WO2017037389A1 - Rotor for a rotary electric machine - Google Patents

Abstract

The present invention proposes a rotor for a rotary electric machine of a motor vehicle. The rotor (4), mounted rotatably about an axis (X), comprises at least one magnetic element (29) and one pair of pole wheels (17) each comprising: - a flange (18), - a plurality of claws (19) extending axially from said flange (18), comprising a claw body (22) having a defined claw length (A) between the flange (18) and a free end (23) of said claw body and comprising at least one maintaining lip (30) for a magnetic element (29) arranged contiguous to said claw body and facing an adjacent claw of the other pole wheel, the maintaining lip (30) extending axially along said lip length (B), said lip length (B) being less than said claw length (A).

Description

 ROTOR FOR ROTATING ELECTRIC MACHINE

The invention relates to a rotor for a rotating electrical machine. The invention finds a particularly advantageous application in the field of rotating electrical machines such as alternators or reversible machines. It will be recalled that a reversible machine is a rotating electrical machine able to work in a reversible manner, on the one hand, as an electric generator in alternator function and, on the other hand, as an electric motor in particular for starting the engine of the motor vehicle.

 A rotating electrical machine comprises a rotor rotatable about an axis and a fixed stator surrounding the rotor. In alternator mode, when the rotor is rotating, it induces a magnetic field to the stator which transforms it into electric current to power the vehicle electronics and recharge the battery. In motor mode, the stator is electrically powered and induces a magnetic field driving the rotor in rotation.

 The rotor has, here, a claw structure comprising an excitation winding and two pole wheels each comprising claws arranged to fit between two consecutive claws of the other pole wheel. The rotor further comprises a plurality of magnetic elements arranged respectively between two adjacent claws of two distinct polar wheels, that is to say in an inter-claw space. These magnetic elements are used in particular to prevent leakage of magnetic flux between the claws forming the magnetic poles. It has indeed been found that a large part of the magnetic flux created by the rotor coil passes through leak paths instead of crossing the air gap of the machine to cause the desired induction in the magnetic poles of the rotor. stator.

Each claw has a retaining lip of the magnetic element arranged opposite an adjacent claw of the other pole wheel. A magnetic element is then held by two lips holding two adjacent claws, each of the claws belonging to a separate polar wheel. These holding lips ensure the good mechanical retention of the magnetic element. However, these holding lips reduce the distance between two adjacent claws and thus reduce the inter-claw gap, which causes an increase in magnetic flux leakage between the two claws.

 Thus, the present invention aims to avoid the disadvantages of the prior art.

 The present invention therefore aims to provide a rotor provided with magnetic elements whose magnetic flux leakage between the claws are limited to improve the magnetic performance of the rotating electrical machine.

 For this purpose, the subject of the present invention is a rotor for a rotating electric machine of a motor vehicle. According to the present invention, the rotor is rotatably mounted about an axis and comprises at least one magnetic element and a pair of polar wheels each comprising:

 - a flask,

 a plurality of claws extending axially from said flange, comprising a claw body having a claw length defined between the flange and a free end of said claw body and comprising at least one holding lip of an arranged magnetic element; contiguously to said claw body and facing an adjacent claw of the other pole wheel,

said pairs of pole wheels being mounted such that each claw of a pole wheel extends towards the other pole wheel being arranged between the space between two consecutive claws of the other pole wheel,

said magnetic element being arranged between two adjacent claws of two separate pole wheels and held by two respective holding lips of the two adjacent claws,

at least one holding lip of the magnetic element extending axially over a length called lip length, said lip length being less than said claw length. The present invention makes it possible to increase the distance between the claw having the holding lip as defined and the adjacent claw facing this lip. It allows, in particular, to increase the minimum distance between the claw having the retaining lip and the adjacent claw. This minimum distance extends in a direction substantially perpendicular to the holding lip. Thus, leakage of the magnetic flux between the claws are reduced, while ensuring a good maintenance of the magnetic element.

 The present invention also makes it possible to remove a portion of the holding lip, relative to a holding lip of the prior art, which does not produce a mechanical holding effect of the magnetic element. Thus, as the amount of material is reduced, such a rotor is less expensive.

