ROTATING ELECTRIC MACHINE WITH STATOR

专利摘要:
Stator (6) of rotating electrical machine (1) comprising: - a stator body (4) formed by a stack of sheet metal sheets, said stator body being provided with an axis (X) and being delimited by a radial surface and an outer radial surface, - arranged notches (44) in said stator body and extending axially, each having a notch bottom (48) and a notch opening (49), said opening slot being located on the side of said inner radial surface, -a stator winding (5) carried by said stator body, said winding comprising a plurality of winding portions (51, 52, 53) each of which is housed in a said notches, characterized in that each of the notches (44, 41, 42, 43) is provided at the notch opening with at least one notch closure member (451, 452, 453, 454). so that the winding portion which is housed in said notch is held between the bottom of the notch and said el in that for each of the notches, said closure element is formed by an offset (451, 452a, 452b, 453, 454) of at least one of the sheet metal sheets of an adjacent notch in the direction of said notch. Applications: alternators, alternator-starters, electric motors
公开号:FR3043506A1
申请号:FR1560709
申请日:2015-11-09
公开日:2017-05-12
发明作者:Pierre-Yves Bilteryst；Henri Delianne；David Margueritte；Eric Jozefowiez；Sylvain Perreaut；Patrice Balthaze；Julien Battut
申请人:Valeo Equipements Electriques Moteur SAS；
IPC主号:

专利说明:

