EP3925061A1 - Mechanical-commutator polyphase synchronous electric machine - Google Patents

Abstract

Mechanical commutator (40) for electric machine (1) suitable for supplying power via a polyphase current system comprising q phases, where q is a positive integer strictly greater than 1, to a rotary electric machine rotor (3) having 2*p magnetic poles, comprising: - a slip ring (41) that rotates about an axis (X) of the electric machine (X), of elementary pattern equal to 2*π/(p*q); - at least one pair radially extending brushes, a positive brush (45) and a negative brush (46), suitable for rubbing against the slip ring (41), which are rotatably fixed and each defined over an angular sector, and suitable for connection to one and the same voltage source, in particular a vehicle battery (B), characterized in that the mechanical slip ring (41) comprises n*p*q, where in particular n = 1 or n = 2, conductive strips (60) which come one after the other circumferentially, each strip (60) being defined over an angular sector, adjacent strips being isolated from one another, the strips being distributed in q groups (a', b', c'), all of the strips (60) of one and the same group being electrically connected to one another, the q groups alternating circumferentially, and in that the brushes (45, 46) of one and the same pair are circumferentially offset relative to one another by [(2k+1)*2*π]/(2*p)], k being a natural integer.

Description

Description

Title of the invention: Synchronous electric machine

polyphase with mechanical switch

[1] The present invention relates to a mechanical switch for supplying a rotating electrical machine with a polyphase current system. The invention also relates to an electric machine equipped with such a switch for a motor vehicle.

[2] The invention finds a particularly advantageous application in the field of rotating electrical machines such as alternators, alternator-starters, electric motors and reversible machines. The invention also finds particular application in the traction of low-power motor vehicles, in particular between 4kW and 25kW, for example between 4kW and 8kW, for example between 15kW and 25kW.

[3] The invention can thus advantageously be implemented in particular with low power four-wheel electric vehicles ("microcars" in English), two-wheeled vehicles of the motorcycle type, or heavy quadricycles.

[4] It is known from EP 1037362 A2, a lightened electric motor for

produce vibrations. This electrical machine outside the automotive field comprises an axial eccentric collector on which rubs flexible tabs supplied with direct current. The machine also includes an eccentric rotor with a three-phase winding without iron. The electric motor can therefore run at very high speed without torque. Due to the absence of iron, such a machine does not present torque or armature reaction and is therefore not suitable for automotive traction.

[5] It is known from the prior art of direct current electric machines,

used in particular in motor vehicle starters but also to propel a vehicle. These machines provided with a stator, here the inductor, comprising several permanent magnets or wound poles (electromagnets) and with a rotor, here the armature, comprising conductors forming the rotor winding. The armature comprises a mechanical collector provided with blades on which brushes rub to supply the armature with direct current. [6] The brush / collector assembly forms a mechanical switch which allows the mechanical self-piloting of the winding supply. Each change in the angular position of the armature corresponds, thanks to the arrangement of the angular position of the blades and of the brushes, to a new supply of the winding. The positioning of the brushes and of the collector is fixed by the angular position of the field poles.

[7] The main drawback of these machines lies in the sudden variations in the magnetic energy with each switching of current in the conductors, especially in armature sections of the winding. Switching current causes excessive brush wear. Moreover, the performance of such machines is insufficient for an application in the power train of a motor vehicle in comparison with polyphase synchronous rotating electrical machines, in particular three-phase, with synchronous alternating current.

[8] Such a polyphase synchronous machine conventionally comprises a rotor

movable in rotation around an axis and a fixed stator surrounding the rotor. In alternator mode, when the rotor is rotating, it induces a voltage at the stator which transforms it into electric current to then supply the electrical consumers of the vehicle and recharge the battery. In motor mode, the stator is electrically supplied and creates a rotating magnetic field and then a torque relative to the field poles, causing the rotor to rotate, for example to start the heat engine. These machines have a clear advantage in terms of volume performance compared to direct current machines.

[9] Such a machine conventionally comprises a shaft, integral with the rotor, a rear end of which carries slip rings belonging to a collector. Brushes are arranged so as to rub on the slip rings. The brush holder is connected to a voltage regulator for use in alternator mode.

[10] The stator comprises a body formed by a stack of thin sheets

forming a crown, the inner face of which is provided with notches open inwards to receive a winding comprising phase windings connected together, for example, in star or in delta. These windings pass through the notches of the stator body and form chignons protruding from either side of the stator body. The phase windings are obtained for example from a continuous wire covered with enamel or from conductive elements in the form of pins connected together by welding. The coil is electrically connected to an electronic assembly by an input and an output. Unlike direct current electric machines, the windings are open.

[1 1] The electronic assembly includes electronic power modules for controlling the supply of the winding phases. Switching here is electronic and requires semiconductor inverters. For example, in the case of electric traction by a three-phase synchronous machine, the phases of the winding are conventionally supplied by an electronic inverter comprising 6 stages of MOSFET type power transistors, the control of which requires the rotor position data obtained at by means of different position sensors. In the case of a two-phase supply, 6 inverter arms each with MOFSET are required, twice as many as in the case of a three-phase supply. The position sensors can be Hall effect in the case of a synchronous machine with permanent magnets direct current ("BLDC" in English) whose power is toothed. The position sensors can also be of the resolver type, more expensive than Hall effect sensors, in the case of a synchronous machine with magnets

permanent alternating current ("BLAC" in English) whose power supply is sinusoidal.

[12] This electronic assembly is expensive. The reliability of semiconductor components in a harsh temperature or vibration environment is not optimal due to the fragility of these components. These components are also dependent on materials such as silicon, the supply of which may or may be sensitive.

[13] There is therefore a need to supply electrical machines with a polyphase current system in a less expensive manner and / or less dependent on power electronics, or even completely independent on power electronics. [14] The invention aims to effectively remedy this drawback by proposing a mechanical switch for an electrical machine capable of supplying power by a polyphase current system comprising q phases, with q positive integer strictly greater than 1, a rotating electrical machine rotor having 2 ^* magnetic poles, including:

- a movable collector rotating around an axis of the machine

electric, with elementary pattern equal to 2 ^* TT / (p ^* q),

- at least one pair of radial extension brushes, a positive brush and a negative brush, able to rub on the collector, fixed in rotation, each defined on an angular sector, able to be connected to the same voltage source, in particular a vehicle battery,

[15] The mechanical switch is characterized in that the collector

mechanical comprises n ^* p ^* q, with n integer, with in particular n = 1 or n = 2, conductive blades succeeding one another circumferentially, each blade being defined on an angular sector, the adjacent blades being isolated from each other, the blades being divided into q groups, all the blades of the same group being electrically connected together, the q groups being alternated

circumferentially,

[16] The mechanical switch is also characterized in that the brushes of the same pair are circumferentially offset from each other by

[(2k + 1) ^* 2 ^* TT] / (2 ^* p)], k being a natural number.

[17] Such a power supply is thus more durable and less expensive. The

performance is also significantly better than that of a direct current electric machine.

[18] Such a switch allows the supply of electrical machines by a polyphase current system without an electronic converter so that the number of power electronic components and the associated cost is greatly reduced or even eliminated. Such an autopilot power supply also eliminates the need for a rotor position sensor.