 Advantageously, the retaining lip extends from the flange. Indeed, the portion of the retaining lip which ensures a better mechanical retention of the magnetic element is the portion of said lip adjacent to the flange. Thus, for a given length of holding lip, it improves the maintenance of the magnetic element by positioning the holding lip adjacent to the flange.

 Advantageously, the holding lip is arranged contiguously with an outer radial surface of the claw body and extends, in a plane perpendicular to the axis, in an ortho-radial direction.

 Advantageously, the retaining lip has a lateral end facing the adjacent claw which extends along a straight line. This simplifies the process for producing said holding lip.

In an advantageous example of implementation of the present invention, the claw comprises, on an outer radial surface in a section plane perpendicular to the axis, at least one chamfered portion, said chamfered portion extending axially at least on a part of the retaining lip. This makes it possible to reduce the magnetic noise generated by the rotation of the rotor. In an advantageous embodiment, the lip length of a retaining lip of one claw is equal to the length of the lip of another retaining lip of an adjacent claw of the other polar wheel, said two lips holding means being arranged to maintain the same magnetic element. This simplifies the manufacturing process of a rotor and in particular the step of producing the pole wheels since the latter can be symmetrical.

 In another advantageous embodiment, the lip length of a holding lip of a claw is greater than the lip length of another holding lip of an adjacent claw of the other pole wheel, said two holding lips being arranged to maintain the same magnetic element. This embodiment is all the more advantageous as during rotation of the rotor, the displacement due to the vibrations of one of the pole wheels is greater than that of the other pole wheel. Thus, increasing the length of the holding lip of the polar wheel which has the greatest displacement makes it possible to maintain the magnetic element even better.

 Advantageously, the claw body comes from material with the associated holding lip. This makes it possible to simplify the method for producing the polar wheel.

 Advantageously, the claw comprises two retaining lips respectively arranged opposite two distinct claws of the other pole wheel. For example, the two separate claws are located on either side of the claw having the two holding lips. This allows to have more magnetic elements in the rotor to improve its magnetic performance.

In addition, advantageously, all the claws of a pole wheel and / or the other pole wheel has at least one holding lip. This makes it possible to simplify the method for producing the polar wheel. According to another embodiment, all the claws of a pole wheel and / or the other pole wheel has two holding lips. For example, the magnetic element is advantageously a permanent magnet. This improves the magnetic performance of the rotor while maintaining reduced costs.

 In one embodiment, a side surface of the claw, formed by the portion of the lateral surface located at an axial distance greater than the lip length and the surface of the holding lip at its first axial end, is a non-linear surface. that is to say, which does not extend along a line.

 In one embodiment, the retaining lip protrudes from the claw body.

 According to one embodiment, the portion of the lateral surface located at an axial distance greater than the lip length, forms, with the surface of the holding lip at its first axial end, an angle of between 80 ° and 160 °. More particularly, said angle is between 90 ° and 160 °. For example, said angle is between 10 ° and 150 °. In particular, the angle a is between 120 ° and 150 ° and for example of the order of 140 °.

 The angle measuring from the lateral surface located at an axial distance greater than the lip length to the surface of the holding lip at its first axial end in the clockwise direction. Such an angle simplifies the manufacturing process of the polar wheel. In particular, it makes it possible to simplify the demolding of the polar wheel after the forging step. In addition, the larger the angle, the easier the demoulding will be. In addition, the larger the angle and the more the gap between two adjacent claws is gradually reduced which increases the portion of the claw where magnetic flux leakage between the claws are reduced. However, if this angle is too large, the magnet may not be sufficiently maintained. We must therefore find a good compromise between the manufacture of the polar wheel, the loss of magnetic flux and the maintenance of the magnet.