ROTATING ELECTRIC MACHINE PROVIDED WITH A STATOR TECHNICAL FIELD OF THE INVENTION
The present invention relates to a rotating electrical machine and more particularly to the stator of such a rotating electrical machine.
BACKGROUND TECHNOLOGY
It is known to use rotating electrical machines in motor vehicles. It can be a compact and polyphase alternator. This alternator transforms mechanical energy into electrical energy and can be reversible. Such a reversible alternator is called an alternator-starter and in another mode of operation transforms electrical energy into mechanical energy in particular to start the engine of the vehicle.
This machine essentially comprises a housing 1 and, inside thereof, a rotor 2 with claws, integral in rotation with a shaft 3, and a stator body 4, which surrounds the rotor with the presence of a small air gap and which comprises a body in the form of a pack of sheets provided with notches, here of the semi-closed type, equipped with notch insulator for mounting the phases of the stator, each comprising at least one winding forming part and 5 of the stator body is a bun 5. The windings are obtained for example from a continuous wire coated with enamel or from bar-like conductor elements, such as pins connected together, for example by welding .
These windings are, for example, three-phase windings connected in a star or in a triangle, the outputs of which are connected to at least one rectifier bridge comprising rectifying elements such as diodes or transistors of the MOSFET type, in particular when it is a question of an alternator-starter as described for example in the document FR A 2,745,445 (US A 6,002,219).
The number of phases depends on the applications and can be greater than three, one or two bridge rectifiers can be provided.
The claw rotor 2 comprises two axially juxtaposed and ring-shaped polar wheels 7, 8 each having a transverse flange provided at its outer periphery with trapezoidal teeth 9 directed axially towards the flange of the other pole wheel, the tooth of FIG. a pole wheel penetrating the space between two adjacent teeth 9 of the other pole wheel, so that the teeth of the pole wheels are interlocked, the flanges of the wheels 7, 8 are annular and have at their outer periphery radial protrusions (not referenced) connected by chamfers to the teeth 9. These projections form claws with the teeth 9. The number of teeth 9 depends on the applications and in particular the number of phases of the stator. For example, eight teeth can be provided per pole wheel. Alternatively each pole wheel has six or seven teeth.
A cylindrical core is interposed axially between the flanges of the wheels 7, 8. Here this core consists of two half-cores each belonging to one of the flanges. This core carries at its outer periphery an excitation winding 10. An insulator, such as a winding support coil 10, is inserted radially between the core and the winding 10. The shaft 3 of the rotor 2 carries at its end before a drive member, such as a pulley 12 belonging to a device for transmitting movements to at least one belt between the alternator and the engine of the motor vehicle, and at its rear end 13, of reduced diameter, slip rings connected by wire links to the ends of the rotor excitation coil. The wired links and the slip rings belong here to an attached manifold of the type described in FR 2,710,197. Brooms belong to a brush holder 14 and are arranged so as to rub on the slip rings. The brush holder is connected to a voltage regulator. The front and rear ends of the shaft 3 therefore each have several sections.
When the excitation winding 10 is electrically powered from the brushes, the rotor 2, made of ferromagnetic material, is magnetized and becomes an inductor rotor with the formation of magnetic poles at the teeth of the pole wheels.
This inductive rotor 10 creates an alternating induced current in the stator induced when the shaft 3 rotates, the rectifier bridge or bridges for transforming the induced alternating current into a direct current, in particular for powering the loads and consumers of the electrical system. vehicle, and to recharge the battery of said vehicle.
The housing 1 internally carries at its outer periphery the stator body 4 and centrally rotating the shaft 3. This housing is here in two parts, namely a front bearing 16 adjacent to the pulley 12 and a rear bearing 17 carrying the door - the tension regulator and at least one bridge rectifier. The bearings are of hollow form and each comprise a ball bearing respectively 19 and 20 for the rotational mounting of the shaft 3 of the rotor 2. The diameter of the bearing 19 is greater than that of the bearing 20. In FIG. an elastic system for filtering the vibrations is provided at the outer periphery of the stator body 4, with a flat gasket 48 at the front and buffers 49 at the rear, the flexible and thermoconductive resin being interposed between the front bearing and the stator body to evacuate the heat. As a variant, the bearings 16, 17 rigidly bear the body of the stator 4.
The bearings are, in Figure 1, perforated to allow cooling of the alternator by air circulation. For this purpose, the rotor 2 carries at least at one of its axial ends a fan intended to ensure this circulation of air. In the example shown, a fan 23 is provided on the front end face of the rotor and another fan 24, more powerful, on the rear back face of the rotor, each fan being provided with a plurality of blades 25, 26.
In these machines two problems arise in particular on the winding 5 of the stator body 4. Firstly, the winding is not well compacted and occupies a place in the notch greater than that which it could occupy if it were compacted. . This is detrimental because for a given total wire length, the addition of copper in the notches can increase the performance and in particular the efficiency of the machine. Second, the winding is not well fixed in the notches and can exceed in the internal diameter of the stator which induces a risk of collision with the rotor in rotation.
The proposed solutions according to the state of the art do not solve this problem satisfactorily.
Thus, it is known from US7808148 patent to crush the wire radially in order to increase its orthoradial width so that it bears on the edges of the notch. However, the wire and especially its insulation may be damaged during this operation.
It is known from patent FR2900773 to apply a radial compression on the son of a notch to increase their orthoradial distance. However, this method applies specifically to the notches having two son columns. It does not offer a solution including notches with son aligned in a single column.
Finally, it is known from patent FR 2 708 398 to crush the wires radially on the outer surface of the rotor. This solution is not applicable as such on the stator slots because in this state of the art, it is to maintain the wire in the rotor notches.
There is therefore a need for a solution that both keeps the wire in the notches and compact it in a reproducible manner and without reducing the performance of the electric machine. This need is even more compelling in the case of stators having notches without toothpins.
OBJECT OF THE INVENTION The object of the invention is to meet this wish while at the same time remedying at least one of these aforementioned drawbacks.
According to the invention, there is provided a rotating electrical machine stator comprising: a stator body formed by a stack of sheets of sheet metal, said stator body being provided with an axis and being delimited by an internal radial surface and a external radial surface, notches provided in said stator body and extending axially, each having a notch bottom and a notch opening, said notch opening being located on the side of said inner radial surface; a stator winding carried by said stator body, said winding comprising several winding parts each of them being housed in one of said notches,
