WO2020260711A1 - Electrical machine comprising a bearing and a closure member for same - Google Patents

Abstract

One aspect of the invention relates to a rotating electrical machine having an axis X and comprising at least: - a bearing (1) having a transverse wall (12) and a skirt (11) extending axially from the transverse wall, phase passage openings (123) being distributed in a peripheral region of the transverse wall (12) of the bearing (1), - at least one closure member (2, 2') which is mounted on the transverse wall (12) of the bearing so as to partially close off at least one phase passage opening (123), and which extends over an angular range of less than 360°.

Description

DESCRIPTION

TITLE: Electric machine comprising a bearing and its shutter

TECHNICAL FIELD OF THE INVENTION

The technical field of the invention is that of electrical machines, in particular in the automotive field, comprising bearings comprising phase output louvers for the passage of the phase outputs of a stator winding to an electronic device of the machine. The electric machines can in particular be alternators and alternator-starters.

TECHNOLOGICAL BACKGROUND OF THE INVENTION

[0002] Electrical machines are known comprising a stator comprising a winding comprising a chignon and phase outputs, a rotor surrounded by the stator, a rear bearing and a front bearing surrounding the stator. The rear bearing comprises phase output louvers through which the phase outputs of the stator winding pass. The electrical machine comprises an electronic device comprising a voltage converter, for example a rectifier or / and inverter, and a control and management unit of the electrical machine. The electronic device includes a heat sink to cool all the electronics in the electronic device. The heat sink includes fins extending from a wall of the heat sink to a transverse wall of the rear bearing. The transverse wall of the rear bearing comprises axial ventilation openings which pass through and open axially towards the rotor and towards the heat sink and phase output passage louvers crossed by the phase outputs of the winding to be connected to the electronic device. The rotor includes a rotor shaft supported in a bearing secured in a front and rear bearing bracket. The friction of the rotor shaft bearing in the bearing heats up the bearing.

The air sucked in by the fan is introduced radially from the outside and licks the fins of the heat sink of the rotating machine then passes through the openings of the rear bearing to be ventilated by the fan and ejected by the radial vents of the bearing .. The rotor includes a fan which draws air axially through the axial ventilation holes licking the fins of the heat sink and discharges at least part of the air drawn in through the radial holes of the rear bearing while cooling. part of the chignon of the stator winding. The electronic device may include a temperature sensor to make it possible to evaluate the efficiency of the machine but also to prevent the electric machine from exceeding a maximum temperature. This is particularly the case during repeated use of the machine at maximum power.

It is known to mount a ring-shaped shutter mounted axially sandwiched between the heat sink and the bearing in order to reduce the looping of hot air coming from the stator winding to the electronic device at the level of the outlet passage openings phase. The ring-shaped shutter may extend slightly over the vents while allowing the phase outputs to pass. The ring may further include a cap or petals to improve efficiency against hot air re-looping. The shutter is mounted axially on the bearing by radially inserting the phase outputs into openings in the shutter and then connectors, such as lugs, are attached to the ends of the phase outputs.

[0005] However, with such a ring-shaped shutter, the bearing does not cool down quickly and the heat conduction resistivity of the heat sink is increased due to the short fins, which may contribute to the rise in the temperature of the electric machine beyond the maximum temperature which may prevent the use of the electric machine at maximum power. Also, due to these ring-shaped shutters, especially when the machine is not turned on (engine off), the ring-shaped shutter may prevent the bearing from cooling or limit the thermal conductivity performance of the heat sink. resulting in slower cooling of the winding and therefore a reduction in the efficiency of the electrical machine the next time the vehicle is started. The more the stator winding is cooled, the better the efficiency of the machine and the more powerful the electronic device of the machine, the more efficient the heat sink must be.

[0006] In order to reduce the pollution of a vehicle, there is a need to have improved yields of electric machines while having more powerful electric machines.

