WO2021123612A1 - Rotor for a rotating electrical machine - Google Patents

Abstract

The invention relates to a rotor (1) for a rotating electrical machine, the rotor comprising a rotor mass comprising: - a plurality of pole parts (5) each made up of a stack of pole plates (6a, 6b), - a hub (7) made up of a stack of hub plates (8), pole plates (6a, 6b) and hub plates (8) being arranged alternately in at least one longitudinal section of the rotor mass of the rotor, at least one pole plate following a hub plate when moving along a longitudinal axis parallel to an axis of rotation of the machine.

Description

Description

Title: ROTARY ELECTRIC MACHINE ROTOR

The present invention claims the priority of the French application 1915343 filed on December 20, 2019, the content of which (text, drawings and claims) is incorporated here by reference.

The present invention relates to the field of rotating electrical machines and more particularly the rotors of such machines. The invention relates in particular to the manufacture of the rotor mass of the rotor, and in particular to rotors with salient poles.

Technical area

The invention relates more particularly to synchronous or asynchronous machines with alternating current. It relates in particular to traction or propulsion machines for electric motor vehicles (Battery Electric Vehicle) and / or hybrids (Hybrid Electric Vehicle - Plug-in Hybrid Electric Vehicle), such as passenger cars, vans, trucks or buses. The invention also applies to rotating electrical machines for industrial and / or energy production applications, in particular naval, aeronautical or wind turbines.

Prior art

Some salient pole rotors are one piece, with both the shaft, the hub, and the poles being one piece. Others are in two parts, with a shaft inserted into a rotor mass, which can be formed from a stack of ro toric sheets.

Still others are made up of an assembly of the shaft, the hub and so-called inset poles. The attached poles can be screwed onto the hub, in this case with solid poles, or fixed to the latter for example by a dovetail assembly, such as for example in patent application EP 1 249 919. However, , such an axial mounting of the pole on the hub necessarily implies a certain radial play, and therefore the presence of a parasitic air gap.

Patent application EP 2 626 975 discloses a rotor comprising pole parts formed of a stack of first sheets connected to each other by a central annular portion, and arranged between second sheets comprising a slot to be fixed to parts of central bases. In patent application DE 102007 024406, the pole parts also include first sheets interconnected by a central annular part, and arranged between second free sheets.

In patent EP 0 641 059, a rotor of a rotating electrical machine comprises first packs of floating sheets and second packs of sheets ensuring the mechanical cohesion of the rotor. Rods are introduced through the sheets to ensure the assembly is held. The number of sheets of the second packages is relatively small compared to the number of sheets of the first packages, so that the rods are not held by the sheets of the second packages over a large part of their length. Such a machine is not suitable for running at high speeds.

There is therefore a need to benefit from a rotating electrical machine rotor which is simple to manufacture and which benefits from improved mechanical strength, in particular at high rotational speeds of the rotor.

There is also a need to facilitate the winding of the poles in the case of a wound rotor and to facilitate the filling of the spaces between the poles, in particular when the polarity of the rotor is higher.

Summary of the invention

The invention aims to meet this need and it achieves this, according to one of its aspects, by means of an electric machine rotor, the rotor comprising a rotor mass comprising:

- a plurality of pole parts each formed from a stack of pole plates,

- a hub formed by a stack of hub plates, the pole plates and the hub plates being, in at least one longitudinal section of the rotor mass of the rotor, arranged alternately with each other, at least one pole plate succeeding a hub plate when moving along a longitudinal axis parallel to an axis of rotation X of the machine.

The cohesion between the hub and the pole parts is ensured by adhesion between the sheets in alternating contact zones. Adhesion can be achieved by simple friction, or by gluing, or by any other means of adhesion plane on plane.

In the invention, the pole parts are formed by the stacking of pole plates. The pole plates are distinct from the hub plates. The pole plates are not integral with the hub plates. Thanks to the invention, the mechanical and magnetic cooperation between the pole plates and the hub plates is improved, and therefore the torque transmission between the rotor mass and the hub, which is particularly advantageous with a rotor with added poles. Radial play is avoided between the pole pieces and the hub, so that the stability of the assembly is improved. A parasitic radial air gap is also avoided, which makes it possible to improve the electromagnetic performance of the rotor and of the electric machine comprising it.

