WO2020175222A1

WO2020175222A1 - Armature and rotating electrical machine

Info

Publication number: WO2020175222A1
Application number: PCT/JP2020/006141
Authority: WO
Inventors: 暁斗田村
Original assignee: 株式会社デンソー
Priority date: 2019-02-25
Filing date: 2020-02-17
Publication date: 2020-09-03
Also published as: JP7147629B2; JP2020137373A

Abstract

A stator winding (731) has phase windings comprising a plurality of partial windings (741) per phase. A base member (736) includes a cylindrical back yoke (732) that is a core sheet laminate formed by stacking core sheets (732a) in the axial direction. The plurality of partial windings are arranged side-by-side in the circumferential direction to either the inner side or the outer side of a base member in the radial direction, and are each provided with a pressing portion (756) that is integrally provided to the partial winding and presses an axial-direction end surface of the back yoke in the axial direction from the outer side in the axial direction.

Description

\¥02020/175222 1 卩 (: 17 2020/006141

Specification

Title of invention: Armature and rotating electric machine

Cross-reference of related applications

[0001] This application was filed on February 25, 2010 in Japanese application number 2 0 1 9-0

It is based on No. 3 2 1 83, the contents of which are incorporated herein by reference.

Technical field

[0002] The disclosure in this specification relates to an armature and a rotating electric machine.

Background technology

[0003] Conventionally, there is known a rotary electric machine including a field element including a magnet unit having a plurality of magnetic poles whose polarities alternate in the circumferential direction, and an armature having a multi-phase armature winding. The armature winding has a phase winding for each phase. In the phase winding of each phase, conductor portions are arranged at predetermined intervals in the circumferential direction, and the coil ends at both ends in the axial direction connect the conductor portions of the same phase.

[0004] An armature generally has an armature winding and an armature core, and the armature winding is assembled to the armature core configured as a laminated body of core sheets made of electromagnetic steel sheets. Has become. Regarding the armature core, for example, Patent Document 1 discloses a technique relating to a so-called helical core in which band-shaped core sheets are spirally stacked.

Prior art documents

Patent literature

Patent Document 1: Japanese Patent Laid-Open No. 2 0 1 4 _ 8 7 2 4 0

Summary of the invention

[0006] In the armature core, there is a concern that the core axial length may be increased due to the expansion of the voids between the core sheets in the laminated state in the core sheet laminate. For example, if the core sheets have spring properties, it is possible that the elastic force expands the voids between the core sheets. In this case, there is concern that this may lead to an increase in the size of the armature. 〇 2020/175 222 2 (: 170? 2020/006141

[0007] The present disclosure has been made in view of the above circumstances, and an object of the present disclosure is to provide an armature and a rotary electric machine that can realize a reduction in size.

[0008] The plurality of aspects disclosed in this specification adopt different technical means from each other in order to achieve the respective objects. The objects, features, and effects disclosed in this specification will become clearer with reference to the following detailed description and the accompanying drawings.

[0009] Means 1 is

A multi-phase armature winding having a phase winding consisting of a plurality of partial windings per phase, and a base member including a cylindrical back yoke that is a core sheet laminated body in which core sheets are laminated in the axial direction,

An armature having

The plurality of partial coiled lines are arranged side by side in the circumferential direction on the radially inner side or the radially outer side of the base member,

A pressing portion that is provided integrally with the partial winding line and that presses the axial end surface of the back yoke in the axial direction from the axially outer side is provided.

[0010] In the above configuration, the armature winding has a phase winding of each phase composed of a plurality of partial windings, and the plurality of partial windings are arranged radially inward or radially outwardly of the base member. They are arranged side by side in the circumferential direction. The cylindrical back yoke is configured as a core sheet laminated body in which core sheets are laminated in the axial direction, and it is desirable to make the minute gap between the core sheets as small as possible. In this respect, the partial winding is integrally provided with a pressing portion that axially presses the axial end surface of the back yoke from the outside in the axial direction, so that in the armature, the pressing force in the axial direction against each core sheet, By doing so, it is possible to apply a biasing force against the core sheets attempting to separate from each other in the axial direction. As a result, the minute gap between the core sheets can be made as small as possible, and the axial length of the back yoke can be reduced. As a result, it is possible to reduce the size of the armature.

[001 1] In this case, since the pressing portion integrally provided on the partial ridge line presses the back yoke from the axially outer side, it is tentatively extended from the back yoke in the radial direction. 〇 2020/175 222 3 (: 170? 2020 /006141

Even in an armature having no teeth, that is, in an armature having a slotless structure, the desired back yoke can be properly held.

[0012] In Means 2, in the Means 1, the armature winding includes a plurality of coil modules including the partial winding and a back yoke side insulating wall provided on the side of the partial yoke and on the side of the yoke. And the plurality of coil modules are arranged side by side in the circumferential direction on the radially inner side or the radially outer side of the base member, whereby the plurality of partial windings are arranged. The pressing portion is provided on the side insulating wall.

[0013] In the above configuration, the coil module is provided with the function of assembling the partial winding line to the back yoke in an insulated state and the function of pressing the back yoke from the axially outer side by the pressing portion in the back yoke side insulating wall. Has been done. In this case, by arranging the plurality of coil modules side by side on the radially inner side or the radially outer side of the base member, it is possible to exert a pressing function on the back yoke.

[0014] In the means 3, in the means 2, the back yoke-side insulating wall is provided with the pressing portion that presses the axial end surface of the back yoke from outside in the axial direction on both sides in the axial direction of the back yoke. There is.

[0015] In the above configuration, the back yoke-side insulating wall is provided with the pressing portions on both axial sides of the back yoke. In this case, the back yoke can be pressed from both axial sides by the individual coil modules.

[0016] In the means 4, in the means 2 or 3, the axial end surface of the back yoke is pressed by the pressing portions of the different coil modules on one axial side and the other axial side of the back yoke. Has been done.

[0017] In the above configuration, in the configuration in which the back yoke is pressed from both sides in the axial direction, the axial end surface of the back yoke is pressed by the pressing portions of different coil modules on one axial side and the other axial side of the back yoke. I decided to do it. In this case, the coil module that presses the axial end surface from one axial side of the back yoke and the coil module that presses the axial end surface from the other axial side of the back yoke. 〇 2020/175 222 4 (: 170? 2020/006141

-By adjusting the relative position in the axial direction with respect to the lever, it is possible to appropriately adjust the pressing force in the axial direction against the back yoke. For example, a constant pressing force can be applied to the back yoke even if there is a product thickness tolerance due to an error in the thickness of the core sheet or a variation in the number of sheets in the back yoke.

[0018] In the means 5, in the means 2, the back yoke-side insulating wall is provided with the pressing portions on both sides in the axial direction of the back yoke, and the plurality of pressing portions are provided with respect to the back yoke. The coil modules are assembled with their axial directions staggered so that the axial end surface of the back yoke is pressed by the pressing portions from both axial sides of the back yoke.

[0019] In the above configuration, the plurality of coil modules are assembled to the back yoke with their axial directions staggered. That is, the coil module in which the pressing portion is provided on one side in the axial direction and the coil module in which the pressing portion is provided on the other side in the axial direction are alternately arranged in the circumferential direction. Then, in this state, the back yoke end surface is pressed by the pressing portions on both axial sides of the back yoke. In this case, by adjusting the relative axial positions of the coil modules that are opposite to each other in the axial direction, it is possible to appropriately adjust the pressing force in the axial direction against the back yoke. For example, a constant pressing force can be applied to the back yoke even if there is a stacking thickness tolerance due to an error in the thickness of the core sheet or variations in the number of sheets in the back yoke.

[0020] In the means 6, in any one of the means 2 to 5, the coil modules are fixed such that the coil modules adjacent to each other in the circumferential direction cannot be relatively moved in the axial direction.

[0021] In the above configuration, since the coil modules adjacent to each other in the circumferential direction are not allowed to move relative to each other in the axial direction, the axial pressing force against the core sheet caused by the axial displacement of the coil modules is caused. Can be suppressed. As a result, the axial length of the back yoke can be reduced more appropriately.

[0022] In the means 7, in any one of the means 2 to 6, the coil module 〇 2020/175 222 5 (: 170? 2020/006141

In the above, the back yoke side insulating wall has a yoke outer portion that extends axially outwardly beyond the axial end surface of the back yoke, and the yoke outer portion has a surface facing the back yoke in the circumferential direction. The pressing portion is integrally formed so as to protrude toward the back yoke side.

[0023] In the above configuration, the coil module has a configuration in which the pressing portion that presses the back yoke in the axial direction is integrally formed on the outside of the yoke of the back yoke side insulating wall. The back yoke side insulating wall and the pressing portion can be simultaneously molded. As a result, the configuration can be simplified.

[0024] Means 8 is any one of Means 2 to 7, wherein the back yoke has a radial inner side and a radial outer side at positions opposite to the back yoke side insulating wall. In addition to the pressing portion, a stack holding structure for holding the stacked state of the core sheets is provided.

[0025] In the above configuration, in addition to the axial pressing by the coil module on one of the radial inside and outside of the back yoke, the stack holding structure is provided on the other radial inside and outside of the back yoke. The laminated state of the core sheets is maintained. As for the stack holding structure, welding by joining core sheets, joining by crimping the core sheet, joining by adhesive, and stack holding by the frictional force of the tubular member assembled on the side opposite to the coil module in the back yoke can be considered. To be This makes it possible to more appropriately reduce the axial length of the back yoke.

[0026] In the means 9, in any one of the means 2 to 8, the pressing provided on the outer yoke portion that extends axially outward from the axial end surface of the back yoke on the back yoke side edge wall. And a plate-shaped spacer that abuts against the axial end surface of the back yoke, the spacer being a diameter relative to the axial end surface of the back yoke. The overlapping amount in the direction is larger than that of the pressing portion, and the axial end surface of the back yoke is pressed by the pressing portion via the spacer. 〇 2020/175 222 6 卩 (: 170? 2020 /006141

[0027] In the above configuration, as a spacer provided between the pressing portion of the back yoke side insulating wall and the axial end surface of the back yoke, the overlapping amount in the radial direction with respect to the axial end surface of the back yoke is greater than that of the pressing portion. A large spacer is used, and the axial end surface of the back yoke is pressed by the pressing portion via the spacer. In this case, the wide range of the back yoke can be uniformly pressed in the axial direction. Therefore, it is possible to suppress the curling of the edge portion of the core sheet.

[0028] In the means 10, in the means 9, a concave portion extending in the axial direction is formed in a surface of the spacer facing the pressing portion, and a part of the pressing portion enters the concave portion. It is composed.

The [0029] above-described structure, since the portion of the back yoke side insulating wall ^_ body shaped pressing portion of the coil module, Komu contains the recess formed in the axial direction in the spacer, to the back yoke Radial movement of the coil module is restricted. Thereby, the axial pressing function of the back yoke by the coil module can be preferably maintained.

[0030] In the means 11 described in any one of the means 1 to 10, the base member has an end ring fixed to an axial end surface of the back yoke, and the end ring includes: A recess is formed so as to be recessed from the radial surface of the back yoke on the side of the partial winding, and the pressing portion is provided so as to face the recess in the radial direction, and in the recess, the protrusion is formed. It is engaged with the base member in the circumferential direction.

[0031] In the above configuration, the pressing portion is provided so as to face the concave portion formed in the end ring of the base member in the radial direction, and in this state, the back yoke presses the back yoke in the axial direction by the pressing portion. Has been done. Further, since the pressing portion engages with the base member in the circumferential direction in the concave portion, the positional accuracy in the circumferential direction of each partial winding with respect to the base member can be improved. In this case, even in the armature having the slotless structure, the armature winding can be favorably assembled.

Means 12 In the means 1, in the back yoke and the partial winding, 〇 2020/175 222 7 卩(: 170? 2020/006141

The back yoke and the portion axially opposite end portions of the卷線, and are resin-molded ^_ the body in a range including the side portions of the anti back yoke side of the portion卷線, covering portion formed by the resin molding Of these, the end face coating portions that cover the axial end faces of the back yoke on both axial sides function as the pressing portions.

[0033] In the above-mentioned configuration, the back yoke and the partial winding are integrated by resin molding, and in that state, the axial end surface of the back yoke is on both sides in the axial direction of the covering portion formed by the resin molding. The end surface covering portion that covers the area functions as a pressing portion. In this case, the coating part formed by resin molding is provided in the range including both axial end parts of the back yoke and the partial winding, and the side part of the partial winding on the side opposite to the back yoke side. Since both end portions in the axial direction are also connected to the side surface portions of the covering portion, the distance between the end portions in the axial direction of the covering portion is maintained without expanding. As a result, it is possible to exert the pressing function against the back york in the covering portion.

[0034] It is preferable that the back yoke has a structure in which the laminated core sheets are resin-molded in a state of being axially pressed and compressed.

[0035] A rotating electric machine as the means 13 comprises: the armature according to any one of the means 1 to 12; and a field element having a plurality of magnetic poles whose polarities alternate in the circumferential direction, Either the field element or the armature rotates together with the rotating shaft.

[0036] According to the above configuration, by using the armature in which the axial length of the back yoke is reduced and the performance is ensured, the rotating electric machine can be downsized and sufficient safety can be secured. Further, it is possible to suitably realize a rotating electric machine having a slotless structure armature.

Brief description of the drawings

[0037] The above and other objects, features, and advantages of the present disclosure will be made clearer by the following detailed description with reference to the accompanying drawings. The drawing is [Fig. 1] Fig. 1 is a longitudinal sectional perspective view of a rotating electric machine.

[Fig. 2] Fig. 2 is a vertical cross-sectional view of a rotating electrical machine.

[Fig. 3] Fig. 3 is a sectional view taken along line 111-111 in Fig. 2. 20/175222 8 卩 (: 170? 2020 /006141

[FIG. 4] FIG. 4 is an enlarged cross-sectional view showing a part of FIG.

[Fig. 5] Fig. 5 is an exploded view of the rotating electrical machine.

[Fig. 6] Fig. 6 is an exploded view of the inverter unit.

[Fig. 7] Fig. 7 is a torque diagram showing the relationship between the ampere-turn of the stator winding and the torque density.

[Fig. 8] Fig. 8 is a cross-sectional view of the rotor and the stator.

[FIG. 9] FIG. 9 is an enlarged view of a part of FIG.

[Fig. 10] Fig. 10 is a cross-sectional view of the stator.

[Fig. 11] Fig. 11 is a longitudinal sectional view of the stator.

[Fig. 12] Fig. 12 is a perspective view of the stator winding line.

[FIG. 13] FIG. 13 is a perspective view showing the structure of a conductor.

[Fig. 14] Fig. 14 is a schematic diagram showing the structure of a wire.

[FIG. 15] FIG. 15 is a view showing the form of each conductor in the n-th layer,

[Fig. 16] Fig. 16 is a side view showing the conductors of the nth layer and the _n + 1st layer.

[FIG. 17] FIG. 17 is a diagram showing the relationship between the electrical angle and the magnetic flux density of the magnet of the embodiment.

[Fig. 18] Fig. 18 is a graph showing the relationship between the electrical angle and the magnetic flux density for the magnet of the comparative example.

[Fig. 19] Fig. 19 is an electric circuit diagram of the control system for the rotating electric machine.

[FIG. 20] FIG. 20 is a functional block diagram showing a current feedback control process by the control device.

[Fig. 21] Fig. 21 is a functional block diagram showing the torque feedback control process by the control unit.

[FIG. 22] FIG. 22 is a cross-sectional view of a rotor and a stator according to the second embodiment.

[Fig. 23] Fig. 23 is an enlarged view of a part of Fig. 22.

[Fig. 24] Fig. 24 is a diagram specifically showing the flow of magnetic flux in the magnet unit. 〇 2020/175 222 9 boxes (: 170? 2020/006141

[Fig. 25] Fig. 25 is a cross-sectional view of a stator in Modification 1,

[Fig. 26] Fig. 26 is a cross-sectional view of a stator in Modification Example 1,

[Fig. 27] Fig. 27 is a cross-sectional view of a stator according to Modification 2.

[Fig. 28] Fig. 28 is a cross-sectional view of a stator according to Modification 3.

[Fig. 29] Fig. 29 is a cross-sectional view of a stator in Modification 4,

[FIG. 30] FIG. 30 is a cross-sectional view of a rotor and a stator in Modification 7.

[FIG. 31] FIG. 31 is a functional block diagram showing a part of the processing of the operation signal generation unit in Modification 8.

[Fig. 32] Fig. 32 is a flow chart showing the procedure for changing the carrier frequency.

[FIG. 33] FIG. 33 is a diagram showing a connection form of each conductor wire which constitutes the conductor wire group in Modification 9,

[FIG. 34] FIG. 34 is a diagram showing a configuration in which four pairs of conductor wires are arranged in a laminated manner in Modification Example 9.

[FIG. 35] FIG. 35 is a cross-sectional view of an inner rotor type rotor and a stator in Modification 10.

[Fig. 36] Fig. 36 is an enlarged view of a part of Fig. 35.

[Fig. 37] Fig. 37 is a vertical cross-sectional view of an inner rotor type electric rotating machine.

[Fig. 38] Fig. 38 is a vertical cross-sectional view showing a schematic configuration of an inner rotor type rotating electric machine.

[FIG. 39] FIG. 39 is a diagram showing a configuration of a rotating electric machine having an inner rotor structure in Modification 11;

[FIG. 40] FIG. 40 is a diagram showing a configuration of a rotating electric machine having an inner rotor structure in Modification Example 11.

[FIG. 41] FIG. 41 is a diagram showing a configuration of a rotary armature-type rotary electric machine in Modification 12;

[FIG. 42] FIG. 42 is a cross-sectional view showing a structure of a conductor wire in Modification Example 14.

[Fig. 43] Fig. 43 shows the relationship between reluctance torque, magnet torque, and mouth IV!. 〇 2020/175 222 10 boxes (: 170? 2020/006141

And

[Fig.44] Fig.44 is a diagram showing teeth.

[Fig. 45] Fig. 45 is a perspective view showing the wheel of the in-wheel motor structure and its peripheral structure.

[Fig. 46] Fig. 46 is a longitudinal sectional view of the wheel and its peripheral structure.

[Fig. 47] Fig. 47 is an exploded perspective view of the wheel.

[Fig. 48] Fig. 48 is a side view of the rotary electric machine as seen from the protruding side of the rotary shaft, and [Fig. 49] Fig. 49 is a sectional view taken along the line 4-9-49 of Fig. 48.

[Fig. 50] Fig. 50 is a sectional view taken along line 50--50 of Fig. 49.

[Fig. 51] Fig. 51 is an exploded cross-sectional view of a rotating electric machine.

[Fig. 52] Fig. 52 is a partial sectional view of the rotor.

[Fig. 53] Fig. 53 is a perspective view of a stator winding and a stator core.

[FIG. 54] FIG. 54 is a front view showing the stator winding wire in a flat state, and [FIG. 55] FIG. 55 is a view showing skew of the conductive wire.

[Fig. 56] Fig. 56 is an exploded sectional view of the inverter unit.

[Fig. 57] Fig. 57 is an exploded sectional view of the inverter unit.

[Fig. 58] Fig. 58 shows how the electric modules are arranged in the inverter housing.

[FIG. 59] FIG. 59 is a circuit diagram showing an electrical configuration of the power converter,

[Fig. 60] Fig. 60 is a diagram showing a cooling structure example of the switch module, [Fig. 61] Fig. 61 is a diagram showing a cooling structure example of the switch module, and [Fig. 62] Fig. 62 is a diagram. [Fig. 63] Fig. 63 is a diagram showing an example of the cooling structure of the switch module, and [Fig. 64] Fig. 64 is an example of the cooling structure of the switch module. Fig. 65 Fig. 65 is a diagram showing the arrangement order of the electric modules with respect to the cooling water passage,

[Fig. 66] Fig. 66 is a sectional view taken along line 6 6--6 6 of Fig. 49.

[Fig. 67] Fig. 67 is a sectional view taken along the line 6 7--6 7 of Fig. 49. 20/175222 1 1 卩 (: 170? 2020 /006141

[Fig. 68] Fig. 68 is a perspective view showing the bus bar module as a single unit.

[Fig. 69] Fig. 69 is a diagram showing an electrical connection state between each electric module and the bus bar module.

[Fig. 70] Fig. 70 is a diagram showing an electrical connection state between each electric module and the bus bar module.

[Fig. 71] Fig. 71 is a diagram showing an electrical connection state between each electric module and the bus bar module.

[Fig. 72] Fig. 72 is a configuration diagram for explaining a modification 1 of the in-wheel motor.

[Fig. 73] Fig. 73 is a configuration diagram for explaining a second modification of the in-wheel motor.

[Fig. 74] Fig. 74 is a configuration diagram for explaining Modification 3 of the in-wheel motor.

[Fig. 75] Fig. 75 is a configuration diagram for explaining a modification 4 of the in-wheel motor.

[FIG. 76] FIG. 76 is a perspective view showing the entire rotating electric machine in Modification Example 15, [FIG. 77] FIG. 77 is a vertical sectional view of the rotating electric machine,

[Fig. 78] Fig. 78 is an exploded cross-sectional view of a rotating electric machine.

[Fig. 79] Fig. 79 is a sectional view of the rotor.

[Fig. 80] Fig. 80 is a partial sectional view showing the sectional structure of the magnet unit.

[Fig. 81] Fig. 81 is a partial sectional view showing a magnified part of the magnet unit.

[Fig. 82] Fig. 82 is a perspective view showing the structure of the stator.

[Fig. 83] Fig. 83 is an exploded perspective view of the stator winding and the stator core. [Fig. 84] Fig. 84 is the II-phase winding of the phase winding of each phase. It is a perspective view showing only the corresponding configuration,

[Fig.85] Fig.85 is a longitudinal sectional view of the stator.

[Fig. 86] Fig. 86 is a circuit diagram showing the state of connection of partial windings in each phase winding of three phases. 20/175222 12 卩 (: 170? 2020 /006141

[Fig. 87] Fig. 87 is a diagram showing the structure of the coil module.

[Fig. 88] Fig. 88 is a diagram showing a configuration of a coil module.

[Fig. 89] Fig. 89 is a diagram showing a configuration of a coil module.

[FIG. 90] FIG. 90 is a diagram showing a configuration of a coil module,

[Fig. 91] Fig. 91 is a sectional view showing a longitudinal section of the stator.

[Fig. 92] Fig. 92 is a cross-sectional view showing a cross section of the stator.

[FIG. 93] FIG. 93 is a cross-sectional view showing the stator core and the end ring, and the coil module separated from each other.

[Fig. 94] Fig. 94 is a vertical sectional view of the inner unit.

[Fig. 95] Fig. 95 is a vertical sectional view of the inner unit.

[Fig. 96] Fig. 96 is a perspective view of the bus bar module.

[Fig. 97] Fig. 97 is a cross-sectional view showing a part of the vertical cross-section of the busbar module, and [Fig. 98] Fig. 98 is a schematic view showing the connection positions of the connection terminals for each busbar.

[Fig. 99] Fig. 99 is a diagram showing a winding sequence of conductor wires in the partial winding,

[Fig. 100] Fig. 100 is a diagram showing the structure of a coil module.

[Fig. 101] Fig. 101 is a diagram showing a configuration of a coil module.

[Fig. 102] Fig. 102 is a diagram showing a configuration of a coil module.

[Fig. 103] Fig. 103 is a diagram showing a configuration of a coil module.

[Fig. 104] Fig. 104 is a diagram showing a configuration of a coil module.

[Fig. 105] Fig. 105 is a cross-sectional view showing a cross section of the stator.

[Fig. 106] Fig. 106 is a cross-sectional view showing a cross section of the stator.

[Fig. 107] Fig. 107 is a cross-sectional view showing a cross section of the stator.

[Fig. 108] Fig. 108 is a diagram showing a cross section of the stator and a core sheet of the stator core.

[Fig. 109] Fig. 109 is a diagram showing a configuration of a coil module.

[Fig. 110] Fig. 110 shows the assembly of the coil module to the stator core. 20/175222 13 卩(: 170? 2020 /006141

[Fig. 1 1 1] Fig. 1 1 1 shows the assembly of the coil module to the stator core.

[Fig. 1 12] Fig. 1 12 shows the assembly of the coil module to the stator core.

[Fig. 13] Fig. 113 is a front view of the stator core.

[Fig. 114] Fig. 114 shows the assembly of the coil module to the stator core.

[Fig. 115] Fig. 115 shows the assembly of the coil module to the stator core.

[Fig. 116] Fig. 116 shows the assembly of the coil module to the stator core.

[Fig. 117] Fig. 117 shows the assembly of the coil module to the stator core.

[Fig. 118] Fig. 118 is a front view of the coil module.

[Fig. 119] Fig. 119 shows how the coil module is assembled to the stator core.

[Fig. 120] Fig. 120 is a diagram showing the assembly of the coil module to the stator core.

[Fig. 121] Fig. 121 shows the assembly of the coil module to the stator core.

[Fig. 122] Fig. 122 is a diagram showing the assembly of the coil module to the stator core.

[Fig. 123] Fig. 123 is a perspective view of the stator.

[Fig. 124] Fig. 124 is a perspective view showing the structure of the stator in Modification 17 and [Fig. 125] Fig. 125 is a front view of the stator.

[Fig. 126] Fig. 126 is a longitudinal sectional view of the stator.

[Fig. 127] Fig. 127 is a cross-sectional view of the stator.

[Fig. 128] Fig. 128 is an exploded perspective view of the stator winding and the stator core. 〇 2020/175 222 14 卩(: 170? 2020/006141

[Fig. 129] Fig. 129 is a circuit diagram showing a connection state of partial windings in each phase winding of three phases.

[Fig. 130] Fig. 130 is a perspective view of the coil module.

[Fig. 131] Fig. 131 shows the configuration of the coil module.

[Fig. 132] Fig. 132 is a perspective view showing a state in which a plurality of coil modules are arranged in the circumferential direction.

[Fig. 133] Fig. 133 is a diagram showing a cross section of a plurality of coil modules arranged in the circumferential direction.

[Fig.134] Fig.134 is a sectional view showing the sectional structure of the partial winding.

[FIG. 135] FIG. 135 is a perspective view showing the structure of a conductor.

MODE FOR CARRYING OUT THE INVENTION

[0038] Embodiments will be described with reference to the drawings. In some embodiments, functionally and/or structurally corresponding parts and/or associated parts may be given the same reference signs, or hundreds or more different reference signs. For the corresponding part and/or the related part, the description of the other embodiments can be referred to.

[0039] The rotary electric machine according to the present embodiment is used, for example, as a vehicle power source. However, rotating electrical machines can be widely used for industrial applications, vehicles, home appliances, equipment for 88 devices, and amusement machines. Note that in the following embodiments, the portions that are the same ^_ or equivalent to each other, in the drawing, are designated by the same _ code, portions of the ^_ sign of which is incorporated by reference in its description.

[0040] (First Embodiment)

The rotary electric machine 100 according to the present embodiment is a synchronous multi-phase AC motor and has an outer port structure (outer rotation structure). An outline of the rotating electric machine 10 is shown in Figs. 1 is a vertical cross-sectional perspective view of the rotary electric machine 10, FIG. 2 is a vertical cross-sectional view of the rotary electric machine 10 in a direction along the rotary shaft 11 and FIG. The cross-sectional view of the rotating electric machine 10 in the direction of 〇 2020/175 222 15 卩(: 170? 2020/006141

Yes, FIG. 4 is a cross-sectional view showing an enlarged part of FIG. 3, and FIG. 5 is an exploded view of the rotary electric machine 10. Note that, in FIG. 3, for convenience of illustration, the hatching showing the cut surface is omitted except for the rotating shaft 11. In the following description, the direction in which the rotary shaft 11 extends is the axial direction, the direction that extends radially from the center of the rotary shaft 11 is the radial direction, and the direction that extends circumferentially around the rotary shaft 11 is the circumferential direction. I am trying.

The rotating electric machine 10 is roughly provided with a bearing unit 20, a housing 30, a rotor 40, a stator 50, and an inverter unit 60. Each of these members is arranged coaxially with the rotating shaft 11 and is assembled in the axial direction in a predetermined order to form the rotating electric machine 10. The rotating electric machine 10 of the present embodiment is configured to have a rotor 40 as a “field element” and a stator 50 as an “armature”, and is a rotating field type rotating electric machine. Is embodied as

[0042] The bearing unit 20 has two bearings 21 and 22 that are arranged apart from each other in the axial direction, and a holding member 23 that holds the bearings 21 and 22. .. The bearings 2 1, 2 2 are, for example, radial ball bearings, each having an outer ring 25, an inner ring 26, and a plurality of balls 27 arranged between the outer ring 25 and the inner ring 26. ing. The holding member 23 has a cylindrical shape, and the bearings 21 and 22 are assembled inside the holding member 23. The rotating shaft 11 and the rotor 40 are rotatably supported inside the bearings 21 and 22 in the radial direction. The bearings 21 and 22 constitute a set of bearings that rotatably support the rotary shaft 1 1.

In each of the bearings 21 and 22, a ball 27 is held by a retainer (not shown), and the pitch between the balls is maintained in that state. Each of the bearings 21 and 22 has a sealing member at the upper and lower portions in the axial direction of the retainer, and the inside thereof is filled with a non-conductive grease (for example, a non-conductive urea-based grease). In addition, the position of the inner ring 26 is mechanically held by a spacer, and a constant pressure preload is applied so that it projects from the inside in the vertical direction.

[0044] The housing 30 has a cylindrical peripheral wall 31. The peripheral wall 31 has a first end and a second end that face each other in the axial direction. The peripheral wall 3 1 has an end face 3 2 at the first end. 〇 2020/175 222 16 卩(: 170? 2020/006141

It also has an opening 33 at the second end. The opening 33 is opened at the entire second end. A circular hole 34 is formed in the center of the end face 32, and the bearing unit 20 is fixed with a fixing tool such as a screw or rivet in a state where the circular hole 34 is made to pass through the hole 34. There is. A hollow cylindrical rotor 40 and a hollow cylindrical stator 50 are housed in the housing 30, that is, in the internal space defined by the peripheral wall 31 and the end face 32. In the present embodiment, the rotary electric machine 10 is of the rotor type, and the stator 50 is arranged inside the housing 30 in the radial direction of the cylindrical rotor 40. The rotor 40 is cantilevered on the rotating shaft 1 1 on the end face 3 2 side in the axial direction.

The rotor 40 has a magnet holder 4 1 formed in a hollow cylindrical shape, and an annular magnet unit 42 provided inside the magnet holder 41 in the radial direction. The magnet holder 41 has a substantially cup shape and functions as a magnet holding member. The magnet holder 4 1 includes a cylindrical portion 4 3 having a cylindrical shape, a fixing portion (3 3 1116^) 4 4 having the same cylindrical shape and a smaller diameter than the cylindrical portion 4 3, and the cylindrical portion 4 3 and the fixing portion. It has an intermediate part 4 5 which serves as a part for connecting the part 4 4. The magnet unit 4 2 is attached to the inner peripheral surface of the cylindrical portion 4 3.

[0046] The magnet holder 41 is a cold-rolled steel plate with sufficient mechanical strength.

, Forging steel, carbon fiber reinforced plastic

Etc.

The rotary shaft 11 is passed through the through hole 4 43 of the fixed portion 4 4. The fixed portion 4 4 is fixed to the rotating shaft 1 1 arranged in the through hole 4 4 ₃ . That is, the magnet holder 41 is fixed to the rotating shaft 11 by the fixing portion 44. The fixed portion 44 is preferably fixed to the rotary shaft 11 by spline connection using unevenness, key connection, welding, caulking, or the like. As a result, the rotor 40 rotates together with the rotary shaft 1 1.

[0048] Further, the bearings 21 and 22 of the bearing unit 20 are assembled on the outer side in the radial direction of the fixed portion 44. Since the bearing unit 20 is fixed to the end face 32 of the housing 30 as described above, the rotating shaft 11 and the rotor 40 are 〇 2020/175 222 17 卩(: 170? 2020/006141

It is rotatably supported by 30. As a result, the rotor 40 is rotatable within the housing 30.

[0049] The rotor 40 is provided with the fixed portion 44 only at one of the two end portions that face each other in the axial direction, whereby the rotor 40 is cantilevered on the rotation shaft 1 1. It is being touched. Here, the fixed portion 44 of the rotor 40 is rotatably supported at two different axial positions by the bearings 21 and 22 of the bearing unit 20. That is, the rotor 40 is rotatably supported by the two bearings 21 and 22 spaced apart from each other in one of the two axially opposite ends of the magnet holder 41. Is supported. Therefore, even if the rotor 40 is cantilevered by the rotating shaft 11, stable rotation of the rotor 40 is realized. In this case, the rotor 40 is supported by the bearings 21 and 22 at a position displaced to one side with respect to the axial center position of the rotor 40.

[0050] In the bearing unit 20, the bearing 22 located near the center of the rotor 40 (lower side in the figure) and the bearing 2 1 on the opposite side (upper side in the figure) are the outer ring 25 and The clearance between the inner ring 26 and the ball 27 is different, for example, the bearing 2 2 near the center of the rotor 40 has a larger clearance than the bearing 2 1 on the opposite side. Has become. In this case, on the side closer to the center of the rotor 40, even if vibration of the rotor 40 or vibration due to imbalance due to component tolerance acts on the bearing unit 20, the vibration and the effect of vibration will not occur. Absorbed well. Specifically, by increasing the play size (gap size) in the bearing 22 located near the center of the rotor 40 (lower side in the figure) by preload, the vibration generated in the cantilever structure is generated in the play part. Is more absorbed. The preload may be a fixed position preload or a constant preload. In the case of fixed position preload, both the bearing 21 and the outer ring 25 of the bearing 22 are joined to the holding member 23 by a method such as press fitting or adhesion. Further, both the bearing 21 and the inner ring 26 of the bearing 22 are joined to the rotary shaft 11 by a method such as press fitting or adhesion. Pre-load can be generated by arranging the outer ring 25 of the bearing 21 at a position different from the inner ring 26 of the bearing 21 in the axial direction. The outer ring 2 5 of bearing 2 2 is axially aligned with the inner ring 2 6 of bearing 2 2. 〇 2020/175222 18 Preload can also be generated by arranging in different positions (: 170? 2020/006141).

[0051] When the constant pressure preload is adopted, the preload panel is designed so that a preload is generated in the axial direction from the region sandwiched by the bearing 22 and the bearing 21 toward the outer ring 25 of the bearing 22. For example, place the wave washer 2 4 etc. in the same area between the bearing 2 2 and the bearing 2 1. Also in this case, both the bearing 21 and the inner ring 26 of the bearing 22 are joined to the rotating shaft 11 by a method such as press fitting or adhesion. The bearing 21 or the outer ring 25 of the bearing 22 is arranged with a predetermined clearance with respect to the holding member 23. With such a configuration, the paner of the preload panel acts on the outer ring 25 of the bearing 22 in a direction away from the bearing 21. Then, this force is transmitted to the rotary shaft 11 to exert a force that pushes the inner ring 26 of the bearing 21 toward the bearing 22. As a result, the axial positions of the outer ring 25 and the inner ring 26 of both the bearings 21 and 22 are displaced, and the two bearings can be preloaded in the same manner as the fixed position preload described above.

[0052] Note that when generating a constant pressure preload, it is not always necessary to apply a paneler to the outer ring 25 of the bearing 22 as shown in FIG. For example, a Baneka may be applied to the outer ring 25 of the bearing 21. Also, place the inner ring 26 of either of the bearings 21 and 22 on the rotating shaft 11 with a predetermined clearance, and press the outer ring 25 of the bearings 21 and 22 into the holding member 23. Alternatively, the two bearings may be preloaded by joining them using a method such as bonding.

[0053] Further, in the case where the inner ring 26 of the bearing 21 exerts a force so as to separate from the bearing 22, the inner ring 26 of the bearing 22 also separates from the bearing 21. Is better to use. On the contrary, when the inner ring 26 of the bearing 21 exerts a force so as to approach the bearing 22, the inner race 26 of the bearing 22 also exerts a force so as to approach the bearing 21. Better to let.

