EP3804085A1

EP3804085A1 - Stator for a rotating electrical machine

Info

Publication number: EP3804085A1
Application number: EP19727429.3A
Authority: EP
Inventors: Jacques Saint-Michel; Xavier JANNOT; Olivier Gas; Nicolas Langlard; Sébastien DESURMONT
Original assignee: Moteurs Leroy Somer SAS; Skyazur SAS
Current assignee: Moteurs Leroy Somer SAS; Skyazur SAS
Priority date: 2018-06-07
Filing date: 2019-06-04
Publication date: 2021-04-14
Also published as: US20210203214A1; FR3082372A1; WO2019234026A1; KR20210064110A; JP2021527388A; FR3082372B1; CN112602252A

Abstract

The present invention relates to a process for manufacturing an electrical-machine stator (2), the process employing: - a toothed ring (25) comprising teeth (23) that are connected together by bridges of material and that define, therebetween, notches (21) that are radially open toward the exterior, - windings (22) produced outside of the notches (21), and - a yoke (29) configured to be added to the toothed ring (25), the process comprising: fastening at least one sheet insulator to at least one segment (22a, 22b) of each of the windings, inserting said segments of winding (22a, 22b) with the insulators into the notches (21) via a radial movement directed toward the interior of the notches (21), and assembling the yoke (29) on the radially exterior surface of the ring (25) in order to radially close the notches (21).

Description

ROTATING ELECTRIC MACHINE STATOR

The present invention relates to rotating electrical machines and more particularly the stators of such machines. It also relates to the manufacturing processes of these machines.

In most known stators, the breech household notches completely open or semi-open towards the gap, so as to allow the introduction of windings. Generally, the half-open notches receive electrical conductors of circular cross section arranged in bulk, while the open notches house electrical conductors of rectangular cross section, arranged in a row. In both cases, the electrical conductors are isolated from the stator mass by sheets inserted into the U-shaped slots and receiving the electrical conductors. In the case of a notch receiving two windings of different phases, the windings of different phases are also separated from each other by an insulating sheet. The insulating sheet (s) must be held in position in the notches during insertion of the electrical conductors.

US Pat. No. 6,198,190 discloses a stator having semi-open recesses towards the air gap receiving U-shaped electrical conductors of rectangular cross-section. Such electrical conductors are inserted into the notches by sliding electrical conductors in the notches along the longitudinal axis of the notches. The electrical conductors are isolated from the stator mass and between them by an S-shaped insulation arranged in the notches. The insulation is inserted into the notches before the insertion of the electrical conductors.

The patent application LR 3,019,947 describes a stator comprising a toothed crown comprising teeth interconnected by material bridges and defining between them notches for receiving the coils, the notches being open radially outwards. The openings of the notches are closed by a yoke attached to the toothed crown.

There is a need to benefit from a method of manufacturing a rotating electric machine stator allowing an easy and effective filling of the notches, while ensuring satisfactory electromagnetic performance. The invention relates more particularly to the insulation of windings in the notches by limiting the risk of damage to the insulators while allowing a quick and easy installation of the coils in the notches.

Process

The invention meets this need, according to a first aspect, using a method of manufacturing an electric machine stator, the method implementing:

a toothed crown comprising teeth interconnected by material bridges and defining between them notches open radially outwards, coils made out of the notches, and

a cylinder head configured to be attached to the crown,

the process comprising the following steps

Fastening at least one sheet insulator to at least a portion of each of the coils,

Inserting said winding portions with the sheet insulators into the notches by a radial displacement directed inwards of the notches, and

• assembly of the cylinder head on the crown to close the notches radially.

The cylinder head allows in particular to keep the windings in the notches after insertion. The breech can be assembled to the crown in various ways.

The fact that the notches open radially outwardly allows the coils to be inserted into the notches by a radial inward movement of the notches. The installation of the coils is facilitated, firstly in that the access to the interior of the notches is easier, being open notches completely and towards the outside rather than the gap, and secondly in that the space available around the crown, for the necessary tools, is greater than the space available in the stator bore.

Fixing sheet insulators on the windings isolates the coils from the edges of the notch, but also to mechanically hold the conductors of the coils during the manufacture of the stator. This maintenance facilitates the insertion of the coils into the notches and reduces the space between the coils of the coil.

The insertion of the coils with the insulators in the notches is, in particular, made possible by the fact that the notches are open towards the outside, which increases the space available for inserting the windings. The risk of damage to the insulation is reduced. In addition, the step of isolating the coils from the surface of the notches is performed out of the notches, which makes it easier and more reliable.

Finally, such an insulation makes it possible to increase the possibilities of arrangement of the insulators on the coils because it is no longer necessary for the insulators to open towards the opening of the notch to allow the insertion of the electrical conductors. This allows better insulation of the windings.

The method comprises a step of forming the windings prior to the step of fixing the insulators.

The method may comprise a step of sizing the sheet insulator or corresponding winding portions prior to the step of fixing the sheet insulator on each winding portion when the sheet insulator is not pre-glued. .