[19] According to one aspect of the invention, the angular offset between the brushes is from center to center, that is to say between the median planes of each brush. A brush may have a substantially parallelepipedal shape. According to one aspect of the invention, the brushes can always be in contact with a blade. A brush may include a radially inner cylindrical surface in contact with the collector, in particular with the blades.

[20] According to one aspect of the invention, the number of pairs of brushes is between 1 and p. For example, the number of pairs of brushes may be equal to one or two for a machine with two pairs of poles. All pairs of brushes rub on the same blades. According to the invention, the number of palaces is therefore even.

[21] According to one aspect of the invention, the brushes can rub in a radial direction on the collector. The switch is then said to be radial. Alternatively, the friction can be established in the axial direction

[22] According to one aspect of the invention, the manifold may be cylindrical. The friction surface between the brushes and the collector is cylindrical.

[23] According to one aspect of the invention, the collector is bladed, that is, it is not printed.

[24] According to one aspect of the invention, the manifold includes a fan.

[25] The presence of the fan creates an air flow to evacuate the hot air and thus cool the collector itself and its environment.

[26] According to one aspect of the invention, the fan may be made of a material

insulation, especially made of plastic.

[27] According to one aspect of the invention, the fan may be in action. Alternatively, the fan can be reaction.

[28] According to one aspect of the invention, the fan can be arranged axially next to the blades. The fan can be one piece.

[29] According to one aspect of the invention, the fan may include a plurality of blades. The number of blades can be between 2 and 16, in particular 8, in particular 6 or 10 blades.

[30] The blades can be evenly distributed circumferentially. In

As a variant, the blades can be distributed unevenly, for example from logarithmically. Uneven or variable space can make the system quieter.

[31] The blades can be curved. The blades can be curved so that the air circulates inwards. Alternatively, the blades can be curved so that the air circulates outwards. The blades can extend radially to the radial height of the blades. The blades can all be one piece. The blades can be separate pieces from each other.

[32] According to one aspect of the invention, the collector can include a plurality of capacitors, each capacitor being mounted between two separate groups of blades.

[33] The presence of capacitors makes it possible to reduce the discontinuities of

current during switching. Thus the collector and the electrical machine in which it can be integrated have better durability and improved efficiency.

[34] For the purposes of the application, the insulation of adjacent slats is understood in the circumferential direction. Directly adjacent blades can belong to the same group of blades while being electrically isolated from each other without departing from the scope of the invention.

[35] The capacitors can be arranged axially on the opposite side to that of the fan. The blades are therefore arranged between the capacitors and the fan. This allows for more positioning latitude for each of the two functions. Alternatively, the fan and the capacitors can be on the same axial side with respect to the blades.

[36] According to one aspect of the invention, at least one capacitor is mounted between two separate groups of blades. The collector includes at least q

capacitors.

[37] According to one aspect of the invention, each capacitor comprises two

armatures separated by a polarizable insulator. The two plates of the same capacitor are electrically connected to two separate groups of blades. The frames can be directly attached to the boards. even though capacitors connect two groups of blades, the polarizable insulator makes it possible to respect the electrical insulation between the blades.

[38] According to one aspect of the invention, a single capacitor is provided between two separate groups of blades. As a variant, a plurality of capacitors can be provided between two groups of distinct blades. This plurality of capacitors can be arranged in series or in parallel between two groups of blades.

[39] The capacitors can be identical. Each capacitor may have a substantially parallelepipedal shape.

[40] Each capacitor can have an electrical capacity of between 1 and 100 microfarads, for example 25 pF, for example 50 pF. When several capacitors are connected in series or in parallel between two groups of distinct blades, the equivalent capacity is between 1 and 100 microfarads.

[41] Each capacitor may include a housing encapsulating the insulation

polarizable and / or all or part of the reinforcements.

[42] According to one aspect of the invention, all or part of the capacitors are axially offset from the blades. There is a plane normal to the axis of rotation that intersects the capacitors without cutting a blade.

[43] According to a first embodiment of the capacitors, the collector only comprises q capacitors. There is only one capacitor between each group of blades. The reduction of current discontinuities is obtained by a minimum number of capacitors.

[44] According to a second embodiment of the capacitors, the collector comprises at least one capacitor between two blades of groups of different groups successive circumferentially. The collector then comprises at least p ^* q capacitors, in particular only p ^* q capacitors. When n = 1, each blade is electrically connected to two capacitors. When n = 2, each plate is associated with only a single capacitor.

[45] According to one aspect of the invention, each capacitor can be fixed on an axially oriented finger of one of the blades. The capacitor plates can be fixed directly to the fingers, in particular by soldering. Capacitors can only be attached to the fingers. [46] According to one aspect of the invention, the capacitors can all be arranged in a given angular sector, in particular less than 90 °, in particular less than 45 °. As a variant, the capacitors can be arranged regularly over the entire circumference of the collector. The capacitors can all be circumferentially offset from each other.

[47] The capacitors can be at the same radial level as the blades. Alternatively, the capacitors can be arranged radially closer to the axis than the blades. The capacitors can be arranged one above the other.

[48] According to one aspect of the invention, the capacitors can all be of a

same axial side of the blades.

[49] According to one aspect of the invention, the collector may include a protective element for the capacitors. This protective element can be in one piece. This protection element may include several cavities receiving the capacitors. Alternatively, a single continuous circular cavity can receive the capacitors. As a further variant, the protection element can be formed of as many protective portions, distinct from each other, as there are capacitors.

[50] According to one aspect of the invention, the fan and the protective element

can be all in one piece. This makes it possible to pool functions.

[51] According to one aspect of the invention, the collector has p ^* q passages from one type of blade to another. The collector can include as many changes from one type of blade to another as there are capacitors in the second embodiment of the latter. The type of a blade is defined by its membership in one of the groups of blades. Thus, when n = 2, two blades of the same type follow one another circumferentially. The collector may have an electrical pattern

elementary of blades which repeats p times.

[52] According to one aspect of the invention, the blades all have the same angular sector and / or the axial dimension. In particular, all the blades are identical. The blades may not be axially offset. The blades can be copper. The slats can have a radial thickness included between 1mm and 3mm, for example 2mm. This thickness makes it possible to reduce the volume density of the current in the blades. The blades can have an axial dimension between 8mm and 12mm, for example 10mm. According to the invention, the collector has a single circumferential arrangement of conductive plates around the axis.

[53] According to one aspect of the invention, the manifold comprises a skeleton, of

revolution around the axis of the electric machine, to keep the blades in position. The skeleton can be made of an electrically insulating material, for example plastic. The skeleton can be in one piece. The skeleton can include radial openings, in particular n ^* p ^* q openings receiving the blades. The skeleton can be overmolded on the blades. The skeleton may include a central opening for receiving a rotor shaft. The manifold may include a sleeve disposed in the central opening of the skeleton and capable of being integral with the rotor shaft. The sleeve is fixed relative to the skeleton. The sleeve is more rigid than the skeleton so as to strengthen the connection between the collector and the rotor shaft.

[54] According to one aspect of the invention, the capacitors can be attached to the skeleton. The capacitor housings can be attached to an axially oriented face of the skeleton.

[55] According to one aspect of the invention, the ventilator may be integral with the skeleton. As a variant, each pale can be attached to the skeleton. As a further variant, the ventilator can be integral and attached to the skeleton.

[56] According to one aspect of the invention, q can be equal to 3. The switch is thus able to supply an electrical machine according to a three-phase current system.