When the rotating electric machine 10 is applied to a vehicle for the purpose of a vehicle power source or the like, there is a possibility that vibration having a component in the preload generation direction may be applied to the mechanism for generating the preload, There is a possibility that the direction of gravity applied to the object to which the preload is applied may change. Therefore, when applying this rotating electrical machine 10 to a vehicle, a constant position preload is used. 〇 2020/175 222 19 卩(: 170? 2020/006141

It is desirable to use.

[0055] The intermediate portion 4 5 have the outer shoulder 4 9 spoon annular inner shoulder 4 9 ₃ and the annular. The outer shoulder portion 4913 is located outside the inner shoulder portion 493 in the radial direction of the intermediate portion 45. Inner shoulder 4 9 ₃ and the outer shoulder 4 9 spoon are spaced apart from each other in the axial Direction of the intermediate portion 4 5. As a result, the cylindrical portion 4 3 and the fixed portion 4 4 partially overlap each other in the radial direction of the intermediate portion 45. In other words, the cylindrical portion 4 3 projects outward in the axial direction with respect to the base end of the fixed portion 4 4 (bottom end on the lower side of the figure). In this configuration, as compared with the case where the intermediate portion 45 is provided in the shape of a flat plate without a step, the rotor 40 is supported on the rotating shaft 11 at a position near the center of gravity of the rotor 40. It is possible to achieve stable operation of the rotor 40.

According to the configuration of the intermediate portion 45 described above, the rotor 40 has a bearing unit 20 that is located at a position that surrounds the fixed portion 4 4 in the radial direction and is located inward of the intermediate portion 45. A bearing accommodating recess 46 for accommodating a part of it is formed in an annular shape, and at a position that surrounds the bearing accommodating recess 46 in the radial direction and is on the outer side of the intermediate part 45, a stator 5 described later is formed. A coil accommodating recess 47 for accommodating the coil end 5 4 of the stator winding 51 of 0 is formed. The accommodation recesses 46, 47 are arranged so as to be adjacent to each other inside and outside in the radial direction. That is, a part of the bearing unit 20 and the coil end 5 4 of the stator winding 5 1 are arranged so as to overlap radially inward and outward. As a result, the axial length of the rotary electric machine 10 can be shortened.

The intermediate portion 45 is provided so as to project radially outward from the rotary shaft 11 side. Further, a contact avoidance portion that extends in the axial direction and that avoids contact with the coil end 5 4 of the stator winding 51 of the stator 50 is provided in the intermediate portion 45. The intermediate portion 45 corresponds to the projecting portion.

[0058] The coil end 5 4 can be bent inward or outward in the radial direction to reduce the axial dimension of the coil end 5 4 and reduce the axial length of the stator 50. Is. The bending direction of the coil end 54 is the same as that of the rotor 40. 〇 2020/175 222 20 units (: 170? 2020 /006141

It is good to consider the assembly of. Assuming that the stator 50 is assembled on the inner side of the rotor 40 in the radial direction, it is preferable that the coil end 5 4 be bent inward in the radial direction on the side of the insertion end with respect to the rotor 40. The coil end on the side opposite to the coil end 54 may be bent in any direction, but a shape bent outward with a spatial allowance is preferable for manufacturing.

[0059] Further, the magnet unit 42 as a magnet portion is composed of a plurality of permanent magnets arranged radially inside the cylindrical portion 4 3 so that the polarities thereof alternate alternately along the circumferential direction. ing. As a result, the magnet unit 42 has a plurality of magnetic poles in the circumferential direction. However, details of the magnet unit 42 will be described later.

[0060] The stator 50 is provided inside the rotor 40 in the radial direction. The stator 5 0 has a stator winding 5 1 formed in a substantially cylindrical (annular) winding shape, and a stator core 5 2 as a base member arranged radially inside thereof. The stator winding 51 is arranged so as to face the annular magnet unit 42 with a predetermined air gap in between. The stator winding 51 consists of multiple phase windings. Each of the phase windings is composed of a plurality of conductor wires arranged in the circumferential direction and connected to each other at a predetermined pitch. In the present embodiment, a three-phase winding wire of re-phase, V-phase and phase and a three-phase winding wire of X-phase, negative phase and phase are used. The child winding 51 is configured as a 6-phase winding.

[0061] The stator core 52 is formed in an annular shape by a laminated steel sheet in which electromagnetic steel sheets which are soft magnetic materials are laminated, and is assembled inside the stator winding 51 in the radial direction. The electromagnetic steel sheet is, for example, a silicon steel sheet obtained by adding about several percent (for example, 3%) of silicon to iron. The stator winding 5 1 corresponds to the armature winding, and the stator core 5 2 corresponds to the armature core.

[0062] The stator winding 5 1 is a portion that overlaps the stator core 5 2 in the radial direction, and is located radially outside the stator core 5 2 and the coil side portion 5 3 in the axial direction. The stator core 52 has coil ends 5 4 and 5 5 projecting from one end side and the other end side, respectively. The coil side portion 5 3 faces the stator core 52 and the magnet unit 42 of the rotor 40 in the radial direction. Rotor 〇 2020/175 222 21 卩(: 170? 2020/006141

With stator 50 placed inside 40, coil ends on both axial sides

The coil end 54, which is the bearing unit 20 side (upper side in the figure) of 5 4 and 5 5, is housed in the coil housing recess 4 7 formed by the magnet holder 41 of the rotor 40. .. However, details of the stator 50 will be described later.

[0063] The inverter unit 60 is composed of a unit base 61 which is fixed to the housing 30 by fasteners such as bolts, and a plurality of electrical components which are assembled to the unit base 61. 6 2 and. Unit base 61 is, for example, carbon fiber reinforced plastic.

It is composed by. The unit base 61 includes an end plate 63 fixed to the edge of the opening 33 of the housing 30 and a casing 64 integrally formed with the end plate 63 and extending in the axial direction. Have The end plate 63 has a circular opening 65 at the center thereof, and a casing 64 is formed so as to stand upright from the peripheral edge of the opening 65.

A stator 50 is attached to the outer peripheral surface of the casing 64. That is, the outer diameter of the casing 64 is the same as the inner diameter of the stator core 52 or slightly smaller than the inner diameter of the stator core 52. casing

By mounting the stator core 52 on the outer side of the stator 64, the stator 50 and the unit base 61 are integrated. In addition, since the unit base 61 is fixed to the housing 30 and the stator core 5 2 is assembled to the casing 6 4, the stator 5 0 / / housing 30 It is in an integrated state with respect to.

The stator core 52 is preferably attached to the unit base 61 by adhesion, shrink fitting, press fitting, or the like. As a result, the positional deviation of the stator core 52 from the unit base 61 side in the circumferential direction or the axial direction is suppressed.

[0066] Further, the inside of the casing 64 in the radial direction is a housing space for housing the electric component 62, and the electric component 62 is arranged in the housing space so as to surround the rotating shaft 11. There is. The casing 64 has a role as a storage space forming unit. Electrical component 6 2 is the inverter 〇 2020/175 222 22 卩 (: 170? 2020 /006141

It is equipped with a semiconductor module 66 that constitutes the path, a control board 67, and a capacitor module 68.

The unit base 61 is provided inside the stator 50 in the radial direction and corresponds to a stator holder (armature holder) that holds the stator 50. The housing 30 and the unit base 61 constitute a motor housing of the rotating electric machine 10. In this motor housing, the holding member 23 is fixed to the housing 30 on one side in the axial direction across the rotor 40, and the housing 30 and the unit base 61 are on the other side. Are connected to each other. For example, in an electric vehicle or the like which is an electric vehicle, the rotating electric machine 10 is mounted on the vehicle or the like by mounting the motor housing on the vehicle or the like side.

Here, the configuration of the inverter unit 60 will be further described using FIG. 6 which is an exploded view of the inverter unit 60 in addition to FIGS. 1 to 5 described above.

[0069] In the unit base 61, the casing 64 includes an end face 7 provided at one end (the end on the bearing unit 20 side) of the tubular part 71 and the two ends facing each other in the axial direction. Has 2 and. The opposite side of the end face 7 2 among the both axial ends of the tubular portion 7 1 is entirely opened through the opening 65 of the end plate 63. A circular hole 7 3 is formed in the center of the end face 72, and the rotating shaft 11 can be passed through the hole 73. The hole 7 3 is provided with a seal material 1 7 1 that seals a gap between the hole 7 3 and the outer peripheral surface of the rotating shaft 11. The seal material 1 71 is preferably a sliding seal made of, for example, a resin material.

[0070] The tubular portion 7 1 of the casing 6 4 partitions between the rotor 40 and the stator 50 arranged radially outside thereof and the electric component 62 arranged radially inside thereof. It is a partition part, and the rotor 40, the stator 50, and the electrical component 62 are arranged side by side inside and outside in the radial direction with the tubular part 71 sandwiched therebetween.

[0071] Further, the electric component 62 is an electric component that constitutes an inverter circuit, and a current is applied to each phase winding of the stator winding 5 1 in a predetermined order to cause the rotor 4 to rotate. 〇 2020/175 222 23 卩 (: 170? 2020 /006141

It has a powering function that rotates 0 and a power generation function that inputs the three-phase AC current flowing in the stator winding 5 1 as the rotary shaft 11 rotates and outputs it as generated power to the outside. The electric component 62 may have only one of the power running function and the power generating function. The power generation function is a regenerative function that outputs the regenerated electric power to the outside when the rotating electric machine 10 is used as a power source for a vehicle, for example.

[0072] As a specific configuration of the electric component 6 2, as shown in Fig. 4, a hollow cylindrical capacitor module 6 8 is provided around the rotating shaft 11, and the capacitor module 6 8 is provided. A plurality of semiconductor modules 66 are arranged side by side in the circumferential direction on the outer peripheral surface of the. The capacitor module 68 includes a plurality of smoothing capacitors 68 ₃ connected in parallel with each other. Specifically, the capacitor 683 is a laminated film capacitor in which a plurality of film capacitors are laminated, and the cross section has a trapezoidal shape. The capacitor module 68 is configured by arranging 12 capacitors 6 8 3 arranged side by side in a ring shape.

[0073] In the manufacturing process of the capacitor 683, for example, a long film having a predetermined width formed by laminating a plurality of films is used, and the film width direction is defined as the trapezoid height direction and A capacitor element is made by cutting a long film into an isosceles trapezoidal shape so that the bottom and the bottom are alternated. Then, by attaching electrodes etc. to the capacitor element, a capacitor 68 3 is manufactured.

The semiconductor module 66 has, for example, semiconductor switching elements such as 1//103 and I/09, and is formed in a substantially plate shape. In the present embodiment, the rotating electric machine 10 is provided with two sets of three-phase windings, and since an inverter circuit is provided for each of the three-phase windings, a total of 12 semiconductor modules 6 6 are looped. The semiconductor module group 6 68, which is formed by arranging in parallel with each other, is provided in the electrical component 6 2.

[0075] The semiconductor module 6 6 includes a cylindrical portion 7 1 of the casing 6 4 and a capacitor module. 〇 2020/175 222 24 卩 (: 170? 2020 /006141

It is placed so that it is sandwiched between the tool 68. The outer peripheral surface of the semiconductor module group 68 is in contact with the inner peripheral surface of the cylindrical portion 71, and the inner peripheral surface of the semiconductor module group 66 is in contact with the outer peripheral surface of the capacitor module 68. In this case, the heat generated in the semiconductor module 66 is transferred to the end plate 63 via the casing 64 and is released from the end plate 63.

[0076] The semiconductor module group 6 68 preferably has a spacer 6 9 between the semiconductor module 6 6 and the cylindrical portion 71 in the outer peripheral surface side, that is, in the radial direction. In this case, in the capacitor module 68, the cross-sectional shape of the cross section orthogonal to the axial direction is a regular 12-sided polygon, while the cross-sectional shape of the inner peripheral surface of the tubular portion 71 is circular, so the space is small. The inner surface of the support 69 is flat and the outer surface is curved. The spacer 69 may be integrally provided so as to be continuous in an annular shape on the radially outer side of the semiconductor module group 668. The spacer 69 is a good heat conductor, and is preferably a metal such as aluminum or a heat dissipation gel sheet. The cross-sectional shape of the inner peripheral surface of the tubular portion 71 may be the same 12-sided polygon as the capacitor module 68. In this case, both the inner peripheral surface and the outer peripheral surface of the spacer 69 are preferably flat surfaces.

Further, in the present embodiment, the cooling water passage 74 for circulating the cooling water is formed in the tubular portion 71 of the casing 64, and the heat generated in the semiconductor module 66 is the cooling water. It is also discharged to the cooling water flowing through the passage 74. That is, the casing 64 is equipped with a water cooling mechanism. As shown in FIGS. 3 and 4, the cooling water passage 74 is formed in an annular shape so as to surround the electric components 62 (semiconductor module 66 and capacitor module 68). The semiconductor module 66 is arranged along the inner peripheral surface of the cylindrical portion 71, and the cooling water passage 74 is provided at a position overlapping the semiconductor module 66 inside and outside in the radial direction.

[0078] Since the stator 50 is arranged on the outer side of the tubular portion 71 and the electric component 62 is arranged on the inner side, the tubular portion 71 is fixed from the outside thereof. As the heat of the determinant 50 is transferred, the heat of the electrical component 6 2 (for example, the heat of the semiconductor module 6 6) is transferred from the inside. In this case, stator 5 〇 2020/175 222 25 卩 (: 170? 2020 /006141

0 and the semiconductor module 66 can be cooled at the same time, and the heat of the heat generating member in the rotating electric machine 10 can be efficiently released.

[0079] Furthermore, at least a part of the semiconductor module 6 6 that constitutes part or all of the inverter circuit that operates the rotating electric machine by energizing the stator winding 5 1 is connected to the casing 6 4. It is arranged in a region surrounded by a stator core 52 arranged radially outside the tubular portion 71. Desirably, one semiconductor module 66 is wholly arranged in the region surrounded by the stator core 52. Furthermore, preferably, all the semiconductor modules 66 are entirely arranged in a region surrounded by the stator core 52.

Further, at least a part of the semiconductor module 66 is arranged in a region surrounded by the cooling water passages 74. Desirably, all the semiconductor modules 6 6 are entirely arranged in a region surrounded by the yoke 1 4 1.

[0081] Further, the electrical component 62 includes an insulating sheet 75 provided on one end surface of the capacitor module 68 and a wiring module 76 provided on the other end surface in the axial direction. .. In this case, the capacitor module 68 has two end faces that face each other in the axial direction, that is, the first end face and the second end face. The first end face of the capacitor module 68 close to the bearing unit 20 faces the end face 72 of the casing 64, and is superposed on the end face 72 with the insulating sheet 75 sandwiched. A wiring module 7 6 is attached to the second end surface of the capacitor module 68 close to the opening 65.

The wiring module 7 6 is composed of a circular plate-shaped main body 7 63 made of a synthetic resin material, and a plurality of bus bars 7 6 and 7 6 embedded in the main body 7 63.

The busbars 76 and 760 make electrical connection with the semiconductor module 66 and the capacitor module 68. Specifically, the semiconductor module 66 has a connecting pin 663 extending from the end face in the axial direction, and the connecting pin 663 is located outside the main body 763 in the radial direction. It is connected to the swamp. Further, the bus bar 760 extends to the opposite side of the capacitor module 68 from the outer side of the main body 763 in the radial direction, and the wiring member 7 〇 2020/175 222 26 卩 (: 170? 2020 /006141

It is designed to be connected to 9 (see Figure 2).

As described above, the insulating sheet 75 is provided on the first end surface of the capacitor module 68 facing in the axial direction, and the wiring module 76 is provided on the second end surface of the capacitor module 68. For example, as a heat dissipation path of the capacitor module 68, a path is formed from the first end surface and the second end surface of the capacitor module 68 to the end surface 72 and the tubular portion 71. That is, a path from the first end surface to the end surface 72 and a path from the second end surface to the tubular portion 71 are formed. As a result, in the capacitor module 68, heat can be dissipated from the end surface portion other than the outer peripheral surface where the semiconductor module 66 is provided. In other words, it is possible to dissipate heat not only in the radial direction but also in the axial direction.

[0084] Further, the condenser module 68 has a hollow cylindrical shape, and the rotary shaft 11 is arranged in the inner periphery of the condenser module 68 with a predetermined gap therebetween. Therefore, the heat of the condenser module 68 is It can also be released from the hollow part. In this case, the rotation of the rotating shaft 11 causes a flow of air to enhance the cooling effect.

A disc-shaped control board 67 is attached to the wiring module 76.

The control board 6 7 has a printed circuit board (∘) on which a predetermined wiring pattern is formed. On the board, various control circuits and a control device corresponding to a control unit composed of a microcomputer 7 are provided. 7 has been implemented. The control board 67 is fixed to the wiring module 76 by a fixing tool such as a screw. Control board 6 7 at its center, and a揷通hole 6 7 ₃ for揷通the rotary shaft 1 1.

The wiring module 76 has a first surface and a second surface that face each other in the axial direction, that is, face each other in the thickness direction. The first side faces the capacitor module 68. The wiring module 76 is provided with a control board 67 on its second surface. The bus bar 760 of the wiring module 76 extends from one side of both sides of the control board 67 to the other side. In such a configuration, the control board 67 may be provided with a notch for avoiding interference with the bus bar 760. For example, a part of the outer edge of the circular control board 67 is cut off. 〇 2020/175 222 27 卩(: 170? 2020/006141

I hope it is lacking.

[0087] As described above, the electrical components 6 are enclosed in the space surrounded by the casing 64.

2 is housed, and the housing 30, the rotor 40, and the stator 50 are provided in a layered form on the outer side of the housing 2, so that the electromagnetic noise generated in the inverter circuit can be suitably shielded. There is. That is, in the inverter circuit, switching control is performed in each semiconductor module 66 using \^/1\/1 control with a predetermined carrier frequency, and electromagnetic noise may occur due to the switching control. The electromagnetic noise can be suitably shielded by the housing 30 on the radial outside of the electric component 62, the rotor 40, the stator 50, and the like.

Further, by disposing at least a part of the semiconductor module 6 6 in the region surrounded by the stator core 52 arranged radially outside the tubular portion 71 of the casing 6 4, Compared with the configuration in which the semiconductor module 6 6 and the stator winding 5 1 are arranged without the stator core 5 2 interposed, even if magnetic flux is generated from the semiconductor module 6 6, the stator winding 5 1 Hard to affect. Further, even if the magnetic flux is generated from the stator winding 51, the semiconductor module 66 is not easily affected. It is more effective if the entire semiconductor module 6 6 is arranged in the area surrounded by the stator core 52 arranged radially outside the tubular portion 71 of the casing 6 4. .. Further, when at least a part of the semiconductor module 6 6 is surrounded by the cooling water passage 74, the heat generated from the stator winding 5 1 and the magnet unit 4 2 hardly reaches the semiconductor module 6 6. Can be obtained.

[0089] In the vicinity of the end plate 63 in the tubular portion 71, the outer stator 5 is

A through hole 7 8 is formed to allow a wiring member 7 9 (see FIG. 2) to electrically connect 0 and the inner electric component 62 to each other. As shown in Fig. 2, the wiring member 79 is connected to the end of the stator winding 51 and the bus bar 760 of the wiring module 7 6 by crimping, welding, or the like. The wiring member 79 is, for example, /<sub bar, and its joint surface is preferably flat and crushed. The through holes 78 may be provided at one power point or at a plurality of points. 〇 2020/175 222 28 卩 (: 170? 2020 /006141

Has through-holes 78 at two power stations. In the configuration in which the through holes 78 are provided at the two power points, it is possible to easily connect the winding terminals extending from the two sets of three-phase windings to the wiring members 79, respectively, and it is possible to perform multi-phase wiring. It is suitable.

[0090] As described above, the rotor 40 and the stator 50 are provided in this order from the outside in the radial direction in the housing 30 as shown in Fig. 4, and the inserter unit is provided inside the stator 50 in the radial direction. 60 is provided. Here, when the radius of the inner peripheral surface of the housing 30 is defined as, the rotor 40 and the stator 50 are arranged radially outward from the distance X 0 .705 from the center of rotation of the rotor 40. Are arranged. In this case, the region that is radially inward from the inner peripheral surface of the stator 50 on the radially inner side of the rotor 40 and the stator 50 (that is, the inner peripheral surface of the stator core 52) is the first region X. 1, the area between the inner peripheral surface of the stator 50 and the housing 30 in the radial direction is the second area X 2, and the cross-sectional area of the first area X 1 is the cross section of the second area X 2. The structure is larger than the surface area. In the radial direction, the volume of the first region X 1 is larger than the volume of the second region X 2 when viewed in the range where the magnet unit 42 of the rotor 40 and the stator winding 51 overlap. Has become.

[0091] When the rotor 40 and the stator 50 are magnetic circuit component assemblies, the first region X1 inside the housing 30 that is radially inward from the inner peripheral surface of the magnetic circuit component assembly. However, the volume is larger in the radial direction than the second region X 2 between the inner peripheral surface of the magnetic circuit component assembly and the housing 30.

Next, the configurations of the rotor 40 and the stator 50 will be described in more detail.

[0093] Generally, as a structure of a stator in a rotating electric machine, a plurality of slots are provided in a circumferential direction on a stator core made of laminated steel plates and having an annular shape, and a stator winding is wound in the slot. Things are known. Specifically, the stator core has a plurality of teeth extending from the yoke in the radial direction at predetermined intervals, and a slot is formed between the teeth that are adjacent to each other in the circumferential direction. Then, a plurality of layers of conductor wires are accommodated in the slot, for example, in the radial direction, and the conductor wires form the stator winding. Has been done.

[0094] However, in the above-described stator structure, when the stator winding is energized, as the magnetomotive force of the stator winding increases, magnetic saturation occurs in the teeth portion of the stator core, which causes As a result, the torque density of the rotating electric machine may be limited. In other words, in the stator core, it is considered that magnetic saturation occurs because the rotating magnetic flux generated by the energization of the stator windings concentrates on the teeth.

[0095] In general, as a configuration of a PM (Interior Permanent Magnet) rotor in a rotating electric machine, a permanent magnet is arranged on the d axis in the d _ q coordinate system, and a rotor core is arranged on the q axis. It has been known. In this case, the stator winding near the d-axis is excited, and the exciting magnetic flux flows from the stator to the q-axis of the rotor according to Fleming's law. It is considered that this causes a wide range of magnetic saturation in the q-axis core of the rotor.

[0096] FIG. 7 is a torque diagram showing the relationship between the ampere-turn [A T] indicating the magnetomotive force of the stator winding and the torque density [N m /L]. The broken line shows the characteristics of a general P M Mouth type rotating electrical machine. As shown in Fig. 7, in a general rotating electrical machine, increasing the magnetomotive force in the stator causes magnetic saturation at two force points, the tooth portion between the slots and the q-axis core portion. This limits the increase in torque. In this way, in this general rotating electrical machine, the ampere-turn design value is limited by A 1.

[0097] Therefore, in the present embodiment, in order to eliminate the limitation caused by magnetic saturation,

In 10, the following structure is added. In other words, as the first measure, a slotless structure is adopted in the stator 50 to eliminate magnetic saturation that occurs in the teeth of the stator core in the stator, and it is generated in the q-axis core part of the PM mouth. The SPM (Surface Permanent Magnet) rotor is used to eliminate magnetic saturation. According to the first device, the above two force points where magnetic saturation occurs can be eliminated, but the torque may be reduced in the low current region (see the chain line in Fig. 7). Therefore, as the second device,

In order to recover the torque decrease by increasing the magnetic flux of the SPM port overnight, the rotor 40 In this magnet unit 42, a magnetic anisotropy structure in which the magnet magnetic path is lengthened to enhance the magnetic force is used.

[0098] As a third device, the flattened wire structure in which the radial thickness of the stator 5 0 of the wire is reduced in the coil side portion 5 3 of the stator winding 5 1 is adopted to recover the torque reduction. I am trying. Here, it is conceivable that a larger eddy current will be generated in the stator winding 5 1 facing the magnet unit 4 2 due to the above-mentioned polar anisotropic structure with increased magnetic force. However, according to the third device, since the flat conductor structure is thin in the radial direction, it is possible to suppress the generation of radial eddy currents in the stator winding 51. Thus, according to each of the first to third configurations, as shown by the solid line in FIG. 7, while a magnet with a high magnetic force is adopted and a significant improvement in torque characteristics is expected, a magnet with a high magnetic force is used. Concerns about the generation of large eddy currents that can occur can be alleviated.

[0099] Furthermore, as a fourth measure, a magnet unit having a magnetic flux density distribution close to a sine wave is used by utilizing a polar anisotropic structure. According to this, the sine wave matching rate can be increased by the pulse control described later to increase the torque, and eddy current loss (copper loss due to eddy current: eddy cur rent loss) can be further suppressed.

[0100] The sine wave matching rate will be described below. The sine wave matching rate can be obtained by comparing the measured waveform of the surface magnetic flux density distribution measured by tracing the surface of the magnet with a magnetic flux probe and a sine wave with the same period and peak value. The sine wave matching rate is the ratio of the amplitude of the primary waveform, which is the fundamental wave of the rotating electrical machine, to the amplitude of the measured waveform, that is, the amplitude of the fundamental wave plus other harmonic components. Sine wave As the matching rate increases, the surface magnetic flux density distribution waveform approaches a sine wave shape. When a primary sinusoidal current is supplied from an inverter to a rotating electrical machine equipped with a magnet with an improved sinusoidal matching factor, the waveform of the surface magnetic flux density distribution of the magnet should be close to the sinusoidal shape. Combined with, a large torque can be generated. The surface magnetic flux density distribution may be estimated by a method other than actual measurement, for example, electromagnetic field analysis using Maxwell's equation. 〇 2020/175 222 31 卩(: 170? 2020/006141

[0101] Further, as a fifth device, the stator winding 51 has a strand conductor structure in which a plurality of strands are collected and bundled. According to this, since the wires are connected in parallel, a large current can flow and the generation of eddy currents generated by the wires spread in the circumferential direction of the stator 50 in the flat wire structure is prevented from occurring. Since the area is reduced, it can be more effectively suppressed than the reduction in the radial direction by the third measure. By constructing a plurality of strands twisted together, it is possible to cancel the eddy current with respect to the magnetic flux generated from the conductor by the right-handed screw law in the direction of current flow. ..

[0102] In this way, by further adding the fourth device and the fifth device, the eddy current loss due to the high magnetic force is suppressed while the magnet with high magnetic force, which is the second device, is adopted. However, torque can be increased.

[0103] The slotless structure of the stator 50, the flat conductor structure of the stator winding 51, and the polar anisotropic structure of the magnet unit 42 described above will be individually described below. Here, first, the slotless structure in the stator 50 and the flat conductor structure in the stator winding 5 1 will be described. 8 is a cross-sectional view of the rotor 40 and the stator 50, and FIG. 9 is an enlarged view of a part of the rotor 40 and the stator 50 shown in FIG. FIG. 10 is a sectional view showing a cross section of the stator 50 along the line X--X in FIG. 11, and FIG. 11 is a sectional view showing a longitudinal section of the stator 50. Further, FIG. 12 is a perspective view of the stator winding line 51. 8 and 9, the magnetizing directions of the magnets in the magnet unit 42 are indicated by arrows.

As shown in FIGS. 8 to 11, the stator core 52 has a cylindrical shape in which a plurality of electromagnetic steel plates are laminated in the axial direction and has a predetermined thickness in the radial direction. The stator winding 5 1 is mounted on the radially outer side of the rotor 40 side. In the stator core 52, the outer peripheral surface on the rotor 40 side is a conductor wire installation portion (conductor area). The outer peripheral surface of the stator core 52 has a curved surface with no irregularities, and a plurality of conductor wire groups 81 are arranged at predetermined intervals in the peripheral direction on the outer peripheral surface. The stator core 52 functions as a back yoke which is a part of a magnetic circuit for rotating the rotor 40. In this case, each two circumferentially adjacent In this structure, the teeth (that is, iron core) made of soft magnetic material are not provided between the conductor wire groups 8 1 (that is, the slotless structure). In this embodiment, the resin material of the sealing member 57 is inserted into the gap 56 of each of the conductor wire groups 81. That is, in the stator 50, the inter-conductor member provided between each conductor group 81 in the circumferential direction is configured as the sealing member 57 which is a non-magnetic material. Speaking of the state before the sealing member 5 7 is sealed, the conductor wire groups 8 1 are arranged at predetermined intervals in the circumferential direction on the outer side in the radial direction of the stator core 5 2 with a gap 5 6 which is an inter-conductor wire region. The slotted stator 50 is constructed. In other words, each conductor group 8 1 is composed of two conductors 8 2 as described later, and only non-magnetic material is provided between each two conductor groups 8 1 adjacent to each other in the circumferential direction of the stator 50. Are occupied by. The non-magnetic material includes a non-magnetic gas such as air and a non-magnetic liquid in addition to the sealing member 57. In the following, the sealing member 57 is also referred to as a conductor-to-conductor member.

[0105] The configuration in which teeth are provided between the conductor wire groups 81 arranged in the circumferential direction means that the teeth have a predetermined thickness in the radial direction and a predetermined width in the circumferential direction. Thus, it can be said that a part of the magnetic circuit, that is, the magnet magnetic path is formed between the conductor wire groups 81. In this respect, the structure in which the teeth are not provided between the conductor wire groups 81 is H-strain when the above magnetic circuit is not formed.

[0106] As shown in Fig. 10, the stator winding (that is, armature winding) 51 has a predetermined thickness T2 (hereinafter also referred to as the first dimension) and a width W2 (hereinafter, the second dimension). Also referred to as). The thickness T 2 is the shortest distance between the outer surface and the inner surface that face each other in the radial direction of the stator winding 51. The width W 2 functions as one of the polyphases of the solid winding line 51 (three phases in the embodiment: three phases of U phase, V phase and W phase or three phases of X phase, Y phase and Z phase). This is the circumferential length of a part of the stator winding 51 which is a part of the stator winding 51. Specifically, in FIG. 10, two conductor groups 8 1 adjacent to each other in the circumferential direction are one of the three phases, for example, as a U phase. 〇 2020/175 222 33 卩(: 170? 2020/006141

When functioning, it has a width 2 from end to end of the two conductor groups 81 in the circumferential direction. And the thickness 2 is smaller than the width \^ 2.

[0107] The thickness 2 is preferably smaller than the total width dimension of the two conductor wire groups 8 1 existing within the width 2. If the cross-sectional shape of the stator winding 5 1 (more specifically, the conductor 8 2) is a perfect circle, an ellipse, or a polygon, the conductor 8 2 along the radial direction of the stator 50 is Of the cross-sections, the maximum radial length of the stator 50 in the cross-section may be 12 and the maximum circumferential length of the stator 50 in the cross-section may be 11.

As shown in FIGS. 10 and 11, the stator winding 51 is sealed with a sealing member 57 made of a synthetic resin material as a sealing material (molding material). That is, the stator winding 51 and the stator core 52 are molded by the molding material. The resin can be regarded as a non-magnetic material or an equivalent material of the non-magnetic material as 3=0.

As seen in the cross section of FIG. 10, the sealing member 57 is provided between the conductor wire groups 81, that is, the gaps 56 are filled with the synthetic resin material. As a result, an insulating member is interposed between each conductor wire group 81. That is, the sealing member 57 functions as an insulating member in the gap 56. The sealing member 5 7 is located outside the stator core 52 in a range including all the conductor wire groups 81, that is, the radial thickness dimension is smaller than the radial thickness dimension of each conductor wire group 81. It is provided in a range that makes it larger.

[0110] Also, when viewed in the vertical cross section of Fig. 11, the sealing member 57 is provided in a range including the evening portion 8 4 of the stator winding 51. Inside the stator winding 51, in the radial direction, a sealing member 57 is provided in a range including at least a part of the axially opposed end faces of the stator core 52. In this case, the stator winding 51 is resin-sealed at the end of the phase winding of each phase, that is, almost the entire terminal except the connection terminal with the inverter circuit.

[01 1 1] In the configuration in which the sealing member 5 7 is provided in the range including the end face of the stator core 52, the laminated steel plate of the stator core 5 2 is pressed inward in the axial direction by the sealing member 5 7. 〇 2020/175 222 34 卩 (: 170? 2020 /006141

You can Thus, the sealing member 57 can be used to maintain the stacked state of the steel plates. In this embodiment, the inner peripheral surface of the stator core 52 is not resin-sealed, but instead of this, the entire stator core 52 including the inner peripheral surface of the stator core 52 is made of resin. The structure may be sealed.

[01 12] When the rotary electric machine 10 is used as a vehicle power source, the sealing member 57 is made of highly heat-resistant fluororesin, epoxy resin,

Resin, Minami Resin,! _○ It is preferable to be composed of a resin, a silicone resin, a resin, an I resin, or the like. Considering the coefficient of linear expansion from the viewpoint of suppressing cracking due to the difference in expansion, it is desirable that the material is the same as the outer coating of the conductor wire of the stator winding 51. That is, silicone resins having a coefficient of linear expansion that is generally at least twice that of other resins are desirably excluded. For electric products that do not have an engine that uses combustion, such as electric vehicles, 〇 resin, phenol resin, and ¾ resin that have a heat resistance of approximately 180° 〇 are also candidates. This does not apply to areas where the ambient temperature of the rotating electrical machine can be considered to be less than 100 ^° C.

[01 13] The torque of the rotating electric machine 10 is proportional to the magnitude of magnetic flux. Here, when the stator core has teeth, the maximum amount of magnetic flux at the stator is limited depending on the saturation magnetic flux density at the teeth, but the stator core does not have teeth. In this case, the maximum amount of magnetic flux at the stator is not limited. Therefore, the structure is advantageous for increasing the current flowing through the stator winding 51 and increasing the torque of the rotating electric machine 10.

[0114] In the present embodiment, the stator 50 has a structure without the teeth (slotless structure), so that the inductance of the stator 50 is reduced. Specifically, the inductance is, for example, 1% in the stator of a general rotating electrical machine in which conductors are housed in each slot partitioned by multiple teeth.

To 1 ^to 1 to Ru der longitudinal stator 5 0 In the inductance of this embodiment is reduced to 5-6 0 ^1-1 extent. In this embodiment, the mechanical time constant can be reduced by reducing the inductance of the stator 50 even in the rotating electric machine 10 having the outer rotor structure. In other words, while increasing the torque, the mechanical time constant Can be reduced. When the inertia is J, the inductance is L, the torque constant is K t, and the back electromotive force constant is K e, the mechanical time constant T m is calculated by the following equation.

T m = (J X L )/( K t X K e)

In this case, it can be confirmed that the mechanical time constant T m is reduced by reducing the inductance L.

[0115] Each conductor wire group 8 1 on the outer side in the radial direction of the stator core 5 2 is configured by arranging a plurality of conductor wires 8 2 having a flat rectangular cross-section in the radial direction of the stator core 5 2. ing. The conductors 82 are arranged in a direction of “diameter dimension<circumferential dimension” in the cross section. As a result, each conductor wire group 81 is thinned in the radial direction. In addition to reducing the wall thickness in the radial direction, the conductor area extends flat to the area where the teeth were previously, resulting in a flat conductor wire area structure. As a result, the increase in the amount of heat generated by the conductor, which is concerned that the cross-sectional area becomes smaller due to the thinner wall, is suppressed by flattening in the circumferential direction to increase the conductor cross-sectional area. Even with a configuration in which multiple conductors are arranged in the circumferential direction and are connected in parallel, the conductor cross-sectional area is reduced by the amount of the conductor coating, but the same effect can be obtained. In the following, each of the conductive wire groups 81 and each of the conductive wires 82 are also referred to as a conductive member.

