clearance of said blade vis-à-vis said bulb around a first longitudinal axis X of said foot, - prohibiting any angular displacement of said blade vis-à-vis said bulb about a second longitudinal axis Z of said blade, and - allow an angular movement of said blade screw-to -vis of said bulb around a third axis Y perpen to the first and second axes.

Description

Rotor blade for an aircraft turbomachine

TECHNICAL AREA

The present invention relates in particular to a rotor blade for an aircraft turbomachine.

STATE OF THE ART

[0002] The state of the art notably comprises the documents FR-A1-2 860 741, FR-A1 -2 980 234 and FR-A1 -3 027 622.

[0003] With reference to FIG. 1, a rotor blade 10 for a turbomachine, and in particular for a turbomachine turbine, comprises a foot 12, a heel 14 and a blade 16 extending between the foot 12 and the heel 14.

The foot 12 comprises a bulb 18 connected by a stilt 20 to a platform 22, itself connected to the blade 16. The bulb 18 is configured to be engaged in a cell of complementary shape of a rotor disk, the assembly formed by the disk and the vanes mounted at its periphery being called a rotor wheel.

The wheel or disk rotates about an axis of rotation, which is generally the longitudinal axis of the turbomachine, and the disk cells have a generally elongate shape whose axis of elongation is not parallel to this axis of rotation. Thus, the elongation axes of the bulbs of the vanes of the wheel are not parallel to the axis of rotation of the wheel.

The platforms 22 of the blades 10 extend around the disc and are intended to internally delimit a stream of air flow in the turbine engine or turbine. This vein is delimited externally by the heels 14 of the blades which are shaped to be nested circumferentially with each other. These heels carry protruding wipers which are intended to cooperate by friction with an annular layer of abradable material of a turbine casing, to form a labyrinth type sealing member.

In the current technique, the blades 10 are monobloc and mounted one after the other at the periphery of the disk. For this, the bulb of each blade is slidably engaged along the axis of elongation of the bulb in one of the cavities of the disc. When all the blades are mounted on the disk, each blade is constrained in torsion about a longitudinal axis of its blade, which is an axis substantially radial to the axis of rotation of the disk, and which is denoted Z axis. limits the vibrations of the blades in operation and ensures a good life of the wheel.

The torsional stress is achieved at the moment when the last blade is mounted on the disk between two adjacent blades. This latter blade and the adjacent blades are subjected to pretorations around their respective Z axes and are engaged in the cavities of the disc, which will cause twists of all the vanes of the wheel around their Z axes and result in a optimal wedging of the blades of the blades, which will fit into each other.

The Z axis belongs to a reference XYZ in which X is the longitudinal axis or elongation of the bulb and Y is an axis perpendicular to the X and Z axes. The XYZ mark is defined according to the orientation of the dawn, as shown in Figure 1 However, there are problems of perpendicularity as well as problems of disengagement and overlap of the blades of the blades in operation due to difficulties in mounting. The perpendicularity represents the difference between the actual position of an axis or plane of the blade and the theoretical position of this axis or plane. These problems occur when the blades are misaligned without being able to return to their original position. The misalignment can take place with respect to the X axis or the Y axis. These phenomena induce leaks in the vein and the non-vein part of the turbine, and premature wear of the blades.

The present invention provides a simple, effective and economical solution to this problem.

SUMMARY OF THE INVENTION

The present invention relates to a rotor blade for an aircraft turbomachine, comprising a foot, a heel and a blade extending between the foot and the heel, said foot comprising a bulb and a platform, said bulb being configured to be engaged in a cell of complementary shape of a rotor disk, and said platform being configured to partially delimit a stream of air flow in the turbomachine, characterized in that said bulb and said platform are connected together by means of connecting means which are configured, when the blade is in the free state without stress, to: - allow an angular displacement of said blade with respect to said bulb around a first longitudinal axis X of said foot, - prohibit any angular displacement of said blade with respect to said bulb around a second longitudinal axis Z of said blade, and - allow an angular movement of said blade with respect to said bulb around a third axis Y perpendicular to said first and second axes.

The invention thus proposes to give the blade two degrees of freedom along the X and Y axes, but not along the Z axis. It is thus possible to move the blade with respect to the bulb, and conversely, along the X and Y axes when mounting the blade on the disk. During assembly, the blade remains in fact in the free state without stress and its blade or bulb can be moved in two directions, a substantially axial direction (relative to the axis of rotation of the disk equipped with such dawn), about the Y axis, ie upstream or the leading edge of the blade, or downstream or the trailing edge of the blade, and a substantially tangential direction (by relative to the axis of rotation of the disc), around the axis X, that is to say towards the intrados or towards the extrados of the blade.

In the present application, the term "free state", the state of a room when it is not subject to external forces or constraints, particularly mechanical.