[57] According to one aspect of the invention, the friction zone between the brushes and the blades may be at a radial distance from the axis of between 20 mm and 45 mm, in particular 25 mm, in particular 35 mm.

[58] According to one aspect of the invention, an angular sector on which a given part is defined is the smallest sector which comprises the given part in a plane perpendicular to the axis of the machine. [59] According to another aspect of the invention, the blades of the same group can all be electrically connected to a ring disposed radially inside the blades.

[60] According to the first embodiment of the capacitors, each of the q capacitors can be placed between two separate rings.

[61] Such a ring makes it possible to mutualize the electrical connections between the blades of the same group, which simplifies the manufacture of the switch. As requested, the brushes do not rub on the rings but on the blades.

[62] According to another aspect of the invention, a bridge can be provided between each blade and the associated ring. The bridges extend radially from the ring, in particular without axial offset from the ring. The bridges and the associated ring are in an interior space of the skeleton while the blades are flush outwards to come into electrical contact with the brushes. The blades of the same group, the bridges and the ring form a one-piece ring. The ring and the ring associated with the blades of group q are said to be of type q.

[63] According to another aspect of the invention, a bridge is associated with a single blade.

As a variant, for example when n = 2 and two blades of the same type succeed each other circumferentially, a bridge can be shared by several blades, for example two.

[64] According to another aspect of the invention, the collector comprises q link arms, each being integral with a ring, in particular by welding. Each arm has a free end capable of being connected to one phase, or to several phases, of the rotor winding in order to supply it or feed it. Each connecting arm opens, in particular radially, from the skeleton of the collector through a radial hole made in the skeleton.

[65] According to one aspect of the invention, in particular according to the first embodiment of the capacitors, the capacitors are connected to the link arms of the q groups of blades. The capacitors can be arranged on the same axial side as the link arms with respect to the blades. Each frame can be directly attached to a free end of the link arm. Alternatively, each reinforcement can be fixed by means of a connecting piece, for example a metal wire, for example a piece of metal conductor.

[66] According to one aspect of the invention, the rings of each group can follow one another axially.

[67] This axial juxtaposition promotes the compactness of the collector.

[68] According to one aspect of the invention, bridges of the same type q are offset from bridges of other types. The rings can be axially distributed over an axial length of the blade.

[69] The bridges can be connected to a central area of the blades or to one end thereof. In particular, when q = 3 (that is to say when the current system is three-phase) the collector comprises three rings, a central one and two ends surrounding the central ring. The bridges associated with the central ring are axially connected to the center of the blades and the bridges associated with the end rings are connected at corners of the blades.

[70] Alternatively, the rings can be concentric.

[71] According to one aspect of the invention, each blade can be separated from the two adjacent blades by an inter-blade.

[72] The inter-blade is defined to prevent circumferential contact between two successive blades.

[73] According to one aspect of the invention, the inter-blades can all have the same angular opening.

[74] The angular opening of each blade can thus be equal, in radians, to

[2 * TT- n ^* q ^* p ^* (opening of an inter-blade)] / (n ^* p ^* q).

[75] According to one aspect of the invention, the angular opening of an inter-blade is less than the angular opening of one of the blades. Alternatively, the angular opening of an inter-blade may be greater than the angular opening of one of the blades.

[76] According to one aspect of the invention, the minimum dimension in the direction

circumferential between two successive blades, that is to say the circumferential dimension of the inter-blades, is chosen to avoid dielectric breakdown. The minimum dimension can be between 1.6mm and 2.4mm when the switch is powered at 48V.

[77] This dimension of the inter-blades makes it possible to avoid electric arcs between the adjacent blades while leaving sufficient space for the blades which simplifies the fabrication of the skeleton. This inter-blade dimension can also allow the continuity of the friction between the brushes and the blades.

[78] The minimum radial dimension of the collector is imposed by the number of blades and by the minimum dimension of the inter-blades to be observed.

[79] The angular opening of one of the inter-blades is deduced from the radial distance of the friction zone and from the circumferential dimension of this inter-blade.

[80] The angular opening of the slats can be identical to the angular opening of the inter-slats. Each blade and each inter-blade each extend over 2 * TT / (2 * p ^* q).

[81] According to one aspect of the invention, the interblade can be insulating. The inter-blade can be an empty space between two successive blades. The inter-blade may include a non-conductive protuberance, in particular formed by the skeleton.

[82] According to one aspect of the invention, one of the inter-blades, in particular each inter-blade, may include an isolated blade. The insulated blade is not electrically connected to any other blade. The isolated blade is not connected

electrically to no capacitor. The blade is said to be insulated in opposition to the conductive blades, electrically connected, which form the q groups. As a variant, the inter-blades can be connected together forming a group of insulated blades under the same electrical potential conditions.

[83] According to one aspect of the invention, the insulated blades can be fixed on an inter-blade ring. The inter-leaf ring can be arranged in the interior space of the skeleton. The inter-leaf ring may be radially outside the q-type rings. Insulated blades have a foot inserted into an opening in the inter-blade ring for securing the insulated blade. The inter-leaf ring may include windows for the passage of the bridges between the leaves of one of the q groups and the associated ring. [84] The insulated blade is separated from the conductive blades by interstices. The gaps can be between 1mm and 5mm in the circumferential direction. The insulated blades are received in radial openings. The collector can then comprise 2 ^* n ^* p ^* q blades, the conductive blades being alternating with the insulated blades. The insulated blades are at floating potential.

[85] According to one aspect of the invention, the angular opening of the insulated blades can be between 20 and 50%, in particular between 40% and 50% of the angular opening of the conductive blades.

[86] The insulated blades ensure a uniform contact between the collector and the brushes. Indeed the brushes rub almost continuously on the blades, isolated or conductive.

[87] According to one aspect of the invention, the angular opening of each brush is

greater than the angular opening of the inter-blades. Thus, each brush is always in contact with at least one blade. Each brush can be in simultaneous contact with at most two different groups of blades.

[88] According to one aspect of the invention, the coverage rate can be the ratio between the difference between the angular opening of a brush and the angular opening of an inter-blade divided by the elementary pattern of the collector.

[89] According to one aspect of the invention, the recovery rate can be between 10% and 55%. This recovery rate makes it possible to supply the rotor according to a polyphase current system, for example square waves, for example quasi-sinusoidal while maintaining the current of the voltage source at a non-zero mean value, of the same sign of current during time.

[90] In the sense of the application, the recovery is the period during which a given broom is in contact with two blades of different groups. During this overlap, the brush can thus feed two distinct groups of blades simultaneously. The simultaneous supply of two groups of blades for the same brush influences the form of a polyphase current system. The waveform of each phase is changed.

[91] According to one aspect of the application, with a fixed collector (angular opening of the blades and of the fixed inter-blades), the opening of the brushes can be chosen to get different form of current system. For a given collector, there can therefore be several current systems.

[92] According to one aspect of the invention, the armature reaction is taken into account when defining the angular offset between the brushes. There is a risk of dissymmetry a case of angular offset different from that defined in the present invention

[93] According to one aspect of the invention, the armature reaction is also taken into account when characterizing the recovery rate. Indeed, the armature reaction is a function of the current system, itself a function of the recovery rate. The recovery rate will not be defined in the same way in the case of a machine that produces torque as in the case of a machine that without iron, not seeking to produce torque. The induced reaction is significantly different.