[0116] Since there is no slot, in the stator winding 51 according to the present embodiment, the conductor area occupied by the stator winding 5 1 in one circumferential direction does not include the stator winding 5 1. It can be designed larger than the unoccupied area of the conductor. It should be noted that in the conventional vehicular rotating electrical machine, the conductor region/conductor non-occupied region in one circumferential direction of the stator winding is naturally 1 or less. On the other hand, in the present embodiment, each conductor wire group 81 is provided such that the conductor area is equal to the conductor non-occupancy area or the conductor area is larger than the conductor non-occupancy area. Here, as shown in Fig. 10, the conductor wire area in which the conductor wire 8 2 (that is, the straight line portion 8 3 described later) is arranged in the circumferential direction is WA, and the inter-conductor wire area between adjacent conductor wires 8 2 is WB means that the conductor area WA is larger than the inter-conductor area WB in the circumferential direction. 〇 2020/175 222 36 卩 (: 170? 2020 /006141

[01 17] As a configuration of the conductor wire group 81 in the stator winding 51, the radial thickness dimension of the conductor wire group 81 is smaller than the circumferential width dimension for one phase in one magnetic pole. It is a thing. That is, in a configuration in which the conductor group 8 1 is composed of two layers of conductors 8 2 in the radial direction and two conductor groups 8 1 are provided in the circumferential direction for each phase in one magnetic pole, the radial direction of each conductor 8 2 When the thickness of the wire is 0, and the width of each conductor 82 in the circumferential direction is, it is configured to be "0 2 <\^0 2". As another configuration, in a configuration in which the conductor group 8 1 is composed of two layers of conductors 8 2 and one conductor group 8 1 is provided in one magnetic pole in the circumferential direction for each phase, \N c _i The conductor wire portions (conductor wire group 8 1) arranged at a predetermined interval in the circumferential direction in the stator winding 5 1 have a thickness in the radial direction. The dimension is smaller than the circumferential width dimension of one phase in one magnetic pole.

[01 18] In other words, for each conductor 8 2 one by one, the radial thickness dimension is exactly the circumferential width dimension.

It should be smaller than. Furthermore, the radial thickness dimension of the conductor wire group 81 consisting of two layers of conductor wires 8 2 in the radial direction (2 x 0), that is, the radial thickness dimension of the conductor wire group 8 1 (2 x 0) is Circumferential width dimension

It should be smaller than.

[0119] The torque of the rotary electric machine 10 is substantially inversely proportional to the radial thickness of the stator core 52 of the conductor wire group 81. In this respect, the thickness of the conductor wire group 8 1 is thinned on the outer side in the radial direction of the stator core 52, which is advantageous in increasing the torque of the rotating electric machine 10. The reason is that the magnetic resistance can be lowered by reducing the distance from the magnet unit 42 of the rotor 40 to the stator core 52 (that is, the distance of the part without iron). According to this, the interlinkage magnetic flux of the stator core 52 by the permanent magnet can be increased, and the torque can be increased.

[0120] Further, by reducing the thickness of the conductor wire group 81, even if the magnetic flux leaks from the conductor wire group 81, the magnetic flux is easily collected by the stator core 52, and the magnetic flux is effectively used for improving the torque. It is possible to suppress leakage to the outside without being used. That is, magnetic flux 〇 2020/175 222 37 卩(: 170? 2020/006141

It is possible to suppress a decrease in magnetic force due to leakage, increase the interlinkage magnetic flux of the stator core 52 by the permanent magnet, and increase the torque.

Insulation is ensured between the conductors 8 2 that overlap each other in the radial direction, and between the conductors 8 2 and the stator core 52, which are composed of covered conductors that are covered by two swirls. The insulating coating 82 is composed of a wire 8 6 which will be described later if the wire 8 6 is a self-bonding coated wire, or an insulating member stacked separately from the coating of the wire 8 6. It should be noted that, except for the exposed portion for connection, each phase wire composed of the conducting wire 8 2 is kept insulating by the insulating coating 8 2. The exposed part is, for example, the input/output terminal part or the neutral point part in the case of star connection. In the conductor wire group 81, the resin wires and the self-bonding covered wire are used to mutually bond the conductor wires 82 adjacent to each other in the radial direction. This suppresses the dielectric breakdown, vibration, and sound caused by the rubbing between the conductors 82.

[0122] In this embodiment, the conductor 8 2 ₃ is configured as a plurality of wires 1 1 ^) 8 6 aggregates. Specifically, as shown in FIG. 1 3, the conductor 8 2 ₃ is formed in twisted shape by twisting a plurality of wires 8 6. Further, as shown in FIG. 14, the filaments 8 6 are configured as a composite body in which thin fibrous conductive materials 87 are bundled. For example, the wire 86 is a composite of 〇\1 (fiber-bonded nanotube) fiber,

〇 As 1\1 fibers, fibers containing fine boron-containing fibers in which at least part of carbon is replaced with boron are used. As the carbon-based fine fiber, vapor grown carbon fiber (○○) or the like can be used in addition to the 0\1 \fiber, but it is preferable to use the \0 fiber. The surface of the wire 86 is covered with a polymer insulating layer such as enamel. Further, it is preferable that the surface of the wire 86 is covered with a so-called enamel coating, which is composed of a polyimide coating or an amidimide coating.

[0123] Conductor 82 forms the n-phase winding in stator winding 5 1. And conductor

8 2 (ie, each strand 8 6 of conductor 8 2 is adjacent to and in contact with each other. Conductor 8 2 is a winding conductor formed by twisting multiple strands 8 6 〇 2020/175 222 38 卩 (: 170? 2020/006141

It has one or more parts in the phase, and the resistance value between the twisted wires 8 6 is larger than the resistance value of the wire 8 6 itself. In other words, each two adjacent strands 8 6 have a first electrical resistivity in their adjacent direction, and each strand 8 6 has a second electrical resistivity in its longitudinal direction, The 1st electrical resistivity is larger than the 2nd electrical resistivity. Note that the conductor wire 8 2 may be formed of a plurality of wire wires 8 6 and may be a wire wire assembly that covers the plurality of wire wires 8 6 with an insulating member having an extremely high first electrical resistivity. .. The conductor 8 2 ₃ conductors 8 2 is constituted by a plurality of wires 8 6 twisted.

[0124] Since the above conductors 8 2 ₃ are composed of a plurality of strands 8 6 twisted together, the generation of eddy currents in the respective strands 8 6 is suppressed, and the eddy currents in the conductors 8 2 3 are suppressed. It can be reduced. Further, since each of the strands 86 is twisted, a part where the magnetic field application directions are opposite to each other is generated in one strand 86, and the counter electromotive voltage is offset. Therefore, it is possible to reduce the eddy current. In particular, by constructing the wires 8 6 from the fibrous conductive material 87, it is possible to make the wires thinner and to significantly increase the number of twists, and it is possible to more appropriately reduce the eddy current. it can.

[0125] Note that the method of insulating the wires 8 6 from each other here is not limited to the polymer insulating film described above, and a method of making it difficult for a current to flow between the twisted wires 8 6 by utilizing contact resistance can be used. It may be. That is, if the resistance value between the twisted wires 8 6 is larger than the resistance value of the wires 8 6 themselves, the above-mentioned effect will be caused by the potential difference caused by the difference in resistance value. Can be obtained. For example, by using the manufacturing equipment that creates the wires 86 and the manufacturing equipment that creates the stators 50 (armatures) of the rotating electric machine 10 as separate non-continuous equipment, the movement time, work interval, etc. This is preferable since the wire 86 is oxidized and the contact resistance can be increased.

[0126] As described above, the conductor wire 82 has a flat rectangular cross section, and is arranged in a line in the radial direction. For example, a self-bonding covered wire including a fusion layer and an insulating layer. The multiple wires 86 coated with are assembled in a burning state, and the fusion layers are 〇 2020/175 222 39 卩 (: 170? 2020 /006141

The shape is maintained by fusing. In addition, it is also possible to form a wire having no fusion layer or a self-fusion-bonded wire in a twisted state and fixing it to a desired shape with a synthetic resin or the like. If the thickness of the insulating coating 82 on the conductor 8 2 is set to, for example, 80 to 100, and the thickness is thicker than the film thickness (5 to 40) of commonly used conductors, it is fixed to the conductor 8 2. Even if no insulating paper or the like is interposed between the child core 52 and the child core 52, the insulation between them can be ensured.

[0127] Further, it is preferable that the insulating coating 82 has a higher insulating performance than the insulating layer of the wire 86, and is configured to be able to insulate between the phases. For example, when the thickness of the polymer insulating layer of the wire 8 6 is set to about 5, for example, the thickness of the insulating coating 8 2 of the conductor 8 2 is

It is desirable to be able to suitably perform the insulation between the phases.

[0128] Further, the conducting wire 82 may have a configuration in which a plurality of element wires 86 are bundled without being twisted. In other words, the conducting wire 8 2 has a configuration in which a plurality of strands 8 6 are twisted in its entire length, a configuration in which a plurality of strands 8 6 are twisted in a part of its entire length, and a plurality of strands 8 6 in its entire length. It may be either of the configurations in which the bunches are bundled without being twisted. In summary, each conductor wire 8 2 constituting the conductor wire portion is composed of a plurality of wires 8 6 bundled together, and the resistance value between the bundled wires is larger than the resistance value of the wire wire 8 6 itself. It is an aggregate.

[0129] The conductors 8 2 are formed by bending so as to be arranged in a predetermined arrangement pattern in the circumferential direction of the stator winding 5 1, and as a result, the stator windings 5 1 are separated from each other. The winding is formed. As shown in Fig. 12, in the stator winding 51, the coil side portion 5 3 is formed by the straight portion 8 3 of each conductor 8 2 that extends linearly in the axial direction, and the coil side portion 5 3 is formed in the axial direction. Coil ends 5 4 and 5 5 are formed by the evening portion 8 4 projecting outward from both sides. Each of the conductors 8 2 is configured as a series of corrugated conductors by alternately repeating straight portions 8 3 and turn portions 8 4. The straight line portion 8 3 is arranged at a position that faces the magnet unit 4 2 in the radial direction, and is a straight line of the same phase that is arranged at a predetermined interval at a position on the outer side in the axial direction of the magnet unit 4 2. Part 8 3 to each other 〇 2020/175 222 40 卩 (: 170? 2020 /006141

But are connected to each other by an evening section 84. The straight part 83 corresponds to the "magnet facing part".

[0130] In the present embodiment, the stator winding 51 is formed by distributed winding in an annular shape. In this case, in the coil side section 53, straight sections 8 3 are arranged in the circumferential direction at an interval corresponding to one pole pair of the magnet unit 4 2 for each phase, and in the coil ends 5 4, 5 5 each phase is arranged for each phase. The respective straight line portions 8 3 are connected to each other by a turn portion 8 4 formed in a substantially V shape. The respective straight line portions 83 corresponding to one pole pair have current directions opposite to each other. In addition, one coil end 5 4 and the other coil end 55 have different combinations of the pair of straight line portions 8 3 connected by the evening portion 8 4, and the coil ends 5 4 and 5 5 By repeating the connection at 5 in the circumferential direction, the stator winding 51 is formed in a substantially cylindrical shape.

[0131] More specifically, the stator winding 5 1 constitutes a winding for each phase using two pairs of conductor wires 8 2 for each phase, and one of the stator windings 5 1 3-phase normal line (II phase,

The V phase and phase) and the other three-phase winding (X phase, negative phase, phase) are provided in two layers inside and outside in the radial direction. In this case, if the number of phases of the stator winding 5 1 is 3 (6 in the practical example) and the number per phase of the conductor 8 2 is 2,

Individual conductors 8 2 will be formed. In this embodiment, since the number of phases is 6, the number is 4, and the rotating electric machine has 8 pairs (16 poles), the conductor wire 8 2 of 6 X 4 X 8 = 1 9 2 is the stator core. It is arranged in the circumferential direction of 52.

[0132] In the stator winding 5 1 shown in Fig. 12, in the coil side portion 5 3, the linear portions 8 3 are arranged so as to overlap each other in two layers that are adjacent in the radial direction, and the coil ends 5 4 and 5 5 In the above, the evening part 8 4 extends in the circumferential direction from the straight line parts 8 3 overlapping in the radial direction in the directions opposite to each other in the circumferential direction. In other words, in the conductor wires 8 2 that are adjacent to each other in the radial direction, the directions of the turn portions 8 4 are opposite to each other, except for the end portion of the stator winding 5 1.

[0133] Here, the winding structure of the conductor wire 8 2 in the stator winding 5 1 will be specifically described. 〇 2020/175 222 41 卩(: 170? 2020/006141

.. In the present embodiment, a plurality of conducting wires 82 formed by wave winding are provided in a plurality of layers (for example, two layers) that are radially adjacent to each other. Fig. 15 ( ₃ ) and Fig. 15 (deposit) show the form of each conductor 82 in the nth layer. Fig. 15 (a) shows a side view of the stator winding 51. The shape of the conducting wire 82 is shown in Fig. 15 (b), which is the shape of the conducting wire 82 seen from one side in the axial direction of the stator winding 51. In Fig. 15 (3) and Fig. 15 (匕), the positions where the conductor wire group 81 is arranged are shown as ports 1, 02, 03, respectively. Further, for convenience of explanation, only three conductors 82 are shown, which are referred to as a first conductor 82_8, a second conductor 82_mi, and a third conductor 82_○.

[0134] In each of the conductors 82_8 to 82_○, the straight line portions 83 are arranged at the position of the nth layer, that is, at the same position in the radial direction, and are separated by 6 positions (3X01 pairs) in the circumferential direction. The straight portions 83 are connected to each other by the evening portion 84. In other words, each of the conductors 82_8 to 82_〇 has seven straight lines that are arranged adjacent to each other in the circumferential direction of the stator winding 5 1 on the same circle centered on the axis of the rotor 40. The two ends of section 83 are connected to each other by one turn section 84. For example, in the first conducting wire 828, a pair of straight line portions 83 are arranged at 01 and 07, respectively, and the pair of straight line portions 83 are connected by the inverted V-shaped turn portion 84. In addition, the other conductors 82_M and 82_○ are arranged in the same n-th layer by shifting the position in the circumferential direction one by one. In this case, since the conductors 82_8 to 82_◯ are all arranged in the same layer, the turn parts 84 may interfere with each other. Therefore, in the present embodiment, an interference avoiding portion, which is offset in the radial direction, is formed in the evening portion 84 of each of the conducting wires 828 to 82_O.

[0135] Specifically, the evening part 84 of each conducting wire 82_8 to 82_○ is the same circle (

(One circle) One inclined portion 843 that is a portion that extends in the circumferential direction on the upper side and one side that shifts from the inclined portion 843 radially inward of the same circle (upper side in Fig. 15 (b)) and separates. Has a top 84 that reaches the circle (second circle), a sloped portion 84 〇 that extends circumferentially on the second circle, and a return portion 84 that returns from the first circle to the second circle. 〇 2020/175 222 42 卩 (: 170? 2020/006141

It The top portion 84, the inclined portion 84 and the return portion 8 4 correspond to the interference avoidance portion. The inclined portion 840 may be configured to shift radially outward with respect to the inclined portion 843.

[0136] In other words, the turn portions 8 4 of the conductors 8 2 _ 8 to 8 2 _ 〇 are located on both sides of the top portion 8 4 which is the central position in the circumferential direction, and the inclined portion 8 4 ₃ on one side and the other portion 8 4 ₃ on the other side. Side slopes 840 and each of these slopes 840.

8 40 radial position

(The position in the front-back direction of the paper in Fig. 15 (3) and the position in the vertical direction in Fig. 15 (13)) are different from each other. For example, the evening section 8 4 of the first conducting wire 8 2 _ 8 extends along the circumferential direction starting from the 0 1 position of the layer, and the radial direction (e.g., diameter After turning inward (in the direction), it bends in the circumferential direction again to extend along the circumferential direction again, and then in the returning portion 8 4 again in the radial direction (for example, radial outward), the end point position is reached. It is configured so that it reaches the 0 7 position on the 1st layer.

[0137] According to the above configuration, in the conductors 8 2 _8 to 8 2 _〇, each of the inclined portions 8 4 3 is arranged such that the first conductor 8 2 _ 8 ® the second conductor 8 2 _ The three conductors 8 20 are arranged vertically in this order, and the tops and bottoms of the conductors 8 2 _ 8 to 8 2 _ 〇 are exchanged at the top and bottom, and the other inclined portions 8 40 are arranged from the top to the third conductor 8 8 2 _ 〇 ® 2nd conducting wire 8 2 It is configured to be arranged vertically in the order of 1st conducting wire 8 2 8. Therefore, the conductors 8 2 _ 8 to 8 2 _ 〇 can be arranged in the circumferential direction without interfering with each other.

[0138] Here, in a configuration in which a plurality of conducting wires 8 2 are radially overlapped to form a conducting wire group 8 1, a turn portion connected to the radially inner straight portion 8 3 of each of the plurality of straight portions 8 3 8 4 and the turn portion 8 4 connected to the linear portion 8 3 on the outer side in the radial direction are preferably arranged at a distance from each other in the radial direction. In addition, when the conductors 8 2 of multiple layers are bent to the same side in the radial direction at the end of the evening portion 8 4, that is, near the boundary with the straight portion 8 3, the conductors 8 2 of the adjacent layers are It is advisable not to damage the insulation due to interference between them.

[0139] For example, in Fig. 15 (3) and 07 to 09 in Fig. 15 (slung), 〇 2020/175 222 43 卩 (: 170? 2020 /006141

The conductors 82 are respectively bent in the radial direction at the return part 84 of the turn part 84. In this case, as shown in FIG. 16, the radius of curvature of the bent portion may be different between the conductor wire 82 of the first layer and the conductor wire 82 of the +1st layer. Specifically, the radial inside (

The radius of curvature 1 of the conducting wire 82 of the (th layer) is made smaller than the radius of curvature 2 of the conducting wire 82 of the radially outer side (n+1st layer).

[0140] Further, it is preferable that the conductor wire 82 of the first layer and the conductor wire 82 of the +1st layer have different radial shift amounts. Specifically, the shift amount 31 of the conductor wire 82 on the radially inner side (11th layer) is made larger than the shift amount 32 of the conductor wire 82 on the radially outer side (n+1st layer).

[0141] With the above configuration, mutual interference between the conductors 82 can be preferably avoided even when the conductors 82 overlapping in the radial direction are bent in the same direction. As a result, good insulation can be obtained.

[0142] Next, the structure of the magnet unit 42 in the rotor 40 will be described. In the present embodiment, the magnet unit 42 is made of a permanent magnet, and the residual magnetic flux density is “=1.0 [c], intrinsic coercive force 1 ^to 10”=400 [1<8/01] or more. I am assuming. In short, the permanent magnet used in the present embodiment is a sintered magnet obtained by sintering a granular magnetic material by molding and solidifying, and the "1 ^to 1 characteristic coercive force 1 ^to 10" is 400 [1 <8/〇1] or more and the residual magnetic flux density is “1.0 [Cho] or more. When 5000 to 10000 [Haccho] is applied by interphase excitation, one pole pair, that is, 1 \1 The magnetic length of the 3 poles, or in other words, if you use a permanent magnet with a length of 25 [] that passes through the magnet in the path of the magnetic flux between the 1\1 pole and the 3 pole,

"

= 10000 [eight], which indicates that demagnetization is not performed.

[0143] In other words, the magnet unit 42 has a saturation magnetic flux density "3 of 1.2 [c] or more, a crystal grain size of 10 [] or less, and an orientation ratio of <<.

0 [D] It is above.

[0144] The following supplements the magnet unit 42. Magnet unit 42 (magnet) is 2. 15 [Ding]

2 [Ding] is a feature. In other words, as a magnet used for the magnet unit 42, do 611 _||\1, 2 do 6148, 〇! 〇 2020/175 222 44 卩 (: 170? 2020 /006141

Examples include 2d 617 and 61^ magnets having 1_10 type crystals. In addition, 31^0-5, which is usually called Samakoba,

Which configuration cannot be used. Note that compounds of the same type, such as 2d6148 and 2d6148, typically use the heavy rare earth dsprosium to increase the neodymium content.

3 Even if the magnet with the high coercive force of 〇 is lost while slightly losing its characteristics, 2 .15

2 [Cho] may be met, and this case can also be adopted. In such a case, for example, it will be called ([1 10 乂] 2d 6148). Furthermore, it is possible to achieve two or more types of magnets having different compositions, for example, a magnet made of two or more types of materials such as Do 61\1丨plus 31112 and Do 617, and for example, `` 3 = 1. Achieved with a mixed magnet with an increased coercive force, such as ₆ magnets, and 2 magnets 6148, which has a margin of 3, and a small amount of, for example, 0 2 mm ₆ 148, with 3 magnetism of <1 magnet. It is possible.

[0145] In addition, a rotating electric machine that is operated at a temperature outside the range of human activity, for example, 60 ^° 〇 or more that exceeds the temperature of the desert, for example, in summer, the temperature inside the vehicle becomes close to 80 ^° 〇. Especially for motor applications for vehicles, the temperature dependence coefficient is small.

, 31112 and 617 are desirable. This is because the temperature range close to 40 ° 〇 in Northern Europe, which is within the range of human activity, exceeds 60 ° 〇, which exceeds the desert temperature mentioned above, or the heat-resistant temperature of the coil enamel coating 1800 to 240 ° This is because in the motor operation up to approximately 0, the motor characteristics differ greatly depending on the temperature dependence coefficient, which makes it difficult to perform optimal control with the same motor driver. By using Do 61\1 _1, or 31112 Do 617 with 10-type crystal, etc., it has a temperature dependence coefficient that is less than half that of 2Do 6148, which means that the load of motor dry/ Can be suitably reduced.

[0146] In addition, the magnet unit 42 is characterized in that the particle size of the fine powder state before orientation is 10 or less and the single domain particle size or more by using the above-mentioned magnet mixture. In magnets, coercive force is increased by reducing the size of powder particles to the order of hundreds of doors, so in recent years powders that have been made as small as possible have been used. However, if too finely, the magnet of the snake due to oxidation! ^~ 1 Since the product falls, the single domain particle size or more is preferable. It is known that coercive force increases with size reduction if the particle size is up to a single domain particle size. The particle size described here is the particle size in the fine powder state during the orientation process, which is the manufacturing process of the magnet.

[0147] Further, each of the first magnet 91 and the second magnet 92 of the magnet unit 42 is a sintered magnet formed by so-called sintering in which magnetic powder is hardened at high temperature. In this sintering, the saturation magnetization J s of the magnet unit 42 is 1.2 T or more, the crystal grain size of the first magnet 91 and the second magnet 92 is 10 Mm or less, and the orientation ratio is a In this case, J s Xa is performed so that the condition of 1. OT (Tesla) or more is satisfied. Further, each of the first magnet 91 and the second magnet 92 is sintered so as to satisfy the following conditions. Since the orientation is performed in the manufacturing process, the orientation ratio is different from the definition of the magnetic force direction in the magnetizing process of the isotropic magnet. When the saturation magnetization J s of the magnet unit 42 of the present embodiment is 1.2 T or more and the orientation ratio a of the first magnet 91 and the second magnet 92 is J r ³ J s Xa ³ 1.0 [T]. A high orientation rate is set so that Note that the orientation ratio a referred to here is, for example, in each of the first magnet 91 or the second magnet 92, for example, there are six easy axes of magnetization, and five of them are oriented in the same direction A 10, If the other one faces the direction B 1 0 which is tilted 90 degrees to the direction A 10 then a = 5/6 and the other one is the direction B tilted 45 degrees to the direction A 10 In the case of facing 1 0, the component facing the other direction A 1 0 is cos 45° = 0.707, so a= (5 + 0.707) /6. In this embodiment, the first magnet 91 and the second magnet 92 are formed by sintering, but if the above conditions are satisfied, the first magnet 91 and the second magnet 92 can be formed by another method. You may. For example, a method of forming an MQ3 magnet or the like can be adopted.

[0148] In this embodiment, since a permanent magnet in which the easy axis of magnetization is controlled by orientation is used, a linearly oriented magnet that gives a magnetic circuit length inside the magnet of 1.0 [T] or more as compared with the conventional one It can be made longer than the magnetic circuit length of. sand 〇 2020/175 222 46 卩 (: 170? 2020 /006141

In other words, the magnetic circuit length per pole pair can be achieved with a small amount of magnets, and the reversible demagnetization range can be increased even when exposed to harsh high heat conditions, compared to the conventional design using linearly oriented magnets. Can be kept. Further, the present inventor has found a configuration that can obtain characteristics close to those of a polar anisotropic magnet even when using a conventional magnet.

[0149] The easy axis of magnetization means a crystal orientation that is easily magnetized in the magnet. The direction of the easy axis of magnetization in the magnet is the direction in which the orientation rate, which indicates the degree of alignment of the easy axis of magnetization, is 50% or more, or the direction in which the orientation of the magnet is averaged.

[0150] As shown in Figs. 8 and 9, the magnet unit 42 has an annular shape and is provided inside the magnet holder 41 (specifically, inside the cylindrical portion 43 in the radial direction). .. The magnet unit 42 has a first magnet 91 and a second magnet 92 which are polar anisotropic magnets and have polarities different from each other. The first magnet 91 and the second magnet 92 are arranged alternately in the circumferential direction. The first magnet 91 is a magnet that forms !\! poles in the portion close to the stator winding 5 1, and the second magnet 9 2 forms 3 poles in the portion close to the stator winding 5 1. It is a magnet. The first magnet 91 and the second magnet 92 are permanent magnets made of a rare earth magnet such as a neodymium magnet.

[0151] As shown in Fig. 9, in each magnet 9 1 and 9 2, the axis (“60 1; −3_13”) and the 1\1 pole, which are the magnetic pole centers in the known ¢1-coordinate system, It is a magnetic pole boundary of three poles (in other words, the magnetic flux density is 〇Tesla), and the magnetization direction extends in an arc shape between the axis (9113 〇1“31; 11“6-3_13). In each of the magnets 9 1 and 9 2, the magnetization direction on the axis side is the radial direction of the annular magnet unit 42, and on the 9 axis side, the magnetization direction of the annular magnet unit 4 2 is the circumferential direction. Each of the magnets 9 1 and 9 2 has a first portion 2500 and a first portion in the circumferential direction of the magnet unit 4 2 as shown in FIG. It has two second parts 2 60 located on either side of the part 2 50. In other words, the first part 2 50 is closer to the axis than the second part 2 6 0 and the second part 2 6 0 is , Closer to the 9th axis than the first part 250. And the direction of the easy axis 300 of the first part 250 is the second part 2 6 〇 2020/175 222 47 卩(: 170? 2020/006141

The magnet unit 42 is constructed so that it is more parallel to the axis than the direction of the easy magnetization axis 310 of 0. In other words, the angle 0 1 1 formed by the easy magnetization axis 3 0 0 of the first portion 2 50 with the axis is smaller than the angle 0 1 2 formed by the easy magnetization axis 3 1 0 of the second portion 2 60 with the axis. The magnet unit 42 is configured so that

[0152] More specifically, the angle 0 1 1 is such that when the direction from the stator 5 0 (armature) to the magnet unit 4 2 is positive in the axis, the axis and the easy axis of magnetization 300 are It is an angle.

This is the angle formed by the 9 axis and the easy axis of magnetization 3 10 when the direction from the stator 50 (armature) to the magnet unit 4 2 in the 9 axis is positive. Both the angle 0 1 1 and the angle 0 1 2 are 90° or less in this embodiment. Here, each of the easy magnetization axes 300 and 310 is defined as follows. In each part of the magnets 9 1 and 9 2, if one easy axis is oriented in the direction 8 11 and the other easy axis is oriented in the direction 11 1, the direction 1 1 and the direction 9 1 The absolute value of the cosine of the angle 0 formed by 1 1 (| 〇〇 3 0 |) is defined as the easy axis of magnetization 300 or the easy axis of magnetization 3 10.

[0153] That is, each of the magnets 9 1 and 9 2 is connected to the shaft side (portion near the axis)

The direction of the easy magnetization axis differs from that on the 9-axis side (the portion near the 9-axis). The easy-axis direction on the axis side is close to the direction parallel to the ¢1 axis, and the easy-axis direction is on the axis side. The direction of the axis is close to the direction orthogonal to the 9th axis. An arc-shaped magnet magnetic path is formed according to the direction of the easy axis of magnetization. In each of the magnets 91 and 92, the easy axis may be oriented parallel to the axis on the axis side, and the easy axis may be oriented orthogonal to the axis on the 9 axis side.

[0154] Further, in the magnets 9 1 and 9 2, the outer surface of the stator on the side of the stator 50 (the lower side of Fig. 9) on the peripheral surface of each of the magnets 9 1 and 9 2 and the 9 axes in the circumferential direction. Side end surface is the magnetic flux acting surface that is the inflow and outflow surface of the magnetic flux, and the magnet magnetic path is formed so as to connect these magnetic flux acting surfaces (the outer surface of the stator side and the end surface of the shaft side). ..

[0155] In the magnet unit 42, since the magnetic flux flows in an arc shape between the adjacent 1\1 and 3 poles by the magnets 9 1 and 9 2, the magnet magnetic path is smaller than that of a radial anisotropic magnet, for example. 〇 2020/175 222 48 卩 (: 170? 2020 /006141

It's getting longer. Therefore, the magnetic flux density distribution is close to a sine wave, as shown in Fig. 17. As a result, unlike the magnetic flux density distribution of the radial anisotropic magnet shown in FIG. 18 as a comparative example, the magnetic flux can be concentrated on the center side of the magnetic pole, and the torque of the rotating electric machine 10 can be increased. Further, it can be confirmed that the magnet unit 42 of the present embodiment has a difference in the magnetic flux density distribution as compared with the conventional Halbach array magnet. In FIGS. 17 and 18, the horizontal axis represents the electrical angle and the vertical axis represents the magnetic flux density. Further, in FIGS. 17 and 18, 90° on the horizontal axis indicates the axis (that is, the magnetic pole center), and 0° and 180° on the horizontal axis indicate the 9 axis.

[0156] That is, according to each of the magnets 9 1 and 9 2 having the above configuration, the magnetic flux of the magnet on the axis is strengthened, and the change of the magnetic flux near the axis is suppressed. As a result, it is possible to preferably realize the magnets 9 1 and 9 2 in which the surface magnetic flux changes gently from axis to axis at each magnetic pole.

[0157] The sine wave matching rate of the magnetic flux density distribution may be, for example, a value of 40% or more. By doing so, it is possible to surely improve the magnetic flux amount in the central portion of the waveform, as compared with the case of using a radial oriented magnet or a parallel oriented magnet having a sine wave matching rate of about 30%. Also, if the sine wave matching rate is set to 60% or more, the amount of magnetic flux in the central portion of the waveform can be reliably improved compared to the magnetic flux concentration array such as the Halbach array.

[0158] In the radial anisotropic magnet shown in Fig. 18, the magnetic flux density changes sharply near the axis. The steeper the change in magnetic flux density, the greater the eddy current generated in the stator winding 51. Also, the change in magnetic flux on the stator winding 51 side becomes steep. On the other hand, in the present embodiment, the magnetic flux density distribution has a magnetic flux waveform close to a sine wave. Therefore, the change in the magnetic flux density near the axis is smaller than the change in the magnetic flux density of the radial anisotropic magnet. This can suppress the generation of eddy currents.

[0159] In the magnet unit 42, magnetic flux is generated near the axis of each magnet 91, 92 (that is, the magnetic pole center) in the direction orthogonal to the magnetic flux acting surface 280 on the stator 50 side. 〇 2020/175 222 49 卩 (: 170? 2020 /006141

The magnetic flux has an arc shape that is farther from the axis as it is farther from the magnetic flux acting surface 280 on the side of the stator 50. Also, the more perpendicular to the magnetic flux acting surface, the stronger the magnetic flux. In this respect, in the rotary electric machine 10 of the present embodiment, since the conductor wire groups 8 1 are thinned in the radial direction as described above, the radial center position of the conductor wire groups 8 1 is the magnetic flux acting surface of the magnet unit 4 2. Therefore, the stator 50 can receive a strong magnetic flux from the rotor 40.

[0160] In addition, the stator 50 has a cylindrical stator core 5 2 radially inward of the stator winding 51, that is, on the opposite side of the rotor 40 with the stator winding 5 1 interposed therebetween. It is provided. Therefore, the magnetic flux extending from the magnetic flux acting surface of each magnet 91, 92 is attracted to the stator core 52, and circulates while using the stator core 52 as a part of the magnetic path. In this case, the direction and path of the magnetic flux of the magnet can be optimized.

[0161] In the following, as a method of manufacturing the rotating electric machine 10, an assembly procedure for the bearing unit 20, the housing 30, the rotor 40, the stator 50 and the inverter unit 60 shown in Fig. 5 is performed. Will be described. The inverter unit 60 has a unit base 61 and an electric component 62 as shown in Fig. 6, and the unit base 61 and the electric component 62 are assembled together. Each work process including steps will be described. In the following description, the assembly consisting of the stator 50 and the inserter unit 60 is the first unit, and the assembly consisting of the bearing unit 20 and the housing 30 and the rotor 40 is the second unit. There is.

[0162] The manufacturing process is

-The first step of mounting the electrical component 62 on the inner side of the unit base 61,

-The second step of manufacturing the first unit by mounting the unit base 61 on the inner side of the stator 50 in the radial direction,

The third step of manufacturing the second unit by inserting the fixed portion 44 of the rotor 40 into the bearing unit 20 assembled in the housing 30 and

-The fourth step of mounting the first unit inside the second unit in the radial direction,

-Fifth step of fastening and fixing the housing 30 and the unit base 61, 〇 2020/175 222 50 卩(: 170? 2020/006141

have. The order of performing these steps is 1st step 2nd step 3rd step 4th step 5th step.

[0163] According to the above manufacturing method, the bearing unit 20, the housing 30 and the rotor 4

After assembling 0, stator 50 and inverter unit 60 as multiple assemblies (sub-assemblies) and then assembling these assemblies, easy handling and inspection completion for each unit are achieved. It is possible to construct a rational assembly line. Therefore, it is possible to easily cope with multi-product production.

[0164] In the first step, the radial inside of the unit base 61 and electrical components are

A good thermal conductor with good thermal conductivity is attached to at least one of the radial outer sides of 62 by applying a cloth or adhesive, and in that state, the electrical component 6 is attached to the unit base 61. You should wear 2. This makes it possible to effectively transfer the heat generated by the semiconductor module 6 6 to the unit base 6 1.

[0165] In the third step, the rotor 40 may be inserted while maintaining the housing 30 and the rotor 40 coaxial with each other. Specifically, for example, with the inner peripheral surface of the housing 30 as a reference, the outer peripheral surface of the rotor 40 (outer peripheral surface of the magnet holder 41) or the inner peripheral surface of the rotor 40 (inner peripheral surface of the magnet unit 42). Use a jig that determines the position of the surface) and slide either the housing 30 or the rotor 40 along the jig to assemble the housing 30 and the rotor 40. This makes it possible to assemble heavy parts without imposing an unbalanced load on the bearing unit 20 and improve the reliability of the bearing unit 20.

[0166] In the fourth step, it is advisable to assemble the first unit and the second unit while maintaining the same axis. Specifically, for example, a jig that determines the position of the inner peripheral surface of the unit base 61 with reference to the inner peripheral surface of the fixed portion 44 of the rotor 40 is used, and the first Assemble each of these units while sliding either the unit or the second unit. This prevents mutual interference between the rotor 40 and the stator 50 in the minimal gap. 〇 2020/175 222 51 卩 (: 170? 2020 /006141

It is possible to assemble defective parts due to assembly, such as damage to the stator windings 51 and lack of permanent magnets.

[0167] It is also possible to set the order of the above respective steps to the second step, the third step, the fourth step, the fifth step, the first step. In this case, the delicate electrical component 62 is assembled last, and the stress on the electrical component 62 during the assembly process can be minimized.

