WO2017089670A1 - Rotating electrical machine for a motor vehicle - Google Patents

Abstract

The invention relates to a rotating electrical machine (10) for a motor vehicle, comprising a rotor (105), and a casing (110) defining at least partially an enclosure (125) in which the rotor (105) is mounted to rotate about an axis (X). The rotating electrical machine (10) is characterised in that it comprises a single fan (130) secured to the rotor (105) so as to rotate therewith, and in that the casing (110) comprises two ventilation bearings (135, 150): a first bearing comprising at least one air inlet (140, 145); and a second bearing comprising at least one radial air outlet (160), such that the fan (130) generates a forced flow of cooling air inside the enclosure (125).

Description

 ROTARY ELECTRIC MOTOR VEHICLE MACHINE

TECHNICAL FIELD OF THE INVENTION

 The present invention relates to a cooling device by forced air circulation by a single centrifugal fan.

 The present invention finds a particularly advantageous application in the cooling of a rotating electric machine of a motor vehicle.

 The present invention applies to any rotating electrical machine including alternators, alternator-starters and 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. STATE OF THE ART

 Rotating electrical machines generally include a housing, a shaft, a stator and a rotor. The housing delimits at least in part an enclosure within which are disposed the shaft, the rotor fixed in rotation with the shaft and the stator mounted around said rotor. Rotating electrical machines dissipate some of their energy in the form of heat and often require a cooling system.

 The cooling can be provided by simple radiators, by forced circulation of air in the machine, by circulating a coolant in a sealed chamber in contact with the machine or by combination of several of these cooling means.

A system of the prior art is described in the patent No. FR 2717639 B1 which comprises a fan which causes an air flow axially to the shaft of the rotating electrical machine and which also comprises cooling means by circulation of a coolant in a peripheral annular chamber. In this prior art, the air cooling system comprises a fan, integral in rotation with the rotor, causing a forced air flow from axial inlet openings to axial outlet openings. The inlet and outlet openings are disposed at both axial ends of the housing of the rotating electrical machine. Thus, only the rotor benefits from the forced circulation of the air. This cooling system thus makes it possible to cool the rotor but not the stator.

 In another prior art air cooling system, the housing has radial openings. This air cooling system comprises most often two centrifugal fans axially opposed and integral in rotation of the rotor. Each fan causes a forced air flow from an axial inlet opening to a radial outlet opening for cooling the stator but not the rotor. These systems of the prior art with two fans emit a noise of aeraulic origin important of the order of 1 10 decibels.

 In addition, a rotating electrical machine makes an unpleasant noise to the human ear. The sound emitted by the rotating electrical machine in operation is a periodic wave which can be analyzed according to its components called harmonics. An acoustic analysis shows a higher level of decibels for at least one of the harmonics due to the symmetry of the polar wheel. This so-called emerging harmonic is an unpleasant sound to the human ear and increases the overall noise level emitted by the rotating electrical machine in operation.

 None of the current systems can simultaneously meet all the required requirements, namely to reduce the noise of aeraulic origin while having good cooling performance of the rotating electrical machine.

OBJECT OF THE INVENTION

 The present invention aims to remedy all or part of these disadvantages. The invention relates to a rotating electric machine for a motor vehicle comprising a rotor, a housing at least partly delimiting an enclosure inside which the rotor is rotatably mounted about an axis, the rotary electrical machine being characterized in that it comprises a single fan mounted on and secured in rotation to the rotor and in that the housing comprises two aeration bearings:

 a first bearing comprising at least one air intake opening and

a second bearing comprising at least one radial air outlet opening, so that the fan causes a forced circulation of a cooling air flow in the enclosure so that a same air flow circulates from the air inlet opening of the first bearing to the second bearing radial outlet air outlet. Thanks to these arrangements, the same flow of cooling air cools both the rotor and the stator. Thus, the device that is the subject of the invention makes it possible to reduce the noise of aeraulic origin while guaranteeing good cooling performance. Indeed, the use of a single fan and the fact that a single bearing has radially arranged air outlet openings allows a gain of the order of four decibels. The use of a single fan allows, in addition, a saving of space in the rotating electrical machine and also cost.