According to a general characteristic of the invention, each of the notches is provided at the notch opening with at least one notch closure element so that the winding portion which is accommodated in said notch is held between the notch bottom and said closure member, and for each of the notches, said closure member is formed by an offset of at least one of the sheet metal sheets of an adjacent notch towards said notch.
This allows the quick and easy formation of the closure elements, without hurting the wire and without reducing the performance of the electric machine. For example, the closure element can be made on a stator without a tooth root. He then plays the role of toothpaste. The notch closure element can also be made on a stator already provided with tooth roots.
According to other characteristics taken individually or in combination: - every second notch comprises a number N of closure elements, N being an integer greater than or equal to 2 and the remaining notches comprise a number of closure elements which are strictly less than N, for example N-1. This makes it possible to have an optimum number of closure element. We do not have to have the same number for each notch. two notches having a number N of closure elements are contiguous on either side of a notch having a lower number of closure elements. This is an interresting arrangement because it allows to have a group of tools positioned opposite two notches followed by a rotation of an angle corresponding to two notches of the tool group relative to the stator; the notches being numbered following the circumference of the stator, the notches of even number comprise a number of closing elements different from that of the notches of odd number. Thus, it alternates the number of closure elements in addition to the previously stated possibility of having a group of tools that also allows a good distribution of closure elements; - The closing elements of the notches are distributed axially over the axial length of the stator body. This makes it possible to have a good distribution of the closing elements but this time axially in particular to reduce stress on the wires; - At least one of the closure elements of a notch having a lower number of closure elements is located in an axial plane passing through the middle of two adjacent closure elements of a notch comprising the N closure member. Thus, in addition to allowing an ideal distribution of closure elements, it avoids the phenomenon of interference which corresponds to the deformation to the right and left at the same axial level of the same tooth; for a given notch, the closing elements of this notch being situated respectively in axial first planes of the stator body and the closing elements of the adjacent notch being located respectively in second axial planes of the stator body, the first Axial planes are different from the second axial planes. This avoids the phenomenon of interference mentioned above; the first axial planes and the second axial planes are spaced apart axially by a distance equal to at least two sheets of sheet metal. An axial distance between the two closure elements is defined to avoid the problem of interference; the closure element is formed, on the one hand, by the offset of at least one of the sheet metal sheets of a notch adjacent to the right in the direction of said notch and, on the other hand, by an offset of at least one of the sheet sheets of a notch adjacent to the left in the direction of said notch, the two offsets being located in the same axial plane. With a notch having a closure member comprising two offsets located in the same axial plane, the necessary offset is less important, thereby reducing the forces applied to the tool to deform the notches; - A closure element is formed by an offset of at least two sheets of contiguous sheets so that the closure element has an axial height of at least two sheet sheets. An axial length of the closure element is thus defined; the two notch edges starting at each notch from the notch bottom to the notch opening are each inscribed in a straight line prior to the formation of the notch closure member. Although the invention finds its use for notches provided with toothed feet since it allows a better maintenance of the winding portion and therefore a reduction, or even a removal of the notch closure wedge, the needs are still more imperative in the case where the notches are not equipped with a tooth. - For each closure element of a notch, at least one of the two adjacent notches has traces of deformation by radial introduction of a tool having an orthoradial dimension greater than the notch width. This tool allows orthoradial deformation simply by its radial translation; - For each closure element of a notch, at least one of the two adjacent notches present traces of deformation by radial introduction of a substantially spherical shape tool. It thus has the advantage of having an orthoradial width which increases progressively for a shift of the progressive sheet sheets. It also has a self centering capability within the slot opening so that offsets to the adjacent right and left notch will be balanced or even equal. Finally, this rounded shape makes it possible to avoid damaging the wire when the tool is used to compact the part of the winding; - For each closure element of a notch, at least one of the two adjacent notches present traces of a deformation by radial introduction forms a triangular prism having rounded edges. - The winding portion of a notch has the traces of compaction by said radial introduction of a tool. The compacting action can be easily added to the formation of the notch closure elements. This is particularly the radial introduction of the tool into the notch; - The winding portion of a notch comprises a plurality of son aligned in a column, for example a single column; - The winding portion of a notch comprises a plurality of son aligned along two parallel columns. For example, the threads are aligned in two columns up to the penultimate row from the bottom of the notch, the last row being occupied by a single thread; - The number of closing elements is identical for each of the notches. The invention also relates to a machine comprising a stator as defined above. The invention also has a method of forming a stator, said stator comprising: a stator body formed by a stack of sheets of sheet metal, said stator body being provided with an axis and being delimited by an internal radial surface; and an outer radial surface, notches provided in said stator body and extending axially, each having a notch bottom and a notch opening, said notch opening being located on the side of said surface internal radial, a stator winding carried by said stator body, said winding comprising several winding parts each of them being housed in one of said notches,
According to a general characteristic of the invention, the method comprises a step of closing at the notch opening so that the winding part which is housed in said notch is held between the notch bottom and said closure element , and the closing step comprises a step of shifting at least one of the sheets of sheet metal from an adjacent notch towards said notch. . For example, the closing step can be performed on a stator without a tooth root. This makes it possible to form a tooth base. The notch closing step can also be performed on a stator already provided with tooth roots.
According to other characteristics taken separately or in combination: the closing step comprises for each notch: on the one hand a step of shifting at least one of the sheets of metal from a notch adjacent to the right in the direction of said notch, on the other hand a step of shifting at least one of the sheet metal sheets of a notch adjacent to the left in the direction of said notch, the two shifting steps being carried out in the same axial plane - the step shifting is performed on an axial height of at least two sheet sheets; said step of shifting comprising a step of introducing a tool in a radial direction, said tool having an orthoradial dimension greater than the notch width; said step of shifting comprising a step of introducing a tool in a radial direction, said tool having a substantially spherical shape; during said shifting step, the winding part housed in the notch in which the tool is introduced in a radial direction is compacted; - For a notch having a plurality of axially distributed closure elements, during the shifting step is introduced radially into at least one notch adajacente said notch, a single utensil provided with a plurality of tools distributed axially.