SUMMARY OF THE INVENTION

[0007] The invention offers a solution to the problems mentioned above, by making it possible to increase the surface of the bearing licked by the ventilated air. [0008] One aspect of the invention relates to an X axis rotary electrical machine comprising at least:

a bearing comprising a transverse wall and a skirt extending axially from the transverse wall, phase passage openings being distributed in a peripheral zone of the transverse wall of the bearing,

at least one shutter mounted on the transverse wall of the bearing so as to partially shut off at least one phase passage opening, and in which the shutter extends angularly over less than 360 °.

Thanks to the invention, the shutter makes it possible to avoid re-looping of hot air through the phase passage vents while allowing the ventilated air to be able to lick an entire radial portion of the bearing which was covered by the ring-shaped shutter in the prior art.

[0010] In fact, part of the air sucked in passing through the axial ventilation openings can be expelled by the fan passing through the phase output passage louvers. Thus, the shutter makes it possible to reduce that part of the air drawn in by the fan comes from the phase outlet orifice vents. Thus, by reducing this looping air, it promotes the intake of air from the outside that is less hot than that looping through the phase outlet passage vents.

[001 1] In addition, the fact that the shutter does not make 360 ° allows on the one hand that part of the air drawn in from the outside licks part of the peripheral zone of the bearing is all a radial portion of the bearing while in the prior art part of this radial portion between the internal radius of the shutter and the external radius of the bearing was covered by the shutter. Licking this peripheral zone improves the cooling of the bearing. In addition, this enables the dissipator to be able to have longer fins in this peripheral zone and thus to be able to have electronics which are better cooled by the dissipator and therefore a more efficient and potentially more powerful electrical machine.

[0012] In addition to the characteristics which have just been mentioned, the electric machine may have one or more additional characteristics among the following, considered individually or in any technically possible combination:

According to one embodiment, the shutter extending angularly over less than 180 ° and comprises notch-shaped openings which open to the outer periphery. This facilitates assembly. Indeed, the shutter can be mounted without axial mounting, for example radially or / and by pivoting. The shutter is therefore more easily mounted and the machine is therefore less expensive. In addition, the phase outputs can be attached to a connector, for example a terminal, before placing the shutter, even if the opening is smaller or close to the size of the connector.

According to one embodiment, the shutter comprises an inner radius and an outer radius and in that the difference between the inner radius and the outer radius is at least two times smaller than an outer radius of the transverse wall of the bearing. This makes it possible to have a large area of the transverse wall which can be cooled.

According to one embodiment, the shutter mounted on the transverse wall of the bearing covers less than 50% of the area of the transverse wall of the bearing. This makes it possible to have a large area of the transverse wall cooled by the ventilated air and thus have better thermal conductivity between the latter and the ventilated air.

According to one embodiment, the shutter extends radially between an inner edge comprising an inner radius and an outer edge comprising an outer radius and angularly between two side edges connecting the inner edge to the outer edge, and in which the angular distance between a lateral edge and the ear closest to the lateral edge of the bearing partially closed by said shutter being less than the distance between the passage opening phase output closed and another passage opening phase output closest to the blocked hearing. This increases the area of the transverse wall which can be cooled by the incoming air.

According to one embodiment, the machine further comprises a heat sink mounted on the bearing opposite an external face of the transverse wall of the bearing partially covered by the shutter.

According to an example of this embodiment, the heat sink is provided with fins oriented substantially along the X axis and directed towards the outer face of the transverse wall of the bearing, in which at least one of the fins is arranged opposite the shutter and has a height vis-à-vis the shutter along the X axis that is smaller than at least one other fin arranged opposite the external face of the transverse wall. This maximizes the heat exchange between the air and the heat sink and therefore improves its cooling by having longer fins.

According to this example of this embodiment, at least one of the fins arranged opposite the shutter has:

a first portion facing the shutter having the first height along the X axis and

a second portion facing the outer face of the transverse wall having a second height greater than the first height.