 According to one embodiment, the rotating electrical machine further comprises a stator comprising a stator body and an electric winding extending axially in the stator body and on either side of said stator body so as to form buns. and wherein one of said buns is disposed radially, at least in part, between the radial opening of the second bearing and the fan. This also makes it possible to improve the cooling of the electrical winding of the rotating electrical machine.

 In embodiments, the radial opening of the second bearing is arranged facing the fan.

 In embodiments, the first bearing has at least one radial air inlet opening.

 Thanks to these provisions, the forced air flow forced by the fan rushes into the radial openings of the first bearing and is expelled by the radial outlet openings of the second bearing.

 In embodiments, the first bearing has at least one axial opening of air inlet.

 Thanks to these provisions, the forced air flow forced by the fan rushes into the axial openings of the first bearing and is expelled by the radial outlet openings, opposite the fan, the second bearing.

 In embodiments, the first bearing comprises at least one axial air intake opening and at least one radial air inlet opening.

 Thanks to these provisions, the forced air flow forced by the fan rushes into the axial and radial inlet openings and is expelled by the radial outlet openings, facing the fan, the second bearing.

In an advantageous embodiment, the second bearing further comprises at least one axial opening of air inlet so that the fan causes a forced circulation of another flow of cooling air in the enclosure so that the other flow of air flows from said axial air intake opening of the second bearing to the radial outlet air outlet of the second bearing. This opening is located opposite an electronic assembly of the electrical machine so that a second air flow circulating between this axial opening and the radial outlet opening allows the cooling of the electronic assembly.

 Advantageously, the first bearing corresponds to the front bearing of the rotating electrical machine and the second bearing corresponds to the rear bearing of said machine. In this embodiment, the fan is located at the rear of the electric machine. The rear part of the machine having less space than the front part, it simplifies the realization of the machine.

 In embodiments, the fan is a centrifugal fan. In embodiments, the rotating electrical machine further comprises a plate integral in rotation with the rotor, the plate having a plurality of axial projections.

 The plate modifies the natural symmetry of the polar wheel on which the plate is placed. This allows a reduction of the noise without degrading the circulation of the air flow in the machine and thus the cooling performance.

 Thanks to these provisions, the plate makes it possible to reduce the number of decibels emitted by the harmonic due to the symmetry of the polar wheel and thus to reduce the discomfort to the human ear felt while listening to the rotating electrical machine. operation. The plate integral in rotation with the rotor comprises a plurality of projections which also make it possible to reduce the overall noise emitted by the rotating electrical machine during operation.

 In embodiments, the overall thickness of the plate is less than 4 millimeters. In particular, the thickness of the plate is less than 3.5 millimeters. In addition, the projections each have an axial height of less than 3 millimeters.

 Thanks to these provisions, the technical effect of reducing noise and at least one emerging harmonic can be obtained while ensuring a minimum space in the enclosure of the rotating electrical machine.

In embodiments, the axial projections are formed by extrusions made on the outer periphery of the plate. It is found experimentally that the so-called emerging harmonic emitted by the rotating electrical machine in operation corresponds to the harmonic of an order equivalent to the number of pairs of poles of the rotor of the machine, in particular for the symmetrical claw rotors.

 In embodiments, the number of projections is strictly greater than the number of pole pairs of the rotor of the rotating electrical machine.

 Thanks to these arrangements, the plate makes it possible to more effectively reduce the number of decibels emitted by the emergent harmonic of order corresponding to the number of pole pairs of the rotor and thus to reduce the overall noise of the machine.

 In one embodiment, the rotating electrical machine further comprises an electronic assembly mounted outside the enclosure.

 In one embodiment, the rotating electrical machine further comprises a liquid fluid cooling system such as water.