BRIEF DESCRIPTION OF THE FIGURES The invention will be better understood on reading the description which follows and on examining the figures that accompany it. These figures are given for illustrative but not limiting of the invention. FIG. 1 already described is a view of a rotating electrical machine
FIG. 2 is a perspective view of a stator body of a rotating electrical machine in the form of an alternator; Figure 3 is a view of a stator body detail according to another embodiment of the invention; Figure 4 is a perspective view of a stator according to the invention comprising a stator body and a winding; Figures 5, 6, 7, 8 and 9 are views in an axial section of the stator according to Figure 4; Figure 10 is an internal view of the stator according to the invention; Figure 11 is a schematic view of the steps of the method according to the invention.
Identical, similar or similar elements retain the same reference from one figure to another.
DESCRIPTION OF EXAMPLES OF EMBODIMENT OF THE INVENTION
Figure 2 illustrates a stator body 4 for a rotating electrical machine. The stator body formed by a stack of sheet metal sheets. It is provided with an X axis and is delimited by an inner radial surface and an outer radial surface. Notches 44 are provided in the stator body. These notches 44 extending axially, two notches 44 being separated by a tooth 45. Each of the notches 44 has a notch bottom 48 and a notch opening 49. The notch opening is located on the surface side internal radial. For each notch, there is defined between the notch opening and the notch bottom a radial notch depth.
FIG. 3 illustrates a stator body 4 for a rotating electrical machine according to another embodiment of the invention. This embodiment differs from that of FIG. 2 by the presence of a tooth root 47 on each of the teeth 45. The tooth root 47 is formed by two orthoradial direction projections, one towards the left 46a and another to the right 46b.
FIG. 4 illustrates a stator body 4 carrying a winding 5. The stator body 4 and the winding form a stator 6 of rotating electrical machine. In other words, the stator 6 of the electric machine comprises a stator body 4 provided with notches 44 and a winding 5. The winding 5 comprises several winding portions 58 each of which is housed in one of said notches 44. winding comprises two buns 56 and 57 located on either side axially of the stator body. The winding portions 58 connect the bunches 56 and 57. The winding further comprises inlet inlets 55 which protrude axially with respect to the bun 57.
FIG. 5 illustrates a detail of the stator 6 of FIG. 4. More precisely, it is a section along an axial plane which is used as a synonym perpendicular to the X axis in the following description. In this figure are illustrated three notches 41,42 and 43 respectively receiving the winding portions 51, 52 and 53. The notches 41, 42 and 43 are separated by the teeth 45. The teeth and the notches are covered with an insulating paper 50 also called insulation. This insulator is necessary to ensure electrical insulation between the winding parts 54 and the stator body 4. Indeed, during operation of the electrical machine the winding parts are traversed by a current while the body is at the potential of the electrical ground. The thickness of the insulation is of the order of a tenth of a millimeter. As can be seen in FIG. 5, the winding portions 51, 52 and 53 comprise, for example, 7 wires per notch aligned along a radial column. The coil portions are not compacted so that the last wire on the side of the notch opening protrudes from the inner radial surface of the stator body. For each notch, a notch width 445 is defined which corresponds to the distance along an orthoradial direction between the two edges of the notch. For each notch, an insertion width corresponding to the orthoradial distance between the two edges of the notch is also defined when they are covered with the insulating paper 50. On the stator of FIG. 5, it appears that the wires are not maintained. at the notch opening and have a diameter smaller than the insertion width. There is therefore a risk that the last wire on the side of the slot opening completely out of the notch 54. For the embodiment of Figure 5, the two notch edges starting for each notch of the bottom of the slot. notch towards the notch opening are respectively inscribed in a straight line before forming the notch closure element. However, the invention also applies to the stator illustrated in Figure 2, wherein each tooth is provided with tooth legs.
Figure 6 illustrates the arrival of a tool 60 on the notch 41 whose action eliminates the risk mentioned above. The tool is moved by translation along a radius aligned with the notch 41 and for example within a first axial plane perpendicular to the axis X. In other words, the tool is moved radially relative to the notch into which it must be introduced. The tool illustrated in Figure 6 has a spherical shape, it has the advantage of not injure the wire and have a progressive orthoradial width that allows a centering of the tool in the notch opening. However, any form of tool is appropriate as long as it has a distance greater than the bidding width 445.
FIG. 7 illustrates the continued movement of the tool 60 in the direction of the notch opening of the notch 41. The continuation of this displacement involves a compaction of the winding portion 51 of the notch 41. Thus, the last wire no longer protrudes from the inner radial surface of the stator body. Continued displacement also involves the formation of two closure members 451 and 452a. The closure elements 451 and 452a are formed by the offset of a portion of the sheet metal sheets of the notch 41 receiving the tool respectively to the left and to the right as illustrated in Figure 7 by the two arrows. Thus, the closure elements 451 and 452a protrude in an orthoradial direction within respectively an unnumbered notch and the notch 42.
In other words, at least one of the notches is provided at the notch opening with at least one notch closure member so that the coil portion which is accommodated in said notch is held between the notch notch bottom and said closure member. The closure member is formed by an offset of at least one of the sheet metal sheets of an adjacent notch towards said notch.
Of course, one could also provide N tools 60 distributed axially on the notch 41, it would then cause the formation of 2 N axially distributed closure elements. One would also have a better compaction of the winding portion 51 of the notch 41 thanks to radial supports distributed axially. For this purpose, it is possible to provide a single utensil provided with said N tools 60, in order to facilitate their handling.
FIG. 8 illustrates the displacement of a tool 60 towards the notch opening of the notch 42. According to a first embodiment, the tool 60 illustrated in FIG. 8 is the same as that of FIG. 7. It is located opposite the notch 42 with a relative rotational movement of the tool relative to the stator. According to an example of this first embodiment, to move from the configuration of Figure 7 to that of Figure 8 is retracted the tool 60, the stator is rotated and the tool 60 is moved towards the Notch 42. According to a second embodiment, the tool 60 is an additional tool to that illustrated in FIG. 7. It is different from the fact that it is situated opposite another notch, the notch 42 while the tool of Figure 7 is opposite the notch 41. According to an example of this second embodiment, is retracted the tool 60 of Figure 7 and then moves the tool 60 of the Figure 8 towards the notch 42.