The present invention furthermore relates to a method of manufacturing a rotor for a rotating electric machine of a motor vehicle, mounted rotatably about an axis and comprising at least one element magnetic and a pair of polar wheels. According to the present invention, the method comprises the following steps:

 a step of producing a first polar wheel,

a step of producing a second pole wheel, said pole wheels each comprising a flange and a plurality of claws extending axially from said flange and comprising a claw body having a claw length defined between the flange and a free end of said claw body,

 a step of forming, in at least one claw of a first polar wheel, at least one lip for holding a magnetic element,

 a step of forming, in at least one claw of a second polar wheel, at least one holding lip of a magnetic element,

said holding lips being arranged contiguously with said claw body and facing an adjacent claw of the other pole wheel,

 a step of mounting the two pole wheels and at least one magnetic element so that each claw of a pole wheel extends towards the other pole wheel by being arranged between the space existing between two consecutive claws of the other pole wheel and such that the magnetic element is arranged between two adjacent claws of two separate pole wheels and held by a holding lip of each of said two adjacent claws,

at least one forming step forming at least one holding lip of a magnetic element such that said lip extends axially over a length called lip length, said lip length being less than said claw length; .

Such a manufacturing method makes it possible to produce a rotor whose distance between the claw having the holding lip as defined and the adjacent claw facing this lip is increased. Thus, such an embodiment method makes it possible to realize, simply and inexpensively, a rotor whose leakage of the magnetic flux between the claws is reduced, while ensuring a good maintenance of the magnetic element. Finally, the present invention relates to a rotating electrical machine comprising a rotor as previously described.

 In addition, a rotating electrical machine as described above can advantageously form an alternator or a reversible machine.

 The present invention may be better understood on reading the following detailed description of examples of non-limiting implementation of the invention and of examining the appended drawings, in which:

 FIG. 1 represents, schematically and partially, a cross-sectional view of a rotating electrical machine according to an exemplary implementation of the invention,

 FIG. 2 represents, schematically and partially, a view of an external radial surface of a claw according to a first example of implementation of the invention,

 FIG. 3 represents, schematically and partially, a perspective view of a claw according to a second exemplary implementation of the invention,

 FIG. 4 represents, schematically and partially, a perspective view of a rotor according to the example of FIG. 2,

 FIG. 5 represents, schematically and partially, a perspective view of a rotor according to the example of FIG. 3,

 FIG. 6 represents, schematically and partially, a perspective view of a rotor according to a third example of implementation of the invention,

 FIG. 7 represents, schematically and partially, a perspective view of a rotor according to a fourth embodiment of the invention, and

 - Figure 8 shows, schematically and partially, a logic diagram of a method of manufacturing a rotor according to an exemplary implementation of the invention.

Identical, similar or similar elements retain the same references from one figure to another. FIG. 1 represents a rotating electrical machine 1 compact and polyphase, in particular for a motor vehicle. This rotating electrical machine 1 transforms mechanical energy into electrical energy, into alternator mode, and can operate in motor mode to transform electrical energy into mechanical energy.

 The rotary electrical machine 1 comprises a housing 2. Inside this housing 2, it further comprises a shaft 3, a rotor 4 integral in rotation with the shaft 3 and a stator 5 surrounding the rotor 4. The rotational movement of the rotor 4 is around an axis X. In the remainder of the description the radial, ortho-radial and axial orientations are to be considered with respect to this axis X.

 In this example, the housing 2 comprises a front bearing 6 and a rear bearing 7 which are assembled together. These bearings 6, 7 are of hollow form and each bear, centrally, a ball bearing 10, 1 1 respective for the rotational mounting of the shaft 3.

 A pulley 12 is fixed on a front end of the shaft 3, at the front bearing 6, for example by means of a nut bearing on the bottom of the cavity of this pulley. This pulley 12 makes it possible to transmit the rotational movement to the shaft 3.

 The rear end of the shaft 3 carries, here, slip rings belonging to a collector. Brushes belonging to a brush holder 8 are arranged so as to rub on the slip rings. The brush holder 8 is connected to a voltage regulator included in a rectifier bridge 9.

 The front bearing 6 and the rear bearing 7 may further comprise substantially lateral openings for the passage of air in order to allow the cooling of the rotary electric machine by air circulation generated by the rotation of a fan. before 13 on the front dorsal face of the rotor 4, that is to say at the front bearing 6 and a rear fan 14 on the rear dorsal face of the rotor, that is to say at the level of the bearing back 7.