 In one embodiment, the rotating electrical machine forms an alternator, an alternator-starter or a reversible machine.

BRIEF DESCRIPTION OF THE FIGURES

 Other advantages, aims and particular characteristics of the present invention will emerge from the following nonlimiting description of at least one particular embodiment of the rotary electric machine forming the subject of the present invention, with reference to the appended drawings, in which:

 FIG. 1 represents, schematically and in perspective, a particular embodiment of the rotating electrical machine which is the subject of the invention;

FIG. 2 represents, schematically and in section, a particular embodiment of the rotating electrical machine according to the invention which comprises at least one radial opening on the first bearing,

 FIG. 3 represents, schematically and in section, a particular embodiment of the rotating electrical machine according to the invention which comprises at least one axial opening on the first bearing,

 FIG. 4 is a diagrammatic sectional view of a particular embodiment of the rotating electrical machine according to the invention, which comprises at least one axial opening and one radial opening on the first bearing;

FIG. 5 represents, schematically and in section, a particular embodiment of the rotating electrical machine which is the subject of the invention and which comprises at least one axial opening on the second bearing and at least one opening on the hood,

 FIG. 6 represents, schematically and in perspective, a particular embodiment of the noise reduction plate integral in rotation with the shaft and surmounting the rotor,

 FIG. 7 represents, schematically and in perspective, a particular embodiment of the noise reduction plate,

 FIG. 8 represents, in graphical form, the noise emitted by a rotating electrical machine in operation according to various embodiments of the invention and the noise emitted by a rotating electrical machine in operation of the prior art,

 FIG. 9 represents, in graphical form, the overall noise and the noise of a set of harmonics emitted by a rotating electrical machine in operation having no noise reduction plate and

 - Figure 10 shows, in graphical form, the overall noise and noise of a set of harmonics emitted by a rotating electrical machine in operation having a noise reduction plate.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION

 This description is given in a nonlimiting manner, each feature of an embodiment being able to be combined with any other feature of any other embodiment in an advantageous manner.

 As of now, we note that the figures are not to scale.

 FIG. 1 shows a rotary electric machine 10 of a motor vehicle comprising a rotor 105, a housing 1 10 delimiting at least in part an enclosure 125 inside which the rotor 105 is rotatably mounted about an axis X, the rotating electrical machine 10 being characterized in that it comprises a single fan 130, rotatably connected to the rotor 105 and in that the housing 1 10 comprises two bearings 135, 150 aeration:

 a first bearing comprising at least one opening 140, 145 for the entry of air and

a second bearing comprising at least one radial opening 160 of air outlet, so that the fan 130 causes a forced circulation of a cooling air flow in the enclosure so that a same air flow flows from the air inlet opening of the first stage to the radial opening of second bearing air outlet.

 The rotating electrical machine 10 comprises in particular a series of pole wheels rotatably connected to a shaft 191 of the rotor. Axis X is defined as the axis in which the rotor 105 is oriented and which also corresponds to the axis of the shaft 191.

 The rotor 105 is mounted inside the casing 1 10 so as to be surrounded by a stator 192. In this example, the rotor 105 is a claw rotor.

 In embodiments, the housing 1 comprises a front bearing 135 and a rear bearing 150 which are assembled together, in particular, the front bearing 135 corresponds to the first bearing and the rear bearing 150 corresponds to the second bearing.

 More specifically, the front bearing 135 is positioned on the side of a pulley 193 of the rotating electrical machine 10 and the rear bearing 150 is axially opposed to the front bearing 135, preferably on the side of an electronic assembly 194 of said rotating electric machine. The electronic assembly 194 is mounted on the rotating electrical machine 10 between the rear part of said machine, that is to say the rear bearing 150, and a cover 195. In other words, the electronic assembly 194 is not in the enclosure 125 defined by the two levels. The cover 195 protects the electronic assembly.