[94] The invention also relates to a mechanical switch for

electrical machine capable of supplying, by a polyphase current system comprising q phases, with q positive integer strictly greater than 1, a rotating electrical machine rotor having 2 ^* magnetic poles, comprising:

-a movable collector in rotation around an axis (X) of the electric machine, of elementary pattern equal to 2 ^* TT / (p ^* q),

- at least one pair of radial extension brushes, a positive brush and a negative brush, able to rub on the collector, fixed in rotation with respect to one another, each defined on an angular sector, able to be connected to the same voltage source, in particular a vehicle battery,

characterized in that the mechanical collector comprises n ^* p ^* q, with n integer, with in particular n = 1 or n = 2, conductive plates following one another

circumferentially, each blade being defined on an angular sector, the adjacent blades being isolated from each other, the blades being distributed in q groups, all the blades of the same group being electrically connected together, the q groups being alternated circumferentially, and in that the collector comprises a fan. [95] Everything that has been said with reference to the fan also applies to this part of the invention.

[96] The invention also relates to a mechanical switch for

electrical machine capable of supplying, by a polyphase current system comprising q phases, with q positive integer strictly greater than 1, a rotating electrical machine rotor having 2 ^* magnetic poles, comprising:

- a movable collector rotating around an axis (X) of the machine

electric, with elementary pattern equal to 2 ^* TT / (p ^* q),

- at least one pair of radial extension brushes, a positive brush and a negative brush, able to rub on the collector, fixed in rotation with respect to one another, each defined on an angular sector, able to be connected to the same voltage source, in particular a vehicle battery,

characterized in that the mechanical collector comprises n ^* p ^* q, with n integer, with in particular n = 1 or n = 2, conductive plates following one another

circumferentially, each blade being defined on an angular sector, the adjacent blades being isolated from each other, the blades being distributed in q groups, all the blades of the same group being electrically connected together, the q groups being alternated circumferentially, and in that the collector comprises a plurality of capacitors, each capacitor being mounted between two groups of distinct blades.

[97] Everything that has been said with reference to capacitors also applies to this part of the invention.

[98] The invention also relates to an electric machine which comprises:

- a mechanical switch as described above,

- a fixed rotating stator comprising 2 ^* magnetic poles, the stator forming the inductor of the machine,

- a movable rotor rotating around the axis of the electric machine, the rotor forming with the collector an armature of the machine, the rotor comprising:

i. a rotor shaft, and ii. a rotor body comprising:

1.a pack of sheets including stacked sheets

axially, the bundle of sheets having (2 ^* p) ^* m ^* q notches of axial extension, with m integer,

2. at least one winding, the winding being divided into q phases supplied by the switch, the phases comprising winding sections housed in the notches, the sections of each phase following one another circumferentially, each phase having two ends.

[99] Such a polyphase synchronous electric machine is economical because it avoids an expensive electronic assembly for the alternating current supply of the multiple phases of the machine from a direct current.

[100] The plate pack is particularly important for propulsion applications. Without it, the machine could not produce the desired torque. However, the armature reaction must be taken into account when defining the switch.

[101] The commutator, in particular by the overlap rate and angular offset parameters of the brushes as defined above, makes it possible to obtain a machine which produces torque and which does not vibrate. Vibrations are particularly harmful in automotive vehicle propulsion applications.

[102] According to one aspect of the invention, the rotor is cylindrical.

[103] Such a machine is particularly remarkable in that the rotor is supplied according to a polyphase current system and in that the stator is supplied with direct current. The rotor and the stator get their voltage and their current from a voltage source, for example the accumulator battery, so in direct and not in alternating.

[104] The brushes are also supplied with direct current, they are connected to the same voltage source. They are not connected to the phases of the rotor, they are the groups of blades which are connected to the q phases of the rotor. [105] According to one aspect of the invention, the fan can be arranged axially on the side of the rotor body.

[106] According to one aspect of the invention, the ventilator can expand, at least by

part, in a space inside the rotor body. The fan can extend radially between the rotor shaft and the rotor body. This helps to stir the air inside the rotor body and cool the winding.

[107] According to one aspect of the invention, the capacitors are axially on the side opposite the rotor body, particularly when they are directly attached to the blades.

[108] The machine can have a number of pairs of poles between 1 and 12. In particular, the machine can have 6 pairs of magnetic poles or 6 pairs of magnetic poles.

[109] The integer m here is the number of notches per pole and per phase, for example one, for example two.

[1 10] According to one aspect of the invention, when m is strictly greater than 1, the notches associated with the same phase follow one another circumferentially.

[1 1 1] According to one aspect of the invention, each phase may have a unique

conductor forming the various winding sections. Each phase can have multiple conductors assembled together outside of the notches. These conductors can be pins, for example U-shaped, for example I-shaped. These pins can be inserted axially and then connected together. The pins allow better performance, especially in terms of engine torque.

[1 12] According to another aspect of the invention, the number of notches can be one

multiple of the number of blades. Each plate is aligned with a median plane which equally separates the m notches of a q phases of one of the poles which follow one another. Each blade is aligned with a barycenter of the following m blades. For example, when n = m = 1, each blade is aligned with a tooth of the rotor body which separates two of the notches in which the sections of the same phase are housed. [1 13] According to another aspect of the invention, the phases of the winding can be connected to the blades of the collector, in particular to the collector rings, by means of the link arms.

[1 14] According to another aspect of the invention, the brushes can be aligned

axially with the stator poles.

[1 15] According to another aspect of the invention, the stator can be clawed. The stator can include a winding, claws and inter-pole magnets, in particular made of ferrite which is a cheap material. The inter-polar magnets can also be made of Neodymium-Iron-boron to benefit from a

higher volume performance. As a variant, the stator may comprise a yoke equipped with several electromagnets distributed circumferentially. The stator is able to be connected to the voltage source, in particular to the vehicle battery.

[1 16] As a variant, the stator may include a cylinder head fitted with one or

several permanent magnets distributed circumferentially, without claw, in particular without any winding.

[1 17] According to another aspect of the invention, the electrical machine may also include a fixed rotating brush holder assembly in which the switch brushes are housed. The brush holder can surround the collector.

[1 18] The electric machine may include a fixed rotating casing. The housing can surround the assembly of the stator, rotor and commutator. The housing can be in two parts, a front and a rear. The brush holder can be attached to the rear part of the housing. The stator can be fixed on the front part of the housing.

[1 19] According to another aspect of the invention, the manifold can be fixed in rotation on the rotor shaft, in particular the manifold sleeve can be press-fitted. Alternatively, the manifold can be reversibly mounted on the rotor shaft. Running gear can be disposed between the rotor shaft and the housing to support the rotor.

[120] According to a first winding mode, each of the q groups of blades is electrically connected to one of the two ends of one of the q phases of the rotor, the other ends of the q phases are electrically connected together so as to form a star coil.

[121] According to one aspect of the invention, when the coil is in the first mode, the recovery rate can be between 10% and 50%. When the recovery rate is between 10% and 20%, the system currents are of the square type. When the recovery rate is between 20% and 50%; the currents of the system are of the sinusoidal or quasi-sinusoidal type.

[122] In the sense of the request, a current is of the quasi-sinusoidal type, if the

harmonics of the signal up to harmonic 15, are all less than 12%, in particular 10%, in particular 8% of the value of the fundamental.

