FR3054742B1 - ROTOR FOR ROTATING ELECTRIC MACHINE - Google Patents

Abstract

The present invention provides a motor vehicle rotating electric machine rotor, said rotor (4) comprising: - a rotor body (22), - a shaft (3) on which the rotor body (22) is mounted, this shaft (3) comprising: - a mounting portion (23) for mounting a drive member (12), said driving member (12) being arranged to be coupled, directly or indirectly, for example via of a belt, to a combustion engine of the vehicle, - a shoulder (24) positioned between the rotor body (22) and the mounting portion (23) for the drive member, said shoulder (24) being arranged to allow axial positioning of the drive member (12) when the drive member is mounted on the shaft (3).

Description

ROTOR FOR ROTATING ELECTRIC MACHINE

The invention relates in particular 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, alternator-starters 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 for example to start 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 generally comprises a shaft extending along an axis, a collector mounted on a rear portion of the shaft, a rotor body mounted on the shaft and a drive member such as a pulley. mounted on a front part of the tree.

In such a rotor of the prior art, the rotor body is mounted on the shaft by inserting it through the front part of the shaft until it comes into contact with a projecting portion disposed on the rear part of said tree. Then inserted around the shaft a rod, then a rotational guiding member and finally a drive member, always in a direction from the front portion of the shaft towards the rear portion of the shaft.

A final step is then to tighten the drive member so as to prevent any axial displacement of one or the other of said parts mounted on the shaft and so as to ensure a good retention of said drive member in order to ensure transmission of the torque between the rotating electrical machine and the belt of the engine of the vehicle.

During this clamping step, the protruding portion disposed at the rear of the shaft serves as an abutment against which come to rest the different parts of the rotor. The surfaces in contact between the parts arranged between the projecting portion of the shaft and the drive member have an important role in controlling the tightening of said drive member. Each surface in contact has geometric defects, mainly related to the manufacture of parts. In addition, the different parts are each formed of a specific material resulting, for example, differences in hardness and coefficient of friction between the parts. All these geometrical defects and all these differences between the parts generate a poor robustness of the tightening of the drive member. This may therefore cause loosening of the drive member and impair the transmission of torque between the electric machine and the engine.

In addition, another disadvantage of this type of configuration is that the protruding portion at the rear of the shaft sinks into the rotor body during the clamping operation of the drive member. This is due both to the fact that the force applied during the clamping of the drive member is important to ensure good maintenance of the parts and the fact that the shaft has a harder material than the rotor body . In some cases, this depression may be of the order of a millimeter, which can cause problems of mechanical strength of the rotor.

In addition, in the case where the rotor body is formed by two pole wheels and a coil disposed between the pole wheels, the coil can oppose the clamping force of the drive member. There is then a gap between the two pole wheels, the latter are not blocked axially. The same situation also occurs when the pole wheels are separated from the core around which the coil is wound. There can then be two gaps between the core and the pole wheels respectively.

The present invention aims to avoid the disadvantages of the prior art.

Thus, the present invention aims to provide a rotor whose maintenance and good positioning of the drive member are guaranteed.

For this purpose, the subject of the present invention is therefore a rotor of a rotating electric machine of a motor vehicle. According to the present invention, the rotor comprises:

a rotor body,

a shaft on which the rotor body is mounted, this shaft comprising:

a mounting portion for mounting a driving member, said driving member being arranged to be coupled, directly or indirectly for example by means of a belt, to a combustion engine of the vehicle,

- A shoulder positioned between the rotor body and the mounting portion for the drive member, said shoulder being arranged to allow axial positioning of the drive member when the drive member is mounted on the tree.

The invention makes it possible to prevent the geometrical defects and the specificities of each piece stacked on the shaft, in particular the rotor body formed by the pole wheels and the core, from influencing the maintenance of the drive member. . Thus, having a shoulder serving as an axial stop positioned between the rotor body and the drive member makes it possible to increase the clamping force of the drive member in order to prevent the latter from becoming relax beyond a certain temperature. This helps to increase the reliability of the rotating electrical machine.

In addition, with the present invention, the rotor body no longer undergoes stress and is therefore no longer impacted by the clamping operation of said drive member. Thus, the present invention allows a better tightening of the drive member without risk of damaging the rotor body and therefore a better axial locking of the parts around the shaft. The mechanical strength of such a rotor is improved as well as its magnetic performance.

In addition, the present invention makes it possible to remove the ring and its insertion step around the shaft. This makes it possible to reduce the number of parts of the rotor and to simplify its manufacturing process.