In the case where the winding is of substantially rectangular section, the step of fixing the sheet insulator on each of the winding portions may comprise the following sub-steps:

positioning the insulation in flat sheet,

positioning a first face of the winding on the sheet insulation, particularly in the center of the sheet insulation, by pressing the winding portion in contact with the sheet insulation, in particular by applying pressure on a second opposite face at the first face, to maintain contact between the sheet insulator and the first face of the coil,

application of the two free sides of the sheet insulator on two opposite sides of the winding,

flap of one side of the free sheet insulation on the second face and then flap of the sheet of free sheet insulation remaining on the second face, the sheet insulation being of a width relative to the corresponding winding such that its extremities are superimposed on the second face, and

application of a pressure on the second face of the winding.

Such a folding method allows the sheet insulation to be pressed against the winding portion, which prevents the sheet insulation from being folded on the winding portion and limits the risk of deterioration of the insulating material. sheet during insertion of the coils into the notches and when mounting the cylinder head on the crown. The various steps of fixing the insulation can be performed using a suitable folding device comprising flaps for folding the sheet insulation on the side faces, drawers for folding the two sides of the sheet insulator on the second face and a holding tool for maintaining the winding in position and exerting pressure on the second face of the winding. In addition, the presence of material bridges reduces the risk of loss of varnish in the air gap during the impregnation with a varnish of the complete stator. This reduces the need for cleaning.

It also makes it possible to reduce the leakage of the varnish into the air gap during operation and the machine on which the stator is mounted. This simplifies the maintenance of the machine.

The term "varnish" must be understood here in a broad sense and covers any type of impregnating material, in particular polymer.

The stator can be used as a closed impregnation chamber by sealing the ends of the stator only. The tooling is thus simplified. This also reduces the amount of varnish lost and cleaning operations.

In addition, such a stator strongly reduces the electromagnetic disturbances related to the presence of the openings of the notches giving on the air gap in the prior art. The absence of opening of the notches to the air gap reduces the pulsations of notches. The electromagnetic performance of the machine is improved.

stator

nick

At least one notch, better all the notches, may have opposite edges parallel to each other. The width of the notches is preferably substantially constant over their entire height.

At least one tooth, better all the teeth, may be generally trapezoidal when observed in section in a plane perpendicular to the axis of the stator.

Preferably, several material bridges each have a deformable zone, and preferably all the bridges of material each have a deformable zone. By "deformable zone", it includes a zone of the material bridge deforming preferentially during a relative movement of the teeth it connects. Deformation of the material bridge may result in an elongation or shortening the circumferential dimension of the material bridge, resulting in an elongation or shortening of the circumferential dimension of the crown. The preferential deformation can result from a particular shape given to the bridge.

The deformable zone makes it possible to adapt to the mechanical stresses to which the crown is subjected during the assembly of the crown with the cylinder head. In addition, it allows if desired to have more open slots before mounting the cylinder head and therefore a greater clearance between the coils and the wall of the notches during the insertion of the coils, which facilitates it and reduces the risk of insulation damage.

Preferably, the bridges of material each have a zone with reduced magnetic permeability, especially in the form of at least one localized narrowing, at least one localized crush, at least one opening or at least one localized treatment. . The area of reduced magnetic permeability of the material bridge is magnetically saturated during operation of the machine, which limits the passage of the flow and increases the efficiency of the machine.

Preferably, the bottom of the notches each has at least one flat portion against which a winding, preferably of substantially rectangular section, is supported. The flat portion or portions are substantially perpendicular to the radial axis of the notch.

The bottom of the notch may be flat, with the exception of a recess and / or a deformable zone.

The deformable zone or the recess preferably forms a clearance between the material bridge and the corresponding winding, which can facilitate the penetration of the varnish during the impregnation of the stator.

This allows a good filling of the notches by the windings in the case of windings of rectangular cross section, allowing the windings to support flat in the bottom of the notch.

Breech - crown interface

Preferably, the crown has reliefs on its radially outer surface cooperating during the step of assembling the cylinder head on the crown with complementary reliefs of the cylinder head. Such reliefs allow, by complementarity of shapes, to maintain the ring and the yoke fixed relative to each other. The cooperating reliefs are preferably of the dovetail and mortise type. The method may comprise a preliminary step of manufacturing the ring comprising a helical winding step of a sheet metal strip having teeth connected by the material bridges, the opposite edges of each notch becoming, preferably, substantially parallel between them when the band is rolled up on itself to form the crown.

Alternatively, the strip may be formed of sectors each having a plurality of teeth, the sectors being connected by links, these sectors being cut in a sheet metal strip. The connections may be flexible bridges connecting the sectors to each other and / or parts of complementary shapes, for example of the dovetail and mortise type or complementary reliefs bearing against each other, especially when the crown is kept in compression by the cylinder head.

The complementary shapes can be on the material bridges so that the different sectors are assembled at the bridges of material. Preferably, the assembly of the complementary shapes of the different sectors is outside the deformable zones and / or reduced permeability of the material bridges. This facilitates assembly, especially in the case of large machines. For example, the sectors have recessed shapes cooperating with complementary projecting forms of an adjacent sector.

As a variant, the step of manufacturing the crown may include a step of stacking precut magnetic sheets.

In another variant, the ring may be manufactured by additive manufacturing, for example by sintering powder.

The cylinder head can be made by directly winding a sheet metal strip if its width allows it, forming or not in said sheet metal strip adapted slots during its cutting, so as to facilitate this winding, or by stacking magnetic sheets precut or cakes made by additive manufacturing, for example by sintering powder.

windings

The coils can be arranged in the notches in a concentrated or distributed manner.