[0168] Next, the configuration of the control system for controlling the rotary electric machine 10 will be described. Figure

Reference numeral 19 is an electric circuit diagram of a control system of the rotary electric machine 10, and FIG. 20 is a functional block diagram showing control processing by the control device 110.

[0169] In Fig. 19, two sets of 3-phase windings 5 1 3 and 5 1 are shown as the stator winding 51, and the 3-phase winding 5 1 3 is the II-phase winding and the V-phase winding. It consists of a winding wire and a phase winding, and the three-phase winding wire 5 1 13 consists of an X-phase winding, a normal winding wire and a phase winding. A first inverter 10 1 and a second inverter 10 2 corresponding to a power converter are provided for each of the three-phase windings 5 1 3 and 5 1 13. The inverters 10 1 and 10 2 are composed of a full bridge circuit that has the same number of upper and lower arms as the number of phases of the phase winding, and is fixed by turning on and off the switch (semiconductor switching element) provided in each arm. The energizing current is adjusted in each phase winding of the child winding 51.

[0170] Each inverter 1 0 1 and 1 0 2 has a DC power supply 10 3 and a smoothing capacitor.

10 4 and 10 are connected in parallel. The DC power supply 103 is composed of, for example, an assembled battery in which a plurality of unit cells are connected in series. Each switch of the inverters 10 1 and 10 2 corresponds to the semiconductor module 66 shown in FIG. 1 etc., and the capacitor 10 4 corresponds to the capacitor module 68 shown in FIG. 1 etc.

[0171] The control device 110 is equipped with a microcomputer including a II and various memories. Based on various detection information of the rotating electric machine 10 and demands for powering drive and power generation, the inverter 1 0 1, 1 The energization is controlled by turning on/off each switch in 02. The control device 110 corresponds to the control device 77 shown in FIG. The detection information of the rotating electric machine 10 includes, for example, the rotation angle (electrical angle information) of the rotor 40 detected by an angle detector such as a resolver or the voltage sensor. 〇 2020/175 222 52 卩 (: 170? 2020 /006141

The power supply voltage (inverter input voltage) and the energizing current of each phase detected by the current sensor are included. The control device 110 generates and outputs an operation signal for operating each switch of the inverters 10 1 and 10 2. The request for power generation is a request for regenerative driving when, for example, the revolving electric machine 10 is used as a power source for vehicles.

[0172] The first inverter 1001 includes a series connection body of the upper arm switch 3 and the lower arm switch 3 in each of the three phases of the II phase, the V phase, and the phase. The high potential side terminal of the upper arm switch 3 of each phase is connected to the positive terminal of the DC power supply 103, and the low potential side terminal of the lower arm switch 3 of each phase is connected to the negative terminal (ground) of the DC power supply 103. It is connected. At the intermediate connection points between the upper arm switch 3 and the lower arm switch 3 n of each phase, the _ ends of the II phase winding, the V phase winding, and the phase winding are connected. Each of these phase lines is connected in a star shape (cable connection), and the other ends of each phase line are connected to each other at a neutral point.

[0173] The second inverter 1002 has the same configuration as the first inverter 101, and the upper arm switch 3 and the lower arm switch 3 are provided in the three phases including the X phase, the negative phase, and the phase. And a series connection body with each. The high potential side terminal of the upper arm switch 3 of each phase is connected to the positive terminal of the DC power supply 103, and the low potential side terminal of the lower arm switch 3 n of each phase is the negative terminal (ground) of the DC power supply 103. ) It is connected to the. At the intermediate connection point between the upper arm switch 3 and the lower arm switch 3 n of each phase, one ends of the X-phase winding, the normal-phase winding, and the phase winding are connected, respectively. Each of these phase windings is connected in a star shape, and the other ends of each phase winding are connected to each other at a neutral point.

[0174] Fig. 20 shows the current feedback control processing for controlling the phase currents of the II, V, and phases, and the current feedback control processing for controlling the phase currents of the X, V, and phases. Here, first, the control processing on the II, V, and phase sides will be described.

[0175] In FIG. 20, the current command value setting unit 1 1 1 is obtained by time-differentiating the power running torque command value or the power generation torque command value for the rotating electric machine 10 or the electrical angle 0 using the torque-9 map. Based on the electrical angular velocity 〇), the current command value of 〇! 〇 2020/175 222 53 卩 (: 170? 2020 /006141

Set the axis current command value. The current command value setting unit 11 11 is provided in common for the II, V, phase side and the X, side, phase side. The power generation torque command value is, for example, a regenerative torque command value when the rotary electric machine 10 is used as a vehicle power source.

[0176] The conversion unit 1 1 2 has a current detection value (

Current and 9-axis current.

[0177] The 1-axis current feedback control unit 113 calculates the 0-axis command voltage as an operation amount for feedback-controlling the 1-axis current to the 1-axis current command value. Further, the 9-axis current feedback control unit 1 1 1 4 calculates the axis command voltage as an operation amount for feedback controlling the 9-axis current to the axis current command value. In each of these feedback control units 1 1 1 3 and 1 1 1 4, the command voltage is calculated by using the feedback method, based on the deviation of the 1-axis current and the 1-axis current from the current command value.

[0178] The three-phase conversion unit 1 15 converts the command voltages of the 9th and 9th axes into the command voltages of the II phase, V phase, and phase. Each of the above sections 1 1 1 to 1 1 1 5 is a feedback control section that performs feedback control of the fundamental current based on the 9 conversion theory, and the command voltages of the II phase, V phase, and phase are feedback control values. is there.

[0179] Then, the operation signal generation unit 1 16 uses a well-known triangular wave carrier comparison method to generate an operation signal for the first inverter 1 0 1 based on the command voltages of the three phases. Specifically, the operation signal generator 1116 controls \^/1\/1 based on the magnitude comparison between the signal obtained by normalizing the three-phase command voltage with the power supply voltage and the carrier signal such as the triangular wave signal. Generates a switch operation signal (duty signal) for the upper and lower arms in each phase.

[0180] In addition, the X side, the side, and the phase side also have the same configuration,

Converter 1

2 2 indicates the current detection value (three phase currents) by the current sensor provided for each phase, which is the component of the orthogonal two-dimensional rotary coordinate system with the field direction as ¢1 axis and ¢1 axis current. 〇 2020/175 222 54 卩 (: 170? 2020 /006141

And the shaft current.

[0181] The 1-axis current feedback control section 1 2 3 calculates the 1-axis command voltage, and the 1-axis current feedback control section 1 2 4 calculates the 9-axis command voltage. The 3-phase converter 1 2 5 converts the command voltages for the axes 9 and 9 into command voltages for the X phase, the negative phase, and the phase. Then, the operation signal generation unit 1 26 generates the operation signal of the second inverter 1 0 2 based on the three-phase command voltage. Specifically, the operation signal generator 1 2 6 controls \^/1\/1 based on the magnitude comparison between the signal obtained by normalizing the three-phase command voltage with the power supply voltage and the carrier signal such as the triangular wave signal. Generates a switch operation signal (duty signal) for the upper and lower arms in each phase.

[0182] Based on the switch operation signals generated by the operation signal generators 1 1 6 and 1 2 6, the driver 1 1 7 switches the 3-phase switches in each inverter 1 0 1 and 1 0 2. Turn 3, 3 on and off.

[0183] Next, the torque feedback control process will be described. This process is mainly for the purpose of increasing the output of the rotating electric machine 10 and reducing the loss under operating conditions where the output voltage of each inverter 10 1, 10 2 is large, such as in the high rotation area and high output area. Used. The control device 110 selects and executes one of the torque feedback control process and the current feedback control process based on the operating conditions of the rotary electric machine 100.

[0184] Fig. 21 shows the torque feedback control processing corresponding to the II, V, and phases, and the torque feedback control processing corresponding to the X, V, and phases. It should be noted that, in FIG. 21, the same components as those in FIG. First, I will explain the control processing on the II, V, and phase sides.

[0185] The voltage amplitude calculation unit 1 2 7 determines the voltage based on the power running torque command value or the power generation torque command value for the rotating electric machine 10 and the electrical angular velocity £0 obtained by time differentiating the electrical angle 0. A voltage amplitude command, which is a command value of the vector size, is calculated.

[0186] The torque estimation unit 1 2 8 3 and the ¢1 axis current converted by the ¢1 conversion unit 1 1 2

Based on the 9-axis current, the estimated torque value corresponding to the R, V, and phase is calculated. 〇 2020/175 222 55 卩 (: 170? 2020 /006141

It should be noted that the torque estimator 1 283 may calculate the voltage amplitude command based on the map information in which the 0 axis current, the axis current and the voltage amplitude command are associated.

[0187] The torque feedback control unit 1 2 9 3 controls the voltage phase which is the command value of the phase of the voltage vector as the operation amount for feedback controlling the estimated torque value to the power running torque command value or the power generation torque command value. Calculate the command. In the torque feedback controller 1293, the voltage phase command is calculated using the feedback method based on the deviation of the estimated torque value with respect to the power running torque command value or the power generation torque command value.

[0188] Operation signal generation unit 1 3 0 _3, the voltage amplitude command, based on the voltage phase command and the electrical angle 0, and generates a first operation signal of the inverter 1 0 1. Specifically, the operation signal generating unit 1 3 0 _3, standard voltage amplitude command, and calculates a command voltage of 3-phase based on the voltage phase command and the electrical angle 0, the power supply voltage command voltage calculated 3-phase The switch operation signals of the upper and lower arms in each phase are generated by \^/1\/1 control based on the magnitude comparison of the converted signal and the carrier signal such as the triangular wave signal.

[0189] Incidentally, the operation signal generating unit 1 3 0 _3, the voltage amplitude command, a voltage phase command, a map information 0 and the switch operation signal electrical angle associated Parusubata - down information, the voltage amplitude command, a voltage The switch operation signal may be generated based on the phase command and the electrical angle 0.

[0190] In addition, the X-side, the side-side, and the phase side have the same configuration, and the torque estimation unit

The 1 2 8 13 calculates the estimated torque value corresponding to the X, phase, and phase based on the 1-axis current and the 1-axis current converted by the 1-converting section 1 2 2.

[0191] The torque feedback control unit 129 calculates a voltage phase command as an operation amount for feedback controlling the estimated torque value to the power running torque command value or the power generation torque command value. In the torque feedback control unit 129, the voltage phase command is calculated using the I feedback method based on the deviation of the estimated torque value from the power running torque command value or the power generation torque command value.

[0192] The operation signal generation unit 1300 generates an operation signal for the second inverter 1O 2 based on the voltage amplitude command, the voltage phase command, and the electrical angle 0. Specifically, the operation 〇 2020/175 222 56 卩 (: 170? 2020 /006141

The signal generator 130013 calculates the command voltage of the three phases based on the voltage amplitude command, the voltage phase command, and the electrical angle 0, and the signal that standardizes the calculated three-phase command voltage with the power supply voltage and the triangular wave. By the \^/1\/1 control based on the magnitude comparison with the carrier signal such as the signal, the switch operation signal of the upper and lower arms in each phase is generated. Based on the switch operation signal generated by the operation signal generation unit 1330, 1330, the driver 1177 determines the three-phase switches 3 and 3 in each inverter 1101 and 102. Turn on and off.

[0193] By the way, the operation signal generator 1300 has a pulse amplitude information, a voltage amplitude command, a voltage phase command, a voltage phase command, a voltage angle command, and a voltage amplitude command, which are map information associated with the switch operation signal. The switch operation signal may be generated based on the phase command and the electrical angle 0.

[0194] By the way, in the rotary electric machine 10, it is feared that electrolytic corrosion of the bearings 2 1 and 2 2 occurs due to the generation of the axial current. For example, when the energization of the stator winding 5 1 is switched by switching, the magnetic flux is distorted due to a minute shift in switching timing (switching imbalance), which causes the bearing that supports the rotating shaft 1 1. There is concern that electrolytic corrosion may occur in 2 1 and 2 2. The distortion of the magnetic flux occurs according to the inductance of the stator 50, and the electromotive force in the axial direction caused by the distortion of the magnetic flux causes dielectric breakdown in the bearings 21 and 22 to promote electrolytic corrosion.

[0195] In this regard, the present embodiment takes the following three measures as measures against electrolytic corrosion. The first countermeasure against electrolytic corrosion is to reduce the inductance as the stator 50 is made coreless and to reduce the magnetic flux of the magnet unit 4 2 so as to suppress electrolytic corrosion. The second countermeasure against electrolytic corrosion is a countermeasure against electrolytic corrosion by using a cantilever structure with bearings 2 1 and 2 2 for the rotating shaft. The third countermeasure against electrolytic corrosion is a countermeasure against electrolytic corrosion by molding the annular stator winding 5 1 together with the stator core 52 with a molding material. The details of each of these measures are explained below.

[0196] First, in the first countermeasure against electrolytic corrosion, in the stator 50, each conductor wire group in the circumferential direction 〇 2020/175 222 57 卩 (: 170? 2020 /006141

The space between the 81's is made toothless, and a sealing member 57 made of a non-magnetic material is provided between the conductor groups 81 in place of the teeth (iron core) (see Fig. 10). This makes it possible to reduce the inductance of the stator 50. By reducing the inductance of the stator 50, even if there is a deviation in the switching timing when the stator winding 5 1 is energized, the magnetic flux distortion due to the deviation in the switching timing is suppressed, and the bearing It is possible to suppress the electrolytic corrosion of 2 1 and 2 2. It is preferable that the inductance of the 1st axis is equal to or less than the inductance of the 1st axis.

[0197] Further, in the magnets 9 1 and 9 2, the orientation was set so that the easy axis of magnetization on the axis side was parallel to the axis as compared to the 9 axis side (see Fig. 9).

.. As a result, the magnetic flux in the axis is strengthened, and the change in the surface magnetic flux (increase/decrease in magnetic flux) from axis to axis becomes gentle at each magnetic pole. Therefore, abrupt voltage changes due to switching imbalance are suppressed, which in turn contributes to suppression of electrolytic corrosion.

[0198] In the second countermeasure against electrolytic corrosion, in the rotating electric machine 10, the bearings 2 1 and 2 2 are arranged so as to be deviated to one side in the axial direction with respect to the axial center of the rotor 40. (See Figure 2). As a result, the influence of electrolytic corrosion can be reduced compared to a configuration in which a plurality of bearings are provided on both sides of the rotor in the axial direction with the rotor interposed therebetween. In other words, in a configuration in which the rotor is supported on both sides by multiple bearings, the closed path that passes through the rotor, the stator, and each bearing (that is, each bearing on both sides of the rotor in the axial direction) is generated due to the generation of high-frequency magnetic flux. A circuit is formed and there is a concern that the shaft current may cause electrolytic corrosion of the bearing. On the other hand, in the configuration in which the rotor 40 is cantilevered by the plurality of bearings 21 and 22, the closed circuit is not formed, and the electrolytic corrosion of the bearing is suppressed.

[0199] Further, the rotary electric machine 10 has the following configuration in relation to the configuration in which the bearings 21 and 22 are arranged on one side. In the magnet holder 41, a contact avoidance portion that extends in the axial direction and avoids contact with the stator 50 is provided in the intermediate portion 45 that projects in the radial direction of the rotor 40 (see Fig. 2). In this case, if a closed circuit of the axial current is formed via the magnet holder 41, increase the closed circuit length and 〇 2020/175 222 58 卩 (: 170? 2020 /006141

It is possible to increase the road resistance. As a result, the electrolytic corrosion of the bearings 21 and 22 can be suppressed.

[0200] While holding the rotor 40, the holding member 23 of the bearing unit 20 is fixed to the housing 30 on one side in the axial direction, and the housing 30 and unit base are fixed on the other side. The screws 6 1 (stator holder) are connected to each other (see Fig. 2). According to this configuration, it is possible to preferably realize a configuration in which the bearings 2 1 and 2 2 are arranged eccentrically on one side in the axial direction of the rotating shaft 11. Further, in this configuration, the unit base 6 1 is connected to the rotary shaft 11 via the housing 30 so that the unit base 6 1 is electrically separated from the rotary shaft 11. Can be placed in different positions. If an insulating member such as resin is interposed between the unit base 61 and the housing 30, the unit base 61 and the rotating shaft 11 will be electrically separated from each other. Becomes As a result, the bearing 2 1,

22 It is possible to properly suppress the electrolytic corrosion.

[0201] In the rotary electric machine 10 of the present embodiment, the shaft voltage acting on the bearings 21 and 22 is reduced by the one-sided arrangement of the bearings 21 and 22 and the like. Further, the potential difference between the rotor 40 and the stator 50 is reduced. Therefore, the potential difference acting on the bearings 21 and 22 can be reduced without using conductive grease in the bearings 21 and 22. Since conductive grease generally contains fine particles such as carbon, noise may occur. In this respect, in the present embodiment, the bearings 21 and 22 are configured to use non-conductive grease. Therefore, it is possible to suppress the inconvenience that noise is generated in the bearings 21 and 22. For example, when applied to an electric vehicle such as an electric vehicle, it is considered necessary to take noise countermeasures for the rotating electric machine 10. However, it is possible to appropriately implement the noise countermeasures.

[0202] In the third countermeasure against electrolytic corrosion, the stator winding 5 1 and the stator core 5 2 are molded with a molding material to suppress the positional deviation of the stator winding 5 1 in the stator 50. (See Figure 11). Particularly, in the rotating electric machine 100 of the present embodiment, the inter-conductor member (tee) is provided between each conductor wire group 8 1 in the circumferential direction in the stator winding 5 1. 〇 2020/175 222 59 卩(: 170? 2020/006141

However, by molding the stator winding 5 1 together with the stator core 5 2, the stator winding 5 1 can be misaligned. The deviation of the position of the conducting wire of 5 1 is suppressed. Therefore, it is possible to suppress the distortion of the magnetic flux due to the positional deviation of the stator winding 51 and the occurrence of electrolytic corrosion of the bearings 21 and 22 caused by the distortion.

[0203] Note that a unit base as a housing member for fixing the stator core 52.

6 1 for carbon fiber reinforced plastic

Since it is composed of, the discharge to the unit base 61 is suppressed compared with the case of, for example, aluminum and the like, and it is possible to take a suitable countermeasure against electrolytic corrosion.

[0204] In addition, as a countermeasure against electrolytic corrosion of the bearings 21 and 22, at least one of the outer ring 25 and the inner ring 26 is made of a ceramic material, or an insulating sleeve is provided on the outer side of the outer ring 25. It is also possible to use the above configuration.

[0205] Hereinafter, another embodiment will be described focusing on differences from the first embodiment.

[0206] (Second Embodiment)

In the present embodiment, the polar anisotropic structure of the magnet unit 42 in the rotor 40 is changed, which will be described in detail below.

[0207] As shown in Figs. 22 and 23, the magnet unit 42 is configured using a magnet array called a Halbach array. That is, the magnet unit 4 2 has a first magnet 1 3 1 having a magnetization direction (direction of magnetization vector) as a radial direction and a second magnet 1 3 2 having a magnetization direction (direction of magnetization vector) as a circumferential direction. The first magnet 1 3 1 is arranged at a predetermined interval in the circumferential direction, and the second magnet 1 3 2 is located at a position between the first magnets 1 3 1 adjacent to each other in the circumferential direction. It is arranged. The first magnet 1 3 1 and the second magnet 1 3 2 are permanent magnets made of rare earth magnets such as neodymium magnets.

[0208] The first magnet 1 3 1 has alternating poles on the side facing the stator 50 (inside in the radial direction).

They are arranged so as to be separated from each other in the circumferential direction so as to have 1\1 pole and 3 poles. The second magnets 1 3 2 are arranged next to the first magnets 1 3 1 so that the polarities alternate in the circumferential direction. It is provided so as to surround each of these magnets 1 3 1, 1 3 2. 〇 2020/175 222 60 卩(: 170? 2020/006141

The cylindrical portion 43, which is preferably a soft magnetic core made of a soft magnetic material, functions as a back core. The magnet unit 42 of the second embodiment also has the same relationship as the axis or the easy axis of magnetization with respect to the 9-axis in the 19-coordinate system as in the first embodiment.

[0209] In addition, the first magnet 1 31 is radially outside, that is, the cylindrical portion 4 of the magnet holder 4 1.

On the 3 side, a magnetic body 1 3 3 made of a soft magnetic material is arranged. For example, the magnetic body 133 may be made of electromagnetic steel plate, soft iron, or powdered iron core material. In this case, the circumferential length of the magnetic body 1 3 3 is the same as the circumferential length of the first magnet 1 3 1 (in particular, the circumferential length of the outer peripheral portion of the first magnet 1 3 1 ). The radial thickness of the first magnet 1 3 1 and the magnetic body 1 3 3 in the integrated state is the same as the radial thickness of the second magnet 1 3 2. In other words, the first magnet 1 3 1 is thinner than the second magnet 1 3 2 in the radial direction by the amount of the magnetic body 1 3 3. The magnets 1 3 1, 1 3 2 and the magnetic body 1 3 3 are fixed to each other by, for example, an adhesive. The outer side in the radial direction of the first magnet 1 3 1 in the magnet unit 4 2 is the side opposite to the stator 50, and the magnetic body 1 3 3 is one of the two sides of the first magnet 1 3 1 in the radial direction. It is provided on the opposite side of the stator 50 (opposite side of the stator).

A key 1 3 4 is formed on the outer peripheral portion of the magnetic body 1 3 3 as a convex portion that protrudes radially outward, that is, to the side of the cylindrical portion 4 3 of the magnet holder 4 1. Further, a key groove 1 3 5 is formed on the inner peripheral surface of the cylindrical portion 4 3 as a concave portion for accommodating the key 1 3 4 of the magnetic body 1 3 3. The protruding shape of the keys 1 3 4 and the groove shape of the key grooves 1 3 5 are the same, and the same number of keys as the keys 1 3 4 correspond to the keys 1 3 4 formed on each magnetic substance 1 3 3. Grooves 1 3 5 are formed. Due to the engagement of the keys 1 3 4 and the key grooves 1 3 5, the positional deviation of the first magnet 1 3 1 and the second magnet 1 3 2 and the magnet holder 4 1 in the circumferential direction (rotational direction) is suppressed. It should be noted that the key 1 3 4 and the key groove 1 3 5 (convex portion and concave portion) may be provided on either the cylindrical portion 4 3 of the magnet holder 4 1 or the magnetic body 1 3 3 as desired. In addition, a keyway 1 3 5 is provided on the outer periphery of the magnetic body 1 3 3 as well as inside the cylindrical portion 4 3 of the magnet holder 41. 〇 2020/175 222 61 卩 (: 170? 2020 /006141

It is also possible to provide keys _ 1 3 4 on the circumference.

[021 1] Here, in the magnet unit 42, the magnetic flux density in the first magnet 1 3 1 is increased by alternately arranging the first magnet 1 3 1 and the second magnet 1 3 2. It is possible. Therefore, in the magnet unit 42, the magnetic flux can be concentrated on one side, and the magnetic flux can be strengthened on the side closer to the stator 50.

[0212] Further, since the magnetic body 1 3 3 is arranged on the outer side in the radial direction of the first magnet 1 3 1, that is, on the side opposite to the stator, partial magnetic saturation on the outer side in the radial direction of the first magnet 1 3 1 is achieved. Can be suppressed, and by extension, demagnetization of the first magnet 1 3 1 caused by magnetic saturation can be suppressed. As a result, it is possible to increase the magnetic force of the magnet unit 42. The magnet unit 42 of the present embodiment is, so to speak, configured such that the portion of the first magnet 1 3 1 where demagnetization is likely to occur is replaced with a magnetic body 1 3 3.

[0213] Fig. 24 (3) and Fig. 24 (匕) specifically show the flow of magnetic flux in the magnet unit 4 2. Fig. 24 (3) shows that in the magnet unit 4 2. The case where the conventional configuration without the magnetic substance 1 3 3 is used is shown, and FIG. 24 (匕) shows the configuration of the present embodiment having the magnetic substance 1 3 3 in the magnet unit 4 2. The case is shown. In addition, in Fig. 24 (3) and Fig. 24 (匕), the cylindrical part 4 3 and the magnet unit 4 2 of the magnet holder 41 are shown in a straight line, and the lower side of the figure shows the stator side. The upper side is the side opposite the stator.

[0214] In the configuration of Fig. 24 (3), the magnetic flux acting surface of the first magnet 1 31 and the side surface of the second magnet 1 3 2 are in contact with the inner peripheral surface of the cylindrical portion 4 3, respectively. The magnetic flux acting surface of the second magnet 1 3 2 is in contact with the side surface of the first magnet 1 3 1. In this case, the magnetic flux 1 entering the contact surface with the first magnet 1 3 1 through the outer path of the second magnet 1 3 2 in the cylindrical portion 4 3 is substantially parallel to the cylindrical portion 4 3 and 2 A combined magnetic flux with the magnetic flux that attracts the magnetic flux 2 of the magnet 1 3 2 is generated. Therefore, there is a concern that a magnetic saturation may partially occur in the cylindrical portion 4 3 near the contact surface between the first magnet 1 3 1 and the second magnet 1 3 2.

[0215] On the other hand, in the configuration of Fig. 24 (匕), what is the stator 50 of the first magnet 1 31? 〇 2020/175 222 62 卩 (: 170? 2020 /006141

Since a magnetic body 1 3 3 is provided between the magnetic flux acting surface of the first magnet 1 3 1 and the inner peripheral surface of the cylindrical portion 4 3 on the opposite side, the magnetic body 1 3 3 allows the passage of magnetic flux. To be done. Therefore, the magnetic saturation in the cylindrical portion 43 can be suppressed, and the resistance to demagnetization is improved.

[0216] Unlike the configuration shown in Fig. 24( ₃ ), the configuration shown in Fig. 24(匕) can eliminate 2 which promotes magnetic saturation. As a result, the permeance of the entire magnetic circuit can be effectively improved. With this configuration, the magnetic circuit characteristics can be maintained even under severe high heat conditions.

[0217] In addition, the magnet magnetic path through the inside of the magnet becomes longer than the radial magnet in the conventional 3 1\/1 rotor. Therefore, the magnet permeance can be increased, the magnetic force can be increased, and the torque can be increased. Furthermore, since the magnetic flux concentrates at the center of the 1st axis, the sine wave matching rate can be increased. In particular, if the current waveform is a sine wave or a trapezoidal wave by the control of \^/1\/1, or the switching I 0 of 120° conduction is used, the torque can be more effectively enhanced.

[0218] When the stator core 52 is made of an electromagnetic steel plate, the radial thickness of the stator core 52 is 1/2 of the radial thickness of the magnet unit 42, or 1/ Greater than 2 is good. For example, the radial thickness of the stator core 52 is preferably 1/2 or more of the radial thickness of the first magnet 1 31 provided at the magnetic pole center in the magnet unit 4 2. Further, the radial thickness of the stator core 52 is preferably smaller than the radial thickness of the magnet unit 42. In this case, the magnetic flux of the magnet is about 1 [D], and the saturation magnetic flux density of the stator core 5 2 is 2 [D], so the radial thickness of the stator core 5 2 is equal to that of the magnet unit 4 2. By setting the thickness in the radial direction to 1/2 or more, magnetic flux leakage to the inner peripheral side of the stator core 52 can be prevented.

[0219] Since the magnetic path of a Halbach structure or polar anisotropic magnet has a pseudo-arc shape, the magnetic flux can be increased in proportion to the thickness of the magnet that handles magnetic flux in the circumferential direction. In such a configuration, it is considered that the magnetic flux flowing in the stator core 52 does not exceed the magnetic flux in the circumferential direction. That is, when an iron-based metal with a saturation magnetic flux density of 2 [c] is used for a magnetic flux of 1 [c] of the magnet, the stator core 5 〇 2020/175 222 63 卩 (: 170? 2020 /006141

If the thickness of 2 is equal to or more than half the thickness of the magnet, it is possible to provide a suitably small and lightweight rotating electric machine without magnetic saturation. Here, since the demagnetizing field from the stator 50 acts on the magnetic flux of the magnet, the magnetic flux of the magnet is generally below 0.9 [C]. Therefore, if the stator core has a thickness half that of the magnet, its magnetic permeability can be suitably kept high.

[0220] Hereinafter, a modified example in which a part of the above-described configuration is modified will be described.

[0221] (Modification 1)

In the above embodiment, the outer peripheral surface of the stator core 52 is formed into a curved surface without unevenness, and a plurality of conductor wire groups 8 1 are arranged side by side on the outer peripheral surface at predetermined intervals, but this may be changed. Good. For example, as shown in Fig. 25, the stator core 52 has an annular shape provided on the radial opposite sides of the stator winding 51 on the side opposite to the rotor 40 (lower side in the figure). It has a yoke 1 4 1 and a protrusion 1 4 2 extending from the yoke 1 4 1 so as to protrude between the linear portions 8 3 adjacent to each other in the circumferential direction. The protrusions 1 4 2 are provided on the outer side in the radial direction of the yoke 1 4 1, that is, on the side of the rotor 40, at predetermined intervals. Each conductor wire group 8 1 of the stator winding 5 1 is engaged with the protrusion 1 4 2 in the circumferential direction, and the protrusions 1 4 2 are arranged side by side in the circumferential direction while being used as the positioning portion of the conductor wire group 8 1. Has been done. The protrusions 14 2 correspond to “inter-conductor members”.

[0222] The protrusion 1 4 2 is the thickness in the radial direction from the yoke 1 4 1. In other words, as shown in FIG. 25, in the radial direction of the yoke 1 4 1, the yoke 1 4 3 of the straight portion 8 3 is formed. The distance from the inner side surface 3 2 0 adjacent to 4 1 to the apex of the protrusion 1 4 2 is the straight line portion adjacent to the yoke 1 4 1 in the radial direction among the straight layers 8 3 in multiple layers inside and outside the radial direction. It is smaller than 1/2 the radial thickness of 8 3 (1 ^to 11 in the figure). In other words, the dimension (thickness) of the conductor wire group 8 1 (conductive member) in the radial direction of the stator winding 5 1 (stator core 5 2) is 1 (twice the thickness of the conductor wire 8 2). For example, the three-quarter range of the face 3 20 in contact with the stator core 52 of the conductor group 8 1 and the face 3 30 facing toward the rotor 40 of the conductor group 8 1) is not a three-quarter range. The magnetic material (sealing member 57) should be occupied. The thickness control of these protrusions 1 4 2 〇 2020/175 222 64 卩 (: 170? 2020 /006141

Due to the limitation, the protruding portions 1 4 2 do not function as teeth between the conductor wire groups 8 1 (that is, the straight line portions 8 3) that are adjacent to each other in the circumferential direction, so that the magnetic path is not formed by the teeth. The protrusions 1 4 2 do not have to be provided all between the respective conductor wire groups 8 1 arranged in the circumferential direction, as long as they are provided between at least one conductor wire group 8 1 adjacent in the circumferential direction. Good. For example, the protrusions 1 42 may be provided at equal intervals in the circumferential direction by a predetermined number between the conductor wire groups 8 1. The shape of the protrusions 1 4 2 may be any shape such as a rectangular shape or an arc shape.

[0223] Further, the outer peripheral surface of the stator core 52 may be provided with a single linear portion 83. Therefore, in a broad sense, the radial thickness of the protrusion 1 4 2 from the yoke 1 4 1 may be smaller than 1/2 of the radial thickness of the straight portion 8 3.

[0224] Assuming an imaginary circle centered on the axis of the rotary shaft 11 and passing through the radial center of the straight portion 8 3 radially adjacent to the yoke 1 41, the projection 1 4 It is preferable that 2 has a shape that projects from the yoke 1 41 within the range of the virtual circle, in other words, a shape that does not project radially outward (that is, the rotor 40 side) from the virtual circle.

[0225] According to the above configuration, the projections 1 4 2 are limited in the radial thickness dimension and do not function as teeth between the straight line portions 8 3 adjacent in the circumferential direction. Compared to the case where teeth are provided between the straight line portions 8 3, adjacent straight line portions 8 3 can be brought closer to each other. This makes it possible to increase the cross-sectional area of the conductor 8 2 _3, can be low reducing the heat generated due to the energization of the stator winding 5 1. In such a configuration, since there is no tooth, it is possible to cancel the magnetic saturation, and it is possible to increase the current flowing to the stator winding 51. In this case, it is possible to appropriately deal with the increase in the amount of heat generated as the energizing current increases. Further, in the stator winding 51, the evening section 8 4 is shifted in the radial direction and has an interference avoiding section for avoiding interference with other evening sections 8 4, so that the different evening It is possible to dispose the inner portions 84 apart from each other in the radial direction. As a result, the heat dissipation can be improved even in the evening section 84. 〇 2020/175 222 65 卩(: 170? 2020/006141

It From the above, it is possible to optimize the heat dissipation performance of the stator 50.

[0226] If the yoke 1 41 of the stator core 5 2 and the magnet unit 4 2 of the rotor 40 (that is, the magnets 9 1 and 9 2) are separated by a predetermined distance or more, the protrusion 1 The radial thickness dimension of 42 is not restricted to !· I 1 in Figure 25. Specifically, the yoke 1 4 1 and the magnet unit 4 2

If it is more than the distance, the protrusion

The radial thickness dimension of 1 4 2 may be greater than or equal to !· I 1 in FIG. For example, the straight part

And the conductor wire group 8 1 is composed of two layers of conductor wires 8 2 inside and outside in the radial direction, the straight part 8 3 that is not adjacent to the yoke 1 4 1, that is, from the yoke 1 4 1 The projecting portion 1 4 2 may be provided within the range up to the half position of the conducting wire 8 2 in the second layer. In this case, if the radial thickness of the projection 1 4 2 is up to "1 ^to 1 1 3 /2", increasing the conductor cross-sectional area of the conductor wire group 8 1 will not significantly reduce the above effect. You can get it.

[0227] The stator core 52 may have the configuration shown in Fig. 26. Figure 2

In FIG. 6, the sealing member 57 is omitted, but the sealing member 57 may be provided. In FIG. 26, for convenience, the magnet unit 42 and the stator core 52 are shown in a linear form.

[0228] In the configuration of FIG. 26, the stator 50 has the protrusions 1 4 2 as inter-conductor members between the conductors 8 2 (that is, the straight portions 8 3) that are circumferentially adjacent to each other. .. When the stator winding 5 1 is energized, the stator 50 magnetically functions together with one of the magnetic poles of the magnet unit 4 2 (1\1 pole or 3 poles), and the stator 50 It has a portion 350 that extends circumferentially. The length in the circumferential direction of the stator 50 of this part 350 is! Then, this length range! Is the total width of the protrusions 1 4 2 existing in (i.e., the total dimension of the stator 50 in the circumferential direction), and the saturated magnetic flux density of the protrusions 1 4 2 is defined as 5, the magnet unit. If the width of one pole of the rotor 4 2 in the circumferential direction is \/\/ 01 and the residual magnetic flux density of the magnet unit 4 2 is

X X 3 0 1 X X "( 1) 〇 2020/175 222 66 卩(: 170? 2020/006141

It is made of a magnetic material.

[0229] Incidentally, the range W _n is a plurality of conductors group 8 1 adjacent in the circumferential direction, the excitation time period is set to include a plurality of conductors group 8 1 overlap. At that time, it is preferable to set the center of the gap 5 6 of the conductor wire group 8 1 as a reference (boundary) when setting the range W _n . For example, in the case of the configuration illustrated in FIG. 26, the fourth to the fourth conductor wire group 8 1 corresponds to the plurality of conductor wire groups 8 1 in order from the shortest distance from the magnetic pole center of the pole in the circumferential direction. .. Then, the range w _n is set so as to include the four conductor groups 81. At that time, the ends (starting point and ending point) of the range W _n are the centers of the gaps 56.

[0230] In Fig. 26, since both ends of the range n include half the protrusions 1 4 2 each, the range W n includes a total of 4 protrusions 1 4 2. ing. Therefore, if the width of the protrusion 1 4 2 (that is, the dimension of the protrusion 1 4 2 in the circumferential direction of the stator 5 0, in other words, the interval between the adjacent conductor wire groups 8 1) is set to 8, the range W n is The total width of the protrusions 1 4 2 included is

Eight + Eighty-eight + Eight + One-two-eight = Four-eighth.