According to an advantageous embodiment, the rotor body bears against the shoulder.

For example, the rotor body is positioned in axial contact with the shoulder which allows axial stopping of the rotor body in a direction towards the drive member.

According to an advantageous embodiment, the rotor body is positioned between the shoulder and a collector mounted on the shaft.

According to an advantageous embodiment, the rotor body is fitted on the shaft.

According to an advantageous embodiment, the rotor body is fitted on the shaft in a direction of the rear part of the shaft, that is to say close to the collector, towards the front part of said shaft; ie close to the drive member.

According to an advantageous embodiment, the shoulder and the shaft are monobloc. They are thus integral in rotation with respect to one another. This makes it possible to better guarantee the tightening of the drive member.

According to an advantageous embodiment, the shoulder is made of material with the shaft.

According to another advantageous example of embodiment, the shoulder comprises an insert attached to the shaft. In this example, the insert can be fixed on the shaft for example by welding, gluing or by screwing.

According to an advantageous embodiment, the shoulder extends radially projecting relative to the shaft.

According to an advantageous embodiment, the shoulder comprises an annular surface around the axis of rotation of the shaft, this face being for example substantially planar.

According to an advantageous embodiment, the drive member is tightly mounted on the shaft.

According to an advantageous embodiment, the mounting portion of the drive member of the shaft has a thread for screwing the drive member on the shaft. The drive member then comprises a threaded internal potion complementary to the thread of the shaft. For example, a nut makes it possible to tighten the drive member on the shaft.

According to an advantageous embodiment, the rotor further comprises at least one rotational guide member mounted on the shaft, said rotational guiding member being in particular positioned between the shoulder and the drive member.

According to an advantageous embodiment, the rotational guiding member is positioned between the shoulder and the drive member so as to be in axial contact with each of said elements.

According to an advantageous embodiment, the drive member is supported on the rotational guiding member.

According to an advantageous embodiment, the rotational guiding member comprises an inner ring and the shoulder extends radially over a distance between 0.95 and 1.05 times the radial distance between said inner ring and the shaft. This avoids damaging the rotational guiding member by clamping the drive member.

According to an advantageous embodiment, the shaft further comprises a knurling arranged to hold the rotor body. This makes it possible to guarantee the positioning of the rotor body without axial force being applied to said rotor body.

According to an advantageous embodiment, the knurling is a straight knurling, that is to say that it comprises axial ribs parallel to the axis of the shaft. This simplifies the maintenance of the rotor body. Alternatively, the knurling could be helical.

According to an advantageous embodiment, the drive member is a pulley.

According to an advantageous embodiment, the rotational guiding member is a bearing, such as a ball bearing or a needle bearing. In a variant, the rotational guiding member is a bearing with a smooth surface.

According to an advantageous embodiment, the rotor body is a pair of pole wheels. Alternatively, the rotor body is a stack of stacked sheets.

According to an advantageous embodiment, the shaft comprises a metallic material, in particular steel.

According to an advantageous embodiment, the shaft is formed by machining. Alternatively, the shaft may be struck or molded.

The present invention also relates to a method for manufacturing a rotating electrical machine as previously described. The method comprises the following steps:

- mounting a rotor body on a shaft in a direction from the rear of the shaft towards the front of the shaft,

- mounting a drive member on a mounting portion of said shaft in a direction from the front of the shaft towards the rear of the shaft so that a shoulder of the shaft is positioned between the rotor body and the drive member, said shoulder being arranged to allow axial positioning of the drive member and said drive member being arranged to be coupled, directly or indirectly for example via a belt, to a combustion engine of the vehicle.

According to an advantageous embodiment, the method further comprises a step of mounting a rotational guiding member on the shaft in a direction from the front of the shaft to the rear of the shaft so as to that it comes in support against the shoulder.

According to an advantageous embodiment, the method further comprises a step of clamping the drive member against the rotational guiding member.

The present invention also relates to a rotating electrical machine. The rotating electrical machine can advantageously form an alternator or an alternator-starter 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 sectional view of a shaft of FIG. 1.

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. This rotary electric machine 1 is, for example, an alternator, an alternator starter or a reversible machine.

The rotary electrical machine 1 comprises a housing 2. Inside this housing 2, it further comprises a rotor 4 and a stator 5 surrounding the rotor 4. The rotor 4 comprises a shaft 3 and has a rotational movement which is done around an axis X centered on the shaft 3. 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 carry, centrally, a respective rotational guiding member 10, 11 for the rotational mounting of the shaft 3.