According to the first or second embodiment, the offset of part of the sheet metal sheets of the notch 42 is obtained. The closure elements 453 and 454 are thus formed by this offset of the sheet metal sheets of the notch 42 receiving the tool respectively to the left and to the right as shown in Figure 8 by the two arrows. Thus, the closure elements 453 and 454 protrude in an orthoradial direction respectively within the notch 41 and the notch 43. According to these two embodiments, the movement of the tool also involves compacting the part winding 52 of the notch 42. Thus, the last wire no longer exceeds the radial inner surface of the stator body.
In the case of the first embodiment, according to an exemplary embodiment, the tool 60 keeps the same axial position relative to the stator. Closing elements 451, 452a, 453 and 454 are then obtained which are located in the same axial plane. According to another exemplary embodiment, it would be possible to provide a relative axial displacement of the tool 60 relative to the stator 4. This relative axial displacement is achieved for example at the same time as the relative rotation of the stator 4 relative to the 60. The closing elements 451, 452a are then located in a first axial plane and the closure elements 453 and 454 are located in a second axial plane, the first and second axial planes being different. For example, the first and second axial planes are located at a distance greater than two sheets of sheet metal.
In the second embodiment, it is possible to provide that the tool 60 of Figure 7 and that of Figure 8 are located in a first and second substantially different axial planes. For example, the first axial plane and the second axial plane are spaced axially by a distance equal to at least two sheet sheets. The closing elements 451, 452a are then located in the first axial plane and the closing elements 453 and 454 are located in the second axial plane, this first and second axial plane being different.
As already mentioned for Figure 7, of course, one could also provide N tools 60 distributed axially on the notch 42, they would then cause the formation of 2 N axially distributed closure elements. One would also have a better compaction of the winding portion 52 of the notch 42 with axially distributed radial supports. For this purpose, it is possible to provide a single utensil with said N tools 60, in order to facilitate their handling.
FIG. 9 illustrates the movement of a tool 60 in the direction of the notch opening of the notch 43. As already mentioned, the tool 60 illustrated in FIG. 9 may be the same as that of FIG. 8. It can also be different. It is also possible to provide a tool 60 which is not identical to that opposite the notch 42 but identical to that opposite the notch 41. It is then for example a method of closing notch comprising two tools located opposite two consecutive notches in which after a step of moving towards the notch opening and a step of retracting the two tools, the two tools are moved in rotation by an angle corresponding to two notches relative to the stator.
The closure elements 452b and 457 formed by the tool 60 are in any case in the plane of the tool 60 of FIG. 9.
It can be seen that the closure elements 453 and 452a on the one hand and 454 and 452b on the other hand are respectively located on the same tooth 45. It therefore appears that it can be favorable for the closure elements 453 and 452a to one is in two different axial planes and 454 and 452b are in two different axial planes.
The fact that the closing elements 453 and 452a are in two different axial planes makes it possible to prevent the formation of the closing element 453 by shifting the sheets of sheet metal to the left from interfering with the formation of the closure member 452a by shifting the sheets of sheet metal to the right.
Likewise, the fact that the closure elements 454 and 452b are in two different axial planes makes it possible to prevent the formation of the closure element 452b by shifting the sheets of sheet metal to the left from interfering with the formation. of the closure element 454 by shifting the sheets of sheets to the right.
This phenomenon illustrated by way of example for the formation elements 453, 452a on the one hand and 454 and 452b on the other hand is called interference in the following description.
The sizing of the tool 60 is a function, in particular, of the wire size, the radial depth of the notch, the notch width, the insertion width, the insulator width and the number of grooves. son by notch.
For example, with reference to Figures 7 and 9, there is a notch width of 1.95 mm, a wire size of the order of 1.56 mm, and an insulator having a thickness of 0.13 mm. An insertion width of 1.95 - 2 x 0.13 = 1.69 is thus obtained, while the wire has a size of 1.56 mm. Moreover, the radial depth of the notch is of the order of 12.5 mm. Thus, taking into account the fact that the bottom of the notch is covered with insulation, a depth for the winding portion equal to 12.5 - 0.13 = 12.37 mm. The objective is to obtain sufficient compaction so that at least all 7 drivers can enter this length of 12.37 mm. According to an exemplary embodiment, it is possible to define that the radial distance between two wires is at most 0.1 mm. It is deduced that it is then necessary to penetrate the tool 60 with a value as calculated below in the notch: 12.37 - (7 x 1.56 + 6 x 0.1) = 0.85 mm .
It is then necessary to define a tool shape which allows for this penetration value of 0.85 mm a sufficient offset of the sheets of sheet metal to allow the wire to be held in the adjacent notches. This necessary offset can be calculated based on the difference between insertion width and wire size. The value of the offset also depends on the presence of two offsets facing each other in the same notch and in the same axial plane for the closure element. Concretely the value of the offset must be greater if the closure element is formed only by the shift to the right of the tooth between the notches 41 and 42 or by the shift to the left of between the tooth between the notches 42 and 43 On the contrary, if the closure element is formed by the shift to the right of the tooth between the notches 41 and 42 and the shift to the left of the tooth between the notches 42 and 43 then the value of each of the two offsets may be less important.
Thus, in the case where the closure element 452 is formed solely by the offset 452a or 452b then an offset is needed which compensates for at least the difference between the insertion width and the wire size, ie: 1.69 - 1.56 = 0.13 mm.
In the case where the closure element is formed by the offset 452a and the offset 452b, then only one offset is required which is twice as small if it is assumed, for example, that the offset 452a is equal to the offset 452b. to say (1,69 - 1,56) / 2 = 0.065.
So we have a tool shape which must allow compared to the insertion width of 1.56 mm, for an introduction of 0.85 mm, a shift of at least 0.13 mm or 0.065 mm on each of two teeth. In the case of a tool of spherical shape, this is possible with a sphere having a diameter of 4 mm.
Furthermore, there are three embodiments listed below by way of example: Embodiment 1: The tool of notches 41, 42 and 43 is identical. According to an example of this embodiment, if only a relative rotation of the stator relative to the tool is provided, then there are the closure elements 451, 452a, 453, 454, 455 and 452b which are located in the housing. same axial plane. We then have in particular a single closure element 452 formed by the two elements 452a and 452b. Embodiment 2: The tools of the notches 42 and 43 are different. According to an example of this embodiment, there are then the closure elements 453 and 454 on the one hand and 455 and 452b on the other hand which are located in groups of two in two different axial planes. Embodiment 3: The tool of notches 41 and 43 is identical. According to an example of this embodiment, if only a relative rotation of the stator with respect to the tool is provided, then closing elements 451, 452a, 455 and 452b are located in the same axial plane. While the closure elements 453 and 454 are for example located in another axial plane. This avoids the phenomenon of interference mentioned above. A single closure element 452 formed by the two elements 452a and 452b is also obtained.