[123] In a particular example of this first winding mode, q is equal to three, the switch therefore supplies the rotor according to a three-phase current system. One end of each of the three winding phases can be fixed, in particular by welding on one end of one of the three link arms.

[124] According to another aspect of the invention, only one of the two ends of

each phase can be connected to a link arm. Each group of blades can supply a single phase of the q, in particular three, phases of the rotor. Each group of blades, in particular each ring of the collector, supplies a separate phase.

[125] According to one aspect of the invention, the collector may also include a connector capable of electrically connecting the ends of the phases of the winding together. The connector can be disposed circumferentially next to the free ends of the link arms. The connector can open radially from the skeleton. The connector comprises q ends, in particular three, for each to receive each of the phase ends.

[126] According to a second winding mode, each of the q groups of blades is electrically connected to two ends of two distinct phases of the q phases of the rotor so as to form a polygon winding.

[127] According to one aspect of the invention, according to one aspect of the invention, the rate of

recovery can be between 10% and 55%. When the winding is in the second mode. [128] In a particular example of this second winding mode, q = 3, the switch therefore supplies the rotor according to a three-phase current system. The winding is therefore in a triangle. One end of each of three winding phases can be fixed, in particular by welding on one end of one of the three link arms.

[129] According to another aspect of the invention, each phase of the rotor can be

connected to two separate groups of blades. Each phase of the winding can be connected to two connection arms. Each connection arm can be connected to two phases of the winding. The potential can be identical at both ends of each phase of the winding.

[130] The invention is also for a traction system for a transport vehicle comprising:

- an electric machine as described above, and

- a chopper electrically connected to the switch brushes

mechanical and suitable for connection to the vehicle battery.

[131] The transport unit can be a vehicle, in particular a motor vehicle. The transport device can be an autonomous vehicle for delivering objects, in particular with wheels, in particular with propellers, for example a device of the "drone" type or

"Droid".

[132] The chopper is used to adjust the voltage and thus the power variator function. The chopper is not here an inverter which allows the generation of sinusoidal current signals. A rheostat can be provided in place of the chopper which makes it possible to completely extract the power electronics for supplying the electrical machine.

[133] Such a traction system makes it possible to propel a vehicle at low cost.

automobile.

[134] As a variant, the invention can also relate to an alternator comprising the electric machine. The invention may also relate to a system comprising the electric machine capable of operating in engine mode and in alternator mode. [135] Other characteristics and advantages of the invention will become apparent from the following description on the one hand, and from several exemplary embodiments given as an indication and not as a limitation with reference to the appended schematic drawings on the other hand. , on which ones :

[136] [Figure. 1] and [Figure. 2] are schematic sectional views of a

electric machine according to the invention,

[137] [Figure. 3] and [Figure. 4] schematically illustrate the power supply to the winding of the machine according to a first star winding mode,

[138] [Figure 5], [Figure 6] and [Figure 7] illustrate an example of an electric machine of which according to the invention, the winding of which is supplied according to the first mode and in which the capacitors are in a second setting mode. artwork.

[139] [Figure 8] illustrates a variant of the collector described in [Figure 5] in which the capacitors are in a first embodiment.

[140] [Figure 9] and [Figure 10] illustrate another example of a

switch according to the invention to power the coil in the first mode.

[141] [Figure 1 1] schematically illustrates the blades of the collector of Figure 9.

[142] [Figure 12] schematically illustrates a variant of the switch of Figures 9 to 11.

[143] [Figure 13] and [Figure 14] illustrate another example of a

switch according to the invention to power the coil in the first mode.

[144] [Figure 15] illustrates a ring of the manifold of Figure 13.

[145] [Figure 16] and [Figure 17] schematically illustrate the power supply to the machine winding according to a second delta winding mode.

[146] [Figure 18], [Figure 19] and [Figure 20] illustrate an example of a switch collector according to the invention for supplying the winding in the first mode, and [Figure 21] illustrates an isolated ring of the collector of figure 18.

[147] There is schematically shown in Figure 1, in section, an electric machine 1. The machine 1 is suitable for equipping a traction system for a transport vehicle, in particular a motor vehicle. [148] In the example considered, the machine comprises a rotor 3 movable in rotation about the axis X of rotation of the machine and a stator 4 fixed in rotation comprising 2 ^* magnetic poles. The rotor forms the armature and the stator forms the inductor of the machine.

[149] The machine 1 also comprises a casing 5 fixed in rotation, here in two parts, a front 5a and a rear 5b. The casing surrounds the assembly of the stator and the rotor. The casing can be in two parts. The stator 4 is fixed to the front part of the casing, for example force-fitted.

[150] In the example considered, the rotor 3 comprises a rotor shaft 10 and a rotor body 11.

[151] In the example considered, a front bearing 13 and a rear bearing 14 are

through which the rotor shaft 10 passes. The rotor shaft 10 is mounted to rotate with respect to the housing 5, for example by means of rolling members mounted on the bearings 13, 14.

[152] For example, the rotor 3 comprises a first drive member 20

belonging to the machine 1. A second drive member 21 mounted on an element of a traction chain, for example a crankshaft, of the motor vehicle, and an element 22 transmitting the rotational movement of the second drive member 21 to the motor vehicle. first drive member 20 are provided. According to a particular example, the drive members 20, 21 are pulleys and the element 22 transmitting the movement is a belt.

[153] As best seen in Figure 2, the pulley 20 is mounted integral in

rotation on the rotor shaft 10. The rotor shaft can therefore be rotated by the rotational movement of the pulley 20. The pulley 20 is disposed on a first end of the shaft 14, called the front end. The shaft 14 has a second end, called the rear end, opposite to the front end.

[154] In the example considered, the stator 4 can be a claw stator. Such a stator can comprise two pole wheels in the form of annular flanges arranged transversely with respect to the rotor shaft 10. Each pole wheel can comprise on its outer periphery teeth in form of claws extending in a direction substantially parallel to the X axis. The teeth of one of the pole wheels are angularly offset with respect to the teeth of the other pole wheel so that the teeth of the two pole wheels alternately enter each other. The stator 4 also includes an excitation coil 24 mounted between the pole wheels. Magnets

permanent can be arranged between the teeth of the pole wheels.

[155] In the example considered, the excitation winding is supplied with a

direct excitation electric current EXC coming from a chopper of the stator 25. The stator 4 is supplied through the stator chopper by a voltage source which is here the battery B of the vehicle. The excitation winding is connected to terminal B + of battery B.

[156] In the example considered, the rotor body 11 comprises a bundle of sheets, made of ferromagnetic material, comprising sheets stacked axially. The sheet package has (2 ^* p) ^* m ^* q axial extension slots. The rotor body 11 also comprises at least one winding 30, the winding being distributed in q phases. The phases comprise winding sections 31 housed in the notches, the sections of each phase succeeding one another circumferentially. Each phase has two ends 32. The notches are separated from each other by rotor body teeth.

[157] In the example considered in Figure 2, q = 3, the winding is therefore a

three-phase winding whose phases are a, b and c. The rotor 3 is therefore supplied according to a three-phase current system.

[158] The phases of winding 30 can be connected in star or in

polygon. In this embodiment, the rotor has three phases a, b, c connected in a triangle, as illustrated in FIG. 2.

[159] In the example under consideration, each sheet may have an annular shape and include grooves arranged radially. The notches of the stacked sheets form the sheet bundle notches extending in a direction substantially parallel to the X axis.