A drive member 12 is mounted on a front end of the shaft 3, at the front bearing 6. It allows to transmit the rotational movement to the shaft 3 and is arranged to be coupled, directly or indirectly for example via a belt, to a combustion engine of the vehicle.

The rear end of the shaft 3 carries, here, slip rings belonging to a manifold 8. Brushes belonging to a brush holder (not shown) are arranged to rub on the slip rings. The brush holder is connected to a voltage regulator included in a rectifier bridge 9.

Throughout the description, the terms "front" as in the direction of the drive member 12 and "rear" as in the direction of the collector 8 will be understood.

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 exemplary embodiment, the stator 5 comprises a body 15 in the form of a pack of sheets with notches, for example of the semi-closed or open type, equipped with slot insulator for mounting an electric winding. 16. This winding 16 passes through the notches of the body 15 and form a front bun and a rear bun on either side of the stator body. This winding 16 is obtained, for example, from a continuous wire covered with enamel or from conducting elements in the form of bars such as pins connected together. The coil 16 is connected, for example, in a star or in a triangle.

In the example of Figure 1, the rotor 4 is a claw rotor. It comprises a rotor body 22 mounted on the shaft 3 and having 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 having, here, a winding hub and an electric winding on this hub. For example, the collector rings belonging to the collector are connected by wire bonds to said coil. The rotor 4 may also comprise magnetic elements such as permanent magnets interposed between two adjacent claws.

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.

The shaft 3 comprises a mounting portion 23 for mounting the drive member 12 and a shoulder 24 as shown in FIG. 2.

The shoulder 24 is positioned between the rotor body 22 and the mounting portion 23 so as to allow axial positioning of the drive member 12.

In the example of FIG. 2, the shoulder 24 protrudes radially relative to the shaft 3. It has an annular face 25 around the axis of rotation of the shaft, this face being for example substantially flat. The shoulder 24 further comprises a front face 26 and a rear face 27 each extending radially from the annular face 25 towards the axis X. In other words, the shoulder 24 forms a ring which is preferably extends over the entire circumference of the shaft 3.

The rotor body 22 bears against the shoulder 24, in particular the rotor body 22 bears against the rear face 27 of the shoulder 24. For example, the rotor body 22 is positioned in axial contact with the shoulder 24 which allows an axial stop of the rotor body 22 in a direction towards the drive member 12. In other words, the shoulder 24 serves as an axial stop when mounting the rotor body 22 on the shaft 3 in a direction from the back to the front of the tree.

The shoulder 24 and the shaft 3 are, here, monoblocks. They are thus integral in rotation with respect to one another.

In a first embodiment, the shoulder 24 is made of material with the shaft 3.

In a second embodiment, the shoulder 24 has an insert attached to the shaft 3. For example, the insert can be fixed on the shaft 3 by welding, gluing or by screwing.

The mounting portion 23 of the drive member 12 has, for example, a thread enabling the drive member 12 to be screwed onto the shaft 3. The drive member 12 then comprises a threaded internal potion complementary to the threading. of the tree.

In the example of Figure 1, the drive member 12 is mounted tightly on the shaft 3. For this, the drive member 12 is mounted on the shaft 3, for example by screwing, in a direction from front to back of the tree. Then, a clamping member 28, such as a nut positioned in the bottom of a cavity of the drive member 12, is mounted on the shaft 3 so as to clamp the drive member and thus to ensure axial positioning of each element located between said clamping member and the shoulder 24.

In the example shown in Figure 1, the drive member 12 is a pulley.

In the example of FIG. 1, the rotation guiding member 10 positioned at the front of the shaft 3 is positioned between the shoulder 24 and the drive member 12. The rotational guide member 10 is positioned to be in axial contact with each of said elements. In particular, the rotational guiding member 10 is in axial contact with the front face 26 of the shoulder 24 and the drive member 12 is supported on the rotational guiding member 10.

The rotational guiding member 10 comprises an inner ring 29 and an outer ring 30. The inner ring 29 is radially opposed to the outer ring 30 and is located on the side closest to the shaft 3, the outer ring 30 being located on the side closest to the front bearing 6.

The shoulder 24 extends radially over a distance between 0.95 and 1.05 times the radial distance between an outer face of said inner ring 29 and the shaft 3.

The rotational guide member is for example a bearing, such as a ball bearing or a needle bearing. Alternatively, the rotational guiding member may be a smooth surface bearing.

The rotor body 22 is positioned between the shoulder 24 and the collector 8 mounted on the shaft 3.