The first portion and the second portion extend radially and axially and are separated from each other radially.

According to one embodiment, the shutter comprises a body facing the transverse wall comprising at least one portion covering the hearing to close off the phase passage opening and at least one phase passage opening arranged next to at least one phase passage louver for the phase output passage.

According to one example, the covering portion comprises the shutter also being provided with at least one petal extending into the opening, the petal being formed of a removable material, the petal at least partially closing the opening. This improves the plugging of the passageway while facilitating the mounting of the output phases through the shutter. Indeed, in the case where the shutter comprises an opening having the shape of a hole or a notch for the passage of the phase outputs, the hearing is less blocked than by the petals and can moreover be more difficult if the notch or hole is too close to the diameter of the phase output.

According to one example, the shutter comprises a projection extending axially along the X axis from the body, the shutter being sandwiched between the fins of the heat sink resting on said projection and an internal surface of the body resting on the body. transverse wall of the bearing. This makes it possible to maintain the shutter axially in a simple manner while making it possible to take up an assembly clearance. According to this example and the embodiment comprising a heat sink, the projection is elastically deformed by one end of a fin thus calling the shutter against an outer surface of the transverse wall.

According to one example, the shutter comprises at least one retaining wall extending axially from the body along the X axis into the gill. For example in the case of the previous embodiment, the wall extends axially along the X axis outwards, for example towards the heat sink. According to another example, in the case where the shutter is mounted on the outside face of the transverse wall, the wall extends axially along the X axis towards the bun.

According to an implementation of this example, the retaining wall comprises at least one angular stop portion extending radially along a radial edge of the phase passage louver.

According to one implementation, the retaining wall comprises a radial wedging portion extending along an angular edge with respect to the X axis in the gill. The first portion allows positioning during assembly and maintaining angularly and the second portion allows the shutter to be positioned radially during assembly and hold the shutter against the bearing.

In one example, the shutter includes an air blocking wall extending axially towards the heat sink from the body. This allows the wall to limit the re-looping of hot air even better.

According to one embodiment, the shutter is mounted on an outer face of the transverse wall.

According to a variant of the previous embodiment, the shutter is mounted on an internal face of the transverse wall between the bun and the transverse wall.

According to one embodiment, the shutter closes three phase output passage openings.

According to one example, the electrical machine comprises two shutters opposed to each other angularly and in that the two shutters each shut off at least three phase output passage openings.

According to one embodiment, the bearing comprises a plurality of axial ventilation openings facing the rotor. The invention and its various applications will be better understood on reading the following description and on examining the accompanying figures.

BRIEF DESCRIPTION OF THE FIGURES

[0014] The figures are presented as an indication and in no way limit the invention.

Figure 1 shows a schematic representation of a three-dimensional view of a portion of a bearing and a shutter of an electric machine according to a first embodiment.

Figure 2 shows a three-dimensional view of a portion of the bearing of an electrical machine.

Figure 3 shows a representation of a three-dimensional view of the bearing, the shutter, a stator and a heat sink, of the electrical machine according to the first embodiment.

Figure 4 shows a three-dimensional view of part of the bearing, the shutter, part of the stator and part of a heat sink of the electrical machine.

Figure 5 shows a sectional view of a three-dimensional view of the bearing, the shutter and the heat sink of the electrical machine.

Figure 6 shows the shutter of Figure 2 seen from the heatsink.

Figure 7 shows the shutter of Figure 2 seen from the bearing.

Figure 8 shows a sectional view of a perspective view of the shutter according to another embodiment.

DETAILED DESCRIPTION

[0015] The figures are presented as an indication and in no way limit the invention. Unless otherwise specified, the same element appearing in different figures has a single reference.

The electric machine further comprises a bearing 1 and at least one shutter 2, a stator 3 surrounded by the bearing 1, a rotor 4 surrounded by the stator 3 comprising a rotor shaft 41 passing through a bearing fixed to the bearing 1.