By "concentrated", it is understood that the coils are wound each around a single tooth. By "distributed" is meant that at least one of the windings passes successively in two not adjacent notches.

Preferably, the coils are arranged in the notches in a distributed manner, in particular when the number of rotor poles is less than or equal to 8.

The windings each comprise at least one electrical conductor which may be in cross section of circular shape, or of polygonal shape, in particular with rounded edges, preferably of rectangular shape, this list not being limiting.

When the conductors are of circular cross section, they can be assembled according to a hexagonal winding. When the conductors are of polygonal cross section, they can be assembled to form a coil in one or more rows oriented radially. The optimization of the assembly can allow to have in the notches a larger amount of electrical conductors and thus to obtain a stator of greater power at constant volume.

The electrical conductors can be arranged randomly in the windings. Preferably, the electrical conductors are stored in the windings. By "rows" is meant that the conductors are not arranged in the bulk windings but in an orderly manner. They are stacked in the windings non-randomly, for example being arranged in one or more rows of aligned electrical conductors, in particular in one or two rows, preferably in a single row.

Preferably, the electrical conductors are of rectangular cross section and the coils are wound on edge. By "singing" is meant the narrow face of the winding wire, as opposed to "flat". A winding wound on edge is a winding whose wire, oblong rectangular cross section, having a direction of elongation, in particular rectangular, is wound perpendicularly to the flat. The wire is thus wound around a winding axis perpendicular to the direction of elongation of its cross section.

The electrical conductors are preferably electrically isolated from the outside by an insulating coating, in particular an enamel.

Preferably, the winding portions inserted in the notches are each separated from the inner surface of the notch by at least one thickness of the corresponding sheet insulation, better by at least two thicknesses of the corresponding sheet insulation. Such insulating sheet allows better insulation of the windings relative to the notch.

Preferably, during the step of inserting the winding portions, each notch receives at least two winding portions, in particular at least two winding portions of different phases. Preferably, these two winding portions at least are superimposed radially in the notch.

The two winding portions of the same notch may be separated from each other by at least one thickness of sheet insulation, preferably at least two thicknesses of sheet insulation, better by at least four layers of sheet insulation. Between the two winding portions located in the same notch, the greater the number of sheet insulation thicknesses between them, the better the insulation.

The windings form on the outside notches of the buns.

The method may include a step of separating two coils of coils of different adjacent phases by an additional sheet insulator. The additional sheet insulation may be fixed between the two buns on at least a portion of one of two buns in a crossing zone of the two buns.

Preferably, the windings are not U-shaped pins ("U-pin" in English) nor I-shaped ("I-pin" in English).

The method may comprise a step of twisting the stator ("skewing" in English). Such twisting may help to clamp the coils into the notches and reduce the harmonic notches.

Insulating

The sheet insulators may be any electrically insulating material, preferably flexible, especially aramid, for example Nomex®, or aramid laminate and polyester or polyimide, for example a laminate Nomex® NMN type (Nomex®-Mylar®-Nomex®) or NKN (Nomex®-Kapton®-Nomex®) or Mica / polyester.

Preferably, the sheet insulators extend over straight coil portions. Preferably, the sheet insulators extend only over portions of straight coils, the curved portions of the coils being devoid of insulating sheets.

Preferably, the sheet insulators are fixed on the coils on at least a portion of their surface, better over their entire surface, by gluing. The bonding of the sheet insulation can be done using an adhesive on all or part of the sheet insulation and / or all or part of the corresponding winding portion or an adhesive tape. As a variant, each sheet insulator is fixed on the winding portion at at least one of its longitudinal ends, preferably at its two longitudinal ends, by bonding with adhesive on the sheet insulator or directly on the coils or using at least one adhesive tape, for example straddling the sheet insulator and the winding portion.

Preferably, each winding portion is covered by a single sheet insulator.

As a variant, each winding portion is covered by at least two sheet insulators superimposed at least partially or with joined edges, in particular by two U-shaped sheet insulators fixed head-to-tail on the corresponding winding portion.

Preferably, the sheet insulators extend, after insertion of the winding portions in the notches, over the entire height of the notches.

Preferably, the sheet insulators protrude axially out of the notches on either side of the latter after insertion.

Alternatively, the insulators are of a height substantially equal to the height of the notches so that the insulators are fitted into the notches to not protrude from the latter. This can be advantageous in the case of low voltage machines.

The sheet insulators extend over a length greater than or equal to the height of the notches.

Each sheet insulator may have one or more windings around the corresponding winding portion. Preferably, the sheet insulators are at least one turn, more preferably at least two turns, of the corresponding winding portion.

The sheet insulators may each comprise two opposite longitudinal edges extending substantially along the longitudinal axis of the winding portion. associated. Preferably, in this case, the sheet insulators are aramid or laminate aramid and polyester or polyimide.

Preferably, the winding portions are of rectangular cross-section and the two opposite longitudinal edges of each sheet insulator extend on the same face of the corresponding winding portion.

The longitudinal edges of each sheet insulator may be in contact with each other on said face. In this case, the sheet insulators make a turn of the corresponding winding portion.

As a variant, each sheet insulator can be superposed at least in part on itself. In this case, the sheet insulators make more than one turn of the winding portion. Preferably, the insulation is then at least glued on its surface near at least one of the longitudinal edges.