 In this example, the stator 192 comprises a body 196 in the form of a pack of sheets provided with notches for mounting an electrical winding. This winding passes through the notches of the body 196 and forms a front bun 197 and a rear bun 198 on either side of said body 196. This winding is obtained, for example, from a continuous wire covered with enamel or again from conductive elements in the form of bar such as pins connected together.

 In order to reduce the operating temperature of the rotating electrical machine 10, an air-cooling system comprises a rotatably mounted aeration means in the housing 1 and at least one air inlet opening and an outlet opening. 'air.

The aeration means is a single fan 130 integral in rotation with the rotor 105. The fan 130 is preferably a centrifugal fan which comprises a body and a series of blades extending substantially axially. In Embodiments the blades are each made of cut sheet metal. In other embodiments, the fan 130 is made of plastics.

 Thanks to the fan, the air enters the chamber 125, via at least one air inlet opening, by depression and is evacuated via at least one air outlet opening.

 In embodiments, the evacuation of the air sucked by the fan 130 is provided by at least one radial opening 160 formed in the housing 1 10, in particular on the rear bearing 150. By radial opening, it is meant that the air is discharged in a radial direction relative to the axis X of rotation. Preferably, the radial openings 160 are arranged at regular spacing around the perimeter of the rear bearing 150. In a variant, the openings 160 are arranged at a non-regular spacing. The outlet openings 160 are here arranged opposite the centrifugal fan 130.

 FIG. 2 shows a particular embodiment in which the front bearing 135 comprises at least one radial opening 145 for air entry and in particular a series of radial openings 145. Each opening 145 may, for example, be evenly spaced from other openings and be arranged radially around the bearing. In a variant, the openings 145 are arranged at a non-regular spacing.

 The flow of air cooling the rotating electrical machine, represented by an arrow in FIG. 2, then consists of a stream of air entering radially into the front bearing 135 while cooling the passage of the front bun 197 of the stator 192 and then flowing axially. in the enclosure of the casing 1 10 while cooling the passage of the rotor 105 to finally be expelled radially by the radial outlet openings 160 while cooling the rear bun 198 of the stator 192.

 FIG. 3 shows a particular embodiment in which the front bearing 135 comprises at least one axial opening 140 for the entry of air and in particular a series of axial openings 140. Axial opening means that the air is sucked in an axial direction relative to the axis X of rotation.

Each opening 140 may for example be disposed on the upper part of the front bearing 135. In embodiments, the openings 140 are disposed on the same radius of the upper part of the front bearing 135. Preferably, these openings 140 may be arranged substantially vis-à-vis the front bun 197 of the stator 192. The flow of air cooling the rotating electrical machine then consists of a flow entering axially on the front bearing 135 by cooling the passage of the front bun 197 of the stator 192, then flowing axially in the enclosure of the housing 1 10 while cooling to the passage. rotor 105 to finally be expelled radially through the outlet openings 160 while cooling the rear bun 198 of the stator 192.

 FIG. 4 shows a particular embodiment in which the front bearing 135 comprises at least one axial opening 140 and at least one radial opening 145. In this embodiment, the same air flow then has two inputs. air.

 FIG. 5 shows a particular embodiment in which the rear bearing 150 further comprises at least one axial opening 165 for the entry of air. In this embodiment, the cover 195 comprises at least one axial opening 155 of air inlet or radial not shown here. Preferably, the axial opening 155 of the cover is disposed facing the axial opening 165 of the bearing. In addition, the openings 165, 155 are here arranged opposite the centrifugal fan 130.

 Thus, in this embodiment, a second air flow cooling the rotating electrical machine consists of a flow of air entering axially via the axial openings 155, 165 by cooling the electronic assembly 194, to finally be expelled radially via the openings 160 by cooling the passage of the rear bun 198 of the stator 192.

 FIGS. 3, 6 and 7 show an embodiment in which the rotary electrical machine 10 further comprises a plate 170 integral in rotation with the rotor 105.