The implementation of the invention avoids the need for very precise sizing and high precision machining. The cost is therefore reduced. Judicious sizing ensures torque transmission while limiting the assembly effort.

Disclosure of the invention

At least one pole plate and at least one hub plate can be configured so as to allow their tangential cooperation. In one embodiment, each pole plate and each hub plate can be configured so as to allow their tangential cooperation.

By "tangential cooperation" of two sheets is meant that the sheets which cooperate tangentially each have a face in contact with the face of the other sheet, so as to allow a maintenance by adhesion between them when they are tightened one. against each other. Advantageously, the stack of sheets of the rotor mass has no parasitic air gap, once the sheets have been tightened. We can have perfect contact between the different plates, pole plates and hub plates. The solidity of the mechanical connection between the hub and the rotor mass is also promoted.

The stack of pole plates of at least one pole part, better still each pole part, may have first pole plates and second pole plates, differing in shape.

The first pole plates are configured so as to allow their tangential cooperation with the first portions of the hub plates. To this end, at least a first polar sheet may include a cooperation portion. The first polar sheets can all include a cooperation portion. The cooperation portion may include at least one, or even two non-radial edges. It may for example be triangular in shape. The first pole plates may have a shape adapted to cooperate radially with second portions of the hub plates described below.

The second pole plates may have a shape adapted to cooperate radially with the first portions of the hub plates. To this end, they may in particular include a recess. This obviously can include at least one, or even two non-radial edges. It may for example be triangular in shape.

The first pole plates and the second pole plates may be arranged alternately with each other or in groups of first pole plates and a group of second pole plates being arranged alternately with each other.

The stack of hub plates may include first portions of hub plates and second portions of hub plates, differing in shape.

The first portions of the hub plates are configured so as to allow their tangential cooperation with the first pole plates. To this end, at least a first portion of the hub plate may include a cooperation portion. The first portions of the hub plates can all include a cooperation portion. The cooperation portion may include at least one, or even two non-radial edges. It may for example be triangular in shape.

The first portions of the hub plates may have a shape adapted to cooperate radially with the second pole plates.

The second portions of the hub plates may have a shape adapted to cooperate radially with the first pole plates. To this end, they may in particular include a recess. This obviously can include at least one, or even two non-radial edges. It may for example be triangular in shape. The first hub plate portions and the second hub plate portions may be arranged alternately with each other or in groups of first hub plate portions and as a group of second hub plate portions being arranged in a row. alternating with each other.

The rotor may include tie rods for clamping the plates, in particular pole plates and hub plates. Said tie rods can in particular be inserted into orifices formed in the cooperation portions of the plates, in particular of the pole plates and of the hub plates. The tie rods can be tightened with sufficient pressure, for example greater than 5 kN, better still greater than 10 kN, being for example of the order of 26 kN. The tension in the tie rods must be chosen according to the number of cooperation zones tangential, the coefficient of friction between cooperation zones and the pulling force of the required pole part, which can be deduced from the centrifugal force. When the tie rods are tight, for example screwed, the rotor has a very good stability.

In one embodiment, the sheets, in particular pole sheets and hub sheets, can be clamped with an axial clamping force F given by the relationship F = Fcent / (2n * p), where Fcent is the centrifugal force exerted by a polar part, where n is the number of bundles of sheets, n being in particular less than or equal to the number of sheets in the stack, and m is the coefficient of friction between the faces of two consecutive sheets.

In the invention, the sheets are served beyond what would only be necessary to hold the sheets together with an obstacle bond.

In one embodiment, the rotor comprises tie rods for clamping the plates, in particular the first pole plates and the first portions of the hub plates. Said tie rods can in particular be inserted into orifices formed in the cooperation portions of the first pole plates and in the cooperation portions of the first portions of the hub sheets.

The rotor may have hollow tie rods, which can be used to circulate a cooling fluid axially in the poles of the rotor, for example a coolant such as oil, to aid in the cooling of the rotor.