Preferably, the two longitudinal edges of the sheet insulator extend on the same face of the winding portion when the winding is of rectangular section. The sheet insulator is in particular fixed on the winding portion using the method described above. In this case, only the two sides folded on the second face can be glued.

Preferably, each winding portion is disposed in the corresponding notch so that the longitudinal edges of the corresponding sheet insulation extend over one face of the winding portion facing the opening of the notch or towards a portion of a winding, in particular of different phase, inserted in the same notch.

Preferably, in the case where each notch receives at least two coils and where the insulators make a turn of the corresponding winding portion, each coil portion is arranged in the corresponding notch so that the longitudinal edges of the insulator corresponding sheet extend on one side of the winding portion oriented towards the opening of the notch. The two winding portions of different phases are then separated by two thicknesses of sheet insulation with at least one of the thicknesses of insulation which is continuous.

Preferably, in the case where each notch receives at least two windings and where each insulator makes more than one turn of the corresponding winding portion, each winding portion is arranged in the corresponding notch so that the edges longitudinal portions of the corresponding sheet insulation extend on one face of the winding portion facing the other winding portion, in particular of different phase. The windings of different phases are then separated by four thicknesses of insulation.

As a variant, in the case where each notch receives at least two coils, the longitudinal edges of each sheet insulator may be spaced apart from one another by a distance less than the width of the face on which they overlap and each coiling portion is disposed in the corresponding notch so that the longitudinal edges of the corresponding sheet insulator extend over a face of the winding portion facing the opening of the notch. The two winding portions of different phases are then separated by two thicknesses of sheet insulator with at least one of the insulation thicknesses which is continuous.

Alternatively, the sheet insulation may be in the form of a tape wrapped around the coil portion. In this case, the sheet insulator makes a plurality of turns of the corresponding winding portion. Preferably, the tape is superimposed on itself from one turn to the other of the winding portion. In this case, the sheet insulation is preferably made of mica / polyester

stator

The subject of the invention is, according to a second aspect, a stator comprising:

a radially inner crown, comprising:

o teeth leaving between them notches open radially outwards, and

bridges of material each connecting two teeth adjacent to their base on the gap side and defining the bottom of the notch between these teeth, and

a radially outer yoke attached to the crown,

windings arranged in the notches, with notches at least one winding of a first phase and a winding of a second phase different from the first phase, these windings being separated in the notch by at least two thicknesses of one or more sheet insulators, a sheet insulator at least partially surrounding each of these coils.

The features described above in connection with the first aspect of the invention also apply to this second aspect. Machine and rotor

The invention also relates to a rotating electrical machine comprising a stator as defined above. The machine can be synchronous or not. The machine can be reluctant. It can constitute a synchronous motor.

The rotating electrical machine may comprise a wound rotor or permanent magnets.

detailed description

The invention will be better understood on reading the following detailed description, nonlimiting exemplary embodiments thereof, and on examining the appended drawing, in which:

FIG. 1 is a schematic and partial perspective view of a stator according to the invention, the yoke being partially attached to the crown,

FIG. 2 represents a schematic cross-sectional view of the stator of FIG. 1,

FIG. 3 is a schematic perspective view of the stator ring with the windings,

FIG. 4 is a detail of a cross-sectional view of FIG. 3,

FIG. 5 represents a detail of FIG.

FIGS. 6A to 6C represent variants of FIG. 4,

FIGS. 7 and 8 show variants for fixing the insulating sheet on a winding portion, and

- Figure 9 illustrates a method of fixing the insulation on the winding portion.

FIGS. 1 to 5 show a stator 2 of a rotating electrical machine. The stator makes it possible to generate a rotating magnetic field driving a rotor in rotation, in the context of a motor, and in the case of an alternator, the rotation of the rotor induces an electromotive force in the stator windings.

The examples shown below are schematic and the relative dimensions have not necessarily been met.

stator

The stator 2 comprises windings 22, which are arranged in notches 21 formed between teeth 23 of a toothed crown 25. The notches 21 are closed on the air gap side by material bridges 27, each connecting two consecutive teeth of the ring 25 and have a radial opening 28 towards the outside of the ring 25.

The stator 2 comprises a yoke 29 attached to the ring 25. The yoke 29 has recesses 50 recessed mortise type cooperating with protruding reliefs of the dovetail type 52 of the ring gear 25 for mounting the cylinder head 29 on the crown 25.

The notches 21 are, in the example described, with radial edges 33 parallel to each other and are, in section in a plane perpendicular to the axis of rotation X of the machine, of substantially rectangular shape.

The bottoms of the notches 35 are of a shape substantially complementary to that of the coils 22. In the example of FIGS. 1 to 4, the bottoms of the notches 35 have two flat portions 30 on either side of the recess 40, against which the coils 22 rectangular are in support. The bottoms of the notches 35 are connected to the radial edges 33 by rounded edges 36.

The material bridges 27 may be of constant thickness as illustrated and be substantially non-deformable. In a non-illustrated variant, the material bridges 27 each have a zone of reduced magnetic permeability, in particular a localized narrowing, a crushing of the material, a localized treatment or one or more openings, allowing a magnetic saturation of the sheet, which limits the passage of the magnetic flux, and / or each have a deformable zone for varying the circumferential diameter of the ring 25.