As already mentioned for FIGS. 7 and 8, of course, one could also provide N tools 60 distributed axially on the notch 43, it would then cause the formation of a maximum of 2 N axially distributed closure elements. One would also have a better compaction of the winding portion 53 of the notch 43 thanks to radial supports distributed axially.
10, N = 2 tools for the notches 41 and 43 and N = 1 tool for the notch 42. More generally, according to Figure 10, there is a notch on two deformed with a tool and the notches. remaining with two tools. There is also a deformed notch with a tool surrounded two deformed notches with two tools.
In other words, every second notch comprises a number N of closure elements, N being an integer greater than or equal to 2 and the remaining notches comprise a lower number of closure elements. For example, a number N of closing element are contiguous on either side of a notch having an N-1 number of closure elements. In one example, where the notches are numbered following the circumference of the stator, the even numbered notches include a number of closure elements different from that of the odd numbered notches.
As can be seen for the notch 42, the closure members 472 and 462 are distributed axially over the axial length of the stator body. Moreover, as can be seen for the notch 41 or 43 comprising N-1 closure elements the closure element 461 or 463 is located in an axial plane passing through the middle of two adjacent closure elements of the notch 42.
It can be seen that for the notch 42 for example, the closing elements 462 and 472 of this notch are respectively located in axial first planes of the stator body and the closing elements 461 or 463 of the adjacent notch 41 or 43 are located respectively in second axial planes of the stator body, the first axial planes are different from the second axial planes. For example, the first axial planes and the second axial planes are spaced apart axially by a distance equal to at least two sheet sheets.
As can be seen for the notch 41 or 43 the closure element 461 or 463 is formed on the one hand by the offset of at least one of the sheet metal sheets of a notch adjacent to the right towards said notch and on the other hand an offset of at least one of the sheet metal sheets of a notch adjacent to the left in the direction of said notch, the two offsets being located in the same axial plane. Likewise for the notch 42, the two closure elements 472 and 462 are formed on the one hand by the offset of at least one of the sheet metal sheets of a notch adjacent to the right 43 in the direction of said notch and of on the other hand an offset of at least one of the sheet metal sheets of a notch adjacent to the left 41 in the direction of said notch, the two offsets being located in the same axial plane.
For example, a closure member is formed by an offset of at least two sheets of contingent sheets so that the closure member has an axial height of at least two sheet sheets.
According to FIG. 10, for each closure element of a notch, at least one of the two adjacent notches has traces of deformation by radial insertion of a tool having an orthoradial dimension greater than the notch width. For example for each closure element of a notch, at least one of the two adjacent notches present traces of deformation by radial introduction of a tool of substantially spherical shape.
According to one embodiment, the group of the two tools of the notch 41 and the group of two tools of the notch 43 are identical. For this purpose, it is possible to provide a single utensil of the group of two tools 60 which deforms the notches 41 and 43.
According to an example of this embodiment, it is possible to provide only a relative rotation of an angle corresponding to two notches of the stator relative to the utensil, to pass from the notch 41 to the notch 43. for the notch 42 a closing element 472a or 462a resulting from the deformation of the notch 41 in the same axial plane as a closure element 472b or 462b resulting from the deformation of the notch 43. In other words , the first group of closure members 472a and 472b and the second group of closure members 462a and 462b are each in an axial plane and each of these two groups thus form a single closure member 462 or 472.
According to an example of this embodiment, the closure elements formed 461 and 463 by the deformation of the notch 42 may be located in other axial planes that the closing elements 462 and 472 of the boche 42. It avoids thus the phenomenon of interference mentioned above.
According to one embodiment, it can also be provided that the tool 60 deforming the notches 40, 42 and 44 is identical and can act on the various notches mentioned before by rotation of an angle corresponding to two notches. In this case, the closure elements (in particular 461,463) formed by the deformation of the notches 40, 42 and 440 may be situated in the same axial plane which is different from the axial planes of the closure elements resulting from the deformation of the notch 41. or notch 43. This also avoids the phenomenon of interference mentioned above.
More generally, it is not beyond the scope of the invention in the cases below given by way of example.
Case 1 (not illustrated in FIG. 10): the groups of N tools acting on the successive notches are the same group. According to an example of this embodiment, if only a relative rotation of the stator relative to the tool is provided, then there is a number of axial planes comprising at least one closure element equal to N and each of the axial planes. includes the same number of closure elements.
Case 2: the group of tools acting on the notch 42 is different from that acting on the notch 43. In an example of this second case, the closure elements 461 and 463 resulting from the deformation of the notch 42 are located in planes different from those of the closing elements 472b and 462b resulting from the deformation of the notch 43. In other words for a tooth referenced 456 in FIG. 10, the offsets of the sheet sheets to the left 472b and 462b caused by the deformation of the notch 43 and the offsets of the sheets of sheets to the right 472a and 462a caused by the deformation of the notch 42 will never be in the axial plane and the interference phenomenon mentioned therein is avoided above.
Case 3: The groups of N tools acting on the notches 41 and 43 are the same group. According to an example of this case, if one only provides a relative rotation of the stator with respect to the group of N tools, then one has for the notch 42 for the closure elements 472a and 462a resulting from the deformation of the notch 41 a closure element 467a or 462b resulting from the deformation of the notch 43 which is in the same axial plane. The two closure elements in the same axial plane respectively from the deformation of the notch 41 and the deformation of the notch 43 form a single closure element 462 or 472. In one example, this case 3 can be combined with case 2 of this embodiment and thus avoids for example tooth 456 the interference phenomenon mentioned above.
Figure 11 illustrates a method of making a rotating electric machine stator as illustrated above. The method comprises a closing step 111 that includes a closing step includes a step of shifting at least one of the sheet metal sheets from an adjacent notch toward said notch.
For example, the offset step is performed on an axial height of at least two sheet sheets. As illustrated above, the offset step comprises a step of introducing a tool in a radial direction, said tool having an orthoradial dimension greater than the notch width.
Furthermore, the method also comprises a compaction step 112 of the winding portion housed in the notch into which the tool is introduced in a radial direction. According to one embodiment, this compaction is performed during said shifting step.