[160] In the example considered, each phase a, b, c can have a single conductor forming the different winding sections. [161] In the example considered, buns 35 formed by the coil 30 are arranged on either side of the packet of sheets.

[162] The machine 1 according to the example considered is particularly noteworthy in that it comprises a mechanical switch 40 to supply the q phases of rotor 3. In the example considered, in Figures 1 and 2, the mechanical switch therefore supplies power. rotor 3 with a three-phase current system. Switch 40 is located inside the housing.

[163] In the example considered, the switch 40 comprises a manifold 41 movable in rotation about the axis X. The manifold will be described in more detail with reference to Figures 3 to 14. The manifold 41 is fixed in rotation on the rotor shaft 10 and together with rotor 3 forms the armature of machine 1.

[164] In the example considered, the switch 40 also comprises at least one pair of radial extension brushes, a positive brush 45 and a negative brush 46, able to rub on the collector 41. The brushes 45, 46 are fixed in rotation, they are each defined on an angular sector and they are connected to the same voltage source, here battery B of the vehicle. The brushes are therefore supplied with direct current.

[165] In the example considered, a chopper 48 is disposed between the brushes 45, 46 and the terminal B + of the battery B to adjust the voltage and act as a voltage variator.

[166] In the example considered, the brushes 45, 46 have a substantially parallelepipedal shape. Each brush has a radially inner cylindrical surface in contact with the collector 41.

[167] In the example considered, the machine 1 comprises a brush holder assembly 50 fixed in rotation in which the brushes 45, 46 are housed. The brush holder 50 carries the brushes. The brush holder 50 surrounds the collector 41. The brush holder is fixed to the housing, in particular to the rear part 5b of the housing. The brush holder can be fixed on the rear bearing 14 or directly on the cylinder head of the stator.

[168] When the machine 1 operates in generator mode, the pulley 20 and the rotor 3 are driven in rotation and the winding of the rotor 30 is supplied. electrically by the switch 40. The rotor 3 is then magnetized, a magnetic field is created and generates an induced current in the stator winding.

[169] We will now describe in detail the operation and structure of the

switch.

[170] Figures 3 and 4 schematically illustrate the supply by a three-phase current system of the winding of a rotor 3 of a machine 1 comprising two pairs of poles, i.e. p = 2, according to a first star winding mode. Figures 3 and 4 show the switch 40 and the rotor winding 30 unwound.

[171] With reference to FIG. 3, the collector 41 comprises n ^* p ^* q blades

conductors 60 succeeding one another circumferentially, with here n = 1, p = 2 and q = 3, therefore 6 conductive blades. Each blade 60 is defined on an angular sector, the adjacent blades are isolated from each other. The conductive blades are divided into q groups, here three groups a ’, b’, c ’. All the blades 60 of the same group a ’, b’, c ’are electrically connected together and the three groups are alternated circumferentially.

[172] In the example considered, the collector 41 has an elementary pattern of blades which is repeated p times, here two. The elementary pattern of blades is here: blade of group a ', blade of group b' and blade of group c '. The collector 41 has p ^* q passages, here 6, from one type of blade to another. The type of a blade is defined by membership in a group. The collector thus presents an elementary pattern equal to 2 ^* TT / (p ^* q), ie TT / 3 OR again 60 °.

[173] In the example considered, each of the three groups a ', b', c 'of blades is electrically connected to one of the two ends 32 of one of the three phases a, b, c of rotor 3. The other ends 32 of the three phases are electrically connected together so as to form a star coil.

[174] In the example considered, the rotor may have two notches per

phase and per pole (m = 1) that is, here 12 notches. Each of the six manifold blades is aligned with a rotor body tooth. Each of the notches in which a section belonging to a phase of type q is housed is axially aligned with a blade of the collector 41 of the same type. [175] In the example considered, all the blades all have the same angular sector and the same axial dimension. In particular, all the blades 60 are identical and are not axially offset. The blades 60 can be made of copper. The blades 60 may have a radial thickness of between 1 mm and 3mm, for example 2mm. The blades can have an axial dimension between 8mm and 12mm, for example 10mm.

[176] Referring to Figure 4, the switch comprises a single pair of brushes 45, 46 still in contact with the blades 60. Two pairs of brushes could have been considered because the number of pairs can be between 1 and p. The brushes of the pair shown are circumferentially offset from each other by

[(2k + 1) ^* 2 ^* TT] / (2 ^* p)], k being a natural number. In the example considered, the brushes can therefore be offset by an angle of TT / 2 OR 3TT / 2, here the brushes 45, 46 are offset by TT / 2.

[177] The angular offset between the brushes 45, 46 is from center to center, that is to say between the median planes A of each brush.

[178] In the example considered, each blade 60 is separated from the two adjacent blades 60 by an insulating inter-blade 62. The angular opening of each interblade 62 is identical.

[179] In the example considered, the angular opening of each blade 45, 46 is greater than the angular opening of the inter-blades 62. Thus, each blade is always in contact with at least one blade and with two blades during the recovery phases.

[180] Figure 7 illustrates an armature of machine 1 whose collector is described in detail in Figures 5 and 6. In the example considered, the machine 1 is five pairs of poles (p = 5) supplied according to a system of three-phase current (q = 3). The collector 41 here comprises fifteen conductive blades 60 (n = 1). In the example considered, the phases of the winding are connected in a star.

[181] Figure 5 shows the groups of blades a ’, b’, c ’of collector 41. The

FIG. 6 represents the complete collector with in particular a skeleton 65 of the visible collector. [182] In the example considered, the blades 60 of the same group a ', b', c 'are all electrically connected to a ring disposed radially inside the blades. In the example considered, the collector comprises a ring of type a 70 for connecting together the blades 60 of group a ', a ring of type b 71 and a ring of type c 72. In the example considered, the rings 70, 71, 72 follow one another axially. The type b bushing is central and the type a and type c bushes are end points. The rings are axially distributed over an axial length of the blade 60.

[183] In the example considered, a bridge 75 is provided between each blade 60 and the associated ring 70, 71, 72. Each bridge is associated with a single blade 60. The bridges 75 extend radially from the rings without offset axial.

[184] The bridges 75 of the central b-type ring 71 are connected to a central area of the blades 60. The bridges 75 of the end rings 70, 72 are connected to corners of the blades 60.

[185] The bridges and rings are in an interior space of the skeleton 65 while the blades 60 are flush outwardly to come into electrical contact with the brushes. In the example considered, the blades 60 of the same group a ’, b’, c ’, the bridges 75 and the ring 70, 71, 72 form a one-piece ring.

[186] Referring to Figure 6, the skeleton 65, made of insulating material, for example plastic, of revolution about the X axis to hold the blades 60 in position. The skeleton is substantially cylindrical in shape. The skeleton 65 is here in one piece. The skeleton includes fifteen radial openings 67 receiving the blades 60. The skeleton includes a central opening 68 receiving the rotor shaft 10. The manifold 41 also includes a central hub 69 for the passage of the rotor shaft. The skeleton is fixed on the central hub, for example overmolded on the central hub 69.

[187] In the example considered, the collector 41 comprises three link arms 80, each being integral with one of the rings 70, 71, 72. Each link arm comprises a portion made integral with the rings and a portion comprising the free end 81. The two portions are fixed to one another, for example by welding. Each free end 81 is connected to a phase of winding a, b, c to supply it. Each link arm 80 opens

radially of the skeleton 65 through a radial hole 82 formed in the skeleton.