[0017] [Fig. 1] shows a representation of a three-dimensional view of part of the bearing 1, of the shutter 2 and partially of the rotor 4 of the electric machine according to a first embodiment. [0018] [Fig. 2] shows a representation of a three-dimensional view of the bearing 1 of the electric machine and of the rotor shaft 41 according to the first embodiment.

The bearing 1 comprises a skirt 1 1 extending axially and a transverse wall 12 extending radially. The transverse wall 12 comprises an external face 120 visible in the two Figures 1 and 2.

The electrical machine further comprises a heat sink 5, for example made of aluminum alloy, mounted against the bearing 1 opposite the outer face 120 of the transverse wall 12 of the bearing 1 partially covered by the shutter 2. L The shutter is for example made of plastic.

[0021] [Fig. 3] shows a representation of a three-dimensional view of the bearing 1, of the shutter 2, of the stator 3 and of the dissipator 5, of the electric machine according to the first embodiment.

[0022] [Fig. 4] shows a representation of a three-dimensional sectional view of the bearing 1, of the shutter 2, of a stator 3 and of a dissipator 5, of the electric machine according to the first embodiment without the rotor 4.

[0023] In this case, in this example, the electrical machine comprises two shutters 2 visible in FIG. 4, but only one will be described below. In this example, the two shutters are identical but may be different. Being identical reduces the number of part references and therefore reduces the cost of the electrical machine.

The skirt 1 1 of the bearing comprises radial ventilation openings January 10 visible in Figures 3 and 4.

The bearing 1 surrounds a part of the stator 3 comprising a sheet metal package 30, a coil 31 comprising a chignon 310 and phase outputs 312. The coil is in this case a double three-phase, for example with triangle pin or star, for example wavy distributed.

The transverse wall 12 comprises axial ventilation openings 124 vis-à-vis the rotor 4, a bearing support 122 in which the bearing is mounted to support the rotor shaft. The transverse wall 12 comprises phase outlet passage openings 123 located in a peripheral zone of the transverse wall crossed by the phase outlets 312. In this case, the transverse wall 12 comprises six phase outlet passage openings 123. . Each shutter 2 is mounted in this example on the outer face 120 of the transverse wall 12 and each closes three phase outlet passage openings 123. By closing is meant partially closing.

[0028] The shutter 2 extends angularly over less than 360 ° and since there are two shutters 2, each shutter 2 angularly extends over less than 180 °, in this case around 45 °. This facilitates assembly. Indeed, the shutter 2 can be mounted without axial mounting, for example radially or by pivoting. Indeed, in the case of a 360 ° shutter, the assembly involves axial assembly.

In addition, the peripheral zone comprising the phase output passage louvers 123, is not entirely covered by the shutter (s) 2. The peripheral zone is the zone of the transverse wall 12 situated between an external radius Re of the peripheral wall 12 and an internal radius of the passage openings 123.

The shutter 2 comprises an inner edge 21 having an inner radius ri and an outer edge 22 comprising an outer radius re.

By internal radius is meant the smallest radius relative to the X axis and by external radius is meant the largest radius relative to the X axis.

In this example, the difference between the internal radius ri and the external radius re of the shutter 2 is at least two times smaller than the external radius Re of the transverse wall. This allows for a large area of the transverse wall which can be cooled.

[0033] In this case, the inner edge 21 has the shape of a solid arc of a circle and the outer edge 22 in this case has the shape of a hyphen in the form of an arc of a circle. In other words, the outer edge 22 includes a plurality of spaced edges 220. Each spaced edge 220 has the shape of an arc of a circle but could be straight and inclined with respect to each other to form the hyphenated shape. arc of a circle.

[0034] [Fig. 5] shows a sectional and perspective view of shutter 2, heatsink 5 and bearing 1.