权利要求:
Claims (22)
[1" id="c-fr-0001]
1. Stator (6) of rotating electrical machine (1) comprising: - a stator body (4) formed by a stack of sheets of sheet metal, said stator body being provided with an axis (X) and being delimited by a an inner radial surface and an outer radial surface, - arranged notches (44) in said stator body and extending axially, each having a notch bottom (48) and a notch opening (49), said slot opening being located on the side of said inner radial surface, -a stator winding (5) carried by said stator body, said winding comprising a plurality of winding portions (51, 52, 53) each of which being housed in one of said notches, characterized in that each of the notches (44, 41, 42, 43) is provided at the notch opening with at least one notch closure member (451, 452, 453, 454) so that the winding portion which is accommodated in said notch is held between the notch bottom and said closure element, and in that for each of the notches, said closure element is formed by an offset (451,452a, 452b, 453, 454) of at least one of the sheet metal sheets of an adjacent notch towards said notch.
[2" id="c-fr-0002]
2. Stator according to claim 1, characterized in that one notch out of two comprises a number N of closure elements, N being an integer greater than or equal to 2 and the remaining notches comprise a number of lower closure elements strictly at N.
[3" id="c-fr-0003]
3. Stator according to claim 2, characterized in that two notches having a number N of closing element are contiguous on either side of a notch having a lower number of closure elements.
[4" id="c-fr-0004]
4. Stator according to one of the preceding claims, characterized in that the notches being numbered following the circumference of the stator, even numbered notches include a number of closing elements dfférent that of not odd number notches.
[5" id="c-fr-0005]
5. Stator according to one of the preceding claims, characterized in that the closing elements of the notches (42) are distributed axially over the axial length of the stator body.
[6" id="c-fr-0006]
6. Stator according to claim 5 when dependent on claim 2, characterized in that at least one of the closure elements of a notch (41,43) having a lower number of closure elements is located in an axial plane passing by the middle of two adjacent closure members of a notch (42) comprising the N closure member.
[7" id="c-fr-0007]
7. Stator according to any one of claims 1 to 5, characterized in that for a given notch (42), the closing elements of this notch being located respectively in the first axial planes of the stator body and the closure elements the adjacent notch (41,43) being respectively located in second axial planes of the stator body, the first axial planes are different from the second axial planes.
[8" id="c-fr-0008]
8. Stator according to the preceding claim, characterized in that the first axial planes and the second axial planes is axially distant by a distance equal to at least two sheet sheets.
[9" id="c-fr-0009]
9. Stator according to one of the preceding claims, characterized in that a closure element (452) is formed on the one hand by the offset (452a) of at least one of the sheet metal sheets of a notch adjacent to straight in the direction of said notch and secondly by an offset (452b) of at least one of the sheet metal sheets of a notch adjacent to the left in the direction of said notch, the two offsets being located in the same axial plane.
[10" id="c-fr-0010]
10. Stator according to one of the preceding claims, characterized in that a closure element (451, 452, 453, 454) is formed by an offset of at least two sheets of sheet metal so that the element closure has an axial height of at least two sheet sheets.
[11" id="c-fr-0011]
11. Stator according to one of the preceding claims, characterized in that the two notching edges starting for each notch from the notch bottom to the notch opening are each inscribed in a straight line before the formation of the element. notch closure.
[12" id="c-fr-0012]
12. Stator according to one of the preceding claims, characterized in that for each closure element of a notch (42), at least one of the two adjacent notches has traces of deformation by radial insertion of a tool ( 60) having an orthoradial dimension greater than the notch width.
[13" id="c-fr-0013]
13. Stator according to one of the preceding claims, characterized in that for each closure element of a notch (42), at least one of the two adjacent notches present traces of deformation by radial insertion of a tool ( 60) of substantially spherical shape.
[14" id="c-fr-0014]
14. Stator according to claim 12 or 13, characterized in that the winding portion (51, 52, 53) of a notch has the traces of compaction by said radial insertion of the tool (60).
[15" id="c-fr-0015]
15. Stator according to one of the preceding claims, characterized in that the winding portion (51, 52, 53) of a notch comprises a plurality of son aligned in a column.
[16" id="c-fr-0016]
16. Rotating electric machine with a stator according to one of the preceding claims.
[17" id="c-fr-0017]
17. A method of producing a stator (6) of rotating electrical machine, said stator comprising: - a stator body (4) formed by a stack of sheets of sheets, said stator body being provided with an axis (X ) and being delimited by an inner radial surface and an outer radial surface, - arranged notches (44) in said stator body and extending axially, each having a notch bottom (48) and an opening notch (49), said slot opening being located on the side of said inner radial surface, -a stator winding (5) carried by said stator body, said winding comprising a plurality of winding portions (51, 52, 53) each being housed in one of said notches, characterized in that for each notch the method comprises a closing step (111) at the notch opening so that the winding portion which is housed in said notch is held between the notch bottom and said el and in that the closing step comprises a step of shifting at least one of the sheets of sheet metal from an adjacent notch towards said notch.
[18" id="c-fr-0018]
18. The method of claim 17, characterized in that the closing step comprises for each notch: on the one hand a step of shifting at least one of the sheet metal sheets of a notch adjacent to the right in the direction of said notch; on the other hand, a step of shifting at least one of the sheet metal sheets from a notch adjacent to the left in the direction of said notch; the two offset steps being performed in the same axial plane.
[19" id="c-fr-0019]
19. Method according to one of claims 17 or 18, characterized in that the shifting step is performed on an axial height of at least two sheets of sheets.
[20" id="c-fr-0020]
20. Method according to one of claims 17 to 19, characterized in that said shifting step comprises a step of introducing a tool (60) in a radial direction, said tool having an orthoradial dimension greater than the width of the blade. notch.
[21" id="c-fr-0021]
21. Method according to one of claims 17 to 20, characterized in that said shifting step comprises a step of introducing a tool (60) in a radial direction, said tool having a substantially spherical shape.
[22" id="c-fr-0022]
22. The method of claim 20 or 21, characterized in that during said shifting step, compaction (112) of the coil portion housed in the notch in which is introduced in a radial direction, the tool (60).