The blade according to the invention may comprise one or more of the following characteristics, taken separately from one another or in combination with each other: said connecting means are of the ball-and-socket type; said connecting means may be formed by one or more pieces; said connecting means comprise a ball carried by one of the elements selected from the platform and the bulb, and housed in a recess complementary shape of the other of these elements; said ball is connected to the platform by an element extending substantially along said second axis Z; Such an element may be a bar; said ball comprises a protruding finger housed in an elongated shape of the other of said elements, said finger being configured to cooperate by sliding along the light during a displacement of said blade vis-à-vis said bulb, around said first axis X, and to cooperate by abutment with lateral edges facing the light to prevent any displacement of said blade vis-à-vis said bulb, about said second axis Z; said finger extends substantially parallel to said third axis Y; said recess is delimited by two blocks fixed to one another and defining between them this recess. said recess is delimited by a fixed block and a sheet inserts and fixed on this block.

The invention also relates to an aircraft turbomachine rotor, comprising a disk having at its periphery an annular row of cells in which are engaged bulbous blade roots as described above, the blades being torsionally constrained about their second axes Z and their blades being held motionless about said X, Y and Z axes with respect to their bulbs.

The invention also relates to a method of mounting a rotor as evoked above, comprising a step of mounting each blade on the disc, by engaging the bulb of his foot in a cavity of the disk, the minus the last rise dawn being as defined above. The wheel may comprise one or more blades according to the invention, depending on the potential areas where mounting difficulties may be encountered.

The invention also relates to an aircraft turbomachine, comprising at least one rotor of the aforementioned type.

BRIEF DESCRIPTION OF THE FIGURES

The invention will be better understood and other details, features and advantages of the invention will appear more clearly on reading the following description given by way of non-limiting example and with reference to the accompanying drawings in which: FIG. 1 is a schematic perspective view of a rotor blade for a turbomachine; FIG. 2 is another schematic perspective and front view of a rotor blade for a turbomachine, and shows the degrees of freedom conferred. FIG. 3 is a very schematic partial view of a wheel according to the invention; FIGS. 4 and 5 are very diagrammatic views of one embodiment of the connection means for a blade according to FIG. FIG. 6 is a diagrammatic perspective view of a block of material intended to form part of a blade bulb; FIGS. 7 and 8 are diagrammatic views, respectively of side and above, the block of Figure 6, on which is fixed a sheet, and - Figure 9 is a top view of a blade bulb formed by fixing two half-blocks.

DETAILED DESCRIPTION OF AN EMBODIMENT

Figure 1 has been described in the foregoing.

Figure 2 shows a rotor blade 10 similar to that of Figure 1 and which includes all of its features.

According to the invention, the bulb 18 and the platform 22 of the blade 10 are connected together by connecting means 24 which are configured, when the blade is in the free state without constraint, to: - allow an angular deflection (arrow 26) of the blade 16 with respect to the bulb 18 around a first longitudinal axis X of the foot 12, - prohibit any angular deflection (arrow with cross 28) of the blade 16 vis-à-vis screw bulb 18 around a second longitudinal axis Z of the blade 16, and - allow an angular deflection (arrow 30) of the blade 16 vis-à-vis the bulb 18 about a third axis perpendicular Y axes X and Z.

The connecting means 24 are for example of the ball type, as is schematically shown in Figure 3. In this figure, the reference 32 designates a disk on which is mounted the blade 10. This figure shows that the bulb 18 is fixedly mounted vis-à-vis the disk and has two degrees of freedom vis-à-vis the blade 16.

Figures 4 and 5 show a more concrete embodiment of the ball joint means 24.

The connecting means 24 comprise a ball 34 which is here carried by the platform 22 and which is housed in a recess 36 of complementary shape of the bulb 18. This is advantageous from a manufacturing point of view because it is easier to make a recess in the most massive part of the dawn, namely his foot and in particular his bulb. Alternatively, the ball could be carried by the bulb and housed in a recess of the platform. In the example shown, the recess 36 opens onto the top of the bulb 18, that is to say on an upper surface opposite the platform 22.

The ball 34 is connected to the platform 22 by a bar 38 extending substantially along the axis Z.

The ball 34 comprises a projecting finger 40 housed in a light 42 of elongated shape of the bulb. The lumen 42 extends substantially along the axis Z. This finger is configured to cooperate by sliding along the lumen 42 during a displacement of the blade 16 with respect to the bulb, around the X axis and to cooperate by abutment with lateral edges 44 facing the light to prevent movement of the blade with respect to the bulb, about the Z axis. The finger 40 extends here substantially parallel to the Y axis.

The angular deflections around the X and Y axes are each of the order of +/- 1 °, preferably +/- 0.5 °, and more preferably +/- 0.15 °.