[188] In the example considered with a star winding, only one of the two ends 32 of each phase a, b, c is connected to a link arm.

Each group of blades a ’, b’, c ’thus feeds a single phase of the 3 phases of the rotor.

[189] In the example considered, the collector 41 also includes a

connector 90 for electrically connecting together the ends 32 of phases a, b, c. The connector 90 also includes link arms which alternate with the link arms integral with the rings. The connector 90 opens out radially from the skeleton 65. The connector comprises three ends 91, each to receive each of the phase ends 32. Thus each phase a, b, c comprises one end 32 connected to a link arm 80 and one end connected to the connector 90.

[190] In the example considered, the collector 41 also comprises fifteen

capacitors 100 each mounted between two adjacent blades, therefore between two blades of groups of different groups. Each blade 60 is thus electrically connected to two capacitors. When n = 2, each plate is associated with only a single capacitor.

[191] In the example considered, the capacitors 100 can all be

identical. Each capacitor 100 has a substantially parallelepipedal shape. Each capacitor comprises two plates 101 separated by a polarizable insulator. Each capacitor 100 includes a housing 102 encapsulating the polarizable insulation and part of the armatures.

[192] In the example considered, each capacitor 100 may have an electrical capacity of between 1 and 100 microfarads, for example 20 microfarads.

[193] In the example considered, the capacitors 100 are all on the same axial side with respect to the blades 60. Each capacitor 100 is directly attached to a finger 103 of axial orientation of one of the blades 60. The armatures 101 can be attached directly to the fingers, in particular by welding. The capacitors are all at the same radial level as the blades 60.

[194] In the example considered, the collector also includes a protective element 110 of the capacitors. This protective element is here in one piece and comprises several cavities 1 1 1 each receiving one of the

capacitors 100.

[195] In the example considered, the collector 41 also includes a

fan 115, in one piece and made of an insulating material, in particular plastic. The fan is integral with the skeleton 65. The fan 1 15 comprises eight blades 1 16 regularly distributed circumferentially. The blades 1 16 are here curved and they deploy radially up to the height of the blades.

[196] In the example considered, the fan 115 is arranged axially next to the blades, on the opposite side to that of the capacitors 100. The blades 60 are therefore arranged between the capacitors 100 and the fan 115. More

Specifically, the capacitors 100 are axially on the side opposite to the rotor body 1 1 while the fan 1 15 is disposed axially on the side of the rotor body 1 1. The fan extends, at least in part, in an interior space of the rotor body 11. The fan 115 extends radially between the rotor shaft and the rotor body.

[197] In the example of Figure 8, the capacitors are in a different embodiment. Only three capacitors are provided, each one is mounted between two groups of separate blades.

[198] In this example, the housings 102 of the capacitors are fixed on an axially oriented face of the skeleton, preferably opposite the rotor body 11.

[199] In the example considered, the capacitors 100 are connected to the link arms 80 of the q groups of blades 60. Each armature 101 is fixed here by means of a link piece 1 18, for example a metal wire low resistance, for example a copper wafer.

[200] In the example considered, the capacitors 100 are all arranged in a given angular sector, in particular less than 90 °, in particular less than 45 ° and they are arranged one above the other radially closer to the axis than the blades 60.

[201] With reference to FIGS. 9 to 12, a description will now be given of a variant of collector 41 for the supply by a three-phase current system (q = 3) of a machine 1 with eight pairs of poles with a winding in star. The collector therefore has an elementary pattern equal to 2 ^* TT / (p ^* q), that is to say TT / 1 2 OR again 15 °.

[202] In the example considered, each inter-blade 62 includes an insulated blade 63 which is not electrically connected to any other blade. The blades 63 are said to be insulated in opposition to the electrically connected conductive blades 60 which form the three groups of blades. The insulated blades are at floating potential. The insulated blades 63 are separated from the conductive blades 60 by interstices 64 which can measure between 1mm and 5mm in the direction

circumferential.

[203] According to one aspect of the invention, the angular opening of the insulated blades 63 is between 40% and 50% of the angular opening of the conductive blades 60.

[204] In the example considered, the collector comprises 48 blades, 24 blades

conductive 60 (n = 1, p = 8 and q = 3) and 24 insulated blades 63, the conductive blades 60 being alternating with the insulated blades 63.

[205] In the example considered, the collector 41 has p ^* q passages, here 24

passages, from one type of conductive blade to another. The type of a blade is defined by membership in a group. Single blades do not belong to any group. The collector 41 has an elementary pattern of blades which is repeated p times, here eight times. The elementary pattern of blades is here: blade of group a ', blade of group a', blade of group b ', blade of group b', blade of group c 'and blade of group c' (a ', b', vs').

[206] In the example considered, the skeleton 65 holds the blades 60, 63 in

position. The skeleton is substantially cylindrical in shape. The skeleton 60 is here in one piece. The skeleton comprises 48 radial openings 67 receiving the blades 60, 63. The skeleton comprises a central opening 68 receiving the rotor shaft 10. The manifold 41 also comprises a central hub 69. for the passage of the rotor shaft. The skeleton is fixed on the central hub, for example overmolded on the central hub 69.

[207] Figure 10 is an exploded view of the collector of Figure 9. The blades 60 of the same group a ", b", c "are all electrically connected to a ring disposed radially inside the blades.

[208] In the example considered, the insulated blades are fixed to a ring

inter-leaf 73. The inter-leaf ring 73 is disposed in the interior space of the skeleton 65. The inter-leaf ring 73 radially outside the rings 70, 71, 72. The insulated leaves 63 comprise a foot 74 inserted into an opening of the inter-blade ring by the fixing of the insulated blade.

[209] The inter-leaf ring 73 includes windows 76 for the passage of bridges 75 between the blades 60 of group b and the ring 72 which is in the central position. Thus, the bridges 75 of the b-type ring 78 pass through the interblade ring 73.

[210] Figure 11 shows in section the conductive blades 60 of the collector 41.

The blades isolated from the inter-blades are not shown here.

[21 1] In the example considered, the angular opening b of the inter-blades 62 is

equal to that of 60 blades. The angular opening of each blade and each inter-blade is 7.5 degrees, i.e. 2 * TT / 48 radians. An elementary pattern of the collector is a plate followed by an inter-plate, the elementary pattern of the collector is equal to 15 °.

[212] The example considered in Figure 12, a variant of the

switch of FIGS. 9 to 11. The elementary pattern of the collector is always equal to 15 ° but the sizes of the blades 60 and of the inter-blades 62 are different. The opening of the inter-blades a is equal to 20% of the elementary pattern, i.e. 3 °, in that the opening of the brushes q is equal to 45% of the elementary pattern, i.e. 6.75 °, and in that l 'opening of the blades b is equal to 80% of the elementary pattern of the collector, i.e. 12 °

[213] In the example considered, the coverage rate, which is the ratio between the difference between the angular opening of one of the brushes 45, 46 and the opening angular of one of the inter-blades 62 divided by the elementary pattern of the collector is equal to (12-3) / 15 = 60%

[214] In the example considered, the switch 40 comprises a single pair of brushes 45, 46 still in contact with the blades 60. The brushes of the pair

shown are circumferentially offset from each other by

[(2k + 1) ^* 2 ^* TT] / (2 ^* p)], with k = 0. In the example considered, the brushes 45, 46 are offset by TT / 8 radians, ie 22.5 °. Each brush 45, 46 therefore has overlap periods during which it is in contact with two blades 60 of different groups a, b, c.