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同族专利:

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公开号 | 公开日

---

CN106953433A|2017-07-14|

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US20190393742A1|2019-12-26|

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EP3166210A1|2017-05-10|

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US20170133893A1|2017-05-11|

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US11075551B2|2021-07-27|

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CN106953433B|2021-02-02|

---

FR3043506B1|2017-11-17|

---

KR20170054304A|2017-05-17|

---

JP2017127179A|2017-07-20|

---

EP3166210B1|2019-10-09|

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法律状态:
2016-11-30| PLFP| Fee payment|Year of fee payment: 2 |

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2017-05-12| PLSC| Publication of the preliminary search report|Effective date: 20170512 |

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2017-11-30| PLFP| Fee payment|Year of fee payment: 3 |

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2019-11-29| PLFP| Fee payment|Year of fee payment: 5 |

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2020-11-30| PLFP| Fee payment|Year of fee payment: 6 |

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2021-11-30| PLFP| Fee payment|Year of fee payment: 7 |

优先权:

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申请号 | 申请日 | 专利标题

---

FR1560709A|FR3043506B1|2015-11-09|2015-11-09|ROTATING ELECTRIC MACHINE WITH STATOR|FR1560709A| FR3043506B1|2015-11-09|2015-11-09|ROTATING ELECTRIC MACHINE WITH STATOR|

---

EP16191674.7A| EP3166210B1|2015-11-09|2016-09-30|Rotary electric motor provided with a stator|

---

KR1020160147658A| KR20170054304A|2015-11-09|2016-11-07|Rotary electrical machine provided with a stator|

---

JP2016217893A| JP2017127179A|2015-11-09|2016-11-08|Rotary electrical machine provided with stator|

---

CN201610982572.3A| CN106953433B|2015-11-09|2016-11-08|Rotating electric machine with stator|

---

US15/347,021| US20170133893A1|2015-11-09|2016-11-09|Rotary electrical machine provided with a stator|

---

US16/518,074| US11075551B2|2015-11-09|2019-07-22|Method for making stator of rotary electrical machine|