The ring 25 and / or the yoke 29 are each formed of a stack of magnetic sheets stacked along the X axis, the sheets being for example identical and superimposed exactly. They can be held together by clipping, rivets, tie rods, welds and / or any other technique. The magnetic sheets are preferably magnetic steel.

The ring 25 and / or the yoke 29 may also be formed of one or more cut sheet metal strips wound on themselves.

Windings and insulators

The coils 22 may be arranged in the notches 21 in a concentrated or distributed manner, preferably distributed. In the example illustrated in Figure 2, the electrical conductors 34 of the windings 22 are arranged in the notches in a row.

As can be seen in FIG. 4, the electrical conductors 34 are preferably of flattened rectangular cross-section and are superimposed radially, for example in a single row. They are superimposed on each other by the dish. The coils 22 are said wound on edge. The coils 22 may be, in cross section, of substantially rectangular shape.

In the examples illustrated, the coils 22 have a single radial row of electrical conductors 34. However, the coils 22 may comprise a plurality of radial rows of electrical conductors, for example two rows of electrical conductors.

Each notch 21 may receive two winding portions 22a and 22b stacked with different phases. Each coil 22 may, in cross section, be of substantially rectangular shape.

In the example illustrated in FIG. 4, each notch 21 receives two winding portions 22a and 22b of different phases.

Each winding portion 22a and 22b intended to be engaged in a notch 21 is surrounded by an insulating sheet 37a and 37b for isolating the windings of the walls 33 and 36 of the notch and to isolate the winding portions. 22a and 22b of different phases between them.

The coils 22 are formed out of the notches 21 and their portions 22a and 22b intended to be engaged in the notches are each surrounded by an insulating sheet 37a or 37b. The insulating sheet 37a or 37b is glued on at least a part of its surface and the winding portions 22a and 22b with the insulated sheets 37a and 37b are inserted in the notches 21. This operation is facilitated by the fact that the notches 21 are fully radially outwardly open.

Each insulating sheet 37a or 37b extends over the entire height of the winding portion 24a or 24b inserted into the corresponding notch 21. Preferably, and as illustrated in FIG. 3, the insulating sheets 37a or 37b may extend axially out of the notches 21 on either side of the ring 25.

The insulating sheets 37ae and 37b may have an adhesive layer over their entire surface, making it possible to fix them by gluing on the winding portion 24a and 24b corresponding. Alternatively, the insulating sheets 37a and 37b are attached to the winding portions 22a and 22b by any other means.

The insulating sheets 37a and 37b may be aramid, for example Nomex®, or laminated with aramid and polyester or polyimide, for example a laminate Nomex® NMN (Nomex®-Mylar®) Nomex®) or NKN (Nomex®-Kapton®-Nomex®)

As illustrated in Figures 4 and 5, each insulating sheet 37a or 37b may be wound on two turns around the corresponding winding portion 22a or 22b. The winding portion 22a or 22b is then isolated from the notch 21 by two thicknesses of the corresponding insulating sheet 37a or 37b.

The longitudinal edges 54a or 54b of the insulating sheets 37a or 37b extend on the same face 60a or 60b of the winding portion 24, in particular on a face 60a or 60b of the winding 22 corresponding to the flat of the electrical conductors 34. Winding portions 22a and 22b are oriented in the notches 21 so that the faces 60a face the faces 60b. Thus, the winding portions 22a and 22b of different phases of the same notch are separated from each other by two thicknesses of insulation 37a and by two thicknesses of insulation 37b, ie four thicknesses of insulation.

As illustrated in FIG. 3, the coils 22 form bunches 56 outside the notches.

The bunches 56 of coils 22 of different adjacent phases have portions of connections 58 devoid of any insulation.

Rotor

The rotor 1 shown in FIG. 1 comprises a central opening 5 for mounting on a shaft and comprises a rotor magnetic mass 3 extending axially along the axis of rotation X of the rotor, this rotor mass being for example formed by a package of magnetic sheets stacked along the X axis, the sheets being for example identical and superimposed exactly.

The rotor 1 comprises for example a plurality of permanent magnets 7 arranged in housings 8 of the rotor magnetic mass 3. In a variant, the rotor is wound. Method of manufacturing the stator and machine

The stator can be obtained by means of the manufacturing method which will now be described.

The coils 22 are wound, in particular on edge, by winding the electrical conductors 34. The coils 22 have rectilinear portions 22a and 22b intended to be inserted into the notches 21. These rectilinear portions 24 are surrounded by an insulator 37a or 37b under sheet form, each sheet of insulation 37a or 37b being as previously described The insulation sheets 37a or 37b are fixed on the corresponding winding portion 22a or 22b by gluing or other means. The insulating sheets 37a or 37b make it possible to isolate the windings vis-à-vis the bundle of sheets and between them.