[0035] [Fig. 6] shows a perspective view of shutter 2 seen from the heatsink side.

[0036] [Fig. 7] shows a perspective view of the shutter 2 seen from the side of the bearing 1. The shutter 2 comprises a body 20 having an internal bearing face 200 visible in FIG. 7 opposite the external face 120 of the transverse wall 12 and an external bearing face 201 visible in FIGS. 1, 3, 5 and 6.

The body 20 comprises at least one covering portion 203 for each phase passage opening 123 to close it and at least one passage opening 23 disposed opposite at least one phase passage opening 123 for the passage of one of the phase outputs 312.

Each passage opening 23 is therefore crossed by a phase output 312. In other words, each phase output passage opening 123 is partially closed by the shutter 2 by the covering portion 203.

[0040] In this example, each opening 23 extends to two spaced edges 220. In other words, each opening has the shape of a notch. Therefore, in this example the shutter 2 can be mounted radially or / and by pivoting by inserting the phase outputs 312 into its opening. According to another example, the shutter 2 comprises openings having the shape of a hole. In other words, in this other example, the outer edge has the shape of a solid arc of a circle and not a hyphen as in this example.

The shutter 2 further comprises two side edges 24 each connecting the inner edge 21 to the outer edge 22.

Thus, in this example the two shutters 2 cover less than 50%, in this case about a quarter of an area in the form of an arc of a circle of the outer face 120 between the inner radius ri and the radius external re. Thus, a cooling surface 125 of this zone of the external face 120 of the transverse wall 12 is licked by the air circulating in the electrical machine. This makes it possible to have a large area of the outer face 120 of the transverse wall which can be cooled and thus have good heat dissipation.

In addition in this example, the angular distance between an outer edge 22 and the ear 123 closest to the outer edge 22 by said shutter being less than the distance between the closed ear 123 and another ear 123 the most close to the closed hearing 123. This increases the area of the transverse wall which can be cooled by the incoming air.

In this example, the shutter 2 comprises a projection 25 extending axially along the X axis from the body 20, in this case from the external bearing face 201. In this example, the projection 25 is located radially internally with respect to the opening 23.

The electrical machine further comprises an electronic device, not shown, comprising electronic components, for example a microcontroller for the control and management of the machine, power transistors, for example MOSFET or IGBT for rectifying or controlling the power of the electric machine. The electronic device is mounted on the heat sink 5 for cooling, in particular some of the electronic components can be mounted against the heat sink to cool them more efficiently.

The heat sink 5 comprises a body 51 and fins 52 oriented substantially along the X axis and directed towards the outer face 120 of the transverse wall 12 of the bearing 1. The fins 52 therefore extend axially from one face of cooling 510 of the body 51 towards the bearing 1. In this embodiment, at least one of the fins 52, called shutter fin 52a, is arranged opposite the shutter 2 is a over at least the entire radial length facing screw of the shutter a height H1 along the X axis that is smaller than at least one other height H2 of a fin 52 disposed opposite the cooling surface 125. This makes it possible to maximize the heat exchange between the air and the heat sink 2 and therefore improve its cooling by having longer fins. By height is meant the longest height.

In this example, the heat sink 5 comprises seven small fins 52a by shutter 2, or fourteen small fins 52a. The two groups of seven small fins are in this case identical and identically arranged with the other heatsink 2. Only one group of seven small fins is discussed below.

In this example of this embodiment, each small fin 52a comprises a first portion 521 a vis-à-vis the shutter 2 having the height H1 and a second portion 522a vis-à-vis the outer face 120 having the height H2.

According to another example not shown, a small fin 52a may have a height H1 over its entire length, that is to say without a second portion.

According to another example not shown, the second portion 522a facing the outer face 120 may have a height smaller than the height H2 but at least greater than the height H1. The second portion 522a can also have a height greater than the height H2. In this embodiment, at least one of the small fins 52a comprises an end in contact with the projection 25. In this case, there are three projections

25 by shutter 2 and three of the seven small fins 52a are each in contact with a corresponding projection 25.