In this embodiment, the stator 5 comprises a body 15 in the form of a pack of sheets with notches, for example of the semi type. closed or open, equipped with notch insulation for mounting the stator phases. Each phase comprises at least one winding 16 passing through the notches of the body 15 and forming, with all the phases, a front bun and a rear bun on either side of the stator body. The windings 16 are obtained, for example, from a continuous wire covered with enamel or else from bar-like conductor elements such as pins connected together. These windings 16 are, for example, three-phase windings connected in a star or in a triangle, whose outputs are connected to the rectifier bridge 9.

 The rotor 4 of Figure 1 is a claw rotor. It comprises two pole wheels 17. Each pole wheel 17 is formed of a flange 18 and a plurality of claws 19 forming magnetic poles. The flange 18 is of transverse orientation and has, for example, a substantially annular shape.

 This rotor 4 further comprises a cylindrical core 20 which is interposed axially between the pole wheels 17. Here, this core 20 is formed of two half-cores each belonging to one of the pole wheels 17.

 The rotor 4 comprises, between the core 20 and the claws 19, a coil 21 comprising, here, a winding hub and an electric winding on this hub. For example, the slip rings belonging to the collector are connected by wire bonds to said coil 21.

 The rotor 4 also comprises, at its outer periphery, magnetic elements interposed between two adjacent claws 19.

 When the electric winding is electrically powered from the brushes, the rotor 4 is magnetized and becomes an inductor rotor with formation of north-south magnetic poles at the claws 19. This inductor rotor creates an alternating induced current in the stator induced when the shaft 3 is rotating. The rectifier bridge 9 then transforms this AC induced current into a direct current, in particular to supply the loads and the consumers of the motor vehicle's onboard network as well as to recharge its battery.

Figures 2 and 3 illustrate, more specifically, a first and a second example of claw 19, respectively. The claws 19 are, each of preferentially trapezoidal shape and in particular shaped claw.

 Each of the claws 19 extends in an axial direction from the flange 18. Thus, the claws 19 of a pole wheel are directed axially towards the flange 18 of the other pole wheel, each claw 19 penetrating into the existing space between two adjacent claws of said other pole wheel, so that the claws 19 of the two pole wheels 17 are interleaved. Each claw penetrating between two consecutive claws of the other pole wheel forms two inter-claw spaces respectively on either side of said claw.

 Each claw 19 comprises a claw body 22. A claw body 22 thus extends in an axial direction, along a central axis Y of the claw body substantially parallel to the axis X, from the flange 18 to at a corresponding free end 23 of the claw body 22.

 The claw body 22 has an outer radial surface 24 facing the stator 5 respectively and an inner radial surface 25 facing the core 20, said surfaces 24, 25 being radially opposed and extending substantially axially. In addition, the claw body 22 has a first lateral surface 26 and a second lateral surface 27 extending radially between the inner and outer radial surfaces 24, 25 and, axially, between the flange 18 and the free end 23. Said first and second lateral surfaces 26, 27 are opposed with respect to an ortho-radial direction of the X axis. The claw has a trapezoidal shape in the sense that it defines two bases, respectively corresponding to the free end 23 and the other axial end arranged at the flange 18, and two sides respectively included in the two side surfaces 26, 27.

 In this example, the flange 18 has a chamfered surface 28 facing the stator. The outer radial surface 24 is contiguous with said chamfered surface 28.

The rotor 4 may comprise a magnetic element 29 inserted into an inter-claw gap of the rotor 4. Preferably, as illustrated in FIG. 4, the rotor 4 comprises several magnetic elements 29 inserted respectively in the inter-claw spaces. In particular, the rotor 4 may comprise a magnetic element for each inter-claw gap. Alternatively, the rotor 4 may alternatively comprise inter-claw spaces having a magnetic member 29 and empty claw spaces. The magnetic element 29 is, for example, arranged between two lateral surfaces of two respective claw bodies of two separate polar wheels. In an exemplary embodiment, the magnetic element

29 is a permanent magnet for example formed of rare earth or ferrite.