The rotor mass can be arranged around a shaft disposed on the axis of rotation X of the machine. The rotor mass, including its hub, and the shaft are configured to cooperate so as to allow the transmission of torque between the rotor mass and the shaft.

Rotor

The rotor can be wound, comprising coils arranged on each of the pole parts of the rotor.

As a variant, it may be a rotor comprising permanent magnets, in particular with surface or buried magnets. The rotor can be in flux concentration. It can include one or more layers of magnets arranged in I, U or V. The housing of the permanent magnets can be made entirely by cutting in the sheets. Each sheet of the stack of sheets can be made in one piece.

As a further variant, it may be a squirrel cage rotor, or a variable reluctance rotor. The number of poles P at the rotor is for example between 4 and 48, being for example 4, 6, 8, 10 or 12.

The diameter of the rotor may be less than 400 mm, better still less than 300 mm, and greater than 50 mm, better still greater than 70 mm, being for example between 100 and 200 mm.

The pole and hub plates are magnetic.

Each sheet is, for example, cut from a sheet of magnetic steel or containing magnetic steel, for example steel 0.1 to 1.5 mm thick. The sheets can be coated with an electrically insulating varnish on their opposite sides before they are assembled in the stack. Electrical insulation can also be obtained by heat treatment of the sheets, if necessary.

The shaft can be made of a magnetic material, which advantageously reduces the risk of saturation in the rotor mass and improves the electromagnetic performance of the rotor.

As a variant, the rotor comprises a non-magnetic shaft on which the rotor mass is placed. The shaft can be made at least in part from a material from the following list, which is not limiting: steel, stainless steel, titanium or any other non-magnetic material.

The rotor mass can in one embodiment be arranged directly on the non-magnetic shaft, for example without an intermediate rim. As a variant, in particular in the case where the shaft is not non-magnetic, the rotor may include a rim surrounding the shaft of the rotor and coming to bear on the latter.

The rotor mass may have one or more holes to lighten the rotor, allow its balancing or for the assembly of the rotor plates constituting it. Holes can allow the passage of tie rods now integral with each other the sheets.

The sheets can be cut in a tool one after the other. They can be stacked and clipped or glued into the tool, in complete packages or sub-packages. The sheets can be snapped onto each other. Alternatively, the sheet bundle can be stacked and welded outside the tool.

The rotor may or may not be cantilevered relative to the bearings used to guide the shaft.

The rotor can be produced in several sections aligned in the axial direction, for example at least two sections. Each of the sections can be angularly offset with respect to the adjacent pieces (“step skew” in English). Machine and stator

Another subject of the invention is a rotating electrical machine, comprising a rotor as defined above. The machine can be used as a motor or as a generator. The machine can be reluctance. It can constitute a synchronous motor or as a variant a synchronous generator. As a further variant, it constitutes an asynchronous machine.

The maximum speed of rotation of the machine can be high, being for example greater than 10,000 rpm, better still greater than 12,000 rpm, being for example of the order of 14,000 rpm at 15,000 rpm or even 20,000 rpm or 25,000 rpm. The maximum speed of rotation of the machine may be less than 100,000 rpm, or even 60,000 rpm, or even less than 40,000 rpm, better still less than 30,000 rpm.

The machine may have a single inner rotor or, alternatively, an inner rotor and an outer rotor, arranged radially on either side of the stator and coupled in rotation.

The machine can be inserted alone in a housing or inserted in a gearbox housing. In this case, it is inserted in a housing which also houses a gearbox.

The machine has a stator. The latter comprises teeth defining notches between them. The stator may comprise electrical conductors, at least some of the electrical conductors, or even a majority of the electrical conductors, possibly being in the shape of a U or I pin.

The notches can be at least partially closed. A partially closed notch makes it possible to provide an opening at the level of the air gap, which can be used, for example, to place the electrical conductors for filling the notch. A partially closed notch is in particular formed between two teeth which each have pole shoes at their free end, which close the notch at least in part.

Alternatively, the notches can be completely closed. By "fully closed notch" is meant notches which are not open radially towards the air gap.