Each projection 25 allows the shutter 2 to be sandwiched between one of the three small fins 52a of the heat sink 5 resting on the projection 25 and the body 20 resting against the transverse wall 12 of the bearing 1. This makes it possible to maintain the shutter 2 axially in a simple manner while making it possible to take up an assembly clearance. In this case, in this example each of the three protrusions 25 is elastically deformed by the end of one of the three of the seven small fins, thus calling the shutter 2 against an outer surface of the transverse wall. The shutter is thus maintained by means of the fins and the bearing.

[0053] According to this example, the shutter 2 comprises at least one retaining wall

26 extending axially from the body 20 along the X axis in the phase outlet passage opening 123. In this case, the retaining wall 26 extends axially from the body 20 in the opening 123 according to the axis X towards the chignon 31 0. Such a retaining wall 26 allows the shutter 2 to be held angularly or radially.

In the example shown, the shutter 2 comprises a retaining wall 26 by phase outlet passage opening 123, visible in particular in Figure 7. The retaining wall 26 comprises an angular stop portion 26b which s' extends radially against an internal radial edge 123a of the ear 123. Further in this example, the retaining wall 26 comprises a radial wedging portion 26a which angularly extends into the ear 123 along an internal angular edge 123b of the hearing 123 extending angularly relative to the X axis. This makes it possible to position the shutter 2 angularly and radially during assembly as well as to maintain it angularly and radially. In particular in this example, the retaining wall 26 comprises two angular stop portions 26b for maintaining in both directions of rotation. Thus, when placing the shutter 2 in position, the shutter 2 is positioned angularly while being in abutment by each pair of angular abutment portions 26b in each phase passage opening 123 and is wedged radially by the wedging portion radial between phase outlet 312 and each inner edge of each phase outlet passage louver 123.

In addition in this example, the shutter 2 comprises an air blocking wall 27 extending axially towards the heat sink 5 from the body 20. This allows to limit the re-looping of hot air even better. In this case, the air blocking wall 27 extends from the body 20 along the edges 220 and around the opening 23. In this example the air blocking wall 27 extends axially like the projections 25. .

In this example the covering portion 203 comprises the part of the body 20 from which the air blocking wall 27 extends and the part of the body from which the retaining wall 26 extends.

According to another embodiment of an electric machine which is identical to the first embodiment except with regard to the shutters 2. In this embodiment, the electric machine comprises a shutter 2 'by passage openings of phase output 123 or twelve shutters 2 '.

[0058] [Fig. 8] shows a cross section of a 2 ’shutter.

According to an example of this embodiment, each shutter 2 ’further comprises petals 27.

Each petal 27 being formed from a removable material, the petal at least partially closing off the opening. This improves the plugging of the passageway while facilitating the mounting of the output phases through the shutter.

The petals 27 are inclined relative to a plane P in which extends the body 20 of the shutter 2 ’so as to present a pyramid shape. The petals may for example form an angle of inclination A1 of the order of 45 degrees relative to the plane P in which the body 20 extends.

Each petal 27 can be formed from several portions. In the exemplary embodiment shown in FIG. 8, each petal 27 comprises an inclined portion 271 and a rim 272. The inclined portion 271 extends between the body 20 and the rim 272 and said rim 272 extends on the side of the free end of the petal 27. These rims 272 delimit the opening 23 ′ for the passage of a phase output 312. Still in this example, the rim 272 extends, in the unconstrained state, in a plane substantially parallel to the plane P in which the body 20 of the shutter 2 extends. In an alternative embodiment not shown, a petal may comprise several portions of different inclination in order to form the shape of a pyramid.