Figures 6 to 8 show an exemplary embodiment of a bulb 18 having the recess 36. The bulb 18 is here formed by a block of material 46 shown in Figure 6 and in which is formed a major part of the recess, as well as a plate 48 (see Figure 7) reported and fixed on the block 46. The plate 48 is here attached to one side of the block 46 and the recess 36 to close the latter laterally. The sheet 48 is for example fixed by brazing, welding or riveting on the block 46, the zones 50 representing the attachment areas.

In the embodiment of Figure 9, the bulb 18 is here formed by two half-blocks of material 52 which are fixed to one another and define between them the recess 36. The joint plane half-blocks 52 may be parallel to the X axis, which is the case of the plane P1, or parallel to the Y axis, which is the case of the plane P2. Advantageously, a configuration with the P2 joint plane allows the realization of two half symmetrical blocks. The half-blocks 52 are for example fastened together by brazing or welding at the joint plane P1, P2.

Once the vanes mounted on the disc, by fitting their bulbs in the form of complementary disk cells, the vanes are torsionally constrained about their Z axes, as mentioned in the foregoing. Because of this constraint and the different supports including blade heels between them, and the blade roots on disk spans, the degrees of freedom around the X and Y axes disappear. In other words, after mounting the blades on the disc, the stresses applied to the blades cause their blades are no longer free to move and are therefore immobilized vis-à-vis the three axes X, Y and Z.

The disc can only wear blades according to the invention. It could alternatively include some or even one, the remainder of the blades being monoblock and as defined in the prior art. The number and the position of the blades according to the invention on the disc depend in particular on the areas on the periphery of the disc where mounting difficulties could be encountered.

The invention provides many advantages over the prior art, because it allows in particular: to ensure in engine operation the correct position of the blades on the disc, to ensure in engine operation the correct position of the blades between them , to no longer have leaks between the gases of the vein and the off-vein part, not to limit the life of the blades associated with the wear of the phenomena of dislocation, overlapping heels, and perpendicularity of the blades, to increase the acceptance tolerances of the discs by reducing their disc discard rate, and to facilitate the respect of the axial clearances in the turbine.

Claims (11)

1. A rotor blade (10) for an aircraft turbomachine, comprising a foot (12), a heel (14) and a blade (16) extending between the foot and the heel, said foot comprising a bulb (18). ) and a platform (22), said bulb being configured to be engaged in a cell of complementary shape of a rotor disc (32), and said platform being configured to delimit in part a stream of air flow in the turbomachine , characterized in that said bulb and said platform are connected together by connecting means (24) which are configured, when the blade is in the free state without stress, to: - allow an angular displacement of said blade vis- said bulb around a first longitudinal axis X of said foot, - prohibit any angular displacement of said blade vis-à-vis said bulb about a second longitudinal axis Z of said blade, and - allow an angular movement of said blade vis-à-vis said bulb around a third axis Y perpendicular to said first and second axes. 2. blade (10) according to claim 1, wherein said connecting means (24) are of the ball type (34). 3. blade (10) according to the preceding claim, wherein said connecting means (24) comprises a ball joint (34) carried by one of the elements selected from the platform (22) and the bulb (18), and housed in a recess (36) of complementary shape to the other of these elements. 4. blade (10) according to the preceding claim, wherein said ball joint (34) is connected to the platform (22) by an element extending substantially along said second axis Z. The blade (10) according to claim 3 or 4, wherein said ball joint (34) comprises a projecting finger (40) housed in an elongated slot (42) of the other of said elements, said finger being configured to slidably cooperate along the light during a movement of said blade with respect to said bulb, around said first axis X, and to cooperate by abutment with side edges (44) facing the light to prevent any moving said blade with respect to said bulb about said second axis Z. 6. blade (10) according to the preceding claim, wherein said finger (40) extends substantially parallel to said third axis Y. 7. blade (10) according to one of claims 3 to 6, wherein said recess (36) is delimited by two blocks (52) fixed to one another and defining between them this recess. 8. blade (10) according to one of claims 3 to 6, wherein said recess (36) is defined by a block (46) fixed and a plate (48) attached and fixed on this block. 9. Aircraft turbine engine rotor, comprising a disc (32) having at its periphery an annular row of cells in which are engaged bulbs (18) of feet (12) of blades (10) of which at least one is as defined according to one of the preceding claims, the blades being torsionally constrained about their second Z axes and their blades (16) being held stationary around said X, Y and Z axes with respect to their bulbs. 10. A method of mounting a rotor according to the preceding claim, comprising a step of mounting each blade on the disc, by engaging the bulb of his foot in a cavity of the disk, at least the last blade mounted as defined by one of claims 1 to 8. 11. Aircraft turbomachine, comprising at least one rotor according to claim 9.