The shaft 3 further comprises a knurling 31 arranged to hold the rotor body 22. The knurling 31 is for example a straight knurling, that is to say that it comprises axial ribs parallel to the axis of the tree. In another example, the knurling 31 may be a helical knurling.

The shaft 3 comprises for example a metallic material, in particular steel. The shaft can be formed by machining, molding or being struck.

A method for manufacturing a rotating electrical machine as previously described is explained below. Such a method comprises the following steps:

- Mounting the rotor body 22 on the shaft 3 in a direction from the rear of the shaft towards the front of the shaft,

- Mounting of the drive member 12 on the mounting portion 23 of said shaft 3 in a direction from the front of the shaft towards the rear of the shaft so that the shoulder 24 is positioned between the rotor body 22 and the drive member 12.

The method further comprises a step of mounting the rotational guide member 10 on the shaft 3 in a direction from the front of the shaft towards the rear of the shaft so that it come to bear against the shoulder 24.

The method further comprises a step of clamping the drive member 12 against the rotational guide member 10.

The present invention makes it possible to prevent the rotor body from being deformed due to the insertion of the shaft into said rotor body during the clamping operation of the drive member. Thus, thanks to the invention, an upper clamping force can be applied to the drive member in order to reduce the risk of loosening of said member during operation of the rotating electrical machine without impacting the performance of said machine.

In addition, the present invention makes it possible to simplify the mounting method of the rotating electrical machine by eliminating a mounting step of a rod on the shaft.

The present invention is described herein for a claw rotor rotor. However, the present invention could also be applied to other types of rotor, such as for example a rotor formed of a stack of stacked sheets, providing the same advantages.

The present invention finds applications in particular in the field of rotating electrical machines for alternator, alternator starter 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 (12)

Rotor of a rotating electric machine of a motor vehicle, said rotor (4) comprising: a rotor body (22), a shaft (3) on which the rotor body (22) is mounted, this shaft (3) comprising: a mounting portion (23) for mounting a driving member (12), this driving member (12) being arranged to be coupled, directly or indirectly, for example by means of a belt, to a combustion engine of the vehicle, - a shoulder (24) positioned between the rotor body (22) and the mounting portion (23) for the drive member, said shoulder (24) being arranged to allow axial positioning of the drive member (12) when the drive member is mounted on the shaft (3), - At least one rotational guiding member (10) mounted on the shaft (3), said rotational guiding member (10) being in particular positioned between the shoulder (24) and the drive member (12). , the rotor being characterized in that the guide member comprises an inner ring (29) and in that the shoulder extends radially over a distance between 0.95 and 1.05 times the radial distance between said inner ring and the tree (3). 2. Rotor according to claim 1, characterized in that the rotor body (22) bears against the shoulder (24). 3. Rotor according to claim 1 or 2, characterized in that the shoulder (24) and the shaft (3) are monobloc. 4. Rotor according to any one of claims 1 to 3, characterized in that the shoulder (24) is made of material with the shaft (3). 5. Rotor according to any one of claims 1 to 3, characterized in that the shoulder (24) has an insert attached to the shaft (3). 6. Rotor according to any one of claims 1 to 5, characterized in that the shoulder (24) has an annular face (26) about the axis of rotation of the shaft (3), this face (26). ) being for example substantially flat. 7. Rotor according to any one of claims 1 to 6, characterized in that the shaft (3) further comprises a knurling (31) arranged to maintain the rotor body (22). 8. Rotating electric machine comprising a rotor (4) according to any one of claims 1 to 7. 9. rotary electric machine according to claim 8, forming an alternator or an alternator-starter or a reversible machine. 10. A method of manufacturing a rotary electrical machine according to claim 8 or 9, said method comprising the following steps: - mounting a rotor body (22) on a shaft (3) in a direction from the rear of the shaft towards the front of the shaft, -mounting a drive member (12) on a mounting portion (23) of said shaft (3) in a direction from the front of the shaft towards the rear of the shaft so that a shoulder (24) of the shaft is positioned between the rotor body (22) and the drive member (12), said shoulder (24) being arranged to allow axial positioning of the drive member and said drive member (12) being arranged to be coupled, directly or indirectly for example via a belt, to a combustion engine of the vehicle. 11. Manufacturing method according to claim 10, further comprising a step of mounting a rotational guide member (10) on the shaft (3) in a direction from the front of the shaft to the rear of the shaft so that it bears against the shoulder (24). 12. The manufacturing method according to claim 10, further comprising a step of clamping the drive member (12) against the rotational guiding member (10).