[0231] Specifically, in this embodiment, the three-phase winding of the stator winding 5 1 is distributed winding, and the stator winding 5 1 has a protrusion for one pole of the magnet unit 4 2. The number of parts 1 4 2, that is, the number of gaps 5 6 between the conductor wire groups 8 1 is “phase number ◯”. Here, ◯ is the number of one-phase conductors 8 2 in contact with the stator core 5 2. When the conductor wire 8 2 is the conductor wire group 8 1 laminated in the radial direction of the rotor 40, it can be said that it is the number of conductor wires 8 2 on the inner peripheral side of the 1-phase conductor wire group 8 1. In this case, when the three-phase winding of the stator winding 51 is energized in a predetermined order for each phase, the protrusions 1 42 for two phases are excited within one pole. Therefore, the total circumferential width of the protrusions 1 4 2 excited by the energization of the stator winding 5 1 within the range of one pole of the magnet unit 4 2 is the protrusion 1 4 2 (that is, the gap 5 If the width of 6) in the circumferential direction is set to 8, then the number of excited phases is 8 = 2 x 2 x 8.

[0232] Then, after the total width dimension is specified in this way, the stator core 52 is Moreover, the protrusions 142 are made of a magnetic material that satisfies the relationship of (1) above. The total width dimension W t is also the circumferential dimension of the part where the relative magnetic permeability can be greater than 1 within one pole. Further, in consideration of the margin, the total width dimension W t may be the circumferential width dimension of the protrusion 142 in one magnetic pole. Specifically, since the number of protrusions 142 for one pole of the magnet unit 42 is “the number of phases XQ”, the circumferential width dimension (total width dimension Wt) of the protrusions 142 for one magnetic pole is , "The number of phases XQXA = 3X2XA = 6 A" may be used.

[0233] The distributed winding mentioned here is one pole pair period (N pole and S pole) of the magnetic pole, and has one pole pair of the stator winding 51. The one pole pair of the stator winding 51 mentioned here is composed of two straight portions 83 and a turn portion 84 in which currents flow in opposite directions and are electrically connected by the turn portion 84. As long as the above conditions are met, even short rolls (Short Pitch Winding) are considered to be equivalent to the distribution rolls of all rolls (Fu 11 Pitch Winding).

[0234] Next, an example of concentrated winding is shown. The term "concentrated winding" as used herein means that the width of one pole pair of magnetic poles is different from the width of one pole pair of the stator winding 51. As an example of concentrated winding, there are three conductor groups 81 for one pole pair, three conductor groups 81 for two pole pairs, and nine conductor groups 81 for four pole pairs. One of them is a group of conductors 81 having five relationships with five pairs of magnetic poles.

[0235] Here, when the stator winding 5 1 is concentrated winding, when the three-phase winding of the stator winding 5 1 is energized in a predetermined order, the stator winding 5 1 for two phases is 1 is excited. As a result, the protrusions 142 of the two phases are excited. Therefore, the width Wt in the circumferential direction of the protrusion 144 that is excited by the energization of the stator winding 51 within the range of one pole of the magnet unit 42 is "AX2". Then, after the width dimension Wt is defined in this way, the protrusions 142 are configured as a magnetic material that satisfies the relationship of (1) above. In the case of the concentrated winding shown above, the total width of the protrusions 142 in the circumferential direction of the stator 50 in the area surrounded by the same-phase wire group 81 is A. In the concentrated winding, Wm is defined as "the entire circumference of the surface of the magnet unit 42 facing the air gap" x "phase number" ÷ "dispersion number of conductor group 81". 〇 2020/175 222 68 卩 (: 170? 2020 /006141

Equivalent to.

[0236] By the way, the 1 ^to 1 product of neodymium magnets, samarium-cobalt magnets, and ferrite magnets is 2 0 [1\/1 〇 6

] The above magnets have a force of 1.0 strong, and the iron has a force of 2.0. Therefore, as a high output motor, the stator core 5 2 has a protrusion 1 4 2

Any magnetic material that satisfies the relationship may be used.

[0237] In addition, when the conductive wire 8 2 has an outer layer coating 1 82 as described later,

The conductor wire 8 2 may be arranged in the circumferential direction of the stator core 5 2 so that the outer layer coatings 18 2 of 8 2 are in contact with each other. In this case, can be regarded as 0 or the thickness of the outer coating 18 2 of both conducting wires 8 2 in contact with each other.

[0238] In the configurations of Figs. 25 and 26, the inter-conductor members (protrusions 1 4 2) which are disproportionately small with respect to the magnetic flux of the rotor 40 side are configured. The rotor 40 is a flat surface magnet type rotor having a low inductance and a flat surface, and does not have salient poles magnetically. With this configuration, the inductance of the stator 50 can be reduced, the generation of magnetic flux distortion due to the deviation of the switching timing of the stator winding 51 can be suppressed, and eventually the bearings 2 1 and 2 2 Electrolytic corrosion is suppressed.

[0239] (Modification 2)

It is also possible to employ the following configuration as the stator 50 that uses the inter-conductor member that satisfies the relationship of the above formula (1). In FIG. 27, tooth-like portions 1 4 3 are provided as inter-conductor members on the outer peripheral surface side (upper surface side in the figure) of the stator core 52. The tooth portions 1 4 3 are provided at predetermined intervals in the circumferential direction so as to project from the yoke 1 4 1, and have the same thickness dimension as the conductor wire group 8 1 in the radial direction. The side surface of the toothed portion 1 4 3 is in contact with each conductor wire 8 2 of the conductor wire group 8 1. However, there may be a gap between the tooth-like portion 14 3 and each conducting wire 8 2.

[0240] The tooth-shaped portions 1 43 are limited in width in the circumferential direction, and are provided with pole teeth (stator teeth) that are disproportionately thin with respect to the magnet amount. With this configuration, the tooth-shaped portion 1 43 is more than 1.8 teeth, and is reliably secured by the magnetic flux of the magnet. 〇 2020/175 222 69 卩(: 170? 2020/006141

Saturates and reduces permeance to reduce inductance

[0241] Here, in the magnet unit 42, if the surface area per pole of the magnetic flux acting surface on the stator side is 3, and the residual magnetic flux density of the magnet unit 4 2 is Is, for example, "3. The surface area on the rotor side of each toothed portion 1 43 is 3 I, and the number of conductors 8 2 per phase is given by the following equation. If part 1 4 3 is excited, the magnetic flux on the stator side is, for example, "3 I

2 X Sumi 3”. in this case,

(2)

The inductance is reduced by limiting the dimensions of the toothed portions 1 4 3 so that

[0242] If the magnet unit 4 2 and the tooth portion 1 4 3 have the same axial dimension, the circumferential width of one pole of the magnet unit 4 2 is set to \ZVrn, The width of the groove 1 4 3 in the circumferential direction.

Assuming I, equation (2) can be replaced by equation (3).

More specifically, assuming that, for example, 3 = 2 chomes, "1 chome" and 01 = 2, the above formula (3) becomes

It becomes a relationship. In this case, the width dimension 3 1 of the toothed portion 1 4 3 is made smaller than 1/8 of the width dimension of one pole of the magnet unit 4 2 to reduce the inductance. If the number is 1, it is recommended that the width dimension 3 I of the toothed portion 1 4 3 be smaller than 1/4 of the width dimension \ZVrn of one pole of the magnet unit 4 2.

[0243] In the above formula (3), "\^/ 3 I \ 〇 12" is a tooth excited by energization of the stator winding 5 1 within the range of one pole of the magnet unit 4 2. Corresponds to the circumferential width dimension of the shaped portions 1 4 3.

[0244] In the configuration of Fig. 27, similar to the configurations of Fig. 25 and Fig. 26 described above, the inter-conductor member (toothed portion 1 4 3) disproportionally small with respect to the magnetic flux of the rotor 40 side. Have \¥02020/175 222 70 卩(: 17 2020/006141

It is composed. With such a configuration, the inductance of the stator 50 can be reduced, the generation of magnetic flux distortion due to the deviation of the switching timing of the stator winding 51 is suppressed, and by extension the bearings 2 1, 2 2 Electrolytic corrosion is suppressed

[0245] (Modification 3)

In the above-described embodiment, the sealing member 57 covering the stator winding 51 is in a range including all the conductor wire groups 81 on the outer side in the radial direction of the stator core 52, that is, the radial thickness dimension is equal to that of each conductor wire. Although it is configured to be provided within a range that is larger than the radial thickness of the group 81, this may be changed. For example, as shown in FIG. 28, the sealing member 57 is provided so that a part of the conducting wire 82 protrudes. More specifically, the sealing member 57 is provided in such a manner that a part of the conductor wire 8 2 which is the outermost radial direction in the conductor wire group 8 1 is exposed radially outward, that is, the stator 50 side. To do. In this case, the radial thickness of the sealing member 57 is preferably the same as or smaller than the radial thickness of each conductor group 81.

[0246] (Modification 4)

As shown in FIG. 29, in the stator 50, each conductor wire group 81 may not be sealed by the sealing member 57. That is, the sealing member 5 7 covering the stator winding 5 1 is not used. In this case, an inter-conductor member is not provided between the conductor groups 81 arranged in the circumferential direction, and a gap is formed. In short, the inter-conductor members are not provided between the conductor groups 81 arranged in the circumferential direction. Note that air may be regarded as a non-magnetic substance or an equivalent of a non-magnetic substance as 3=0, and air may be arranged in this space.

[0247] (Modification 5)

When the inter-conductor member of the stator 50 is made of a non-magnetic material, it is possible to use a material other than resin as the non-magnetic material. For example, a metallic non-magnetic material may be used, such as the use of austenitic stainless steel 3 II 3 304.

[0248] (Modification 6) 〇 2020/175 222 71 卩(: 170? 2020/006141

The stator 50 may not have the stator core 52. In this case, the stator 50 is composed of the stator winding 5 1 shown in Fig. 12. In the stator 50 that does not include the stator core 52, the stator winding 5 1 may be sealed with a sealing material. Alternatively, the stator 50 may be configured to include an annular winding holder made of a non-magnetic material such as synthetic resin, instead of the stator core 52 made of a soft magnetic material.

[0249] (Modification 7)

In the first embodiment described above, a plurality of magnets 9 1 and 9 2 arranged in the circumferential direction are used as the magnet unit 4 2 of the rotor 40, but this is changed and the magnet unit 4 2 Alternatively, an annular magnet, which is an annular permanent magnet, may be used. Specifically, as shown in FIG. 30, an annular magnet 95 is fixed inside the cylindrical portion 43 of the magnet holder 41 in the radial direction. The annular magnet 95 is provided with a plurality of magnetic poles whose polarities alternate in the circumferential direction, and the magnets are integrally formed on both the axis and the nine axes. The annular magnet 95 is formed with an arc-shaped magnet magnetic path in which the orientation direction is radial in the axis of each magnetic pole and the orientation is circumferential in the axis between the magnetic poles.

[0250] In the annular magnet 95, the easy axis of magnetization is perpendicular to the axis or close to the axis in the portion near the axis, and the easy axis of magnetization is orthogonal to the axis or orthogonal to the axis in the portion near the axis. It suffices that the orientation is such that an arc-shaped magnet magnetic path having a direction close to is formed.

[0251] (Modification 8)

In this modification, a part of the control method of the control device 110 is changed. In this modification, differences from the configuration described in the first embodiment will be mainly described.

[0252] First, using Fig. 31, the operation signal generation units 1 1 6 and 1 2 6 shown in Fig. 20 and the operation signal generation units 1 3 0 3 and 1 3 0 6 shown in Fig. 21 are used. The processing inside is explained. In addition, each operation signal generator 1 1 6, 1 2 6,

The processing at 1300 is basically the same. Therefore, in the following, the operation signal generator 1 1 The process of 6 will be described as an example.

[0253] The operation signal generation section 1 16 includes a carrier generation section 1 16 a and U, V, W phase comparators 1 16 bU, 1 16 bV, 1 16 bW. .. In the present embodiment, the carrier generation unit 1 16 a generates and outputs a triangular wave signal as the carrier signal S i g C.

[0254] U, V, W phase comparators 1 1 6 b U, 1 1 6 b V, 1 1 6 bW have carrier signal S ig C generated by carrier generation unit 1 1 6 a and 3 phase The U, V, and W phase command voltages calculated by the converter 1 15 are input. The U, V, and W phase command voltages are, for example, sinusoidal waveforms, and their phases are shifted by 120 ^{° in} terms of electrical angle.

[0255] U, V, W phase comparator 1 1 6 b U, 1 1 6 b V, 1 16 bW is a PWM based on magnitude comparison of U, V, W phase command voltage and carrier signal S ig C. By (PWM: pulse width modulation) control, the operation signal of each switch S p, S n of the upper arm and the lower arm of the U, V, W phases in the first inverter 101 is generated. Specifically, the operation signal generation unit 1 16 uses U, V, and W by performing PWM control based on the magnitude comparison between the signal in which the U, V, and W phase command voltages are normalized by the power supply voltage and the carrier signal. , Generates operation signals for the W-phase switches S p and S n. The driver 1 17 turns on/off the U-, V-, and W-phase switches S p and S n in the first inverter 110 1 based on the operation signal generated by the operation signal generation unit 1 16.

[0256] The control device 110 performs a process of changing the carrier frequency f c of the carrier signal S i g C, that is, the switching frequency of each of the switches S p and S n. The carrier frequency f c is set high in the low torque region or high rotation region of the rotary electric machine 10 and set low in the high torque region of the rotary electric machine 10. This setting is made in order to suppress the deterioration of the controllability of the current flowing through each winding.

[0257] That is, as the stator 50 is made coreless, the inductance of the stator 50 can be reduced. Here, when the inductance becomes low, the electrical time constant of the rotating electric machine 10 becomes small. As a result, the current flowing through each phase wire 〇 2020/175 222 73 卩(: 170? 2020/006141

There is a concern that the current ripple will increase and the controllability of the current flowing in the winding will decrease, resulting in current control divergence. The influence of this decrease in controllability can be more pronounced when the current flowing in the winding (for example, the effective value of the current) is included in the low current region than in the high current region. In order to deal with this problem, in this modification, the control device 110 changes the carrier frequency.

[0258] Processing for changing the carrier frequency will be described with reference to FIG.

This processing is repeatedly executed by the control device 110, for example, at a predetermined control cycle as the processing of the operation signal generation unit 116.

[0259] In step 310, it is determined whether or not the current flowing through the winding 513 of each phase is included in the low current region. This process is a process for determining that the current torque of the rotary electric machine 10 is in the low torque region. The following first and second methods can be given as examples of methods for determining whether or not the current is included in the low current region.

[0260] <First method>

○ 1 Calculate the estimated torque value of the rotating electric machine 10 based on the axis current and 9-axis current converted by the converter 1 1 2. Then, when it is determined that the calculated estimated torque value is less than the torque threshold value, it is determined that the current flowing through the winding 5 13 is included in the low current region, and the estimated torque value is equal to or greater than the torque threshold value. If it is determined, it is determined to be included in the high current region. Here, the torque threshold may be set to, for example, 1/2 of the starting torque (also referred to as the restraint torque) of the rotating electric machine 10.

[0261] <Second method>

When it is determined that the rotation angle of the rotor 40 detected by the angle detector is equal to or greater than the speed threshold value, the current flowing through the winding 5 13 is included in the low current region, that is, in the high rotation region. Judge that there is. Here, the speed threshold may be set to, for example, the rotation speed when the maximum torque of the rotary electric machine 10 becomes the torque threshold.

[0262] If a negative determination is made in step 310, it is determined to be in the high current region. And proceed to step S 1 1. In step S11, the carrier frequency fc is set to the first frequency fL.

[0263] When the affirmative judgment is made in Step S10, the process proceeds to Step S12, and the carrier frequency fc is set to the second frequency fH higher than the first frequency fL.

According to the present modification described above, the carrier frequency f c is set higher when the current flowing through each phase winding is included in the low current region than when it is included in the high current region. Therefore, the switching frequencies of the switches S p and S n can be increased in the low current region, and an increase in current ripple can be suppressed. As a result, a decrease in current controllability can be suppressed.

[0265] On the other hand, when the current flowing in each phase line is included in the high current region, the carrier frequency f c is set to be lower than that in the low current region. In the high current region, the amplitude of the current flowing through the winding is larger than in the low current region, so the increase in the current ripple due to the lower inductance has less effect on the current controllability. .. Therefore, in the high current region, the carrier frequency f c can be set lower than in the low current region, and the switching loss of each inverter 10 1, 10 2 can be reduced.

[0266] In this modification, the following modes can be implemented.

[0267] When the carrier frequency fc is set to the first frequency f L, when the affirmative determination is made in step S10 of FIG. 32, the carrier frequency fc is changed from the first frequency f L to the second frequency f L. It may be gradually changed toward H.

[0268] In addition, when the carrier frequency fc is set to the second frequency fH and a negative determination is made in step S10, the carrier frequency fc is changed from the second frequency fH to the first frequency fL. May be gradually changed toward.

[0269] Instead of the P WM control, a switch operation signal may be generated by space vector modulation (SVM: space vector modulation) control. Even in this case, the change of the switching frequency described above can be applied.

[0270] (Modification 9) 〇 2020/175 222 75 卩(: 170? 2020/006141

In each of the above-described embodiments, two pairs of conductors of each phase forming the conductor wire group 81 are connected in parallel as shown in FIG. 33 (3). Figure 33 (3) shows two pairs of wires.

[0271] Further, three or more pairs of multilayer conductor wires may be laminated in the radial direction. FIG. 34 shows a configuration in which four pairs of conductors, the first to fourth conductors 883 to 88, are stacked and arranged. The 1st to 4th conductors 883 to 88 are the 1st, 2nd, 3rd,

They are arranged in the order of 88 m, 88 m, 88 in the radial direction.

[0272] Here, as shown in FIG.

88 may be connected in parallel, the first conducting wire 883 may be connected to one end of this parallel connection body, and the second conducting wire 88 may be connected to the other end. When connected in parallel, the current density of the parallel-connected conductors can be reduced, and heat generation during energization can be suppressed. Therefore, in the configuration where the cylindrical stator winding is assembled in the housing (unit base 61) in which the cooling water passage 74 is formed, the first and second conductors 88 that are not connected in parallel are connected.

88 units are placed on the side of the stator core 52 that contacts the unit base 61, and are connected in parallel.

88 is arranged on the side opposite to the stator core. This makes it possible to equalize the cooling performance of the conductors 883 to 88 in the multilayer conductor structure.

[0273] Note that the radial thickness dimension of the conductor wire group 81 including the first to fourth conductor wires 883 to 88 is set to be smaller than the circumferential width dimension of one phase in one magnetic pole. Good.

[0274] (Modification 10)

The rotating electric machine 10 may have an inner rotor structure (inner rotation structure). In this case, for example, in the housing 30, the stator 50 may be provided on the radially outer side and the rotor 40 may be provided on the radially inner side. In addition, one or both of the two axial ends of the stator 50 and the rotor 40 should be connected to the inverter unit. 〇 2020/175 222 76 卩 (: 170? 2020 /006141

It is advisable to have a slot 60. FIG. 35 is a cross-sectional view of the rotor 40 and the stator 50, and FIG. 36 is an enlarged view of a part of the rotor 40 and the stator 50 shown in FIG. is there.

[0275] The configurations shown in Figs. 35 and 36 that assume the inner rotor structure are different from the configurations shown in Figs. 8 and 9 that assume the outer rotor structure in that the rotor 40 and the stator 50 are radially inward and outward. It has the same configuration except that it is reversed in. Briefly, the stator 50 has a stator winding 5 1 having a flat conductor structure and a stator core 5 2 having no teeth. The stator winding 51 is assembled inside the stator core 52 in the radial direction. The stator core 52 has one of the following configurations, as in the case of the outer rotor structure.

(8) On the stator 50, provide inter-conductor members between each conductor in the circumferential direction, and as the inter-conductor members, set the circumferential width dimension of the inter-conductor member for one magnetic pole to 1, If the saturation magnetic flux density of the member is 3, and the circumferential width of the magnet unit in one magnetic pole is ◯!, and the residual magnetic flux density of the magnet unit is ‘

"A magnetic material having a relationship of "is used.

(Mitsumi) In the stator 50, an inter-conductor member is provided between the conductor portions in the circumferential direction, and a non-magnetic material is used as the inter-conductor member.

(◯) In the stator 50, the inter-conductor members are not provided between the conductor portions in the circumferential direction.

[0276] The same applies to each of the magnets 9 1 and 9 2 of the magnet unit 4 2. In other words, the magnet unit 42 is oriented so that the direction of the easy axis of magnetization is parallel to the axis on the Axis 1 side, which is the center of the magnetic pole, compared to the axis 9 side, which is the magnetic pole boundary. The magnets 9 1 and 9 2 are used. The details of the magnetization direction of each magnet 9 1, 9 2 are as described above. It is also possible to use an annular magnet 95 (see Fig. 30) in the magnet unit 42.

[0277] Fig. 37 is a vertical cross-sectional view of the rotating electric machine 10 in the case of the inner rotor type, which corresponds to Fig. 2 described above. Differences from the configuration of FIG. 2 will be briefly described. In Fig. 37, inside the housing 30 is an annular stator. 〇 2020/175 222 77 卩(: 170? 2020/006141

50 is fixed, and a rotor 40 is rotatably provided inside the stator 50 with a predetermined air gap interposed therebetween. Similar to Fig. 2, the bearings 21 and 22 are arranged so as to be offset to either side in the axial direction with respect to the center of the rotor 40 in the axial direction. Has been supported. Further, the inverter unit 60 is provided inside the magnet holder 41 of the rotor 40.

[0278] Fig. 38 shows another configuration of the rotating electric machine 10 having an inner rotor structure. Figure

In the housing 38, the rotating shaft 11 is rotatably supported by the bearings 21 and 22 in the housing 30 and the rotor 40 is fixed to the rotating shaft 11. Similar to the configuration shown in FIG. 2 and the like, the bearings 21 and 22 are arranged so as to be biased to one side in the axial direction with respect to the axial center of the rotor 40. The rotor 40 has a magnet holder 41 and a magnet unit 42.

[0279] The rotating electric machine 10 of Fig. 38 differs from the rotating electric machine 10 of Fig. 37 in that the inverter unit 60 is not provided inside the rotor 40 in the radial direction. ing. The magnet holder 41 is connected to the rotary shaft 11 at a position radially inward of the magnet unit 42. The stator 50 has a stator winding 5 1 and a stator core 52, and is attached to the housing 30.

[0280] (Modification 1 1)

Another configuration of the rotating electric machine having the inner rotor structure will be described below. FIG. 39 is an exploded perspective view of the rotary electric machine 200, and FIG. 40 is a side sectional view of the rotary electric machine 200. Here, the vertical direction is shown based on the states of FIGS. 39 and 40.

[0281] As shown in FIG. 39 and FIG. 40, the rotating electric machine 200 has an annular stator core 2

0 1 and a stator 20 3 having a multi-phase stator winding 20 2, and a rotor 20 4 rotatably arranged inside the stator core 20 1. The stator 203 corresponds to an armature, and the rotor 2044 corresponds to a field element. The stator core 20 1 is made up of a number of laminated silicon steel plates. 〇 2020/175 222 78 卩 (: 170? 2020/006141

On the other hand, the stator winding 202 is attached. Although not shown, the rotor 204 has a rotor core and a plurality of permanent magnets as a magnet unit. The rotor core is provided with a plurality of magnet insertion holes at equal intervals in the circumferential direction. A permanent magnet magnetized so that the magnetizing direction is alternately changed for each adjacent magnetic pole is attached to each of the magnet insertion holes. The permanent magnet of the magnet unit may have the Halbach array as described in Fig. 23 or a similar structure. Alternatively, in the permanent magnet of the magnet unit, the orientation direction (magnetization direction) extends in an arc shape between the axis that is the magnetic pole center and the axis that is the magnetic pole boundary as described in FIGS. 9 and 30. It is preferable to have polar anisotropy characteristics.

[0282] Here, the stator 203 may have any of the following configurations.

(8) In the stator 203, an inter-conductor member is provided between each conductor portion in the circumferential direction, and as the inter-conductor member, the circumferential width dimension of the inter-conductor member in one magnetic pole is 1, and the inter-conductor member is Where the saturation magnetic flux density of the magnet unit is 3, and the width of the magnet unit in the circumferential direction in one magnetic pole is defined as, and the residual magnetic flux density of the magnet unit is defined as

"A magnetic material having a relationship of "is used.

(Mimi) In the stator 203, an inter-conductor member is provided between the conductor portions in the circumferential direction, and a non-magnetic material is used as the inter-conductor member.

(◯) In the stator 203, no inter-conductor members are provided between the conductor portions in the circumferential direction.

[0283] Further, in the rotor 204, the magnet unit is oriented so that the direction of the easy axis of magnetization is parallel to the axis on the side of the axis that is the center of the magnetic pole, compared to the side of the axis that is the magnetic pole boundary. It is composed of a plurality of magnets.

[0284] An annular inverter case 211 is provided on one end side of the rotary electric machine 200 in the axial direction. The inverter case 2 11 is arranged such that the lower surface of the case is in contact with the upper surface of the stator core 2 0 1. In the inverter case 211, the pulsation of voltage and current (ripple) caused by the switching operation of the semiconductor switching elements and the power modules 211 that make up the inverter circuit. 〇 2020/175 222 79 卩(: 170? 2020/006141

The smoothing capacitor 2 1 3 that suppresses the noise, the control board 2 1 4 that has the controller, the current sensor 2 15 that detects the phase current, and the resolver stator 2 1 6 that is the rotation speed sensor of the rotor 20 4. And are provided. The power module 2 1 2 has a semi-conducting switching element, such as a knife and a diode.

[0285] The power connector 2 17 connected to the DC circuit of the battery mounted on the vehicle and the rotary electric machine 200 0 side and the vehicle side control device are provided on the periphery of the inverter case 2 11. A signal connector 2 18 used to transfer various signals is provided. The inverter case 2 1 1 1 is covered with a top cover 2 1 9. DC power from the on-vehicle battery is input via the power connector 2 17 and is converted to AC by the switching of the power module 2 1 2 and sent to the stator winding 20 2 of each phase.

[0286] On both sides of the stator core 2 0 1 in the axial direction opposite to the inverter case 2 1 1, the bearing unit 2 2 1 for rotatably holding the rotating shaft of the rotor 2 0 4 and its An annular rear case 2 2 2 which houses the bearing unit 2 2 1 is provided. The bearing unit 2 21 has, for example, a pair of bearings, and is arranged so as to be deviated to either one side in the axial direction with respect to the axial center of the rotor 204. However, a plurality of bearings in the bearing unit 2 21 may be provided dispersedly on both sides in the axial direction of the stator core 2 0 1, and the bearing may support both ends of the rotary shaft. The rear electric machine 220 is attached to the vehicle side by fastening the rear case 222 to a mounting portion such as a gear case or a transmission of the vehicle by bolting.

[0287] Inside the inverter case 211, a cooling channel 211 is formed for flowing the refrigerant. The cooling flow path 2 1 1 1 3 is formed by closing a space that is annularly recessed from the lower surface of the inverter case 2 1 1 with the upper surface of the stator core 2 0 1. The cooling channel 2 11 3 is formed so as to surround the coil end of the stator winding 2 0 2. The module case 2 1 2 ₃ of the power module 2 1 2 is put into the cooling passage 2 1 1 3. Also in the rear case 2 22, a cooling flow path 2 2 2 3 is formed so as to surround the coil end of the stator winding 2 0 2. Cooling flow 〇 2020/175 222 80 卩(: 170? 2020/006141

The passage 2 2 2 ₃ is formed by closing a space, which is annularly recessed from the upper surface of the rear case 2 2 2, with the lower surface of the stator core 2 0 1.

[0288] (Modification 12)

Up to now, the configuration embodied in the rotating field type rotating electric machine has been described, but it is also possible to change this and realize the rotating armature type rotating electric machine. Figure 4 1 shows the structure of a rotating armature-type rotating electric machine 230.

[0289] In the rotary electric machine 230 shown in Fig. 41, the housing

A bearing 2 3 2 is fixed to each of the 2 3 1 bearings, and the rotating shaft 2 3 3 is rotatably supported by the bearing 2 3 2. The bearing 23 2 is, for example, an oil-impregnated bearing made of porous metal containing oil. The rotor 2 3 4 as an armature is fixed to the rotary shaft 2 3 3. The rotor 2 3 4 has a rotor core 2 3 5 and a multiphase rotor winding line 2 3 6 fixed to the outer periphery of the rotor core 2 3 5. In the rotor 2 3 4, the rotor core 2 3 5 has a slotless structure, and the rotor winding wire 2 3 6 has a flat conductor structure. In other words, the rotor winding line 2 36 has a flat structure in which the region for each phase is longer in the circumferential direction than in the radial direction.

[0290] Further, a stator 2 37 as a field element is provided on the outer side in the radial direction of the rotor 2 3 4. The stator 2 3 7 has a stator core 2 3 8 fixed to the housing 2 3 1 3 and a magnet unit 2 3 9 fixed to the inner peripheral side of the stator core 2 3 8. ing. The magnet unit 2 39 is configured to include a plurality of magnetic poles whose polarities alternate in the circumferential direction, and like the magnet unit 4 2 and the like described above, on the side of the axis that is the center of the magnetic pole, The orientation is such that the direction of the easy magnetization axis is parallel to the axis, as compared to the axis side, which is the magnetic pole boundary. The magnet unit 2339 has an oriented sintered neodymium magnet, and its intrinsic coercive force is more than 400 [1 </○!] and the residual magnetic flux density is 1.0 [ It's over.

[0291] The rotary electric machine 230 of this example is a 2-pole 3-coil brushless coreless motor, the rotor winding 2 36 is divided into 3 parts, and the magnet unit 2 3 9 is 2-pole. .. The number of poles and the number of coils of the brushed motor are such as 2:3, 4:10, 4:21, etc. 〇 2020/175 222 81 卩(: 170? 2020/006141

Depending on the application of.

A commutator 2 4 1 is fixed to the rotary shaft 2 3 3, and a plurality of brushes 2 4 2 are arranged on the outer side in the radial direction. The commutator 2 4 1 is electrically connected to the rotor winding 2 3 6 via a conductor 2 4 3 embedded in the rotating shaft 2 3 3. A direct current flows in and out of the rotor winding 2 3 6 through these commutator 2 4 1, brush 2 4 2, and conductor 2 4 3. The commutator 2 4 1 is appropriately divided in the circumferential direction according to the number of phases of the rotor winding 2 3 6. The brush 2 42 may be directly connected to a DC power source such as a storage battery via electric wiring, or may be connected to a DC power source via a terminal block or the like.

[0293] The rotating shaft 2 3 3 is provided with a resin washer 2 4 4 as a seal material between the bearing 2 3 2 and the commutator 2 4 1. The resin washer 2 4 4 prevents the oil exuding from the oil-impregnated bearing 2 3 2 from flowing out to the commutator 2 4 1 side.

[0294] (Modification 13)

In the stator winding 5 1 of the rotating electric machine 10, each conductor wire 82 may have a plurality of insulating coatings inside and outside. For example, it is advisable to bundle a plurality of conductive wires (elementary wires) with an insulating coating and to cover them with an outer coating to form the conductive wire 82. In this case, the insulating coating of the wire constitutes the inner insulating coating, and the outer coating constitutes the outer insulating coating. Further, it is particularly preferable that the insulating ability of the outer insulating coating of the plurality of insulating coatings of the conductor 82 is higher than that of the inner insulating coating. Specifically, the thickness of the outer insulating coating is made thicker than the thickness of the inner insulating coating. For example, the thickness of the outer insulating coating is 100, and the thickness of the inner insulating coating is 40. Alternatively, a material having a lower dielectric constant than the inner insulating film may be used as the outer insulating film. At least one of these may be applied. Note that the strands of wire may be configured as an aggregate of a plurality of conductive materials.

[0295] As described above, by strengthening the insulation of the outermost layer of the conductor 82, high electric current can be obtained. 〇 2020/175 222 82 卩(: 170? 2020/006141

It is suitable for use in a pressure vehicle system. Further, the rotating electric machine 10 can be properly driven even in a high place where the atmospheric pressure is low.

[0296] (Modification 14)

In the conductor 82 having a plurality of insulating coatings inside and outside, at least one of the linear expansion coefficient (coefficient of linear expansion) and the adhesive strength may be different between the outer insulating coating and the inner insulating coating. Figure 4 2 shows the structure of the conducting wire 82 in this modification.

[0297] In Fig. 42, a conductor wire 8 2 is composed of a plurality of (four in the figure) element wires 1 8 1 and an outer layer coating 1 82 2 made of, for example, resin surrounding the plurality of element wires 1 8 1 (outer insulation Coating) and an intermediate layer 183 (intermediate insulating coating) filled around each element wire 1 81 in the outer coating 182. The element wire 1 81 has a conductive portion 181 3 made of a copper material and a conductor film 181 (inner insulating film) made of an insulating material. When viewed as a stator winding, the outer layer coating 182 insulates the phases. In addition, it is preferable that the wire 181 is configured as an aggregate of a plurality of conductive materials.

[0298] The intermediate layer 183 has a linear expansion coefficient higher than that of the conductor coating 181 of the element wire 181 and lower than that of the outer coating 182. In other words, the conductor 82 has a higher linear expansion coefficient toward the outer side. In general, the outer coating 1 82 has a higher linear expansion coefficient than the conductor coating 1 81, but by providing an intermediate layer 1 8 3 having a linear expansion coefficient between them, Layer 1 8 3 acts as a cushioning material and can prevent simultaneous cracking on the outer and inner layers

[0299] Further, in the conductor 8 2, the conductive portion 1 8 1 ₃ and the conductor film 1 8 in the strand 1 8 1

1 Stain is adhered, and conductor coating 1 8 1 Stain and intermediate layer 1 8 3 are bonded, and intermediate layer 1 8 3 and outer coating 1 8 2 are also bonded. The adhesive strength is weaker toward the outside. In other words, the adhesive strength of the conductive part 181 ₃ and the conductor film 181 is the adhesive strength of the conductor film 181 and the intermediate layer 183, and the adhesive strength of the intermediate layer 183 and the outer layer 182. It is getting weaker than that. In addition, the adhesive strength of the conductor coating 1 81 and the intermediate layer 1 8 3 and the intermediate layer 1 8 3 〇 2020/175 222 83 卩(: 170? 2020/006141

And the adhesive strength of the outer coating 182, it is preferable that the latter (outer) is weaker or equivalent. The magnitude of the adhesive strength between the coatings can be grasped, for example, from the tensile strength required to peel off the two coating layers. By setting the adhesive strength of the conducting wire 82 as described above, it is possible to suppress the occurrence of cracks (co-cracking) on both the inner layer side and the outer layer side even if there is a difference in temperature between the inside and outside due to heat generation or cooling. You can

[0300] Here, the heat generation and temperature change of the rotating electric machine mainly occur as copper loss generated from the conductive portion 181 ₃ of the wire 181 and iron loss generated from inside the iron core. The type of loss is

Alternatively, the heat is transmitted from the outside of the conducting wire 82, and the intermediate layer 183 does not have a heat source. In this case, the intermediate layer 183 has an adhesive force capable of acting as a cushion for both, so that the simultaneous cracking can be prevented. Therefore, it can be suitably used even in the field of high withstand voltage or large temperature change such as vehicle application.