In one embodiment, at least one notch, or even each notch, can be continuously closed on the side of the air gap by a bridge of material formed in one piece with the teeth defining the notch. All notches can be closed on the side of the air gap by material bridges closing the notches. The bridges of material may have come in one piece with the teeth defining the notch. The stator mass is then devoid of any cutout between the teeth and the bridges of material closing the notches, and the notches are then continuously closed on the side of the air gap by the bridges of material coming in one piece with the teeth defining the notch.

In addition, the notches can also be closed on the side opposite the air gap by an attached cylinder head or integrally with the teeth. The notches are then not open radially outwards. The stator mass may be without a cutout between the teeth and the cylinder head.

In one embodiment, each of the notches has a continuously closed contour. By "continuously closed" is meant that the notches have a continuous closed contour when viewed in cross section, taken perpendicular to the axis of rotation of the machine. You can go all the way around the notch without encountering a cutout in the stator mass.

The stator mass can be produced by stacking magnetic sheets, the notches being formed by cutting the sheets. The stator mass can alternatively be produced by cutting from a mass of sintered or agglomerated magnetic powder. The closing of the notches on the side of the air gap is obtained by bridges of material coming in one piece with the rest of the sheets or the block forming the stator mass.

The stator may not be fitted with attached magnetic wedges for closing the notches. This eliminates the risk of accidental detachment of these wedges.

The stator may include coils distributed in a distributed manner in the notches, in particular having electrical conductors arranged in a row in the notches. By "distributed" is meant that at least one of the coils passes successively through two non-adjacent notches.

The electrical conductors may not be arranged in the notches in bulk but in an orderly manner. They are stacked in the notches in a non-random manner, being for example arranged in rows of aligned electrical conductors. The stack of electrical conductors is, for example, a stack in a hexagonal network in the case of electrical conductors of circular cross section.

The stator may include electrical conductors housed in the notches. Electrical conductors at least, see a majority of electrical conductors, may be in the shape of pins, U or I. The pin may be U-shaped ("U-pin" in English) or straight, being I-shaped ("I-pin" in English).

Each electrical conductor can have one or more strands ("wire" or "strand" in English). By "strand" we mean the most basic unit for electrical conduction. A strand can be of round cross section, we can then speak of "wire", or flat. The flat strands can be shaped into pins, for example a U or an I. Each strand is coated with an insulating enamel.

The electrical conductors can form a single coil, in particular whole or fractional. By "single winding" is meant that the electrical conductors are electrically connected together in the stator, and that the connections between the phases are made in the stator, and not outside the stator, for example in a terminal box. . A coil is made up of a number of phases m spatially shifted in such a way that when supplied by a multi-phase current system, they produce a rotating field. The winding can be whole or fractional. The winding can be full in pitch with or without shortening, or in a fractional variant. In one embodiment, the electrical conductors form a fractional winding, in particular with a shortened pitch.

The winding can be wavy. The electrical conductors can be placed in series in a so-called corrugated winding. The term “corrugated winding” is understood to mean a winding in which the electrical conductors of the same phase and of the same pole are electrically connected to one another so that, for a winding path, the electric current of the phase circulates in the electrical conductors rotating around the axis of rotation of the machine, always in one direction. For a winding track, the electrical conductors of the same phase and the same pole do not overlap when viewed perpendicular to the axis of rotation of the machine.

The winding may have a single winding path or several winding paths. In an "electrical conductor" flows the current of the same phase by winding. The term “winding path” is understood to mean all the electrical conductors of the machine which are traversed by the same electric current of the same phase. These electrical conductors can be connected to each other in series or in parallel or in series-parallel. In the case where there is only one channel, the electrical conductors are connected in series. In the case where there are several channels, the electrical conductors of each channel are connected in series, and the channels are connected in parallel. The electrical conductors can thus form a distributed coil. The winding may not be focused or wound onto tooth.

In an alternative embodiment, the stator has a concentrated winding. The stator may include teeth and coils arranged on the teeth. The stator can thus be wound on teeth, in other words with an undistributed winding.