The sheet insulators 37a and 37b can be fixed on the winding portions 22a and 22b by the method illustrated in FIG. 9:

A. The sheet insulator 37a is first laid flat on a plate of a not shown folding device.

B. a first face 80a of the winding portion 22a to be insulated is placed on the insulator by applying a pressure P with the aid of a holding tool on a second face 81 opposite the first face 80,

C. the two free sides of the sheet insulator 37a which extend on either side of the winding portion 22a are folded and plated simultaneously or not on the side faces 82 and 83 with flaps of the plate of the folding device,

D. the free pan of the sheet insulator 37a extending from the face 82 is folded on the second face 81 with a sliding drawer along the second face 81 from the face 82 or a flap of the plate of the folding device,

E. the free pan of the sheet insulator 37a extending from the face 83 is folded over the portion of the sheet insulator folded in step D on the second face 81. This step is performed using a drawer sliding along the second face 81 from the face 83,

F. a pressure P is applied to the second face 81 by means of the tool for holding the folding device.

In the method described above, the sheet insulation 37a is glued. In a variant, the winding portion 22a is glued and a layer of glue is placed on the sheet insulator superimposed on the second face 81 between steps D and E to allow the attachment of the portion of the sheet insulation folded back to step E.

The invention is not limited to this method of gluing or the use of a gluing device, the gluing being carried out by hand.

Then, the rectilinear portions 22a and 22b of the coils 22 surrounded by the insulating sheets 37a or 37b are inserted into the notches 21 of the ring 25 by a radially inward movement of the notches 21. Two rectilinear portions of the windings 22 of the phases The two rectilinear portions 22a and 22b of coils 22 of a notch 21 are superimposed radially and oriented so that the faces 60 of the two coils are oriented towards one another.

In an additional step, the yoke 29 is attached to the ring 27 by sliding the dovetails 52 in the mortises 50. The yoke 29 may be preheated in order to expand it and facilitate its insertion on the ring 25. After its insertion on the ring 25, it can retract while cooling, which allows a clearance between the ring 25 and the yoke 29 which is minimal.

Alternatively or in addition, the ring 25 can be cooled beforehand to retract it and facilitate the insertion of the cylinder head 29.

The embodiments illustrated in FIGS. 6A and 6B differ from those of FIGS. 1 to 5 in the manner in which the insulating sheets 37a and 37b are wound on the winding portions 22a and 22b.

In the embodiment illustrated in FIG. 6A, the insulating sheets 37a and 37b are wound around the corresponding winding portion 22a or 22b over a little more than one turn. Each longitudinal edge 54a or 54b of the insulating sheet 37a or 37b is superimposed on a layer of the same insulating sheet 37a or 37b and on the same face 60a or 60b of the coils. Thus, the winding portions 22a and 22b are isolated from the notch by a single thickness of insulation 37a or 37b and insulated from each other by two thicknesses of insulation 37a and by two thicknesses of insulation 37b, ie four thicknesses of insulation. insulating.

In the embodiment illustrated in FIG. 6B, the insulating sheets 37a and 37b are wound so that their longitudinal edges 54a and 54b face each other on the faces 60a and 60b without being superimposed. The winding portions 22a and 22b of a notch 21 are arranged in the notches 21 so that the faces 60a and 60b which are the longitudinal edges 54a and 54b of the sheet insulators 37a and 37b are both oriented toward the aperture 28. The coil portions 22a and 22b are insulated from the notch 21 by a thickness of the insulating sheet 37a or 37b and insulated from each other by a discontinuous thickness of insulation 37b and a continuous thickness of insulation 37a. In this embodiment, the surface of the winding portion 22a or 22b may be glued instead of or in addition to gluing the sheet insulation.

In the embodiment illustrated in FIG. 6C, each winding portion 22a and 22b is insulated from the outside by two U-shaped sheet insulators 37a or 37b. The two sheet insulators 37a or 37b are arranged around the portion of the coil. corresponding winding 22a or 22b being head to tail and overlapping at least partially, in particular overlapping on the faces 60a and 61a or 60b and 6lb oriented towards the air gap and the opening of the notch 21. The portions of FIG. coil 22a and 22b are insulated from the notch 21 by a thickness of the insulating sheets 37a or 37b and insulated from each other by two thicknesses of insulators 37a and 37b, each of the thicknesses being formed by one of the sheet insulators 37a or 37b .

In the variant illustrated in FIG. 7, the sheet insulator 37a or 37b is not glued to the surface of the corresponding winding portion 22a but fixed by adhesive tape 62 at its two ends.

In the variant illustrated in FIG. 8, the sheet insulator 37a or 37b is an adhesive tape which is surrounded around the winding portion 22a. The consecutive turns of the ribbon overlap partially to ensure good insulation. In this embodiment, the adhesive tape is preferably made of mica / polyester.

Of course, the invention is not limited to the embodiments that have just been described, and the rotor can be wound rather than permanent magnets.

The phrase "with one" should be understood as synonymous with "comprising at least one".

Claims

1. A method of manufacturing a stator (2) of an electric machine, the method implementing:

- a toothed crown (25) having teeth (23) interconnected by material bridges (27) and defining between them notches (21) open radially outwards, the notches (21) being at opposite edges ( 33) parallel to each other,

windings (22) made outside the notches (21), and

a yoke (29) configured to be attached to the serrated crown

(25)

the process comprising:

Attaching at least one sheet insulator (37a, 37b) to at least a portion of each of the coils (22a, 22b), the sheet insulators extending over straight coil portions,

Inserting said winding portions (22a, 22b) with the insulators (37a, 37b) in the notches (21) by a radially inward displacement of the notches (21), and

• assembly of the yoke (29) on the radially outer surface of the ring (25) to radially close the notches (21).