[0301] Supplement to the following. The strand 1 8 1 may be, for example, an enameled wire, and in such a case, it has a resin coating layer of I, I, etc. (conductor coating 18 1 匕). Further, it is desirable that the outer layer coating 1 82 outside the element wire 1 81 be made of the same material, such as 丨 and 縨, and be thick. As a result, the destruction of the coating film due to the difference in linear expansion coefficient is suppressed. The outer coating 18 2 is, apart from the thicker ones of the above materials such as 8, I, 8 I, etc., 3, Mimi, Fluorine, Polycarbonate, Silicon, Epoxy, Polyethylene naphthalate,! It is also desirable to use a material with a dielectric constant such as __ that is smaller than 8 or 8 in order to increase the conductor density of the rotating machine. With these resins, even if they are thinner than the equivalent conductor film 1 81 1 \, PA \ film, or have the same thickness as the conductor film 1 8 1 13, the insulation ability can be increased. As a result, it becomes possible to increase the occupation ratio of the conductive portion. Generally, the above-mentioned resin has a better dielectric constant than the insulating coating of the enamel wire. Of course, there are some cases where the dielectric constant deteriorates depending on the molding conditions and the mixture. Among them, 3, Mimi generally has a larger coefficient of linear expansion than the enamel coating. 〇 2020/175 222 84 卩 (: 170? 2020 /006141

However, since it is smaller than other resins, it is suitable as an outer layer coating for the second layer.

[0302] In addition, the adhesive strength between the two kinds of coatings (intermediate insulation coating and outer insulation coating) on the outside of the strand 1 81 and the enamel coating of the strand 1 81 is the copper strength of the strand 1 81. It is desirable that it be weaker than the bond strength between the and enamel coating. This suppresses the phenomenon that the enamel coating and the above two types of coatings are destroyed at once.

[0303] When a water-cooled structure, a liquid-cooled structure, or an air-cooled structure is added to the stator, it is basically considered that thermal stress or impact stress is applied first to the outer layer coating 182. However, even if the insulating layer of the wire 181 and the two types of coatings are different from each other, the thermal stress and impact stress can be reduced by providing a part that does not bond the coatings. it can. That is, a gap is formed between the element wire (enamel wire) and fluorine, polycarbonate, silicon, epoxy, polyethylene naphthalate,! By disposing _ ◯, the insulating structure is formed. In this case, it is desirable to bond the outer layer coating and the inner layer coating with an adhesive material such as epoxy having a low dielectric constant and a low linear expansion coefficient. By doing so, not only the mechanical strength but also the destruction of the coating due to the friction due to the vibration of the conductive portion or the destruction of the outer coating due to the difference in the linear expansion coefficient can be suppressed.

[0304] The outermost layer fixing, which is generally the final step around the stator windings, is responsible for mechanical strength, fixing, etc. for the conductor wire 82 having the above-mentioned structure. Epoxy, 3, Mitsumi! It is preferable to use a resin having good moldability such as __, and having properties such as dielectric constant and linear expansion coefficient similar to those of the enamel coating.

[0305] In general, resin potting with urethane or silicone is generally used. However, the linear expansion coefficient of the resin is almost double that of other resins, and the thermal stress capable of shearing the resin is appear. Therefore, it is not suitable for applications above 60 V where strict insulation regulations are used internationally. In this respect, epoxy, 3, Mami,! According to the final insulation process that can be easily made by injection molding or the like with _ 0 or the like, each of the above requirements can be achieved.

[0306] Modifications other than the above will be listed below. 〇 2020/175 222 85 卩(: 170? 2020/006141

[0307] The distance port 1\/1 in the radial direction between the surface of the magnet unit 42 on the armature side in the radial direction and the axial center of the rotor may be 50 or more. Specifically, for example, the inner surface in the radial direction of the magnet unit 4 2 (specifically, the first and second magnets 9 1 and 9 2) shown in FIG. 4 and the axial center of the rotor 40. In the radial direction of and

The above may be mentioned.

[0308] As a slotless structure rotating electric machine, a small-scale one is known in which the output is used for models of several tens to several hundreds of classes. In addition, the present inventors do not understand a case in which a slotless structure is adopted in a large industrial rotary electric machine that generally exceeds 10. The reason for this was clarified by the present inventor.

[0309] In recent years, mainstream rotating electric machines are roughly classified into the following four types. These rotating electrical machines are brushed motors, cage induction motors, permanent magnet synchronous motors, and reluctance motors.

[0310] An exciting current is supplied to the brushed motor via the brush. For this reason

In the case of a brushed motor of a large machine, the brush becomes large and maintenance becomes complicated. As a result, with the remarkable development of semiconductor technology, it has been replaced by brushless motors such as induction motors. On the other hand, in the world of small motors, coreless motors have been supplied to the majority due to their advantages of low inertia and economy.

[031 1] In the basket-type induction motor, the magnetic field generated by the stator winding on the primary side is received by the iron core of the rotor on the secondary side, and an induced current is concentrated in the cage-type conductor to form a reaction magnetic field. This is the principle of generating torque by doing so. For this reason, it is not necessarily a good idea to eliminate the iron cores on both the stator side and rotor side from the viewpoint of the small size and high efficiency of the equipment.

[0312] Reluctance motors are motors that take advantage of reluctance changes in the iron core, and it is not desirable to eliminate the iron core in principle.

[0313] In the permanent magnet type synchronous motor, I 1\/1 (that is, embedded magnet type rotor) has been predominant in recent years, and especially in the case of large machines, it is the IV! 〇 2020/175 222 86 卩 (: 170? 2020 /006141

There are many cases.

[0314] I 1\/1 has a characteristic that it has both magnet torque and reluctance torque, and it is operated while the ratio of those torques is adjusted appropriately by the inverter control. For this reason, the 丨 IV! is a small motor with excellent controllability.

[0315] According to the analysis of the present disclosure, the torque of the rotor surface that generates the magnet torque and the reluctance torque is measured in the radial direction of the surface of the magnet unit on the armature side in the radial direction and the axial center of the rotor. Distance IV!, that is, the radius of the stator core of a typical Innaro-Yu is plotted along the horizontal axis as shown in Fig. 43.

[0316] The magnet torque has its potential determined by the magnetic field strength generated by the permanent magnet as shown in the following equation (6 9 1), whereas the reluctance torque has the following equation (6 2) Thus, the magnitude of the inductance, especially the axial inductance, determines its potential.

[0317] Magnet torque

1 ˣ .( ø

9 1)

Reluctance torque = !<

.1 .1 ○ 1 .( 6

9 2)

Here, I compared the magnetic field strength of the permanent magnet and the magnitude of the inductance of the winding with mouth IV!. The magnetic field strength generated by the permanent magnet, that is, the amount of magnetic flux is proportional to the total area of the permanent magnet on the surface facing the stator. In the case of a cylindrical rotor, it has the surface area of a cylinder. Strictly speaking, there are 1\1 poles and 3 poles, so it is proportional to the occupied area of half of the cylindrical surface. The surface area of a cylinder is proportional to the radius of the cylinder and the length of the cylinder. That is, if the cylinder length is constant, it is proportional to the radius of the cylinder.

[0318] — On the other hand, the winding inductance !_ 9 depends on the shape of the iron core, but the sensitivity is low. Rather, it is proportional to the square of the number of windings of the stator winding, so the number of windings is highly dependent. Note that is the magnetic circuit permeability,! If \1 is the number of turns, 3 is the cross-sectional area of the magnetic circuit, and 3 is the effective length of the magnetic circuit, the inductance !_ = 1\1 2 \ 3/5. Since the number of turns of the winding depends on the size of the winding space, in the case of a cylindrical motor, it depends on the winding space of the stator, that is, the slot area. 〇 2020/175 222 87 卩(: 170? 2020/006141

It As shown in Fig. 44, the slot area is proportional to the product of the circumferential length dimension 3 and the radial length dimension 3 3 x 3 because the slot shape is approximately square. ..

[0319] The length of the slot in the circumferential direction is proportional to the diameter of the cylinder, because the larger the diameter of the cylinder, the larger the length. The radial dimension of the slot is in proportion to the diameter of the cylinder. So the slot area is proportional to the square of the diameter of the cylinder. Further, as can be seen from the above equation (62), the reluctance torque is proportional to the square of the stator current, so the performance of the rotating electrical machine is determined by how large the current can flow, and the performance is determined by the stator slot. It depends on the area. From the above, if the length of the cylinder is constant, the reluctance torque is proportional to the square of the diameter of the cylinder. With this in mind, Fig. 43 shows a plot of the relationship between magnet torque and reluctance torque and mouth IV!.

[0320] As shown in Fig. 43, the magnet torque increases linearly with the mouth IV! and the reluctance torque increases quadratically with the mouth IV!. It can be seen that when the mouth IV! is relatively small, the magnet torque is dominant, and the reluctance torque is dominant as the stator core radius increases. The present applicant has concluded that the intersection of the magnet torque and the reluctance torque in Fig. 43 is approximately in the vicinity of the stator core radius = 500!!! That is, the stator core radius is 5

Which is well over 1 0

It is difficult to eliminate the iron core in the class-class motors because it is currently the mainstream to utilize reluctance torque, and this is one of the reasons why the slotless structure is not adopted in the field of large machines. To be done.

[0321] In the case of a rotating electric machine in which an iron core is used for the stator, magnetic saturation of the iron core is always an issue. Particularly in radial gap type rotating electrical machines, the vertical cross-sectional shape of the rotating shaft is fan-shaped per magnetic pole, and the magnetic path width becomes narrower toward the inner peripheral side of the equipment, and the inner diameter of the teeth forming the slot rotates. Determine the performance limit of the electric machine. No matter how high-performance permanent magnets are used, if magnetic saturation occurs in this part, the performance of permanent magnets cannot be fully exploited. To prevent magnetic saturation in this part 〇 2020/175 222 88 卩 (: 170? 2020 /006141

Has to be designed with a large inner diameter, resulting in a larger device.

[0322] For example, in a distributed winding rotary electric machine, in the case of a three-phase winding, magnetic flux is distributed by three to six teeth per magnetic pole, but the magnetic flux is concentrated in the teeth in the front in the circumferential direction. Therefore, the magnetic flux does not flow evenly in the three to six teeth. In this case, the magnetic flux concentrates on some of the teeth (for example, one or two), while the teeth that are magnetically saturated also move in the circumferential direction as the rotor rotates. This is also a factor in producing a slotle pill.

[0323] From the above, mouth 1\/1 is 5

To eliminate magnetic saturation in a slotless rotating electric machine, which has the following problem, we would like to eliminate teeth. However, when the teeth are abolished, the magnetic resistance of the magnetic circuit in the rotor and the stator increases, and the torque of the rotating electric machine decreases. The reason for the increase in magnetic resistance is, for example, that the air gap between the rotor and the stator becomes large. Therefore, the above-mentioned mouth 1\/1 is 5

In the above-mentioned slotless rotating electrical machine

, There is room for improvement in increasing torque. Therefore, as mentioned above

There is a great advantage in applying the above-mentioned configuration capable of increasing the torque to the slotless rotating electric machine described above.

[0324] Not only for the rotating electric machine having the outer rotor structure but also for the rotating electric machine having the inner rotor structure, the distance between the surface of the magnet unit on the armature side in the radial direction and the axial center of the rotor in the radial direction.

[0325] In the stator winding 5 1 of the rotating electric machine 10, the linear portion 8 3 of the conducting wire 8 2 may be provided in a single layer in the radial direction. Further, when the straight line portion 83 is arranged in a plurality of layers inside and outside in the radial direction, the number of layers may be arbitrary, and may be three layers, four layers, five layers, six layers or the like.

[0326] For example, in the configuration of Fig. 2, the rotary shaft 11 is provided so as to project in both the one end side and the other end side of the rotary electric machine 10 in the axial direction. However, this is changed to only one end side. It may be configured to project. In this case, the rotary shaft 11 should be installed so as to extend outward in the axial direction with the end supported by the bearing unit 20 as a cantilever. 〇 2020/175 222 89 卩(: 170? 2020/006141

It is good to be. In this configuration, since the rotary shaft 11 does not project inside the inverter unit 60, the internal space of the inverter unit 60, more specifically, the internal space of the tubular portion 71 can be used more widely. Becomes

[0327] In the rotating electric machine 10 having the above configuration, the bearings 2 1 and 2 2 use the non-conductive grease, but this is changed and the bearings 2 1 and 2 2 use the conductive grease. May be For example, the conductive grease containing metal particles and carbon particles is used.

[0328] As a configuration for rotatably supporting the rotating shaft 11, bearings may be provided at two force locations on the axially one end side and the other end side of the rotor 40. In this case, in terms of the configuration of FIG. 1, bearings may be provided at two power points on one end side and the other end side with the inverter unit 60 interposed therebetween.

[0329] In the rotary electric machine 1 0 having the above structure, but between 4 5 within the magnet holder 4 1 In the rotor 4 0 is configured to have an outer shoulder 4 9 spoon interior shoulder 4 9 ₃ and emotions, These shoulders 4 9

It is also possible to eliminate the gap and to have a flat surface.

[0330] In the rotating electric machine 10 configured as described above, a conductor is provided in the conductor wire 8 2 of the stator winding 5 1.

8 23 is configured as an assembly of a plurality of element wires 8 6, but this may be modified to use a rectangular conductive wire having a rectangular cross section as the conductive wire 8 2. Alternatively, a circular conductor having a circular cross section or an elliptical cross section may be used as the conductor 82.

[0331] In the rotating electric machine 10 having the above configuration, the imper unit 60 is provided inside the stator 50 in the radial direction, but instead of this, the inverter unit is provided inside the stator 50 in the radial direction. A configuration without 60 may be adopted. In this case, it is possible to set a space inside the inner region of the stator 50 in the radial direction. In addition, it is possible to place components different from the inverter unit 60 in the internal area.

[0332] The rotary electric machine 10 having the above configuration may not have the housing 30. In this case, for example, in ^_ part of the wheel and other vehicle components, rotating rotor 4 0, it may be configured such that the stator 5 0 and the like are retained. 〇 2020/175 222 90 卩(: 170? 2020/006141

[0333] (Embodiment as in-wheel motor for vehicle)

Next, an embodiment in which the rotary electric machine is provided as an in-wheel motor integrally with a vehicle wheel will be described. FIG. 45 is a perspective view showing a wheel 400 of the in-wheel motor structure and its peripheral structure, FIG. 46 is a longitudinal sectional view of the wheel 400 and its peripheral structure, and FIG. 4 is an exploded perspective view of a wheel 400. FIG. Each of these figures is a perspective view of the wheel 400 as viewed from the inside of the vehicle. The in-wheel motor structure of this embodiment can be applied to various types of vehicles.For example, in the case of a vehicle having two wheels on the front and rear sides of the vehicle, the two wheels on the front side of the vehicle It is possible to apply the in-wheel motor structure of the present embodiment to the two rear wheels or the four front and rear wheels of the vehicle. However, it can be applied to a vehicle in which at least one of the front and rear of the vehicle has one wheel. The in-wheel motor is an example of application as a vehicle drive unit.

[0334] As shown in Figs. 45 to 47, the wheel 400 includes, for example, a tire 401, which is a well-known pneumatic tire, and a wheel 401 fixed to the inner circumferential side of the tire 401. 0 2 and a rotating electric machine 5 00 fixed to the inner peripheral side of the wheel 4 02. The rotating electric machine 500 has a fixed portion that is a portion that includes a stator (stator) and a rotating portion that is a portion that includes a rotor (rotor). The fixed portion is fixed to the vehicle body side and The part is fixed to the wheel 4 02, and the tire 4 01 and the wheel 4 02 rotate due to the rotation of the rotating part. The detailed structure of the rotary electric machine 500 including the fixed portion and the rotating portion will be described later.

[0335] Further, the wheel 400 includes, as peripheral devices, a suspension device for holding the wheel 400 on a vehicle body (not shown), a steering device for changing the direction of the wheel 400, and a wheel. A brake device for braking 400 is installed.

[0336] The suspension device is an independent suspension type suspension, and any type such as a trailing arm type, a strut type, a wishbone type, or a multi-link type can be applied. In this embodiment, as the suspension device, the lower arm 4 11 is provided so as to extend toward the center of the vehicle body, and 〇 2020/175 222 91 卩(: 170? 2020/006141

A suspension arm 4 1 2 and a spring 4 1 3 are provided so as to extend downward. The suspension arm 4 1 2 may be configured as a shock absorber, for example. However, its detailed illustration is omitted. The lower arm 4 11 and the suspension arm 4 12 are both connected to the vehicle body side and also connected to a disk-shaped base plate 4 05 fixed to a fixed portion of the rotating electric machine 500. As shown in Fig. 46, on the rotary electric machine 500 side (base plate 450 side), the lower arm 4 11 and the suspension arm 4 1 2 are coaxial with each other by the support shafts 4 1 4 and 4 1 5. Supported by.

[0337] Further, as the steering device, for example, a rack & pinion type structure, a ball & nut type structure, a hydraulic power steering system, or an electric power steering system can be applied. In the present embodiment, a rack device 4 2 1 and a tie rod 4 2 2 are provided as steering devices, and the rack device 4 21 is mounted on the rotary electric machine 5 00 side via the tie rod 4 2 2. Connected to plate 405. In this case, when the rack device 4 2 1 is operated in accordance with the rotation of the steering shaft (not shown), the tie rod 4 2 2 moves to the left and right of the vehicle. As a result, the wheel 400 rotates about the support shafts 4 1 4 and 4 15 of the lower arm 4 11 and the suspension arm 4 12 and the wheel direction is changed.

[0338] As the brake device, it is preferable to apply a disc brake or a drum brake. In the present embodiment, as a braking device, a disk rotor 431 fixed to a rotary shaft 5001 of a rotating electric machine 500 and a brake caliper fixed to a base plate 405 on the rotating electric machine 500 side. 4 3 2 and are provided. In the brake caliber 4 32, the brake pad is actuated by hydraulic pressure, etc., and the brake pad is pressed against the disc rotor 4 31 to generate a braking force due to friction, thereby causing the wheel 4 0 2. The rotation of 0 is stopped.

[0339] Further, the wheel 400 is provided with a housing duct 440 for housing the electric wiring !I 1 and the cooling pipe !2 extending from the rotary electric machine 500. The accommodating duct 440 extends from the end of the rotating electric machine 500 on the fixed portion side to the end surface of the rotating electric machine 500. 〇 2020/175 222 92 卩 (: 170? 2020 /006141

It is extended so as to avoid the suspension arm 41, and is fixed to the suspension arm 41 in that state. As a result, the connection position of the accommodating duct 440 in the suspension arm 412 is fixed in the positional relationship with the base plate 405. Therefore, it is possible to suppress the stress caused by the vibration of the vehicle in the electric wiring !I 1 and the cooling pipe !2. The electric wiring! I 1 is connected to an on-vehicle power supply unit and an on-vehicle MII II which are not shown, and the cooling pipe! I 2 is connected to a radiator which is not shown.

[0340] Next, the configuration of the rotary electric machine 500 used as an in-wheel motor will be described in detail. In this embodiment, an example in which the rotary electric machine 500 is applied to an in-wheel motor is shown. The rotary electric machine 500 has excellent operating efficiency and output as compared with a motor of a vehicle drive unit having a speed reducer as in the related art. In other words, if the rotary electric machine 500 is used in applications where it is possible to achieve a practical price by reducing costs compared to the conventional technology, it may be used as a motor for applications other than vehicle drive units. Even in such a case, the same excellent performance as when applied to the in-wheel mode is exhibited. The operating efficiency refers to the index used during the test in the driving mode that derives the fuel consumption of the vehicle.

[0341] An outline of the rotating electric machine 500 is shown in Figures 48 to 51. Fig. 48 shows the rotary electric machine 50

Fig. 4 is a side view of 0 viewed from the protruding side (inside of the vehicle) of the rotating shaft 501, and Fig. 49 is a vertical cross-sectional view of the rotating electric machine 550 (cross-sectional view taken along line 4 9-4 9 in Fig. 48). FIG. 50 is a cross-sectional view of the rotary electric machine 500 (cross-sectional view taken along line 50-50 in FIG. 49), and FIG. 51 is an exploded view of the components of the rotary electric machine 500. It is an exploded sectional view. In the following description, the direction of the rotary shaft 50 1 extending in the outer direction of the vehicle body is the axial direction in FIG. 51, and the direction extending radially from the rotary shaft 50 1 is the radial direction. The center of the axis of rotation 5 0 1, in other words, the center of rotation of the rotating part, is drawn on the center line drawn to make the cross-section 4 9 passing through, and from any point other than the center of rotation of the rotating part Each of the two extending directions is the circumferential direction. In other words, the circumferential direction may be either a clockwise direction starting from an arbitrary point on the cross section 49 or a counterclockwise direction. In addition, the 〇 2020/175 222 93 卩(: 170? 2020/006141

Then, in FIG. 49, the right side is the vehicle outside and the left side is the vehicle inside. In other words, from the state of being mounted on the vehicle, the rotor 510 described later is arranged more to the outside of the vehicle body than the rotor force bar_670.

[0342] The rotary electric machine 500 according to this embodiment is an outer rotor type surface magnet type rotary electric machine. The rotating electric machine 500 is roughly divided into a rotor 510, a stator 520, an inverter unit 5300, a bearing 560, and a rotor cover 670. Each of these members is coaxially arranged with respect to a rotating shaft 501, which is integrally provided in the rotor 5100, and is assembled in a predetermined order in the axial direction to form the rotating electric machine 500. There is.

[0343] In the rotating electric machine 500, the rotor 510 and the stator 520 each have a cylindrical shape, and are arranged to face each other with an air gap therebetween. The rotor 5 10 rotates integrally with the rotating shaft 5 0 1, so that the rotor 5 10 rotates on the radially outer side of the stator 5 20. The rotor 5 1 0 corresponds to the "field element" and the stator 5 2 0 corresponds to the "armature".

[0344] The rotor 5110 has a substantially cylindrical rotor carrier 511 and an annular magnet unit 512 fixed to the rotor carrier 511. The rotating shaft 5 0 1 is fixed to the rotor carrier 5 1 1.

[0345] The rotor carrier 5 11 has a cylindrical portion 5 13. A magnet unit 5 12 is fixed to the inner peripheral surface of the cylindrical portion 5 13. That is, the magnet unit 5 12 is provided so as to be surrounded by the cylindrical portion 5 13 of the rotor carrier 5 11 from the outside in the radial direction. Further, the cylindrical portion 5 13 has a first end and a second end that face each other in the axial direction. The first end is located outside the vehicle body and the second end is located in the direction in which the base plate 405 exists. In the rotor carrier 511, an end plate 514 is continuously provided at the first end of the cylindrical portion 513. That is, the cylindrical portion 5 13 and the end plate 5 14 are integrated. The second end of the cylindrical portion 5 13 is open. The rotor carrier 5 11 is, for example, a cold-rolled steel plate with sufficient mechanical strength (thickness 3 1 ^to 10 thicker than 3 0 0 or 3 0 0 0, forging steel, carbon fiber reinforced plastic).

It is formed by. 〇 2020/175 222 94 卩 (: 170? 2020 /006141

[0346] The axial length of the rotary shaft 5 01 is longer than the axial dimension of the rotor carrier 5 11. In other words, the rotary shaft 50 1 projects toward the open end side (inward direction of the vehicle) of the rotor carrier 5 11 and the above-mentioned brake device etc. can be attached to the projecting end. There is.

[0347] A through hole 5 1 4 ₃ is formed in the center of the end plate 5 1 4 of the rotor carrier 5 1 1. The rotating shaft 5 01 is fixed to the rotor carrier 5 1 1 in a state of being passed through the through hole 5 1 4 3 of the end plate 5 1 4. The rotating shaft 5 01 has a flange 5 0 2 extending in a direction intersecting (orthogonal to) the axial direction at a portion where the rotor carrier 5 11 is fixed, and the flange and the end plate 5 1 4 The rotary shaft 5 0 1 is fixed to the rotor carrier 5 1 1 in a state where the outer surface of the vehicle is surface-joined. In addition, in the wheel 400, the wheel 400 is fixed by using a fastener such as a bolt erected from the flange 502 of the rotary shaft 501 in the vehicle outer direction.

[0348] Further, the magnet unit 5 12 is composed of a plurality of permanent magnets arranged such that the polarities thereof alternate along the circumferential direction of the rotor 5 10. As a result, the magnet unit 5 12 has a plurality of magnetic poles in the circumferential direction. The permanent magnet is fixed to the rotor carrier 5 1 1, for example by gluing. The magnet unit 5 1 12 has the configuration described as the magnet unit 4 2 in FIGS. 8 and 9 of the first embodiment. As a permanent magnet, the intrinsic coercive force is 4 0 0 [1<8/ ] And the residual magnetic flux density "[1.0] or more, the sintered neodymium magnet is used.

[0349] The magnet unit 5 1 2 is a polar anisotropic magnet and has a first magnet 9 1 and a second magnet 9 2 having different polarities, like the magnet unit 4 2 in FIG. doing. As explained in Fig. 8 and Fig. 9, the magnets 9 1 and 9 2 each have an easy magnetization axis on the ¢1 axis side (the part near the 0 axis) and the 9 axis side (the part near the axis). On the axis side, the direction of the easy axis of magnetization is close to the direction parallel to the axis, and on the side of the axis, the direction of the easy axis of magnetization is close to the direction orthogonal to the axis. Then, by the orientation according to the direction of this easy axis of magnetization, an arc is formed. 〇 2020/175 222 95 卩(: 170? 2020/006141

A magnet-shaped magnetic path is formed. In addition, in each magnet 91, 92, the easy axis may be oriented parallel to the axis on the axis side, and the easy axis may be oriented directly on the 9 axis side. In short, the magnet unit 5 12 is configured such that the direction of the easy magnetization axis is parallel to the axis, which is the magnetic pole center, compared to the axis, which is the magnetic pole boundary. Has been done.

[0350] According to each of the magnets 9 1 and 9 2, the magnetic flux of the magnet on the axis is strengthened and the change of the magnetic flux near the axis is suppressed. As a result, the magnets 9 1 and 9 2 in which the surface magnetic flux changes gently from axis to axis in each magnetic pole can be suitably realized. As the magnet unit 5 12 it is also possible to use the structure of the magnet unit 4 2 shown in FIGS. 22 and 23 or the structure of the magnet unit 4 2 shown in FIG.

[0351] Note that the magnet unit 5 12 is a rotating unit formed by axially laminating a plurality of electromagnetic steel plates on the side of the cylindrical portion 5 13 of the rotor carrier 5 11; that is, on the outer peripheral surface side. It may have a child core (back yoke). That is, the rotor core is provided on the radially inner side of the cylindrical portion 5 13 of the rotor carrier 5 11 and the permanent magnets (magnets 9 1 and 9 2) are provided on the radially inner side of the rotor core. It is also possible.

As shown in FIG. 47, the cylindrical portion 5 13 of the rotor carrier 5 11 is provided with recesses 5 1 3 3 at predetermined intervals in the circumferential direction and extending in the axial direction. .. The concave portion 5 1 3 3 is formed by, for example, press working, and as shown in FIG. 52, the inner peripheral surface side of the cylindrical portion 5 1 3 has a convex portion at the back side of the concave portion 5 1 3 3. Portion 5 1 3 has been formed. On the other hand, a concave portion 5 1 2 3 is formed on the outer peripheral surface side of the magnet unit 5 1 2 so as to match the convex portion 5 1 3 of the cylindrical portion 5 1 3 and is formed in the concave portion 5 1 2 3. When the convex portion 5 13 of the cylindrical portion 5 13 enters, the positional displacement of the magnet unit 5 12 in the circumferential direction is suppressed. That is, the convex portion 5 13 on the side of the rotator carrier 5 11 functions as a detent portion for the magnet unit 5 12. The method for forming the convex portion 5 13 sack may be any method other than press working. 〇 2020/175 222 96 卩(: 170? 2020/006141

[0353] In Fig. 52, the direction of the magnet magnetic path in the magnet unit 5 12 is indicated by an arrow. The magnet magnetic path extends in an arc shape so as to straddle the axis that is the magnetic pole boundary, and the 0 axis, which is the center of the magnetic pole, is oriented parallel or nearly parallel to the axis. The magnet unit 5 12 is provided with recesses 5 12 on its inner peripheral surface side at each position corresponding to the axis. In this case, in the magnet unit 5 1 2, the length of the magnetic path differs between the side closer to the stator 5 20 (lower side in the figure) and the side farther (upper side in the figure). The magnet magnetic path length is shorter on the closer side, and a concave portion 5 1 2 is formed at a position where the magnet magnetic path length is the shortest. In other words, considering that it is difficult for the magnet unit 5 1 2 to generate a sufficient magnetic flux in the place where the magnetic path length is short, the magnet should be deleted in the place where the magnetic flux is weak. There is.

[0354] Here, the effective magnetic flux density value of the magnet increases as the length of the magnetic circuit passing through the interior of the magnet increases. Moreover, the permeance coefficient ◯ and the effective magnetic flux density of the magnet are in a relationship that when one of them becomes higher, the other becomes higher. According to the configuration of FIG. 52, it is possible to reduce the amount of magnets while suppressing a decrease in the permeance coefficient ◯, which is an index of the height of the effective magnetic flux density of the magnet. In the 1st ^to 1st coordinates, the operating point is the intersection of the demagnetization curve and the permeance line corresponding to the shape of the magnet, and the magnetic flux density at that operating point is the effective magnetic flux density of the magnet. The rotary electric machine 500 of the present embodiment has a configuration in which the amount of iron in the stator 520 is reduced, and in such a configuration, the method of setting the magnetic circuit across the axes is extremely effective.

[0355] Further, the concave portion 512 of the magnet unit 512 can be used as an air passage extending in the axial direction. Therefore, it is possible to improve the air cooling performance.

[0356] Next, the configuration of the stator 520 will be described. The stator 5 2 0 is the stator winding 5 2

1 and a stator core 5 22. FIG. 53 is an exploded perspective view of the stator winding 5 21 and the stator core 5 22.

[0357] The stator winding 5 2 1 is composed of a plurality of phase windings that are wound in a substantially tubular shape (annular shape), and is fixed as a base member inside the stator winding 5 2 1 in the radial direction. Child core 〇 2020/175 222 97 卩(: 170? 2020/006141

5 2 2 is assembled. In the present embodiment, the stator winding 5 21 is configured as a three-phase phase winding by using phase windings of II phase, V phase, and phase. Each winding wire is composed of inner and outer two-layer conductors 5 2 3 in the radial direction. The stator 52 0 is characterized by having a slotless structure and a flat conductor structure of the stator winding 5 21 as in the case of the above-mentioned stator 50, and is shown in Figs. 8 to 16. The stator 50 has the same or similar structure as the stator 50.

[0358] The structure of the stator core 52 2 will be described. The stator core 52 2 has a cylindrical shape in which a plurality of magnetic steel sheets are laminated in the axial direction and has a predetermined thickness in the radial direction, like the stator core 52 described above. The stator winding 5 21 is assembled on the outer side of the core 5 22 on the rotor 5 10 side in the radial direction. The outer peripheral surface of the stator core 5 2 2 has a curved surface without unevenness, and when the stator winding 5 2 1 is assembled, the outer surface of the stator core 5 2 2 is Conductive wires 5 2 3 forming 2 1 are arranged side by side in the circumferential direction. The stator core 5 22 functions as a back core.

[0359] The stator 520 may use any one of the following (8) to (○).

(8) In the stator 520, an inter-conductor wire member is provided between each conductor 523 in the circumferential direction, and as the inter-conductor member, the circumferential width dimension of the inter-conductor member in one magnetic pole is I, When the saturation magnetic flux density of the inter-conductor member is defined as 3, the circumferential width of the magnet unit 5 1 2 in one magnetic pole is defined as \ZV rn, and the residual magnetic flux density of the magnet unit 5 1 2 is defined as X

We use magnetic materials that are related to "Minami".

(Mitsumi) In the stator 520, an inter-conductor wire member is provided between each conductor 523 in the circumferential direction, and a non-magnetic material is used as the inter-conductor member.

(◯) In the stator 520, no inter-conductor material is provided between each conductor 523 in the circumferential direction.

[0360] According to such a structure of the stator 520, a general tee provided with teeth (iron core) for establishing a magnetic path between the conductor wire portions as the stator windings. 〇 2020/175 222 98 卩 (: 170? 2020 /006141

Inductance is reduced compared to a rotary electric machine with a space structure. Specifically, it is possible to reduce the inductance to 1/10 or less. In this case, since the impedance decreases as the inductance decreases, it is possible to increase the output power with respect to the input power in the rotary electric machine 500 and thus contribute to the torque increase. Further, it is possible to provide a rotating electric machine with a large output as compared with a rotating electric machine using an embedded magnet type rotor that outputs torque using the voltage of the impedance component (in other words, uses reluctance torque). Has become.

[0361] In the present embodiment, the stator winding 5 2 1, resin or Ranaru molding material with the stator core 5 2 2 are molded ^_ body by (insulating member), each conductor arranged in the circumferential direction A molding material is interposed between the 5 2 3 and the 5 3 2 3 According to this configuration, the stator 520 of this embodiment corresponds to the configurations of (8) to (○) (Mitsumi) described above. The end faces in the circumferential direction are in contact with each other, or are arranged close to each other with a minute gap therebetween, and in view of this configuration, the configuration of (0) above may be adopted. When adopting the configuration, the outer circumference of the stator core 5 2 2 is adjusted according to the direction of the conductor wire 5 2 3 in the axial direction, that is, in the case of the stator winding 5 2 1 of the skew structure, for example, according to the skew angle. The surface may be provided with a protrusion.

[0362] Next, the configuration of the stator winding 5 21 will be described with reference to FIG. Fig. 5 4 is a front view showing the stator winding 5 2 1 in a flat state, and Fig. 5 4 (a) shows the conductors 5 2 3 located in the outer layer in the radial direction. In Fig. 4(b), the conductors 5 23 located in the inner layer in the radial direction are shown.

[0363] The stator winding 5 2 1 is formed in a ring shape by distributed winding. In the stator winding 5 21, the conductor wire is wound in two layers inside and outside in the radial direction, and the conductors 5 2 3 on the inner and outer layers are skewed in different directions (Fig. 5 4 ( ₃ ), see Figure 54 (b)). The conductors 5 2 3 are insulated from each other. The conducting wire 5 23 is preferably configured as an assembly of a plurality of element wires 8 6 (see Fig. 13). In addition, the conductors 5 2 3 〇 2020/175 222 99 卩(: 170? 2020/006141

, For example, two are provided side by side in the circumferential direction. In the stator winding 5 21, two conductors in the radial direction and 2 conductors in the circumferential direction (that is, a total of 4 conductors) constitute one conductor part of the same phase, and each conductor part has one magnetic pole. There is one inside each.

[0364] In the conductor portion, the radial thickness dimension is set to be smaller than the circumferential width dimension for one phase in one magnetic pole, whereby the stator winding 5 2 1 is formed into a flat conductor structure. It is desirable to do. Specifically, for example, in the stator winding 5 2 1, if two conductors in the radial direction and 4 conductors in the circumferential direction (that is, 8 conductors in total) 5 2 3 constitute one conductor part of the same phase. Good. Alternatively, in the conductor wire cross section of the stator winding 5 21 shown in FIG. 50, the width dimension in the circumferential direction may be larger than the thickness dimension in the radial direction. It is also possible to use the stator winding 5 1 shown in Fig. 12 as the stator winding 5 21. However, in this case, it is necessary to secure a space for housing the coil end of the stator winding in the rotor carrier 5 11.

[0365] In the stator winding 5 21, the conductors 5 2 3 are arranged side by side in the circumferential direction by inclining at a predetermined angle in the coil side 5 2 5 that overlaps with the stator core 5 2 2 in the radial direction. At the same time, the coil ends 526 on both sides, which are axially outside of the stator core 52, are turned inward (folded) inward in the axial direction to form a continuous wire connection. Figure 5 4 (a) shows the range of coil side 5 25 and the range of coil end 5 26, respectively. The inner layer side conductor 5 2 3 and the outer layer side conductor 5 2 3 are connected to each other at the coil end 5 2 6 so that the coil end 5 2 6 reverses the conductor 5 2 3 in the axial direction. Each time it is turned (turned back), the conducting wire 52 3 alternates between the inner layer side and the outer layer side. In short, the stator winding 5 21 has a structure in which the inner and outer layers are switched in accordance with the reversal of the direction of the current in each of the conducting wires 5 23 that are continuous in the circumferential direction.