 A claw 19 which is intended to receive a magnetic element 29 further comprises a retaining lip 30 of said magnetic element. Thus, the magnetic element 29 is held by two holding lips

30 of the two adjacent claws 19 of two separate pole wheels 17. Each retaining lip 30 of a claw 19 is thus arranged contiguously with the claw body 22 and facing another adjacent claw of the other pole wheel. In addition, a retaining lip 30 is arranged to cover a portion of an outer radial surface of the magnetic member 29 held.

 In addition, the claw body 22 has a claw length A defined between the flange 18 and its free end 23. More specifically, the claw length A corresponds to the axial length of the outer radial surface 24.

 The retaining lip 30 extends, axially, between a first axial end 31 and a second axial end 32. Thus, the retaining lip 30 has a length of lip B defined axially between its two axial ends 31, 32. , the lip length B is less than the claw length A. In other words, the retaining lip 30 does not extend over the entire length of the claw body 22 nor over the entire axial length the magnetic element 29 maintained. Thus the magnetic element 29 is held in position only over part of its length.

Preferably, the retaining lip 30 extends axially from the flange 18. Thus, the second axial end 32 of said lip is in contact with the flange 18. Still preferably, the retaining lip 30 is arranged contiguously with the outer radial surface 24. More specifically, the retaining lip 30 is arranged on one of the lateral surfaces 26, 27 at the level of the outer radial surface and facing the stator 5.

 In addition, the holding lip 30 extends, in a plane perpendicular to the axis X, in an ortho-radial direction. Thus, the retaining lip 30 has a first lateral end in contact with the claw body 22 and a second lateral end 33, opposite in a direction ortho-radial to said first lateral end. This second lateral end 33 is opposite the adjacent claw 19. Preferably, the second lateral end 33 extends along a straight line.

 Preferably, the part of the lateral surface 26, 27, located at an axial distance greater than the lip length B, forms, with the surface of the retaining lip 30 situated at its first axial end 31, an angle α of between 80.degree. ° and 160 °, and in particular between 90 ° and 160 °. In particular, the angle a is between 120 ° and 150 ° and for example of the order of 140 °. In the example of Figure 2, the angle is equal to 135 °.

 A side surface of the claw 19, formed by the portion of the lateral surface 26, 27, located at an axial distance greater than the lip length B and the surface of the holding lip 30 located at its first axial end 31, is a nonlinear surface that is to say that does not extend along a line.

In the example shown in Figure 2, the claw 19 has a chamfered portion 34 which extends axially in a section plane perpendicular to the axis X, along an outer radial surface of the retaining lip 30 and preferably over the entire outer radial surface of said lip. As shown in FIG. 6, this chamfered portion 34 may also extend axially over a portion of the outer radial surface 24 of the claw body 22. In a variant, the claw may have no chamfered portion 34. Preferably, the claw body 22 is made of material with the associated holding lip 30. The claw 19 is monobloc. Still preferably, the pole wheel 17 is in one piece.

 In the embodiment shown here, the claw 19 of a pole wheel 17 comprises two retaining lips 30 respectively arranged opposite two consecutive claws of the other pole wheel. The claw 19 is in contact with two separate magnetic elements 29 held respectively by the retaining lips 30. This claw 19 may then have a single chamfered portion 34 or two chamfered portions 34 or not include a chamfered portion 34. In the case of a single chamfered portion, the latter is, for example, associated with only one of the two retaining lips 30, in the sense that the chamfered portion and the retaining lip 30 are disposed at the same side of the In the case where there are two chamfered parts, the latter are, for example, associated with the two respective holding lips 30. In addition, the holding lips 30 of the same claw 19 may or may not have equal lip lengths B.

 Preferably, all the claws 19 of a pole wheel and / or of the other pole wheel has at least one retaining lip 30. In particular, all the claws 19 of a pole wheel and / or the other pole wheel has two retaining lips 30.

 In addition, in the example shown in the figures, the holding lips 30 of the same magnetic element 29 are facing each other and extend in the same direction, that is to say following two respective straight lines that are parallel. Similarly, here, the holding lips 30 of the same claw 19 extend in directions which are symmetrical with respect to the central axis Y.