The teeth of the stator may include pole shoes. Alternatively, the stator teeth are devoid of pole shoes.

The stator may include an outer casing surrounding the yoke.

The teeth of the stator can be made with a stack of magnetic sheets, each covered with an insulating varnish, in order to limit losses by induced currents.

Manufacturing process

The subject of the invention is also, independently or in combination with the foregoing, a method for manufacturing a rotor as defined above.

The process can include the following steps:

(a) Provide a plurality of pole pieces each formed from a stack of pole plates,

(b) Arrange the coils on the pole parts, in particular by winding them,

(c) Insert the pole parts wound on a hub formed by a stack of hub sheets, at least one pole sheet and at least one hub sheet being configured to allow their tangential cooperation.

To this end, the first pole plates and the first portions of the hub plates may include a cooperation portion.

The process can also include the following step:

(d) fixing the sheets by tie rods, the tie rods being in particular inserted into orifices formed in the cooperation portions of the sheets, in particular of the pole sheets and of the hub sheets.

Step (d) can take place after step (b). It may be advantageous to clamp the sheets together by fixing the tie rods after having arranged the coils on the pole parts, in order to facilitate the assembly of the coils. The coils may include coil heads suitable for this purpose.

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

Figure 1 is a cross-sectional view, schematic and partial, of a rotor according to the known prior art.

Figure 2 is an exploded and perspective view, schematic and partial, of a rotor produced in accordance with the invention.

FIG. 3 is a schematic and partial view of the pole plates and of the hub of the rotor of FIG. 2.

Figure 4 illustrates the assembly of the rotor of Figures 2 and 3.

Figure 5 illustrates the assembly of the rotor of Figures 2, 3 and 4.

FIG. 6 is an exploded and perspective view, schematic and partial, of an alternative embodiment of a rotor produced in accordance with the invention.

FIG. 7 is an exploded and perspective view, schematic and partial, of the rotor of FIG. 6.

FIG. 8 is an exploded and perspective view, schematic and partial, of the rotor of FIG. 6.

FIG. 9 is an exploded and perspective view, schematic and partial, of the rotor of FIG. 6.

FIG. 10 is a cross-sectional view, schematic and partial, of an alternative embodiment of the rotor produced in accordance with the invention.

detailed description

Illustrated in Figure 1, by way of explanation, a rotor 30 according to the known prior art, comprising a dovetail assembly between a pole piece 31 and a hub 32 intended to be mounted on a shaft, not shown. The pole piece 31 carries a coil 33, retained by pole shoes 34 on the pole piece 31. It is understood that G dovetail assembly implies the presence of a certain radial play to allow assembly, and therefore the presence of dovetail. 'a parasitic air gap, especially in all areas which do not transmit force. It may also be necessary to provide a radial preloading system which pushes the attached pole outwards, sufficiently to ensure the stability of the assembly with respect to the centrifugal force. There is illustrated in Figures 2 to 5 an inner rotor 1 of a rotary electrical machine, produced in accordance with the invention. The rotating electrical machine also includes an external stator, not shown. The stator makes it possible to generate a rotating magnetic field for driving the rotor 1 in rotation, in the context of a synchronous motor, and in the case of an alternator, the rotation of the rotor induces an electromotive force in the windings of the stator.

The rotor mass 3 has a central opening for mounting on a shaft, not shown. The shaft can, in the example considered, be made of a non-magnetic material, for example non-magnetic stainless steel or aluminum, or on the contrary be magnetic.

The rotor 1 shown in Figure 2 comprises a rotor magnetic mass 3 extending axially along the axis of rotation X of the rotor. The rotor magnetic mass 3 comprises a plurality of pole parts 5 each formed of a stack of pole plates 6a, 6b, and a hub 7 formed of a stack of hub plates 8.

Pole sheets 6a, 6b and hub sheets 8 are, in at least one longitudinal section of the rotor mass of the rotor, namely in the area of overlap between poles and hub, arranged alternately with each other, at least a pole plate succeeding a hub plate when moving along a longitudinal axis parallel to an axis of rotation X of the machine.