The petals make it possible to optimize the closure of the phase outlet passage hearing 123. Indeed, in the case where the shutter comprises a hole or a notch for the passage of the phase outputs 312, the The gill 123 is less obstructed than by the petals and may further make mounting more difficult if the notch or hole is too close to the diameter of the phase outlet. The shutter 2 'comprises a single projection which may be identical to that of the shutter 2 of the first embodiment. The shutter 2 'can therefore have these side edges 24 separated by a length of between 1.1 times the maximum width of a phase outlet passage opening. The width being measured perpendicular to the outer radius re and perpendicular to the thickness of the shutter 2 'measured parallel to the X axis of the machine.

[0065] According to a variant of this embodiment, the shutter has no petal. In other words, the shutter includes an opening like that of the shutter of the first embodiment. Thus the shutter only comprises part of the shutter of the first embodiment and covers only a single phase output passage opening 123.

[0066] According to an example of the first embodiment, the shutter further comprises petals such as those of the second embodiment.

[0067] According to a variant of one of the two previous embodiments, the shutter is mounted on an internal face of the transverse wall between the bun and the transverse wall.

Claims

1. X axis rotating electric machine comprising at least:

- a bearing (1) comprising a transverse wall (12) and a skirt (11) extending axially from the transverse wall, phase passage openings (123) being distributed in a peripheral zone of the transverse wall (12) of the bearing (1),

- at least one shutter (2, 2 ') mounted on the transverse wall (12) of the bearing so as to partially shut off at least one phase passage opening (123), and in which the shutter extends angularly over less of 360 °.

2. An electric machine according to claim 1 wherein the at least one shutter extends angularly over less than 180 ° and comprises notch-shaped openings which open to the outer periphery.

3. Electric machine according to claim 1 or 2 wherein the shutter (2) comprises an internal radius (ri) and an external radius (re), and in that the difference between the internal radius (ri) and the external radius (re) is at least two times smaller than an outer radius (Re) of the transverse wall 12.

4. Electric machine according to one of the preceding claims wherein the shutter (2) mounted on the transverse wall (12) of the bearing (1) covers less than 50% of the area of the transverse wall (12) of the bearing ( 1).

5. Electric machine according to one of the preceding claims wherein the shutter (2) extends radially between an inner edge (21) comprising an inner radius (ri) and an outer edge (22) comprising an outer radius (re ) and

angularly between two side edges (24) connecting the inner edge (21) to the outer edge (22), and in which the angular distance between a side edge (24) and the closest phase output passage louver (123) of the lateral edge (24) partially closed by said shutter (2) being less than the distance between the closed phase output passage opening (123) and another phase output passage opening (123) closest to the closed phase outlet passage opening (123).

6. Electric machine according to one of the preceding claims, further comprising a heat sink (5) mounted on the bearing (1) facing an outer face (125) of the transverse wall (12) of the bearing (1) partially. covered by the shutter (2).

7. Electric machine according to the preceding claim, wherein the heat sink (5) is provided with fins (52, 52a, 52b) oriented substantially along the X axis and directed towards the outer face (125) of the transverse wall (12). ) of the bearing (1), in which at least one of the fins (52a) is arranged opposite the shutter (2) and has a height (H1) vis-à-vis the shutter (2) according to l 'X axis smaller than at least one other fin (52b) disposed opposite the outer face (125) of the transverse wall.

8. Electric machine according to claim 7 wherein at least one of the fins (52a) disposed opposite the shutter (2) has:

- a first portion (521 a) facing the shutter (2) having the first height (H1) along the X axis and

a second portion (522a) facing the external face (125) of the transverse wall (12) having a second height (H2) greater than the first height (H1).

9. Electric machine according to one of the preceding claims, wherein the shutter (2) comprises at least one retaining wall (26a) extending

axially of the body along the X axis in the phase output passage opening (123).

10. Electrical machine according to one of the preceding claims, wherein the shutter (2) comprises an air blocking wall (27) extending axially towards the heat sink (5) from the body (20).