Various embodiments of the rotor will now be described. Figure 4 illustrates a first example of rotor 4 where a ratio of the length of lip B to the claw length A is between 0.70 and 0.95. In particular in FIG. 4, the length of lip B is equal to 0.80 times the length of claw A. Such an exemplary embodiment the advantage of increasing the inter-claw distance and thus reduce magnetic flux leakage while ensuring good forgeability of the holding lips.

 FIG. 5 illustrates a second example of rotor 4 in which the ratio of the length of lip B to the length of claw A is between 0.40 and 0.70. In particular in FIG. 5, the length of lip B is equal to half the length of claw A. Such an embodiment has the advantage of slightly increasing the inter-claw distance, with respect to example of Figure 4, and thus reduce a little more leaks magnetic flux.

 Figure 6 illustrates a third example of rotor 4 where the ratio of the length of lip B to the claw length A is between 0.05 and 0.40. In particular in FIG. 6, the length of lip B is equal to 0.20 times the length of claw A. Such an embodiment has the advantage of increasing even more the inter-claw distance, compared with the example of Figure 5, and thus to reduce ink more magnetic flux leakage and also allows a significant reduction in the amount of material used for the formation of said lips and therefore cost.

 Thus, in the examples shown in Figures 4, 5 and 6, the lip length B of a retaining lip 30a of a claw 19a of a pole wheel 17a is equal to the lip length B of another holding lip 30b of an adjacent claw 19b of the other pole wheel 17b, said two holding lips 30a, 30b being arranged to maintain the same magnetic element 29. In these examples, the pole wheels 17a, 17b are symmetrical .

FIG. 7 illustrates a fourth example of rotor 4 where the ratio of the length of lip B of the holding lips 30a of a first polar wheel 17a to the length of claw A is between 0.05 and 0.40 and where the ratio of the length lip B of the holding lips 30b of a second pole 17b on the claw length A is between 0.70 and 0.95. In particular in FIG. 7, the lip length B of the holding lips 30a is equal to 0.75 times the claw length A and the lip length B of the holding lips 30b is equal to 0.25 times the length of claw A.

 Thus, in the example shown in FIG. 7, the lip length B of a holding lip 30b is greater than the lip length B of another holding lip 30a, said two holding lips 30a, 30b being arranged to maintain the same magnetic element 29. In this example, the pole wheels are asymmetrical.

 The present invention further relates to a manufacturing method 100 of the rotor 4.

 This method 100 comprises a step 101 of producing a first pole wheel and a step 102 of producing a second pole wheel. These steps 101, 102 can be performed simultaneously. Each step 101, 102 for producing a pole wheel 17 can be subdivided into a first step of forming the flange 18 and a second step of forming the claw bodies 22. Preferably, the pole wheels 17 are made by forging.

 The method 100 further comprises a forming step 103, in at least one claw 19 of a first pole wheel, at least one retaining lip 30 and a forming step 104, in at least one claw 19 d a second polar wheel, at least one retaining lip 30. The step 103 and / or the step 104 is carried out in such a way that at least one of the retaining lips 30 extends axially over a length of lip B, this lip length being less than the length of claw A.

 Each step 103, 104 may comprise a forging step which is performed simultaneously with the step 101, 102 for producing the corresponding polar wheel 17. In particular, the steps 103, 104 can then be performed simultaneously with the step of forming the claw bodies 22. The holding lip 30 is then forged to directly have the desired lip length B.

As a variant, each step 103, 104 may comprise a forging step, carried out simultaneously with the step 101, 102 of producing the corresponding pole wheel 17, and then a machining step adapted to machine the retaining lip 30 to have a desired lip length B.

 Finally, the method 100 includes a step 105 for mounting the two pole wheels 17 and at least one magnetic element 29. The two pole wheels are mounted so that each claw of a pole wheel extends towards the other polar wheel being arranged between the space between two consecutive claws of the other polar wheel. The magnetic element 29 is mounted so that it is arranged between two adjacent claws 19 of two separate pole wheels 17 and held by a retaining lip 30 of each of said two adjacent claws 19. The magnetic elements 29 are inserted into the inter-claw space and are only held by the holding lips 30.

 The present invention also relates to a rotary electric machine 1, such as an alternator or a reversible machine, comprising a rotor 4 as previously described.