[0366] Further, the stator winding 5 21 is provided with two types of skews having different skew angles in the end regions at both ends in the axial direction and the central region sandwiched by the end regions. .. That is, as shown in FIG. 〇 2020/175222 100 units (: 170? 2020/006141

The skew angle 0 3 1 is different from the skew angle 0 3 2 in the end region, and the skew angle 0 3 1 is smaller than the skew angle 0 3 2. In the axial direction, the end region is defined in the range including the coil side 5 25. The skew angle 0 3 1 and the skew angle 0 3 2 are the tilt angles at which the conductors 5 23 are tilted with respect to the axial direction. The skew angle 0 3 1 in the central region is preferably set within an appropriate angle range for reducing the harmonic components of the magnetic flux generated by the energization of the stator winding 5 21.

[0367] The skew angle of each conductor 5 2 3 in the stator winding 5 2 1 is made different between the central region and the end region, and the skew angle 0 3 1 in the central region is 0 3 2 in the end region. By making it smaller than this, it is possible to increase the winding line coefficient of the stator winding 5 21 while reducing the coil end 5 26. In other words, it is possible to shorten the length of the coil end 5 26, that is, the length of the conductor wire extending axially from the stator core 5 22 while securing a desired winding coefficient. This makes it possible to improve the torque while reducing the size of the rotary electric machine 500.

[0368] Here, an appropriate range for the skew angle 031 of the central region will be described. When X conductors 5 2 3 are arranged in one magnetic pole in the stator winding 5 2 1, it is considered that the Xth harmonic component is generated by the energization of the stator winding 5 21. .. If the number of phases is 3 and the logarithm is 111, then = 2 3 111. Since the X-order harmonic component is a component that forms a composite wave of the X— 1st-order harmonic component and the + 1st-order harmonic component, the present disclosure discloses that the X— 1st-order harmonic component We also focused on the fact that the X-th harmonic component can be reduced by reducing at least one of the + 1st-order harmonic component. In light of this focus, the present applicant sets the skew angle 0 3 1 within the angle range of “360 ^° /(乂+1) to 360 ^° /(乂1 1)” in electrical angle. It was found that the X-order harmonic component can be reduced by.

[0369] For example, if 3 = 3 and = 2, then = 1 In order to reduce the 2nd order harmonic component, within the angle range of "3 6 0 ° / 1 3 ~ 3 6 0 ° / 1 1" Skew angle 0 3 1 〇 2020/175 222 101 卩(: 170? 2020/006141

To set. In other words, the skew angle 031 should be set within the range of 27.7° to 32.7°.

[0370] By setting the skew angle 0 3 1 in the central area as described above, it is possible to positively interlink three alternating magnetic fluxes in the central area. It is possible to increase the coefficient of roll line of 1.

[0371] The skew angle 0 3 2 in the end area is equal to the skew angle 0 3 in the central area described above.

The angle is greater than 1. In this case, the angle range of the skew angle 0 32 is “0 3 1 <0 3 2 <90 0 ”.

[0372] In addition, in the stator winding 5 2 1, the inner layer 5 2 3 and the outer layer 5 5

23 is preferably welded or bonded to each other at the ends of the respective conductors 5 23, or bent by bending. In the stator winding 5 21, one end of each coil end 5 2 6 on both sides in the axial direction (that is, one end side in the axial direction) has the end of each winding wire connected to a power converter (imperator) or a bus bar. It is configured to be electrically connected via. Therefore, here, a configuration will be described in which the conductors are connected to each other in the coil end 5 26 while distinguishing between the coil end 5 26 on the bus bar connection side and the coil end 5 26 on the opposite side.

[0373] As a first configuration, each wire 5 23 is welded at the coil end 5 2 6 on the bus bar connection side, and each wire 5 2 6 is provided at the coil end 5 2 6 on the opposite side. 2 3 is constructed by a method other than welding. The means other than welding may be, for example, bending by bending the conductor wire. At the coil end 526 on the bus bar connection side, it is assumed that the bus bar will be welded to the end of each phase line. Therefore, by configuring each wire 5 23 to be welded at the same coil end 5 26, each weld can be performed in a series of steps, improving work efficiency. You can

[0374] As a second configuration, in the coil end 5 2 6 on the bus bar connection side, each conductor 5 2 3 is connected by means other than welding, and at the opposite coil end 5 2 6 each conductor is connected. 5 2 3 is constructed by welding. In this case, tentatively weld each conductor 5 2 3 at the coil end 5 2 6 on the bus bar connection side. 〇 2020/175 222 102 卩(: 170? 2020/006141

With this configuration, it is necessary to ensure a sufficient separation distance between the bus bar and the coil end 5 26 in order to avoid contact between the welded part and the bus bar.However, with this configuration, the bus bar and coil It is possible to reduce the separation distance from the end 5 26. As a result, it is possible to loosen the restriction on the length of the stator winding 5 21 in the axial direction and/or the crossbar.

[0375] In the third configuration, the coil ends 5 2 6 on both sides in the axial direction are connected to each conductor 5

2 and 3 are welded together. In this case, the conductor wire prepared before welding may have a short wire length, and the work efficiency can be improved by reducing the bending process.

[0376] As the fourth configuration, the coil ends 5 2 6 on both sides in the axial direction are connected to each conductor 5

2 3 is constructed by a method other than welding. In this case, the portion of the stator winding 5 21 where welding is performed can be reduced as much as possible, and it is possible to reduce the concern that insulation separation will occur in the welding process.

[0377] Also, in the process of manufacturing the annular stator winding 5 21, it is preferable to manufacture a band-shaped winding arranged in a plane and then form the band-shaped winding into a ring. In this case, it is advisable to weld the conductor wires at the coil ends 52 6 as needed in the state of the flat band-shaped winding wire. When forming a flat strip winding into an annular shape, use a cylindrical jig having the same diameter as the stator core 52 to wind the strip winding into an annular shape. Good. Alternatively, the strip winding may be directly wound around the stator core 52 2.

[0378] Note that the configuration of the stator winding 5 21 can be changed as follows.

[0379] For example, in the stator winding 5 21 shown in Figs. 54(a) and 5(c), the skew angles in the central region and the end regions may be the same.

[0380] In addition, in the stator winding 5 2 1 shown in Figs. It may be configured to be connected by a crossover portion extending to.

[0381] The number of layers of the stator winding 5 2 1 may be any 2 c _n layer _(n is a natural number), the fixed 〇 2020/175 222 103 卩 (: 170? 2020 /006141

It is also possible to make the winding line 5 2 1 into 4 layers, 6 layers, etc. in addition to 2 layers.

[0382] Next, the inverter unit 5300, which is a power conversion unit, will be described. Here, the configuration of the inverter unit 5300 will be described with reference to FIGS. 56 and 57, which are exploded cross-sectional views of the inverter unit 5300. In FIG. 57, each member shown in FIG. 56 is shown as two subassemblies.

[0383] The inverter unit 530 electrically connects the inverter housing 531, the plurality of electrical modules 532 assembled in the inverter housing 531, and each of the electrical modules 532. It has a busbar module 5 3 3.

[0384] The inverter housing 5 3 1 has a cylindrical outer wall member 5 4 1 and a cylindrical shape having an outer peripheral diameter smaller than that of the outer wall member 5 4 1, and is arranged radially inward of the outer wall member 5 4 1. Inner wall member 5 42 and a boss forming member 5 4 3 fixed to one end side in the axial direction of the inner wall member 5 4 2. Each of these members 5 41 to 5 4 3 is preferably made of a conductive material, for example, carbon fiber reinforced plastic (. The inverter housing 5 3 1 and the outer wall member 5 4 1 The inner wall member 5 4 2 and the inner wall member 5 4 2 are overlapped with each other in the radial direction, and the boss forming member 5 4 3 is attached to one end side of the inner wall member 5 4 2 in the axial direction. The state is shown in FIG.

[0385] The stator core 5 2 2 is fixed to the outer side of the outer wall member 5 4 1 of the inverter housing 5 3 1 in the radial direction. As a result, the stator 520 and the inverter unit 530 are integrated.

[0386] As shown in FIG. 56, the outer wall member 541 has a plurality of recesses 541 on its inner peripheral surface.

1 3 ,5 4 1 13 ,5 4 1 ○ is formed, and the inner wall member 5 4 2 has a plurality of recesses 5 4 2 on its outer peripheral surface.

5 4 2 6 and 5 4 2 0 are formed. The outer wall member 5 4 1 and the inner wall member 5 4 2 are assembled to each other so that there is a space between them.

5 4 4 13 and 5 4 4 0 are formed (see Fig. 5 7). Of these, the central hollow portion 5454 is used as a cooling water passage 5445 through which cooling water as a refrigerant flows. Also, the hollow part 〇 2020/175 222 104 卩 (: 170? 2020 /006141

Hollow part on both sides with 5 4 4 sqm (cooling water passage 5 4 5) in between

Sealing material 5 46 is contained in 544. This sealing material 5 4 6 allows the hollow part 5

The spillway (cooling water passage 5 445) is sealed. The cooling water passage 5 4 5 will be described in detail later.

[0387] Further, the boss forming member 543 includes a disc ring-shaped end plate 547 and the end plate.

Bosses 5 48 protruding from 5 47 toward the inside of the housing are provided. The bosses 548 are provided in the shape of a hollow cylinder. For example, as shown in Fig. 51, the boss forming member 543 is arranged such that the first end of the inner wall member 542 in the axial direction and the second end on the protruding side (that is, the vehicle inner side) of the rotating shaft 5011 facing it. It is fixed at the second end of the ends. In addition, in the wheel 400 shown in FIGS. 45 to 47, the inverter housing 531 (more specifically, the end plate of the boss forming member 543)

The base plate 405 is fixed to the base plate 405.

[0388] The inverter housing 5 3 1 is configured to have a double peripheral wall in the radial direction about the axis, and the outer peripheral wall of the double peripheral wall is the outer wall member 5 4 1 and the inner wall member 5 1. 42, and the inner peripheral wall is formed by the boss portion 5 48. In the following description, the outer peripheral wall formed by the outer wall member 5 4 1 and the inner wall member 5 4 2 is referred to as “outer peripheral wall \ZV A 1 ”, and the inner peripheral wall formed by the boss portion 5 4 8 is referred to as “ Inner peripheral wall \ZV A 2".

[0389] In the inverter housing 531, an annular space is formed between the outer peripheral wall 81 and the inner peripheral wall 82, and a plurality of electric modules 532 are arranged in the annular space in the circumferential direction. It is arranged. The electric module 5 3 2 is fixed to the inner peripheral surface of the inner wall member 5 4 2 by gluing, screwing or the like. In the present embodiment, the inverter housing 5 3 1 corresponds to the “housing member” and the electric module 5 3 2 corresponds to the “electric component”.

[0390] A bearing 560 is housed inside the inner peripheral wall \ZV A 2 (boss 548), and the bearing 560 rotatably supports the rotary shaft 501. Bearing 5

Reference numeral 60 denotes a hub bearing which rotatably supports the wheel 400 at the center of the wheel. The bearing 560 is composed of a rotor 520, a stator 520, and an inverter unit. 〇 2020/175 222 105 卩(: 170? 2020/006141

It is provided at a position overlapping axially with respect to 5 30. In the rotating electric machine 500 of this embodiment, it is possible to reduce the thickness of the magnet unit 5 12 in the rotor 5 10 according to the orientation, and the stator 5 20 has a slotless structure or a flat conductor structure. By adopting this, it is possible to reduce the radial thickness of the magnetic circuit part and expand the hollow space inside the magnetic circuit part in the radial direction. This makes it possible to arrange the magnetic circuit part, the inserter unit 530, and the bearing 560 in a laminated state in the radial direction. The boss portion 548 is a bearing holding portion that holds the bearing 560 inside thereof.

[0391] The bearing 5600 is, for example, a radial ball bearing, and has a cylindrical inner ring 561 and a cylindrical shape having a diameter larger than that of the inner ring 561 and is arranged radially outside of the inner ring 561. And an outer ring 5 62 and a plurality of balls 5 63 arranged between the inner ring 5 61 and the outer ring 5 62. The bearing 5 6 0 is fixed to the inverter housing 5 3 1 by assembling the outer ring 5 6 2 to the boss forming member 5 4 3 and the inner ring 5 6 1 is fixed to the rotating shaft 5 0 1. These inner ring 5 6 1, outer ring 5

Both 6 2 and balls 5 6 3 are made of a metal material such as carbon steel.

[0392] In addition, the inner ring 561 of the bearing 5600 includes a tubular portion 561-3 for accommodating the rotating shaft 501, and an axial crossing from one axial end of the tubular portion 561. It has a flange 5 6 1 swath extending in the (orthogonal) direction. The flange 5 61 is a part that comes into contact with the end plate 5 14 of the rotor carrier 5 11 from the inside, and when the bearing 5 6 0 is assembled to the rotating shaft 5 01, the rotating shaft 5 0 1 The rotor carrier 5 1 1 is held by being sandwiched between the flange 5 0 1 of 1 and the flange 5 6 1 of the inner ring 5 61. In this case, the flanges 50 2 of the rotating shaft 50 1 and the flanges 5 61 of the inner ring 5 61 have the same angle of intersection with the axial direction (both are right angles in this embodiment), The rotor carrier 5 11 is held in a state of being sandwiched between these flanges 50 2 and 5 61.

[0393] According to the structure in which the inner ring 561 of the bearing 5600 supports the rotor carrier 511 from the inside, the angle of the rotor carrier 511 with respect to the rotation axis 501 is set to an appropriate angle. 〇 2020/175 222 106 卩(: 170? 2020/006141

Therefore, the parallelism of the magnet unit 5 1 2 with respect to the rotating shaft 5 0 1 can be kept good. As a result, even in the configuration in which the rotor carrier 5 11 is expanded in the radial direction, it is possible to enhance resistance to vibration and the like.

[0394] Next, the electrical module 5 3 2 housed in the inverter housing 5 3 1 will be described.

[0395] The plurality of electric modules 532 is a module in which electric components such as a semiconductor switching element and a smoothing capacitor that compose the power converter are divided into a plurality of modules and are individually modularized. 532 includes a switch module 532 having a semiconductor switching element which is a power element, and a capacitor module 532 having a smoothing capacitor.

[0396] As shown in Fig. 49 and Fig. 50, the inner peripheral surface of the inner wall member 5 42 is provided with a plurality of spacers 5 49 having a flat surface for mounting the electric module 5 32. Fixed and the electrical module 5 3 2 is attached to its spacer 5 4 9. In other words, the inner peripheral surface of the inner wall member 5 4 2 is a curved surface, while the mounting surface of the electric module 5 32 is a flat surface. A flat surface is formed on the surface side, and the electric module 5 32 is fixed on the flat surface.

[0397] Note that the structure in which the spacer 549 is interposed between the inner wall member 542 and the electric module 532 is not essential, and the inner peripheral surface of the inner wall member 542 is made flat. Alternatively, the electric module 5 3 2 can be directly attached to the inner wall member 5 4 2 by making the mounting surface of the electric module 5 32 a curved surface. It is also possible to fix the electric module 5 3 2 to the inverter housing 5 3 1 without contacting the inner peripheral surface of the inner wall member 5 4 2. For example, the electric module 5 32 is fixed to the end plate 5 47 of the boss forming member 5 43. The switch module 5 3 2 8 is fixed to the inner peripheral surface of the inner wall member 5 4 2 in contact with it, and the capacitor module 5 3 2 is fixed to the inner peripheral surface of the inner wall member 5 4 2 in a non-contact state. It is also possible to do so.

[0398] When the spacer 549 is provided on the inner peripheral surface of the inner wall member 542, the spacer The peripheral wall WA 1 and spacer 549 correspond to the “cylindrical part”. When the spacer 549 is not used, the outer peripheral wall WA 1 corresponds to the “cylindrical part”.

[0399] As described above, the outer peripheral wall WA1 of the inverter housing 531 is provided with the cooling water passage 5445 for circulating the cooling water as the refrigerant. The cooling water passage 5445 is allowed to flow through the cooling water passage 5445. This allows each electric module 5 32 to be cooled. It is also possible to use cooling oil instead of cooling water as the refrigerant. The cooling water passages 5 45 are annularly installed along the outer peripheral wall WA 1, and the cooling water flowing in the cooling water passages 5 4 5 flows from the upstream side to the downstream side while passing through each electric module 5 3 2. Distribute to the side. In the present embodiment, the cooling water passages 5 45 are provided in an annular shape so as to overlap the electric modules 5 32 in the radial direction and to surround the electric modules 5 32.

[0400] The inner wall member 5 4 2 has an inlet passage 5 for allowing cooling water to flow into the cooling water passage 5 4 5.

7 1 and an outlet passage 5 72 for letting the cooling water flow out from the cooling water passage 5 45 are provided. As described above, a plurality of electric modules 5 32 are fixed to the inner peripheral surface of the inner wall member 5 42, and in such a configuration, there is only one force point between the electric modules adjacent in the circumferential direction. The inner wall member 5 4 2 is further expanded, and a part of the inner wall member 5 4 2 is projected inward in the radial direction to form a protruding portion 5 7 3. The projecting portion 573 is provided with an inlet passage 571 and an outlet passage 572 in a side-by-side arrangement along the radial direction.

[0401] Fig. 58 shows the arrangement of the electric modules 532 in the inverter housing 531. Note that FIG. 58 is the same vertical cross-sectional view as FIG.

[0402] As shown in FIG. 58, each electric module 532 is arranged in the circumferential direction such that the intervals between the electric modules in the circumferential direction are the first interval NT1 or the second interval NT2. Has been done. The second interval NT 2 is wider than the first interval NT 1. The intervals NT 1 and NT 2 are, for example, the distances between the center positions of two electric modules 5 32 adjacent to each other in the circumferential direction. In this case, the interval between the electric modules adjacent to each other in the circumferential direction without sandwiching the protruding portion 573 becomes the first interval INT 1, and the electric modules adjacent to each other in the circumferential direction with the protruding portion 573 interposed therebetween are the same. The interval between the teachers is the second interval INT 2. That is, the interval between the electric modules adjacent to each other in the circumferential direction is expanded by the part ^_ , and the projecting part 5 73 is provided at the central part of the expanded interval (second interval INT 2 ), for example. ..

[0403] The intervals nt1 and nt2 are the arcs between the center positions of two electric modules 5 3 2 which are adjacent to each other in the circumferential direction on the same circle centered on the rotation axis 5 0 1. It may be a distance. Alternatively, the intervals between the electric modules in the circumferential direction may be defined by the angular intervals 0 i 1 and 0 i 2 about the rotation axis 5 0 1 (0 i 1 <0 i 2) ₀

[0404] In addition, in the configuration shown in FIG. 58, the electric modules arranged at the first interval NT1

5 3 2 are arranged so as to be separated from each other in the circumferential direction (non-contact state), but instead of this configuration, the electric modules 5 3 2 are arranged so as to be in contact with each other in the circumferential direction. Good.

[0405] As shown in FIG. 48, the end plate 547 of the boss forming member 543 is provided with an inlet passage 5

7 1 and outlet passage 5 7 2 are provided with a waterway port 5 7 4 in which the passage ends are formed. A circulation path 5 75 for circulating cooling water is connected to the inlet path 5 71 and the outlet path 5 72. The circulation route 5 7 5 consists of cooling water piping. The circulation path 5 7 5 is provided with a pump 5 7 6 and a heat dissipation device 5 7 7, and the cooling water circulates through the cooling water passage 5 4 5 and the circulation path 5 7 5 as the pump 5 7 6 is driven. Pump 5 7 6 is an electric pump. The radiator 577 is, for example, a radiator that radiates heat of cooling water to the atmosphere.

[0406] As shown in Fig. 50, the outer peripheral wall WA 1 has the stator 5 20 arranged outside and the electric module 5 3 2 arranged inside the outer peripheral wall WA 1. As a result, the heat of the stator 520 is transmitted from the outside and the heat of the electric module 532 is transmitted from the inside. In this case, it is possible to cool the stator 5 20 and the electric module 5 32 at the same time by the cooling water flowing through the cooling water passage 5 45, so that the heat generated by the heat-generating components in the rotary electric machine 500 can be efficiently cooled. Can be released well.

[0407] Here, the electrical configuration of the power converter will be described with reference to FIG. 〇 2020/175 222 109 卩(: 170? 2020/006141

[0408] As shown in Fig. 59, the stator winding 5 21 consists of a II-phase winding, a V-phase winding wire and a phase winding wire, and an inverter 600 is connected to the stator winding 5 2 1. Has been done. The inverter 600 is composed of a full bridge circuit having the same number of upper and lower arms as the number of phases, and a series connection body consisting of an upper arm switch 60 1 and a lower arm switch 60 2 is provided for each phase. There is. Each of these switches 60 1 and 60 2 is turned on/off by the drive circuit 60 3, and the winding of each phase is energized by the on/off. Each of the switches 60 1 and 60 2 is composed of a semiconductor switching element such as a 1//1 0 3 den or a den. In addition, the upper and lower arms of each phase are connected to a series connection of switches 60 1 and 60 2 in parallel, and a capacitor 6 for supplying charge that supplies the charges required for switching to each switch 60 1 and 60 2. 0 4 is connected.

[0409] The control device 600 is equipped with a microcomputer consisting of 〇II and various memories, and based on various detection information in the rotary electric machine 500 and requests for power running drive and power generation, each switch 60 Energization control is performed by turning on and off 1,600. The control device 60 7 performs on/off control of each switch 60 1 and 60 2 by, for example, \^/1\/1 control at a predetermined switching frequency (carrier frequency) or rectangular wave control. The control device 600 may be a built-in control device built in the rotary electric machine 500, or an external control device provided outside the rotary electric machine 500.

[0410] By the way, in the rotary electric machine 500 of the present embodiment, the electrical time constant is small because the inductance of the stator 520 is reduced, and the electric time constant is small. Under the circumstances, it is desirable to increase the switching frequency (carrier frequency) and increase the switching speed. At this point, the capacitor for charge supply 60 4 is connected in parallel to the series connection body of the switches 60 1 and 60 2 of each phase to reduce the wiring inductance and increase the switching speed. Even with the configuration, appropriate surge countermeasures can be taken.

[041 1] The high potential side terminal of the inverter 600 is connected to the positive terminal of the DC power source 600, and the low potential side terminal is connected to the negative terminal (ground) of the DC power source 600. 〇 2020/175 222 1 10 卩(: 170? 2020/006141

.. A smoothing capacitor 606 is connected in parallel with the DC power supply 605 to the high potential side terminal and the low potential side terminal of the inverter 600.

[0412] The switch modules 5 3 2 8 are switches 6 0 1 and 6 0 as heat generating parts.

2 (semiconductor switching element), a drive circuit 60 3 (specifically, an electric element forming the drive circuit 60 3 ), and a charge supply capacitor 60 4. Further, the capacitor module 53.2 has a smoothing capacitor 606 as a heat generating component. Figure 60 shows a concrete example of the configuration of the switch module 5 3 2 8.

[0413] As shown in Fig. 60, the switch module 5 3 2 8 has a module case 6 1 1 as a housing case, and the switch 6 0 for one phase housed in the module case 6 1 1. It has 1, 6 02, a drive circuit 6 03, and a capacitor 6 04 for supplying a charge. The drive circuit 60 3 is provided in the switch module 5 32 8 as a dedicated circuit or a circuit board.

[0414] The module case 6 1 1 is made of, for example, an insulating material such as resin, and the side surface of the module case 6 1 1 contacts the inner peripheral surface of the inner wall member 5 4 2 of the inverter unit 5 30. It is fixed. Molding material such as resin is filled in the module case 6 11. In the module case 61 1, the switches 60 1, 60 2 and the drive circuit 60 3, the switches 60 1, 60 2 and the capacitor 60 4 are electrically connected by wiring 6 12 respectively. ing. More specifically, the switch module 5 3 2 8 is attached to the outer peripheral wall 8 1 via a spacer 5 49, but the spacer 5 49 is not shown.

[0415] When the switch module 5 3 2 8 is fixed to the outer peripheral wall 81, the cooling performance is closer to the side closer to the outer peripheral wall 8 1 in the switch module 5 3 2 8 that is, the closer to the cooling water passage 5 45. Therefore, the order of arrangement of the switches 60 1, 60 2, the drive circuit 60 3 and the capacitor 60 4 is determined according to the cooling performance. Specifically, when comparing the calorific values, the order is the largest, the switches 60 1, 60 2, the capacitor 60 4, and the drive circuit 60 3. 〇 2020/175 222 1 1 1 卩(: 170? 2020/006141

These switches are arranged in the order of the switches 60 1, 60 2, the capacitor 60 4, and the drive circuit 60 3 from the side closer to the outer peripheral wall 1 according to the order of the amount of heat. The contact surface of the switch module 532 is preferably smaller than the contactable surface of the inner peripheral surface of the inner wall member 542.

[0416] Although detailed illustration of the capacitor module 5 3 2 is omitted, in the capacitor module 5 32, the capacitor 6 0 Six are housed and configured. As with the switch module 5 3 2 8, the capacitor module 5 3 2 has an outer peripheral wall with the side surface of the module case 6 1 1 abutting on the inner peripheral surface of the inner wall member 5 4 2 of the inverter housing 5 3 1. It is fixed at 1.

[0417] The switch module 532 and capacitor module 532 do not necessarily have to be arranged concentrically on the radially inner side of the outer peripheral wall 81 of the inverter housing 531. For example, the switch module 532 may be arranged radially inward of the capacitor module 532 or vice versa.

[0418] When the rotating electric machine 500 is driven, the inner wall member 5 4 2 of the outer peripheral wall 8 1 is interposed between the switch module 5 3 2 8 and the capacitor module 5 3 2 and the cooling water passage 5 4 5. Heat is exchanged. As a result, cooling is performed in the switch module 532 and the capacitor module 532.

[0419] Each electric module 5 32 may have a configuration in which cooling water is drawn into the inside thereof and cooling is performed by the cooling water inside the module. Here, the water cooling structure of the switch module 5 3 2 8 will be described with reference to FIGS. 6 1 (a) and (b ). Fig. 6 1 (3) is a vertical cross-sectional view showing the cross-sectional structure of the switch module 5 3 2 8 in the direction crossing the outer peripheral wall 81, and Fig. 6 1 (匕) is shown in Fig. 6 1 (a). 1 6-6 1 It is a cross-sectional view taken along the line.

[0420] As shown in Fig. 6 1 (a ), (匕), the switch module 5 3 2 8

As with 60, the module case 6 1 1 and switches for one phase 6 0 1, 6 0 2 〇 2020/175 222 1 12 卩(: 170? 2020/006141

In addition to having a drive circuit 60 3 and a capacitor 60 4, a cooling device including a pair of pipes 6 2 1 and 6 2 2 and a cooler 6 2 3 is provided. In the cooling device, the pair of piping parts 6 2 1 and 6 2 2 are an inflow side piping part 6 2 1 for flowing cooling water from the cooling water passage 5 4 5 of the outer peripheral wall 1 to the cooler 6 23. It is composed of an outflow side pipe section 6 2 2 through which cooling water flows from the cooler 6 2 3 to the cooling water passage 5 4 5. The cooler 6 23 is provided according to the object to be cooled, and the cooling device uses one or a plurality of stages of coolers 6 23. In the configurations shown in Fig. 6 1 (a) and (匕), the two-stage cooler 6 2 3 is placed in the direction away from the cooling water passage 5 4 5; The cooling water is provided to each of the coolers 6 23 via a pair of pipe parts 6 21 and 6 22. The cooler 6 23 has, for example, a hollow inside. However, inner fins may be provided inside the cooler 6 23.

[0421] In the configuration including the two-stage cooler 6 23, (1) the outer peripheral wall \ZV A 1 side of the first-stage cooler 6 23, (2) the first-stage and second-stage cooling (3) The second outer side of the cooler 6 23 3 is the place where the electric parts to be cooled are placed, respectively. The order is (2), (1), and (3). In other words, the place between the two coolers 6 2 3 has the highest cooling performance, and the place adjacent to one of the coolers 6 2 3 has the outer peripheral wall 8 1 (cooling water passage 5 4 5). The closer the cooling performance is, the better. Taking this into consideration, in the configuration shown in Figs. 6 1 (a) and (b), the switches 60 1 and 6

0 2 is arranged between (2) the first and second stage coolers 6 23, and the capacitor 60 4 is (1) the outer peripheral wall 8 1 of the first stage cooler 6 23. The drive circuit 60 3 is located on the side opposite to the outer peripheral wall side of the cooler 6 23 of the second stage (3). Although not shown, the drive circuit 60 3 and the capacitor 60 4 may be arranged in reverse.

[0422] In either case, switch 6

0 1 and 60 2 are electrically connected to the drive circuit 60 3, the switches 60 1 and 60 2 and the capacitor 60 4 by a wire 6 12 respectively. Also switch 〇 2020/175 222 113 卩 (: 170? 2020 /006141

Since 601 and 602 are located between the driving circuit 603 and the capacitor 604, the wiring 6 1 2 extending from the switches 601 and 602 toward the driving circuit 603 and the wiring 6 1 extending from the switches 601 and 602 toward the capacitor 604 6 1 2 is a relationship that extends in mutually opposite directions.

[0423] As shown in Fig. 6 1 (distance), the pair of piping parts 62 1 and 622 are arranged side by side in the circumferential direction, that is, on the upstream side and the downstream side of the cooling water passage 545, and on the upstream side. Cooling water flows into the cooler 623 from the inflow side piping portion 621 located therein, and thereafter, cooling water flows out from the outflow side piping portion 622 located downstream. In order to promote the inflow of cooling water into the cooling device, the cooling water passage 545 is located at a position between the inflow side pipe portion 62 1 and the outflow side pipe portion 62 1 when viewed in the circumferential direction. It is preferable that a regulation unit 624 that regulates the flow of cooling water is provided. The restriction unit 624 may be a blocking unit that blocks the cooling water passage 545, or a throttle unit that reduces the passage area of the cooling water passage 545.

[0424] FIG. 62 shows another cooling structure of the switch module 5328. Fig. 62

(3) is a vertical cross-sectional view showing the cross-sectional structure of the switch module 53,28 in the direction crossing the outer peripheral wall 81, and FIG. Is.

[0425] The configuration of Figs. 62 ( ₃ ) and (b) differs from the configuration of Figs. 61 (a) and (b) described above in that the arrangement of the pair of piping portions 62 1 and 622 in the cooling device is different. It is different, and a pair of piping parts 62 1 and 622 are arranged side by side in the axial direction. In addition, as shown in Fig. 62 (○), the cooling water passage 545 has an axial direction in which a passage portion communicating with the inflow side pipe portion 62 1 and a passage portion communicating with the outflow side pipe portion 622 are arranged in the axial direction. They are provided separately, and their passages are connected to the piping parts 62 1,

622 and each cooler 623 communicate with each other.

[0426] In addition, the following configuration can be used as the switch module 5328.

[0427] In the configuration shown in FIG. 63 _(3), as compared to the arrangement of FIG. 1 _(3), a cooler 62

3 has been changed from 2 tiers to 1 tier. In this case, inside the module case 6 1 1 〇 2020/175 222 1 14 卩(: 170? 2020/006141

In Fig. 6 1 (a), the location with the highest cooling performance is different from that in Fig. 6 1 (a). Next, the cooling performance decreases in the order of the location on the side opposite to the outer peripheral wall of the cooler 6 23 3 and the location away from the cooler 6 23 3. Taking this into consideration, in the configuration shown in Fig. 63 (a), the switches 60 1 and 60 2 are located on the outer peripheral wall 1 side of the cooler 6 23 3 on both sides in the radial direction (both sides in the left and right direction in the figure). , The condenser 60 4 is arranged at a position on the side opposite to the outer peripheral wall of the cooler 6 23, and the drive circuit 60 3 is arranged at a place apart from the cooler 6 23 3.

[0428] In addition, in the switch module 532, a configuration in which the switches 6011 and 602 for one phase, the drive circuit 603, and the capacitor 604 are housed in the module case 611. It is also possible to change. For example, the configuration may be such that the switches 60 1 and 60 2 for one phase and one of the drive circuit 60 3 and the capacitor 60 4 are housed in the module case 6 11.

[0429] In Fig. 6 3 (匕), a pair of piping parts 6 2 1,

6 2 2 and a two-stage cooler 6 2 3 are provided, and switches 6 0 1 and 6 0 2 are placed between the first and second coolers 6 2 3 and the condenser 6 0 4 Alternatively, the drive circuit 60 3 is arranged on the outer peripheral wall 1 side of the first-stage cooler 6 23 3. Further, the switches 60 1 and 60 2 and the drive circuit 60 3 are integrated into a semiconductor module, and the semiconductor module and the capacitor 60 4 are housed in the module case 6 11. Is also possible.

[0430] In Fig. 63 (匕), in the switch module 5328, cooling of at least one of the coolers 623 arranged on both sides of the switches 601, 602 is sandwiched. It is advisable to place a capacitor on the side opposite to the switches 60 1 and 60 2 in the device 6 23. That is, the condenser 60 4 is arranged on only one of the outer peripheral wall 81 side of the first-stage cooler 6 23 and the opposite peripheral wall side of the second-stage cooler 6 23, or both. A configuration in which the capacitor 604 is arranged is possible.

[0431] In this embodiment, the switch module 5 3 2 8 and the capacitor module 5 3 〇 2020/175 222 1 15 卩(: 170? 2020/006141

Only the switch module 5 3 2 8 out of 3 2 m is configured to draw cooling water into the module from the cooling water passage 5 4 5. However, the configuration may be changed so that the cooling water is drawn into the both modules 532, 532 from the cooling water passage 5445.

[0432] Further, it is possible to cool each electric module 532 by placing cooling water directly on the outer surface of each electric module 532. For example, as shown in FIG. 64, a cooling water is applied to the outer surface of the electric module 5 3 2 by embedding the electric module 5 32 in the outer peripheral wall 81. In this case, a configuration in which a part of the electric module 5 32 is sunk into the cooling water passage 5 45, or the cooling water passage 5 45 is expanded in the radial direction compared to the configuration of FIG. It is conceivable that all of 3 2 are immersed in the cooling water passage 5 4 5. When the electric module 5 3 2 is immersed in the cooling water passage 5 4 5, providing cooling fins on the module case 6 1 1 (the immersed part of the module case 6 1 1) further improves the cooling performance. be able to.

[0433] Further, the electric module 532 includes a switch module 532 and a capacitor module 532, and there is a difference in the amount of heat generated when the two are compared. Considering this point, it is possible to devise the arrangement of each electric module 5 3 2 in the inverter housing 5 3 1.

[0434] For example, as shown in Fig. 65, a plurality of switch modules 5 3 2 8 are arranged in the circumferential direction without being dispersed, and the upstream side of the cooling water passage 5 4 5, that is, the inlet passage 5 7 1 Place on the side close to. In this case, the cooling water flowing from the inlet passage 5 71 is first used for cooling the three switch modules 5 3 2 8 and then used for cooling the respective capacitor modules 5 3 2. In Fig. 65, a pair of pipe parts 6 2 1 and 6 2 2 are arranged side by side in the axial direction as shown in Fig. 6 2 ( ₃ ) and (b) above, but this is not restrictive. A pair of pipe parts 6 2 1 and 6 2 2 may be arranged side by side in the circumferential direction as shown in FIGS. 6 1 (a) and (10) in FIG.

[0435] Next, a configuration relating to electrical connection in each electric module 532 and bus bar module 533 will be described. Figure 6 6 is a cross section taken along line 6 6-6 6 of Figure 49. 〇 2020/175 222 1 16 卩(: 170? 2020/006141

Fig. 67 is a sectional view taken along line 6 7-67 of Fig. 49. FIG. 68 is a perspective view showing the bus bar module 5 33 as a single unit. Here, the configuration relating to the electrical connection of each electric module 5 3 2 and bus bar module 5 3 3 will be described by using these drawings together.