[215] In the example considered, the winding is in star and the rate of

60% recovery exhibited by switch 40 of Figure 8 enables the rotor to be supplied with a quasi-sinusoidal three-phase current system.

[216] With reference to FIGS. 13 to 15, a description will now be given of a variant of collector 41 for the supply by a three-phase current system (q = 3) of a machine 1 with six pairs of poles with a winding in star.

[217] This example differs from the previous ones in that n = 2 and in that the inter-blades 62 do not include an insulated blade but are formed by an empty space 36 circumferentially between the conductive blades 60.

[218] In the example considered, the collector 41 has p ^* q passages, here 18, from one type of blade to another. The type of a blade is defined by membership in a group. The collector 41 has an elementary pattern of blades which is repeated p times, here eight times. The elementary motif is here: blade of group a ', blade of group a', blade of group b ', blade of group b', blade of group c 'and blade of group c' (a ', a', b ' , b ', c', c '). The collector 41 thus presents an elementary pattern equal to 2 ^* TT / (p ^* q), ie TT / 9 OR again 20 °.

[219] In the example considered, a bridge 75 is associated with a single blade. As a variant, when n = 2 and two blades of the same type follow one another circumferentially, a bridge can be shared by the two blades.

[220] In the example considered, the angular opening of the inter-blades 62 is equal to that of the blades. The angular opening of each blade and each inter-blade is equal to 5 degrees, ie 2 * TT / 72. FIG. 15 represents the central ring 78 associated with the group of blades b.

[221] Figures 16 and 17 schematically illustrate the power supply by a three-phase current system of the winding of a rotor 3 of a machine 1 comprising two pairs of poles (p = 2) according to a second winding mode (triangle) . Figures 16 and 17 show the switch 40 and the rotor winding 30 unwound.

[222] This example differs from that illustrated in Figures 3 and 4 in that each of the 3 groups of blades a ', b', c 'is electrically connected to two ends 32 of two separate phases a, b, c so as to form a triangle winding.

[223] In the example considered, each phase a, b, c is connected to two

distinct groups of blades a ’, b’, c ’.

[224] With reference to Figures 18 to 21, we will now describe a switch 40 for supplying by a three-phase current system (q = 3) of a machine 1 with six pairs of poles with a delta winding.

[225] In the example considered, the collector here comprises 18 conductive plates 60. (n = 1, p = 6 and q = 3). the collector 41 has p ^* q passages, here 18, from one type of blade to another. The collector 40 has an elementary pattern of blades which is repeated p times, here 6. The elementary pattern is here: blade of group a ', blade of group b' and blade of group c '(a', b ', c' ).

[226] The collector 40 considered here differs from that of the previous ones in that it does not include a connector. The collector only comprises 3 link arms 80 which each receive two phase ends 32. The ends 32 are for example fixed by welding. Each phase a, b, c is therefore connected to two link arms 80 and each link arm 80 is connected to two phases of the coil. The potential is identical at the two ends 32 of each phase a, b, c.

[227] In the example considered, the recovery rate according to this variant can be between 10% and 55%.

Claims

Claims

[Claim 1] Mechanical switch (40) for machine (1)

electrical device suitable for supplying by a polyphase current system comprising q phases, with q positive integer strictly greater than 1, a rotor (3) of a rotating electrical machine having 2 ^* magnetic poles,

including:

- a collector (41) movable in rotation around an axis (X) of the electric machine, of elementary pattern equal to 2 ^* TT / (p ^* q),

- at least one pair of radial extension brushes, a positive brush (45) and a negative brush (46), able to rub on the collector (41), fixed in rotation, each defined on an angular sector, able to be connected to the same voltage source, in particular a vehicle battery (B), characterized in that the mechanical collector (41) comprises n ^* p ^* q, with n integer, with in particular n = 1 or n = 2, conductive blades (60) following one another circumferentially, each blade (60) being defined on an angular sector, the adjacent blades being isolated from each other, the blades being divided into q groups (a ', b', c '), all the blades (60) of the same group being electrically connected together, the q groups being alternated circumferentially,

and in that the brushes (45, 46) of the same pair are circumferentially offset from each other by [(2k + 1) ^* 2 ^* TT] / (2 ^* p)], k being an integer natural.

[Claim 2] Mechanical switch (40) according to claim 1, the blades (60) of the same group (a ', b', c ') all being electrically connected to a ring (70, 71, 72) disposed radially inside the slats (60).

[Claim 3] A mechanical switch (40) according to claim 2, the rings (70, 71, 72) of each group succeeding one another axially.

[Claim 4] A mechanical switch (40) according to any preceding claim, each blade (60) being separated from the two adjacent blades by an inter-blade (62), the circumferential dimension of the inter-blades being chosen to avoid the dielectric breakdown

[Claim 5] A mechanical switch (40) according to any one of the preceding claims, the recovery rate being defined by the difference between the angular opening of a brush (45, 46) and the angular opening of an inter -blade (62) divided by the elementary pattern of the manifold, the coverage rate being between 10% and 55%

[Claim 6] A mechanical switch (40) according to any one of the preceding claims, the collector comprising a fan (1 15)

[Claim 7] A mechanical switch (40) according to any preceding claim, the collector comprising a plurality of capacitors (100), each capacitor being mounted between two separate groups of blades.

[Claim 8] Electric machine (1) comprising:

- a mechanical switch (40) according to any of the

claims 1 to 5,

- a stator (4) fixed in rotation comprising 2 ^* magnetic poles, the stator (4) forming the inductor of the machine,

- a rotor (3) movable in rotation around the axis (X) of the machine

electric, the rotor (3) forming with the collector (41) an armature of the machine, the rotor comprising:

i. a rotor shaft (10), and

ii. a rotor body (11) comprising:

1.a pack of sheets including stacked sheets

axially, the pack of sheets (10) having p ^* q notches of axial extension,

2.at least one winding (30), the winding being divided into q phases (a, b, c) supplied by the switch (40), the phases comprising winding sections housed in the notches, the sections (31) of each phase succeeding one another circumferentially, each phase

having two ends (32).

[Claim 9] An electric machine (1) according to claim 6 and

Claim 8 taken in combination, the fan extending, at least in part, into an interior space of the rotor body.

[Claim 10] An electric machine (1) according to claim 7 and claim 8 taken in combination, the capacitors being axially on the side opposite to the rotor body.

[Claim 1 1] An electric machine (1) according to the preceding claim, each of the q groups of blades (a ', b', c ') being electrically connected to one of the two ends (32) of one of the q phases (a , b, c) of the rotor, the other ends (32) of the q phases being electrically connected together so as to form a star winding (30).

[Claim 12] An electric machine (1) according to claim 6, each of the q groups of blades (60) being electrically connected to two ends (32) of two phases distinct from the q phases (a, b, c) of the rotor so forming a coil (30) in polygon.

[Claim 13] Traction system for a transport vehicle comprising:

- an electric machine (1) according to one of claims 6 to 8, and

- a chopper (48) electrically connected to the brushes (45, 46) of the

switch (40) mechanical and able to be connected to the battery (B) of the vehicle.