 The present invention makes it possible to enlarge the distance, in an ortho-radial direction, between the claws by reducing the axial length of the holding lips while guaranteeing good mechanical strength, especially in centrifugation when the rotor is rotating, magnetic elements .

 The present invention thus makes it possible to reduce magnetic flux leakage between the claws while at the same time offering a solution that is reliable and that makes it possible not to radically change the current design of the polar wheels, while maintaining optimal performance of the rotor. Thus, the magnetic performance of the rotating electrical machine is improved.

 The present invention finds applications in particular in the field of rotor alternator or reversible machine but it could also apply to any type of rotating machine.

 Of course, the foregoing description has been given by way of example only and does not limit the scope of the present invention which would not be overcome by replacing the various elements by any other equivalents.

Claims

1. Rotor for a rotary electric machine for a motor vehicle, rotatably mounted about an axis (X) and comprising at least one magnetic element (29) and a pair of pole wheels (17) each comprising:

 - a flange (18),

 a plurality of claws (19) extending axially from said flange (18), comprising a claw body (22) having a claw length (A) defined between the flange (18) and a free end (23) said claw body and having at least one retaining lip (30) of a magnetic element (29) arranged contiguously with said claw body and facing an adjacent claw of the other pole wheel,

said pairs of pole wheels (17) being mounted such that each claw of a pole wheel extends towards the other pole wheel being arranged between the space between two consecutive claws of the other pole wheel,

said magnetic element (29) being arranged between two adjacent claws (19) of two separate pole wheels (17) and held by two respective holding lips (30) of the two adjacent claws,

characterized in that at least one retaining lip (30) of the magnetic element (29) extends axially over a length called lip length (B), said lip length (B) being less than said length of said lip claw (A) and in that the part of the lateral surface (26, 27), situated at an axial distance greater than the lip length (B), forms with the surface of the holding lip (30) situated at its first axial end (31), an angle (a) between 80 ° and 160 °.

2. Rotor according to claim 1, characterized in that the angle (a) between 120 ° and 150 °.

3. Rotor according to claim 1 or 2, characterized in that the retaining lip (30) extends from the flange (18).

4. Rotor according to any one of claims 1 to 3, characterized in that the holding lip (30) is arranged contiguously with a radial outer surface (24) of the claw body (22) and extends, in a plane perpendicular to the axis (X), in an ortho-radial direction.

5. Rotor according to any one of claims 1 to 4, characterized in that the retaining lip (30) has a lateral end (33) facing the adjacent claw (19) which extends along a right.

6. Rotor according to any one of claims 1 to 5, characterized in that the claw (19) comprises, on an outer radial surface (24) in a cutting plane perpendicular to the axis (X), at least one chamfered portion (34), said chamfered portion (34) extending axially at least over a portion of the holding lip (30).

7. Rotor according to any one of claims 1 to 6, characterized in that the lip length (B) of a retaining lip (30a) of a claw (19a) is equal to the lip length (B ) of another holding lip (30b) of a claw (19b) adjacent to the other pole wheel, said two holding lips being arranged to maintain the same magnetic element (29).

8. Rotor according to any one of claims 1 to 6, characterized in that the lip length (B) of a holding lip (30b) of a claw (19b) is greater than the lip length (B ) of another holding lip (30a) of an adjacent claw (19a) of the other pole wheel, said two holding lips being arranged to maintain the same magnetic element (29).

9. Rotor according to any one of claims 1 to 8, characterized in that the claw body (22) is made of material with the holding lip (30) associated.

10. Rotor according to any one of claims 1 to 9, characterized in that the claw (19) comprises two holding lips (30) respectively arranged opposite two separate claws of the other pole wheel.

1 1. Rotor according to any one of claims 1 to 10, characterized in that all the claws (19) of a pole wheel and / or the other pole wheel has at least one retaining lip (30).

12. Rotor according to any one of claims 1 to 1 1, characterized in that the magnetic element (29) is a permanent magnet.

13. Rotary electric machine for a motor vehicle characterized in that it comprises a rotor (4) according to any one of claims 1 to 12.

14. A rotary electric machine according to claim 13, forming an alternator or a reversible machine.