 Preferably, the plate 170 is fixed on the rotor 170 by welding. Alternatively, the plate 170 can also be fixed to the rotor by screwing, gluing or else be fitted on the shaft 191. In embodiments, the plate 170 is made of forged sheets, in other embodiments it is made of plastics material.

 The plate 170 comprises a disc-shaped element 171 fixed to the rotor

105 and arranged preferentially on one of the pole wheels of the rotor 105, in particular on the front side of the rotor, facing the pulley 193 of the rotary electric machine 10. The plate 170 has a plurality of axial projections 175 extending axially from the member 171. In embodiments, the axial projections 175 are formed for example by removal of material on a sheet disk. In embodiments, the axial projections 175 are formed by extrusions on the outer periphery of the member 171.

 The plate 170 modifies the natural symmetry of the rotor 105, due to the uniform circumferential distribution of the pole wheels, thus making it possible to reduce the noise without degrading the circulation of the air flow in the machine and thus the cooling performance.

 In embodiments, the thickness of the plate 170 is less than

4 millimeters and especially less than 3.5 millimeters. For example, the axial height of the projections 175 is less than 3 millimeters, in particular of the order of 2 millimeters, and the thickness of the element 171 is of the order of 1, 2 millimeters. The overall thickness of the plate 170 is, in this example, of the order of 3.2 millimeters.

 In embodiments, the number of projections 170 is strictly greater than the number of pole pairs of the rotor 105 of the rotating electrical machine. In the embodiment shown in FIGS. 6 and 7, the rotor has eight pairs of poles and the plate 170 has ten axial projections.

 FIG. 8 shows, in graphical form, the noise emitted by a rotating electrical machine in operation according to various embodiments of the invention 330, 335, 340 and the noise emitted by a rotating electrical machine in operation of the art. The noise emitted in decibels represented on the ordinate 305 is expressed as a function of the number of revolutions per minute of the rotating electrical machine 10 shown on the abscissa 310.

 For information, the ordinate axis 305 is graduated in a step of a decibel, a horizontal dotted line is drawn every five decibels.

 It is found experimentally a reduction of three to four decibels on the various embodiments of the rotating machine object of the invention in operation in comparison with a rotating electrical machine in operation of the prior art.

FIG. 9 and 10 show, in graphical form, the overall noise 420, 520 and the noise of a set of harmonics emitted by a rotating electrical machine in operation. In particular, the noise emitted by the rotating electrical machine according to the eight-order harmonic 425, 525 is observed. The bundle of other curves presented and not referenced corresponds to the noise emitted according to the harmonics of orders seven, nine, ten, eleven and twelve.

 The noise emitted in decibels on the ordinate 405, 505 is expressed as a function of the number of revolutions per minute of the rotary electrical machine shown in abscissa 410, 510.

 For information, the ordinate axis 405, 505 is graduated in a step of a decibel, a horizontal dotted line is drawn every five decibels.

 The rotating electrical machines analyzed in FIGS. 9 and 10 are similar. One, in Figure 10, comprising a noise reduction system according to the invention and the other, in Figure 9, not having.

 The rotary electrical machine analyzed in FIG. 9 and 10 comprises a rotor comprising eight pairs of poles.

 The graph presented in FIG. 9 presents the data measured on a rotating electrical machine which does not comprise a plate 170 integral in rotation with the rotor 105. There is a noise level for the harmonic of order eight, represented by the curve 425, higher than all the other harmonics measured. This noise according to the high order eight harmonic causes an increase in the overall noise emitted by the rotating electrical machine represented by the curve 420 and a discomfort for the human ear to hear the noise emitted by the rotating electrical machine in operation. .

 The graph presented in FIG. 10 presents the data measured on a rotating electrical machine in operation, similar to that measured in FIG. 9, but which further comprises a plate 170 integral in rotation with the rotor 105 comprising a plurality of axial projections.