2. A method of manufacturing a stator (2) of an electric machine, the method implementing:

- a toothed crown (25) having teeth (23) interconnected by material bridges (27) and defining between them notches (21) open radially outwardly,

windings (22) made outside the notches (21), the windings (22) each comprising at least one electrical conductor (34) of rectangular cross-section wound on edge, and

a yoke (29) configured to be attached to the serrated crown

(25)

the process comprising: Attaching at least one sheet insulator (37a, 37b) to at least a portion of each of the coils (22a, 22b),

3. A method of manufacturing a stator (2) of an electric machine, the method implementing:

windings (22) made outside the notches (21), and

a yoke (29) configured to be attached to the serrated crown

(25)

the process comprising:

Attaching at least one sheet insulator (37a, 37b) to at least a portion of each of the coils (22a, 22b) over the entire height of the notches (21), the sheet insulator being of a height substantially equal to the height of the notches (21),

4. A method of manufacturing a stator (2) of an electric machine, the method implementing:

windings (22) made outside the notches (21), and

a yoke (29) configured to be attached to the serrated crown

(25) the process comprising:

Attaching at least one sheet insulator (37a, 37b) to at least a portion of each of the coils (22a, 22b), the sheet insulators (37a, 37b) each having two opposite longitudinal edges (54, 54a); , 54b) extending substantially along the longitudinal axis (Z) of the associated winding portion (22a, 22b), the winding portions (22a, 22b) being of rectangular cross section and the two opposite longitudinal edges (54, 54a, 54b) of each sheet insulator (37a, 37b) extending on a same face of the corresponding winding portion (22a, 22b),

Inserting said winding portions (22a, 22b) with the insulators (37a, 37b) in the notches (21) by a radially inwardly directed displacement of the notches (21) so that the longitudinal edges of the corresponding sheet insulators extend on one side of the winding portion oriented towards the opening of the notch or towards a portion of a coil inserted in the same notch, and

5. Method according to any one of claims 1, 2 and 4, wherein after insertion of the coils (22) with the insulators (37) in the notches (21), the insulators (37) extend in each notch (21). ) over the entire height of the notch (21).

6. The method of claim 5, the sheet insulators (27a, 27b) protruding axially out of the notches (21) on either side of the latter after insertion.

7. Method according to any one of claims 1 to 3, the sheet insulators (37a, 37b) each having two opposite longitudinal edges (54, 54a, 54b) extending substantially along the longitudinal axis (Z) of the associated winding portion (22a, 22b), the winding portions (22a, 22b) being of rectangular cross-section and the two opposite longitudinal edges (54, 54a, 54b) of each sheet insulator (37a, 37b) extending on the same face of the corresponding winding portion (22a, 22b).

8. The method of claim 7, the longitudinal edges (54, 54a, 54b) of each sheet insulator (37a, 37b) being in contact with each other on said face.

9. The method of claim 7, each sheet insulator (37a, 37b) superimposed at least in part on itself.

The method according to any one of claims 7 to 9, each winding portion (22a, 22b) being disposed in the corresponding notch (21) so that the longitudinal edges (54) of the sheet insulator (37a , 37b) extending on one side of the winding portion (22a, 22b) facing the opening of the notch (21) or to a portion of a winding (22a, 22b), in particular of different phase inserted in the same notch (21).

11. A method according to any one of claims 1 to 3, the sheet insulator (37a, 37b) being in the form of a ribbon wound around the winding portion (22a, 22b), in particular a ribbon superimposed on itself one turn on the other around the winding portion (22a, 22b).

12. A method according to any one of the preceding claims, wherein the sheet insulators (37a, 37b) are fixed on the coils (22) on at least a portion of their surface, preferably over their entire surface, by gluing.

13. Method according to one of the preceding claims, wherein each sheet insulator (37a, 37b) is fixed on the winding portion (22a, 22b) at at least one of its longitudinal ends, preferably at its two longitudinal ends. , by bonding all or part of the sheet insulator and / or all or part of the corresponding winding portion or by means of at least one adhesive tape, for example straddling the sheet insulator ( 37a, 37b) and the winding portion (22a, 22b).

14. A method according to any one of the preceding claims, each winding portion (22a, 22b) being covered by a single sheet insulator (37a, 37b).

15. Method according to any one of claims 1 to 13, each winding portion (22a, 22b) being covered by at least two insulators sheet (37a, 37b) overlapping at least partially or being joined edges, in particular by two U-shaped sheet insulators (37a, 37b) fixed head-to-tail on the corresponding winding portion (22a, 22b).

16. A method according to any one of the preceding claims, wherein the winding portions (22) inserted in the notches (21) are separated from the inner walls of the notch (33, 35) by at least one thickness of the insulation (37), better by at least two thicknesses of the insulation (37).