The rotor mass 3 is arranged around a shaft, not shown, arranged on the axis of rotation X of the machine. The rotor mass 3, in particular its hub 7, and the shaft are configured to cooperate so as to allow the transmission of torque between the rotor mass and the shaft.

In the invention, the pole pieces 5 are formed by stacking the pole plates 6a, 6b. The pole plates 6a, 6b are separate from the hub plates 8. The pole plates are not integral with the hub plates.

The pole plates 6a, 6b and the hub plates 8 are configured so as to allow their tangential cooperation, as illustrated in Figures 4 and 5.

The stack of pole plates 6a, 6b of each pole part 5 comprises first pole plates 6a and second pole plates 6b, differing in shape.

The first pole plates 6a are configured so as to allow their tangential cooperation with the first portions of the hub plates 8a. They include a cooperation portion 10. The cooperation portion 10 has two non-radial edges 11. It is for example triangular in shape.

The first pole plates 6a have a shape adapted to cooperate radially with the second portions of the hub plates 8b.

The second pole plates 6b have a shape adapted to cooperate radially with the first portions of the hub plates 8a. To this end, they may in particular include a recess 12. This recess 12 may include at least one, or even two non-radial edges 13. It may for example be triangular in shape.

The first pole plates 6a and the second pole plates 6b are arranged alternately with each other or in groups of first pole plates and a group of second pole plates being arranged alternately with each other.

The stack of hub plates thus comprises first portions of hub plates 8a and second portions of hub plates 8b, differing in shape.

The first portions of the hub plates 8a are configured so as to allow their tangential cooperation with the first pole plates 6a. To this end, the first portions of the hub plates 8a comprise a cooperation portion 16. The cooperation portion 16 has two non-radial edges 17. It may for example be triangular in shape.

The second hub plate portions 8b have a shape adapted to cooperate radially with the first pole plates 6a. To this end, they include a recess 18. This recess 18 has two non-radial edges 19. It may for example be triangular in shape.

The first hub plate portions 8a and the second hub plate portions 8b are arranged alternately with each other or in groups of first hub plate portions 8a and in a group of second hub plate portions 8b being arranged alternately with each other.

The rotor comprises tie rods 20 for clamping the plates, both pole plates 6a and 6b and hub plates 8. Said rods can in particular be inserted into orifices 22 formed in the cooperation portions 10 of the first pole plates 6a and in the cooperation portions 16 of the hub plates 8. The tie rods are tightened with sufficient pressure, for example of the order of 26 kN. In the example which has just been described, the orifices 22 are closed, being of closed contour.

The embodiment illustrated in Figs 6 to 9 differs from the previous one by the shape of the first pole plates 6a and of the first portions of the hub plates 8a. These do not include an orifice 22 with a closed contour, but a passage 22 for the tie rods with an open contour. This passage 22 is open respectively to the second portions of hub plates 8b for the first pole plates 6a, and to the second pole plates 6b for the first portions of hub plates 8a. In this embodiment, the second portions of the hub plates 8b and the second pole plates 6b have the same shape as previously.

In the embodiment of Figure 10, the first pole plates 6a and the first hub plate portions 8a have the same shape as in the embodiment of Figures 6 to 9, but the shape of the second hub plate portions 8b and the second pole plates 6b differ. They comprise in the triangular recess 18 and 12 respectively a complementary portion 23 of the recess 22 in a half-moon to accommodate the tie rods 20.

The method for manufacturing the rotor will now be described in more detail. It consists of the following steps:

(a) Provide a plurality of pole parts 3 each formed by a stack of pole plates 6a, 6b,

(b) Arrange coils 25 on the pole parts, in particular by winding them,

(c) Insert the pole parts wound on a hub 5 formed by a stack of hub plates 8, the pole plates 6a, 6b and the hub plates 8 being configured so as to allow their tangential cooperation.

The process also includes the following step:

(d) fixing the sheets by tie rods, the tie rods being in particular inserted into orifices formed in the cooperation portions of the sheets, in particular of the pole sheets and of the hub sheets.

Step (d) preferably takes place after step (b).

The assembly obtained can be impregnated before being inserted into the stator prepared elsewhere.