 FIG. 10 shows a noise reduction for the order eight harmonic represented by the curve 525 as well as a reduction of the overall noise emitted by the electrical machine 10 comprising a plate 170, represented by the curve 520.

In embodiments, the air cooling system as previously described may be combined with another cooling system, including a water or oil cooling system. For example, one of the bearings may comprise a pocket in which a fluid circulates to cool the stator body 196. In another example, the rotating electrical machine may have a pocket in which circulates a fluid from cooling the electronic assembly 194 of said machine. This pocket may be arranged for example in a heat sink included in the electronic assembly 194. In a variant, said pocket may be disposed in the bearing closest to the electronic assembly 194.

 The present invention finds applications in particular in the field of rotors for alternator or reversible machine of a motor vehicle but it could also be applied to any type of rotating machine.

Claims

1. Rotary electric machine (10) for a motor vehicle comprising a rotor (105), a housing (1 10) delimiting at least in part an enclosure (125) inside which the rotor (105) is rotatably mounted around a axis (X), the rotating electrical machine (10) being characterized in that it comprises a single fan (130) mounted on and rotatably connected to the rotor (105) and in that the housing (1 10) comprises two bearings (135, 150) aeration:

 a first bearing comprising at least one opening (140, 145) for the entry of air and

 a second bearing comprising at least one radial opening (160) of air outlet,

so that the fan (130) causes a forced circulation of a cooling air flow in the enclosure (125) so that a same flow of air flows from the opening (140, 145) air inlet of the first bearing to the radial opening (160) of second bearing air outlet.

2. A rotary electric machine (10) according to claim 1, characterized in that it further comprises a stator (192) comprising a stator body (196) and an electric winding extending axially in the stator body. and on either side of said stator body so as to form buns (197, 198) and wherein one of said buns is disposed radially, at least in part, between the radial opening (160) of the second bearing and the fan (130).

The rotary electric machine (10) according to claim 1 or 2, wherein the first bearing has at least one radial air inlet opening (145).

The rotary electric machine (10) according to claim 1 or 2, wherein the first bearing has at least one axial air inlet opening (140).

The rotary electrical machine (10) according to claim 1 or 2, wherein the first bearing has at least one axial air intake opening (140) and at least one radial air inlet opening (145). .

The rotary electric machine (10) according to any one of the preceding claims, wherein the second bearing further comprises at least one axial air inlet opening so that the fan (130) causes forced circulation. another flow of cooling air in the enclosure (125) so that this other air flow flows from said axial air inlet opening of the second bearing towards the radial outlet opening of the second tier air.

The rotary electric machine (10) according to any one of the preceding claims, wherein the fan (130) is a centrifugal fan.

The rotary electric machine (10) according to any one of the preceding claims, wherein the first bearing corresponds to the front bearing (135) of the rotating electrical machine (10) and wherein the second bearing corresponds to the rear bearing (150). of said machine.

The rotary electric machine (10) according to any one of the preceding claims, which further comprises a plate (170) integral in rotation with the rotor (105), the plate (170) having a plurality of axial projections (175).

10. Rotating electrical machine (10) according to the preceding claim, wherein the thickness of the plate (170) is less than 4 millimeters.

1 1. A rotary electric machine (10) according to any one of claims 9 or 10, wherein the axial projections (175) are formed by extrusions made on the outer periphery of the plate (170).

12. Rotating electrical machine (10) according to any one of claims 9 to

1 1, wherein the number of projections (175) is strictly greater than the number of pole pairs of the rotor (105) of the rotating electrical machine.

13. A rotary electric machine (10) according to any one of claims 1 to

12, characterized in that it further comprises an electronic assembly (194) mounted outside the enclosure (125).

14. A rotary electric machine (10) according to any one of claims 1 to

13, characterized in that it further comprises a liquid fluid cooling system such as water.

15. Rotating electric machine (10) according to any one of claims 1 to

14, forming an alternator, an alternator-starter or a reversible machine.