17. Method according to any one of the preceding claims, the coil (22) being of substantially rectangular section, the step of fixing the insulation in sheet (37a, 37b) on each of the winding portions (22a, 22b) comprising the following substeps:

positioning the sheet insulation (37a, 37b) flat,

positioning a first face of the winding (80) on the sheet insulator (37a, 37b), in particular in the center of the sheet insulator (37a, 37b), by applying a pressure (P) on the portion of winding (22a, 22b) in contact with the sheet insulator (37a, 37b), in particular by applying pressure to a second face opposite the first face (81), to maintain contact between the sheet insulator (37a) , 37b) and the first face of the winding (80),

applying the two free sides of the sheet insulator (37a, 37b) to two opposite side faces of the coil (82, 83),

- flap of one of the free sides of the sheet insulation (37a, 37b) on the second face (81) and flap of the sheet of insulation remaining sheet (37a, 37b) remaining on the second face (81) the sheet insulator (37a, 37b) being of a width with respect to the corresponding coil such that its ends are superimposed on the second face (81), and

applying a pressure on the second face of the coil (81) wound with sheet insulation (37a, 37b),

the sub-steps being carried out using a suitable folding device comprising flaps for folding the sheet insulation (37a, 37b) on the third faces (82, 83), drawers for folding the two of the sheet insulator (37a, 37b) on the second face (81) and a holding tool for holding the coil (22) in position and exerting pressure on the second face of the coil (81).

18. The method as claimed in any one of the preceding claims, in which, during the step of inserting the winding portions (22a, 22b), each notch receives at least two winding portions (22a, 22b), in particular at at least two winding portions (22a, 22b) of different phases, preferably, these two winding portions (22a, 22b) superimposed radially in the notch (21).

19. The method of claim 18, wherein the two winding portions (22a, 22b) of the same notch (21) are separated from each other by at least one thickness of the sheet insulator (37a, 37b), preferably at least two layers of the sheet insulation (37a, 37b), better by at least four thicknesses of the sheet insulation (37a, 37b).

20. Method according to one of claims 18 or 19, each winding portion (22a, 22b) being arranged in the corresponding notch (21) so that the longitudinal edges (54) of the sheet insulation (37a, 37b) extend on one side of the winding portion (22a, 22b) facing the other winding portion (22a, 22b).

21. A method according to any one of the preceding claims, the sheet insulators (37a, 37b) being made of electrical insulating material, flexible, especially aramid, for example Nomex®, or laminate aramid and polyester or polyimide, especially a Nomex® laminate of NMN type (Nomex®-Mylar®-Nomex®) or NKN (Nomex®-Kapton®-Nomex®) type, or of mica / polyester.

22. A method according to any one of the preceding claims, sheet insulators extending only over straight coil portions.

23. Stator (2) comprising:

a radially inner ring (25) comprising

o teeth (23) forming between them notches (21) open radially outwards, the notches (21) being at opposite edges (33) parallel to each other, and

material bridges (27) each connecting two adjacent teeth (23) to their base on the gap side and defining the bottom of the notch (21) between these teeth, and

- a yoke (29) radially outer attached to the ring (25),

- windings (22) distributed in the notches (21), with notch (21) at least one coil (22) of a first phase and a coil (22) of a second phase different from the first phase, said winding portions (22a, 22b) being separated in the notch (21) by at least two layers of sheet insulator (37a, 37b), a sheet insulator (37a, 37b) at least partially surrounding each windings (22).

24. Stator (2) comprising:

a radially inner ring (25) comprising

o teeth (23) forming between them notches (21) open radially outwards, and material bridges (27) each connecting two adjacent teeth (23) to their base on the gap side and defining the bottom of the notch (21) between these teeth, and

- a yoke (29) radially outer attached to the ring (25),

- windings (22) distributed in the notches (21), with notch (21) at least one coil (22) of a first phase and a coil (22) of a second phase different from the first phase, said winding portions (22a, 22b) being separated in the notch (21) by at least two layers of sheet insulator (37a, 37b), a sheet insulator (37a, 37b) at least partially surrounding each windings (22), the windings (22) each comprising at least one electrical conductor (34) of rectangular cross-section wound on edge.

25. Stator (2) comprising:

a radially inner ring (25) comprising

o teeth (23) forming between them notches (21) open radially outwards, and

- a yoke (29) radially outer attached to the ring (25),

- windings (22) distributed in the notches (21), with notch (21) at least one coil (22) of a first phase and a coil (22) of a second phase different from the first phase, said winding portions (22a, 22b) being separated in the notch (21) by at least two layers of sheet insulator (37a, 37b), a sheet insulator (37a, 37b) at least partially surrounding each windings (22) over the entire height of the notches (21), the sheet insulation being of a height substantially equal to the height of the notches (21).

26. Stator (2) comprising:

a radially inner ring (25) comprising

o teeth (23) forming between them notches (21) open radially outwards, and

- a yoke (29) radially outer attached to the ring (25), - windings (22) distributed in the notches (21), with notch (21) at least one coil (22) of a first phase and a coil (22) of a second phase different from the first phase, said winding portions (22a, 22b) being separated in the notch (21) by at least two layers of sheet insulator (37a, 37b), a sheet insulator (37a, 37b) at least partially surrounding each windings (22), the sheet insulators (37a, 37b) each having two opposite longitudinal edges (54, 54a, 54b) extending substantially along the longitudinal axis (Z) of the associated winding portion (22a, 22b). ), the winding portions (22a, 22b) being of rectangular cross-section and the two opposite longitudinal edges (54, 54a, 54b) of each sheet insulator (37a, 37b) extending on the same face of the portion of winding (22a, 22b), the longitudinal edges of the corresponding sheet insulator extending over a face of the winding portion facing the opening of the notch or to a portion of the different phase winding of the same notch.