Of course, the invention is not limited to the embodiments which have just been described.

Claims

Claims

1. Rotor (1) of a rotating electrical machine, the rotor comprising a rotor mass comprising:

- a plurality of pole pieces (5) each formed of a stack of pole plates (6a,

6b),

- a hub (7) formed of a stack of hub plates (8), pole plates (6a, 6b) and hub plates (8) being, in at least one longitudinal section of the rotor mass of the rotor, arranged alternately with each other, at least one pole plate succeeding a hub plate when moving along a longitudinal axis parallel to an axis of rotation of the machine, at least one pole plate (6a, 6b) and at least one hub plate (8) being configured so as to allow their tangential cooperation so as to allow maintenance by adhesion between them.

2. Rotor according to the preceding claim, G stack of pole plates of at least one pole part, better still each pole part, comprising first pole plates (6a) and second pole plates (6b), differing in shape.

3. Rotor according to the preceding claim, at least a first pole plate (6a) comprising a cooperation portion (10).

4. A rotor according to any one of the preceding claims, the stack of hub plates comprising first portions of hub plates (8a) and second portions of hub plates (8b), differing in shape.

5. Rotor according to the preceding claim, at least a first portion of the hub plate (8a) comprising a cooperation portion (16).

6. Rotor according to any one of the preceding claims, comprising tie rods (20) for clamping the plates, in particular pole plates and hub plates, said tie rods (20) being in particular inserted into orifices (22) formed in the cooperation portions of the sheets, in particular the pole sheets and the hub sheets.

7. Rotor according to any one of the preceding claims, in which the sheets are used, in particular pole sheets and hub sheets, with an axial clamping force F given by the relationship F = Fcent / (2n * p), where Fcent is the centrifugal force exerted by a polar part, where n is the number of packets of sheets, n being in particular less or equal to the number of sheets in the stack, and m is the coefficient of friction between the faces of two consecutive sheets.

8. A rotor according to any one of the preceding claims, comprising tie rods for clamping the first pole plates (6a) and the first portions of the hub plates (8).

9. Rotor according to the preceding claim, said tie rods being inserted into orifices formed in the cooperation portions (10) of the first pole plates (6a) and in the cooperation portions (16) of the first portions of the hub sheets (8). .

10. A rotor according to any one of the preceding claims, the rotor mass (3) being arranged around a shaft disposed on an axis of rotation (X) of the machine.

11. A rotor according to any one of the preceding claims, being wound, comprising coils arranged on each of the pole parts (3).

12. A rotating electric machine comprising a rotor (1) according to any one of the preceding claims and a stator (2).

13. Machine according to the preceding claim, the stator (2) comprising electrical conductors, at least part of the electrical conductors, or even a majority of the electrical conductors, being in the form of a U-shaped or I-shaped pin.

14. A method of manufacturing a rotor (1) according to any one of claims 1 to 8, comprising the following steps:

(a) Provide a plurality of pole pieces (5) each formed by a stack of pole plates (6a, 6b),

(b) Arrange the coils on the pole parts, in particular by winding them,

(c) Insert the pole parts (5) wound on a hub (7) formed by a stack of hub plates (8), at least one pole plate and at least one hub plate being configured so as to allow their cooperation tangential.

15. Method according to the preceding claim, comprising the following step:

(d) fixing the sheets by tie rods (20), the tie rods being in particular inserted into orifices (22) formed in the cooperation portions of the sheets, in particular of the pole sheets and of the hub sheets.

16. Rotor (1) of a rotating electrical machine, the rotor comprising a rotor mass comprising:

- a plurality of pole parts (5) each formed from a stack of pole plates (6a, 6b),

- a hub (7) formed of a stack of hub plates (8), pole plates (6a, 6b) and hub plates (8) being, in at least one longitudinal section of the rotor mass of the rotor, arranged alternately with each other, at least one pole plate succeeding a hub plate when moving along a longitudinal axis parallel to an axis of rotation of the machine, the stack of pole plates of at least a polar part, better still of each polar part, comprising first polar plates (6a) and second polar plates (6b), differing in their shape.