[0436] As shown in FIG. 6 6, the inverter housing 5 3 1 has a protrusion 5 7 3 provided on the inner wall member 5 4 2 (that is, an inlet passage 5 7 1 leading to the cooling water passage 5 4 5 and Three switch modules 5 3 2 8 are arranged side by side in the circumferential direction at a position adjacent to the projecting portion 5 7 3) provided with the outlet passage 5 7 2 in the circumferential direction, and further adjacent to that, 6 Two capacitor modules 5 3 2 are arranged side by side in the circumferential direction. As an outline of this, in the inverter housing 5 3 1, the inside of the outer peripheral wall 8 1 is divided into 10 areas (that is, the number of modules + 1) in the circumferential direction, and the electric module 5 3 2 are arranged one by one, and a protrusion 5 73 is provided in the remaining one area. Three switch modules ^_ le 5 3 2 eight is re-phase module ^_ Le, V-phase module, a \ / \ / phase module.

[0437] As shown in Fig. 6 6 and the above-mentioned Fig. 5 6 and Fig. 5 7 etc., each electric module 5 3 2 (switch module 5 3 2 8 and capacitor module 5 3 2 M) has a module case 6 1 It has a plurality of module terminals 6 15 extending from 1. The module terminal 6 15 is a module input/output terminal for electrically inputting/outputting the electric module 5 32. The module terminals 6 15 are provided so as to extend in the axial direction, and more specifically, the module terminals 6 15 are arranged so as to extend from the module case 6 11 toward the inner side of the rotor carrier 5 11 (outside the vehicle). It is provided (see Figure 51).

[0438] The module terminals 6 1 5 of each electrical module 5 3 2 are respectively connected to the bus bar module 5 3 3. The number of module terminals 6 1 5 is different between the switch module 5 3 2 8 and the capacitor module 5 3 2 8 and the switch module 5 3 2 8 is provided with 4 module terminals 6 1 5 and is a capacitor. The module 5 3 2 has two module terminals 6 1 5 〇 2020/175 222 1 17 卩(: 170? 2020/006141

There is.

[0439] Further, as shown in FIG. 68, the bus bar module 533 has an annular portion 631 having an annular shape, and extends from the annular portion 631, and is connected to a power supply device or a semiconductor device (electronic control device). ), etc., and three external connection terminals 6 3 2 that enable connection with external devices, and a winding wire connection terminal 6 3 3 connected to the end of the winding wire of each phase in the stator winding wire 5 2 1. have. Busbar module 5 3 3 corresponds to "terminal module"

[0440] The annular portion 631 is arranged inside the outer peripheral wall 81 in the inverter housing 531 in the radial direction and on one side in the axial direction of each electric module 532. The annular portion 631 has, for example, an annular main body formed of an insulating member such as resin, and a plurality of bus bars embedded therein. The plurality of bus bars are connected to the module terminals 6 15 of each electric module 5 3 2, each external connection terminal 6 3 2, and each winding of the stator winding 5 21. The details will be described later.

[0441] The external connection terminals 6 3 2 are the high-potential side power terminals 6 3 2 8 and the low-potential side power terminals 6 3 2 which are connected to the power supply device, and the external potential (3 II 1 Each of these external connection terminals 6 3 2 (6 3 2 8 to 6 3 2 0) is arranged in a row in the circumferential direction and is radially inward of the annular portion 6 3 1. It is provided so as to extend in the axial direction at the bus bar module 5 3 3 together with each electric module 5 3 2 in the inverter housing 5 3 1 as shown in Fig. 5 1. One end of the connection terminal 6 3 2 is configured to project from the end plate 5 47 of the boss forming member 5 4 3. Specifically, as shown in FIGS. The end plate 5 4 7 of 5 4 3 is provided with a shed hole 5 4 7 3, and a cylindrical grommet 6 3 5 is attached to the shed hole 5 4 7 3 and the grommet 6 The external connection terminal 6 3 2 is provided with the 3 5 threaded in. The grommet 6 3 5 also functions as a sealed connector.

[0442] The winding connection terminal 6 3 3 is a terminal connected to the winding wire end of each phase of the stator winding 5 21 and is provided so as to extend radially outward from the annular portion 6 3 1. ing. 〇 2020/175 222 1 18 卩(: 170? 2020/006141

Winding connection terminal 6 3 3 is a winding wire connection terminal 6 3 3 II, which is connected to the end of the II phase winding in the stator winding 5 2 1, and a winding wire that is connected to the end of the V phase winding. It has a connection terminal 6 3 3 V, and a winding wire connection terminal 6 3 3 \^/ that is connected to the connection at each end of the phase winding. It is said that each of these winding wire connection terminals 6 3 3 and a current sensor 6 3 4 for detecting the current (II phase current, V phase current, phase current) flowing in each phase winding wire are provided (Fig. 7 0 See).

[0443] Note that the current sensor 634 may be arranged outside the electric module 532 and around each wire connecting terminal 633, or inside the electric module 532. It may be arranged.

[0444] Here, the connection between each electric module 5 32 and the bus bar module 5 33 will be described more specifically with reference to Figs. 69 and 70. FIG. 69 is a diagram showing each electric module 5 32 in a plan view, and schematically showing the electrical connection state between each electric module 5 32 and the bus bar module 5 33. .. FIG. 70 is a diagram schematically showing the connection between the electric modules 5 3 2 and the bus bar module 5 3 3 when the electric modules 5 32 are arranged in an annular shape. Incidentally, in FIG. 6 9 shows a path for power transmission by the solid line indicates the path of a signal transmission system in ^_ point chain line. In Fig. 70, only the path for power transmission is shown.

[0445] The bus bar module 5 3 3 has a first bus bar 6 4 1, a second bus bar 6 4 2 and a third bus bar 6 4 3 as bus bars for power transmission. Of these, the first bus bar 6 4 1 is connected to the power terminal 6 3 2 8 on the high potential side, and the second bus bar 6 4 2 is connected to the power terminal 6 3 2 on the low potential side. In addition, the three third busbars 6 4 3 are connected to the II phase winding connection terminal 6 3 3 II, the V phase winding connection terminal 6 3 3 V, and the phase winding connection terminal 6 3 3 \^/ Respectively connected to.

[0446] Further, the winding connection terminal 633 and the third bus bar 643 are portions that easily generate heat due to the operation of the rotating electric machine 10. For this reason, a terminal block (not shown) is interposed between the winding connection terminal 6 33 and the third bus bar 6 43, and this terminal block is installed in the inverter housing 5 3 1 having the cooling water passages 5 45. You can touch it 〇 2020/175 222 1 19 卩(: 170? 2020/006141

Yes. Alternatively, the winding connection terminal 6 3 3 and the third bus bar 6 4 3 are bent in a crank shape so that the winding connection terminal 6 3 3 and the third bus bar 6 4 3 are connected to the inverter housing having the cooling water passages 5 4 5. It may be brought into contact with 5 31.

With such a configuration, the heat generated in the winding connection terminal 6 3 3 and the third bus bar 6 4 3 can be radiated to the cooling water in the cooling water passage 5 4 5.

[0448] In Fig. 70, the first busbar 6 4 1 and the second busbar 6 4 2 are shown as annular busbars, but each of these busbars 6 4 1, 6 4 2 is always a circle. It may be ring-shaped and unbroken, or may have a substantially <3 character shape with a partial interruption in the circumferential direction. Also, each wire connection terminal 6 3 3 II, 6 3 3 V, 6 3 3 \^/ need only be individually connected to the switch module 5 3 2 corresponding to each phase, so the busbar module 5 3 3 It may be configured such that it is directly connected to each switch module 5 3 2 8 (actually module terminal 6 15) without going through.

[0449] On the other hand, each switch module 5 3 2 8 has four module terminals 6 1 5 consisting of a positive side terminal, a negative side terminal, a winding terminal and a signal terminal. Of these, the positive terminal is connected to the first bus bar 641, the negative terminal is connected to the second bus bar 642, and the winding wire terminal is connected to the third bus bar 643.

[0450] Further, the bus bar module 533 has a fourth bus bar 644 as a signal transmission bus bar. The signal terminal of each switch module 5 3 2 8 is connected to the fourth bus bar 6 4 4, and the 4 th bus bar 6 4 4 is connected to the signal terminal 6 3 20.

[0451] In this embodiment, the control signal for each switch module 5 3 2 is configured to be input from the external node 11 via the signal terminal 6 3 20. That is, the switches 60 1 and 60 2 in each of the switch modules 5 3 2 8 are turned on/off by the control signal input via the signal terminal 6 3 2 0. Therefore, each switch module 5328 is connected to the signal terminal 6320 without passing through the control unit with a built-in rotary electric machine on the way. However, this 〇 2020/175 222 120 卩 (: 170? 2020 /006141

It is also possible to change the configuration so that a control device is built in the rotating electric machine and the control signal from the control device is input to each switch module 5 3 2 8. Such a configuration is shown in Fig. 71.

[0452] The configuration of Fig. 71 includes a control board 651 on which a control device 652 is mounted, and the control device 652 is connected to each switch module 532. In addition, the signal terminal 6 3 2 (3 is connected to the control device 6 52. In this case, the control device 6 52 is, for example, an external control unit (3 II for power running or power generation from the upper control device). A command signal relating to this is input, and the switches 601, 602 of each switch module 532 are turned on/off as appropriate based on the command signal.

[0453] In the inverter unit 5300, the control board 651 may be arranged on the outer side of the vehicle (the inner side of the rotor carrier 511) than the busbar module 533. Alternatively, the control board 6 51 may be arranged between each electric module 5 32 and the end plate 5 47 of the boss forming member 5 43. The control board 6 51 may be arranged such that at least a part thereof overlaps with each electric module 5 32 in the axial direction.

[0454] Further, each capacitor module 5 3 2 has two module terminals 6 1 5 consisting of a positive side terminal and a negative side terminal, and the positive side terminal is connected to the first bus bar 6 4 1. The negative terminal is connected to the second bus bar 6 42.

[0455] As shown in Fig. 4 9 and Fig. 50, the cooling water inlet passage 5 7 1 and the outlet passage 5 5 are arranged in the inverter housing 5 3 1 at positions circumferentially aligned with the electric modules 5 3 2. The protruding portion 5 73 having 7 2 is provided, and the external connection terminal 6 32 is provided so as to be adjacent to the protruding portion 5 73 in the radial direction. In other words, the protruding portion 5 73 and the external connection terminal 6 32 are provided at the same angular position in the circumferential direction. In the present embodiment, the external connection terminal 6 32 is provided at a position on the radially inner side of the protrusion 5 73. When viewed from the inside of the inverter housing 531, the end plate 547 of the boss forming member 543 is provided with the waterway port 574 and the external connection terminal 632 arranged side by side in the radial direction. (See Figure 48). 〇 2020/175 222 121 卩 (: 170? 2020 /006141

[0456] In this case, the plurality of electric modules 5 3 2 and the protruding portions 5 7 3 and the external connection terminals 6 3 2 are arranged side by side in the circumferential direction, so that the inverter unit 5 30 can be miniaturized, and as a result, the rotating electric machine. It is possible to reduce the size as 500.

[0457] As shown in Fig. 45 and Fig. 47 showing the structure of the wheel 400, cooling pipes are connected to the waterway port 574! I 2 is connected, and electrical wiring is connected to the external connection terminal 6 3 2. !· I 1 is connected, and in that state, electric wiring!· I 1 and piping for cooling! ·I 2 is stored in the storage duct 440.

[0458] In the above configuration, three switch modules 5 3 2 8 are arranged side by side in the circumferential direction in the inverter housing 5 3 1 next to the external connection terminal 6 3 2, and 6 Although the configuration is such that the three capacitor modules 5 32 are arranged side by side in the circumferential direction, this may be changed. For example, the configuration may be such that the three switch modules 5 32 8 are arranged side by side at the position farthest from the external connection terminal 6 32, that is, at the position on the opposite side of the rotary shaft 50 1. It is also possible to disperse each switch module 5 3 2 8 so that the capacitor modules 5 3 2 8 are arranged on both sides of each switch module 5 3 2 8.

[0459] If the switch modules 5 3 2 are arranged at the position farthest from the external connection terminals 6 3 2, that is, on the opposite side of the rotary shaft 5 01, the external connection terminals 6 3 2 It is possible to suppress malfunctions and the like due to mutual inductance between the switch module and each switch module.

[0460] Next, the configuration of the resolver 660 provided as the rotation angle sensor will be described.

[0461] As shown in FIGS. 49 to 51, the inverter housing 531 is provided with a resolver 660 for detecting the electrical angle 0 of the rotary electric machine 500. The resolver 660 is an electromagnetic induction type sensor, and includes a resolver fixed on the rotating shaft 5 01 and a resolver stator 6 6 arranged opposite to the resolver rotor 6 61 in the radial direction. It has 2 and. The resolver rotor 6 6 1 is a disc 〇 2020/175 222 122 卩 (: 170? 2020 /006141

It is in the shape of a groove, and is provided coaxially with the rotating shaft 501, with the rotating shaft 50 1 being passed through. The resolver stator 6 62 includes an annular stator core 6 63 and a stator coil 6 64 wound around a plurality of teeth formed on the stator core 6 63. The stator coil 6 64 includes a 1-phase excitation coil and a 2-phase output coil.

The exciting coil of the stator coil 6 64 is excited by a sinusoidal exciting signal, and the magnetic flux generated in the exciting coil by the exciting signal interlinks the ^_ pairs of output coils. At this time, the relative positional relationship between the exciting coil and the pair of output coils changes cyclically according to the rotation angle of the resolver rotor 6 61 (that is, the rotation angle of the rotation shaft 50 1 ). The number of magnetic fluxes that link the output coil changes periodically. In the present embodiment, the pair of output coils and the excitation coil are arranged so that the phases of the voltages generated in the pair of output coils are shifted from each other by /2. As a result, the output voltage of each of the pair of output coils becomes a modulated wave in which the excitation signal is modulated by each of the modulation waves 311 and 030. More specifically, assuming that the excitation signal is “3 1 1 0 1 :”, the modulated waves are “3 I 11 0 X 3 I ◯ 1:” and “0 0 3 0 X 3 1 门〇”, respectively. 1:”.

[0463] The resolver 660 has a resolver digital converter. The resolver digital converter calculates the electrical angle 0 by detection based on the generated modulated wave and excitation signal. For example, the resolver 660 is connected to the signal terminal 6320, and the calculation result of the resolver digital converter is output to the external device via the signal terminal 6320. Further, when the rotating electric machine 500 has a built-in control device, the calculation result of the resolver digital converter is input to the control device.

[0464] Here, the assembling structure of the resolver 660 in the inverter housing 531 will be described.

[0465] As shown in FIGS. 4 9 and 5 1, the boss portion 5 4 8 of the boss forming member 5 4 3 forming the inverter housing 5 3 1 has a hollow cylindrical shape, and the boss portion 5 4 8 On the inner peripheral side of the, there is formed a protrusion 5 4 8 3 that extends in a direction orthogonal to the axial direction. 〇 2020/175 222 123 卩 (: 170? 2020 /006141

Has been. The resolver stator 6 62 is fixed by a screw or the like in a state where the resolver stator 6 62 is in axial contact with the projecting portion 5 48 3. Inside the boss portion 548, a bearing 5600 is provided on one side in the axial direction with the protruding portion 5448 being sandwiched, and a resolver 6600 is provided coaxially on the other side.

[0466] In addition, the hollow portion of the boss portion 548 is provided with a protruding portion 5448 on one side of the resolver 6600 in the axial direction, and accommodates the resolver 660 on the other side. A disc ring-shaped housing cover 6 6 6 is attached to close the space. The housing cover 6666 is made of a conductive material such as carbon fiber reinforced plastic (○[¾9)). A hole 6 6 6 3 is formed in the center of the housing cover 6 6 6 to allow the rotary shaft 50 1 to pass through it. A seal member 667 is provided in the hole 6663 to seal the gap between the hole 6166 and the outer peripheral surface of the rotary shaft 501. The resolver accommodating space is sealed by the sealing material 667. The sealing material 667 is preferably a sliding seal made of a resin material, for example.

[0467] The space in which the resolver 660 is housed is surrounded by the boss portion 548 having an annular shape in the boss forming member 543, and the axial direction is defined by the bearing 560 and the housing cover 666. The space between the resolvers 660 is surrounded by a conductive material. As a result, the influence of electromagnetic noise on the resolver 660 can be suppressed.

[0468] Further, as described above, the inverter housing 531 has a double outer peripheral wall 1 and a double inner peripheral wall 2 (see Fig. 57). Stator 520 is located on the outside of the perimeter wall 81, electrical module 532 is located between the double perimeter walls (between eight 1 and \ZV A 2), and a double perimeter wall A resolver 660 is arranged inside (inside the inner peripheral wall 82). Since the inverter housing 5 3 1 is a conductive member, the stator 5 20 and the resolver 6 60 are arranged with a conductive partition wall (particularly a double conductive partition wall in this embodiment) separated from each other. Thus, the occurrence of magnetic interference between the stator 520 side (magnetic circuit side) and the resolver 660 can be appropriately suppressed. 〇 2020/175 222 124 卩 (: 170? 2020 /006141

[0469] Next, the rotor cover 6 provided on the open end side of the rotor carrier 5 1 1

7 0 will be described.

[0470] As shown in Figs. 49 and 51, the rotor carrier 5 11 is open on one side in the axial direction, and the open end portion thereof has a substantially disc-shaped rotor cover 6 7 1. 0 is installed. The rotor cover 670 may be fixed to the rotor carrier 511 by any joining method such as welding, adhesion, and screw fixing. It is even more desirable if the rotor cover 670 has a position that is dimensioned to be smaller than the inner circumference of the rotor carrier 511 so as to prevent axial movement of the magnet unit 512. Good. The outer diameter of the rotor cover 6 70 matches that of the rotor carrier 5 11 and the inner diameter is slightly larger than that of the inverter housing 5 31. ing. The outer diameter of the inverter housing 5 3 1 and the inner diameter of the stator 5 20 are the same.

[0471] As described above, the stator 5 2 is located radially outside the inverter housing 5 3 1.

0 is fixed, and at the joint where the stator 5 20 and the inverter housing 5 3 1 are joined to each other, the inverter housing 5 3 1 projects axially with respect to the stator 5 20. .. A rotor cover 670 is attached so as to surround the protruding portion of the inverter housing 531. In this case, a sealing material 671 is provided between the inner peripheral end surface of the rotor cover 6700 and the outer peripheral surface of the inverter housing 531 to seal the gap between them. .. The seal member 671 seals the housing space for the magnet unit 512 and the stator 520. The sealing material 6 71 may be a sliding seal made of, for example, a resin material.

[0472] According to this embodiment described in detail above, the following excellent effects can be obtained.

[0473] In the rotating electric machine 500, the outer peripheral wall 8 1 of the inverter housing 5 3 1 is arranged radially inside the magnetic circuit portion consisting of the magnet unit 5 1 2 and the stator winding 5 2 1. Cooling water passages 5 45 were formed in the outer peripheral wall 1. Further, a plurality of electric modules 5 32 are arranged radially inside the outer peripheral wall 1 along the outer peripheral wall 1 in the circumferential direction. As a result, the rotary electric machine 50 〇 2020/175 222 125 卩 (: 170? 2020 /006141

Magnetic circuits, cooling water passages 5 45, and power converters can be arranged so that they are stacked in the radial direction of ◯, and efficient component arrangement is possible while reducing the size in the axial direction. .. In addition, it is possible to efficiently cool the plurality of electric modules 5 32 forming the power converter. As a result, in the rotary electric machine 500, high efficiency and downsizing can be realized.

[0474] An electric module 5 3 2 (switch module 5 3 2 8 and capacitor module 5 3 2) having heat-generating components such as semiconductor switching elements and capacitors is provided in contact with the inner peripheral surface of the outer peripheral wall 1. It was composed. Thereby, the heat in each electric module 5 32 is transferred to the outer peripheral wall 1, and the electric module 5 32 is suitably cooled by the heat exchange in the outer peripheral wall 81.

[0475] In the switch module 532, the coolers 623 are arranged on both sides of the switches 601, 602, respectively, and the coolers 62 on both sides of the switches 601, 6022 are arranged. In at least one of the three coolers, the condenser 60 4 is arranged on the opposite side of the switches 60 1 and 60 2. As a result, the cooling performance for the switches 60 1 and 60 2 can be improved, and at the same time, the cooling performance of the capacitor 60 4 can be improved.

[0476] In the switch module 532, the coolers 623 are arranged on both sides of the switches 601 and 602, respectively, and the coolers 62 on both sides of the switches 601 and 6022 are arranged. The drive circuit 603 is arranged on the opposite side of the switches 6 0 1 and 6 0 2 in the cooler ^{_ of} 3 and the reverse of the switches 6 0 1 and 6 0 2 in the other cooler 6 2 3. The capacitor 604 is placed on the side. As a result, the cooling performance for the switches 60 1, 60 2 can be improved, and at the same time, the cooling performance for the drive circuit 60 3 and the capacitor 60 4 can also be improved.

[0477] For example, in the switch module 5328, cooling water is made to flow into the module from the cooling water passage 5445, and the semiconductor switching elements and the like are cooled by the cooling water. In this case, in addition to the heat exchange by the cooling water in the outer peripheral wall 81, the switch module 532 〇 2020/175 222 126 卩(: 170? 2020/006141

It is cooled by heat exchange. As a result, the cooling effect of the switch module 5 3 2 8 can be enhanced.

[0478] In a cooling system in which cooling water flows in from an external circulation path 5 7 5 to the cooling water passage 5 4 5, the switch module 5 3 2 8 is close to the inlet passage 5 7 1 of the cooling water passage 5 4 5. In addition to the upstream side, the capacitor module 532 is arranged downstream of the switch module 5328. In this case, assuming that the cooling water flowing through the cooling water passage 5 445 has a lower temperature on the upstream side, it is possible to realize a configuration in which the switch module 5 32 8 is preferentially cooled.

[0479] The interval between the electric modules adjacent to each other in the circumferential direction is partially expanded, and the inlet passage 5 7 1 and the outlet passage 5 7 are provided in a portion which becomes the expanded gap (second interval 1\1 2). The configuration is such that the protruding portion 5 73 having 2 is provided. As a result, the inlet passage 5 7 1 and the outlet passage 5 72 of the cooling water passage 5 45 can be preferably formed in the radially inner portion of the outer peripheral wall 81. That is, in order to improve the cooling performance, it is necessary to secure the flow rate of the refrigerant, and for that purpose, it is conceivable to increase the opening area of the inlet passage 5 71 and the outlet passage 5 72. In this respect, as described above, by partially expanding the interval between the electric modules and providing the protrusion 5 73, the inlet passage 5 7 1 and the outlet passage 5 7 2 having a desired size are preferably formed. be able to.

[0480] The external connection terminals 6 3 2 of the bus bar module 5 3 3 are arranged at positions radially aligned with the protrusion 5 73 on the radially inner side of the outer peripheral wall 1. In other words, the external connection terminals 6 32 are placed together with the protrusions 5 7 3 at the portion where the gap between the electric modules adjacent to each other in the circumferential direction is widened (the portion corresponding to the second interval I!\! I decided to do it. As a result, the external connection terminals 6 32 can be preferably arranged while avoiding interference with the electric modules 5 32.

[0481] In the rotor-rotating electric machine 500 of the outer rotor type, the stator 520 is fixed to the outside of the outer peripheral wall 1 in the radial direction, and the plurality of electric modules 532 are arranged inside of the radial direction. This allows the outer wall \ZV A 1 to 〇 2020/175 222 127 卩(: 170? 2020/006141

The heat of the stator 5 20 is transmitted from the side, and the heat of the electric module 5 32 is transmitted from the radially inner side. In this case, the stator 520 and the electric module 532 can be cooled at the same time by the cooling water flowing through the cooling water passage 545, and the heat of the heat generating member in the rotating electric machine 550 can be efficiently released. can do.

[0482] The electric module 5 3 2 on the radially inner side and the stator winding 5 2 1 on the radially outer side with the outer peripheral wall 1 interposed therebetween are electrically connected to each other by the winding wire connection terminal 6 3 3 of the bus bar module 5 3 3. It is configured to connect. Further, in this case, the winding connection terminal 6 33 is provided at a position axially separated from the cooling water passage 5 45. As a result, even if the cooling water passages 5 45 are formed in an annular shape on the outer peripheral wall 1, that is, the inside and outside of the outer peripheral wall 81 are divided by the cooling water passages 5 45, the electric module 5 3 2 and the stator winding 5 2 1 can be suitably connected.

[0483] In the rotary electric machine 500 of the present embodiment, by reducing or eliminating the teeth (iron core) between the conductors 5 23 arranged in the stator 5 20 in the circumferential direction, the conductors 5 2 3 In addition to suppressing the torque limit due to magnetic saturation that occurs between the two, the conductor wire 52 3 is made flat and thin to suppress the torque decrease. In this case, even if the outer diameter of the rotary electric machine 500 is the same, it is possible to expand the radially inner area of the magnetic circuit section by thinning the stator 520, and the inner area thereof. Using, it is possible to suitably arrange the outer peripheral wall 1 having the cooling water passages 5 45, and the plurality of electric modules 5 32 provided inside the outer peripheral wall 1 in the radial direction.

[0484] In the rotary electric machine 500 of the present embodiment, the magnet magnetic flux gathers on the shaft side in the magnet unit 512, so that the magnet magnetic flux on the shaft is strengthened, and the torque can be increased accordingly. .. In this case, as the thickness of the magnet unit 5 1 2 in the radial direction can be reduced (thinner), it is possible to expand the region of the magnetic circuit part on the radial inside. The inner area is used to provide the outer peripheral wall 1 having the cooling water passages 5 45 and the inner peripheral surface of the outer peripheral wall 1 in the radial direction. 〇 2020/175 222 128 卩 (: 170? 2020 /006141

It is possible to suitably arrange a plurality of electric modules 5 32.

[0485] Further, not only the magnetic circuit part, the outer peripheral wall 81, and the plurality of electric modules 532, but also the bearing 5600 and the resolver 660 can be similarly preferably arranged in the radial direction.

[0486] A wheel 400 that uses the rotating electric machine 500 as an in-wheel motor is a vehicle body that is equipped with a base plate 450 fixed to an inverter housing 531 and a mounting mechanism such as a suspension device. Be attached to. Here, since the rotating electrical machine 500 has been downsized, it is possible to save space even if it is supposed to be mounted on the vehicle body. Therefore, it is possible to realize an advantageous configuration in expanding the installation area of a power supply device such as a battery or expanding the vehicle interior space in a vehicle.

[0487] Hereinafter, modifications of the in-wheel motor will be described.

[0488] (Modification 1 of in-wheel motor)

In the rotating electric machine 500, the electric module 5 32 and the bus bar module 5 33 are arranged radially inward of the outer peripheral wall 81 of the inverter unit 5 30 and the outer peripheral wall 1 is separated from the outer peripheral wall 81 in the radial direction. An electric module 532, a busbar module 5333, and a stator 52O are arranged inside and outside, respectively. In such a configuration, the position of the bus bar module 533 with respect to the electric module 532 can be set arbitrarily. Also, when connecting each winding of the stator windings 5 2 1 and the busbar module 5 3 3 across the outer peripheral wall 8 1 in the radial direction, the winding connection wires (for example, winding wire) used for the connection. The position to guide the connection terminal 6 3 3) can be set arbitrarily.

[0489] That is, as the position of the busbar module 533 with respect to the electric module 532, (<<1) the busbar module 533 is located outside the electric module 532 in the axial direction, that is, the rotor. Carrier 5 1 1 side is the back side,

{(X 2) The busbar module 5 3 3 is arranged inside the vehicle in the axial direction with respect to the electric module 5 3 2, that is, on the front side of the rotor carrier 5 1 1 side. 〇 2020/175 222 129 卩 (: 170? 2020 /006141

Is possible.

[0490] Further, as a position for guiding the winding connection line,

((3 1) A structure in which the winding connecting wire is guided outside the vehicle in the axial direction, that is, on the back side of the rotor carrier 5 11 side,

(/3 2) A structure in which the winding connecting wire is guided inside the vehicle in the axial direction, that is, on the front side of the rotor carrier 5 11 side,

Is possible.

[0491] Hereinafter, four configuration examples regarding the arrangement of the electric module 5 32, the bus bar module 5 33 and the winding wire connection line will be described with reference to Figs. 7 2 ( ₃ ) to (¢0). Fig. 7 2 ( ₃ ) to (¢ 0 is a simplified vertical sectional view showing the configuration of the rotary electric machine 500, and the same reference numerals are given to the configurations already described in the figure. The connecting wire 6 3 7 is an electrical wiring that connects each phase wire of the stator winding 5 21 and the bus bar module 5 3 3, for example, the above-mentioned winding connecting terminal 6 3 3 corresponds to this. To do.

[0492] In the configuration of Fig. 7 2 (a), the above (<< 1) is adopted as the position of the bus bar module 5 33 with respect to the electric module 5 32, and the position for guiding the winding connecting wire 6 3 7 is adopted. As above, (/3 1) is adopted. That is, the electric module 5 32, the bus bar module 5 33, the stator winding 5 21 and the bus bar module 5 33 are all connected outside the vehicle (the inner side of the rotor carrier 5 11). It is composed. Note that this corresponds to the configuration shown in FIG.

According to this configuration, the cooling water passages 5 45 can be provided in the outer peripheral wall 1 without fear of interference with the winding connection lines 6 37. Further, the winding wire connecting wire 6 3 7 connecting the stator winding 5 21 and the bus bar module 5 3 3 can be easily realized.

[0494] In the configuration of Fig. 7 2 (匕), the above (<< 1) is adopted as the position of the bus bar module 5 3 3 with respect to the electric module 5 3 2 and the position for guiding the winding connecting wire 6 3 7 The above (/3 2) is adopted as. That is, the electric module 〇 2020/175 222 130 卩(: 170? 2020/006141

-The ruler 5 3 2 and the busbar module 5 3 3 are connected on the outside of the vehicle (the inner side of the rotor carrier 5 11 1), and the stator winding 5 2 1 and the busbar module 5 3 3 are connected on the inside of the vehicle ( It is configured to be connected by the front side of the rotor carrier 5 11).

According to this configuration, the cooling water passages 5 45 can be provided in the outer peripheral wall 1 without fear of interference with the winding connection line 6 37.

[0496] In the configuration of Fig. 7 2 (○), the above (<< 2) is adopted as the position of the busbar module 5 3 3 with respect to the electric module 5 3 2 and the position for guiding the winding connecting wire 6 3 7 As above, (/3 1) is adopted. That is, the electric module 5 3 2 and the busbar module 5 3 3 are connected inside the vehicle (front side of the rotor carrier 5 11 1), and the stator winding 5 2 1 and the busbar module 5 3 3 are connected. And are connected on the outside of the vehicle (the inner side of the rotor carrier 5 11).

[0497] In the configuration of Fig. 7 2 (), the above (<< 2) is adopted as the position of the bus bar module 5 3 3 with respect to the electric module 5 3 2 and the position for guiding the winding connecting wire 6 3 7 is adopted. The above (/3 2) is adopted. In other words, the configuration in which the electric module 5 3 2 and the busbar module 5 3 3, the stator winding 5 2 1 and the busbar module 5 3 3 are all connected inside the vehicle (front side of the rotor carrier 5 1 1) Has become.

[0498] According to the configurations of Fig. 7 2 (○) and Fig. 7 2 (, the bus bar module 5 3 3 is arranged inside the vehicle (front side of the rotor carrier 5 1 1), so that a fan motor, etc. It is conceivable that the wiring will be easier if an electric component of the busbar module 5 3 3 is placed closer to the resolver 6 6 0 arranged inside the vehicle than the bearing. It will be possible, and wiring to the resolver 660 will be easier.

[0499] (Modification 2 of in-wheel motor)

A modified example of the mounting structure of the resolver rotor 6 61 will be described below. That is, the rotating shaft 501, the rotor carrier 511 and the inner ring 561 of the bearing 5600 are integrated. 〇 2020/175 222 131 卩 (: 170? 2020 /006141

A modification of the mounting structure of the resolver rotor 6 61 with respect to the rotating body will be described below.

[0500] FIGS. 73 (3) to (◯) are configuration diagrams showing an example of the mounting structure of the resolver rotor 6 61 to the rotating body. In either configuration, the resolver 660 is surrounded by the rotor carrier 5 11 and the inverter housing 5 3 1 and is provided in a closed space protected from water and mud from the outside. In Fig. 73 (a) of Fig. 73 (3) to (○), the bearing 560 has the same configuration as that of Fig. 49. In addition, in Fig. 7 3 (slung) and Fig. 7 3 (○), the bearing 5 60 has a different configuration from that of Fig. 49 and is located at a position away from the end plate 5 1 4 of the rotor carrier 5 11. It is arranged. In each of these figures, two force stations are illustrated as the mounting locations of the resolver rotor 6 61. Although the resolver stator 6 62 is not shown, for example, the boss portion 5 48 of the boss forming member 5 4 3 is extended to the outer peripheral side of the resolver rotor 6 61 or its vicinity, and the boss portion 5 4 8 is formed. It suffices that the resolver stator 6 62 be fixed to the.

[0501] In the configuration shown in Fig. 73 (a), the resolver rotor 6 6 is attached to the inner ring 5 61 of the bearing 5 60.

1 is installed. Specifically, the resolver rotor 6 61 is provided on the axial end surface of the flange 5 6 1 13 of the inner ring 5 61, or on the axial end surface of the tubular portion 5 6 1 3 of the inner ring 5 61. Has been.

[0502] In the configuration shown in Fig. 73 (匕), the resolver rotor 6 61 is attached to the rotor carrier 5 11. Specifically, the resolver rotor 6 61 is provided on the inner surface of the end plate 5 14 in the rotor carrier 5 11. Alternatively, in the configuration in which the rotor carrier 5 11 has the cylindrical portion 5 15 extending from the inner peripheral edge portion of the end plate 5 14 along the rotation axis 5 0 1, the resolver rotor 6 6 1 includes the rotor carrier 6 1 1. It is provided on the outer peripheral surface of the cylindrical portion 5 1 5 1. In the latter case, the resolver rotor 6 61 is arranged between the end plate 5 14 of the rotor carrier 5 11 and the bearing 5 6 0.

[0503] In the configuration shown in Fig. 73 (○), the resolver rotor 6 61 is attached to the rotary shaft 50 1. Specifically, the resolver rotor 6 61 is located on the rotary shaft 5 01. 〇 2020/175 222 132 卩(: 170? 2020/006141

Is provided between the end plate 5 1 4 of the rotor carrier 5 11 and the bearing 5 6 0, or the opposite of the rotor carrier 5 11 with the bearing 5 6 0 sandwiched on the rotating shaft 5 0 1. It is located on the side.

[0504] (Modification 3 of in-wheel motor)

A modification of the inverter housing 531 and the rotor cover 670 will be described below with reference to FIG. Fig. 7 4 ( ₃ ) and Fig. 7 4 (匕) are vertical cross-sectional views showing a simplified structure of the rotating electric machine 500, in which the same reference numerals are assigned to the structures already described. There is. Note that the structure described in FIG. 4 (a) substantially corresponds to the configuration described in FIG. 4 9 such that the configuration shown in FIG. 4 (spoon) is 7 4 Configuring ₍₃₎ ^_ This corresponds to the configuration in which the parts are changed.

[0505] In the configuration shown in Fig. 7 4 ( ₃ ), the rotor cover 6 70 fixed to the open end of the rotor carrier 5 1 1 surrounds the outer peripheral wall 8 1 of the inverter housing 5 3 1. It is provided in. That is, the end surface on the inner diameter side of the rotor cover 670 is opposed to the outer peripheral surface of the outer peripheral wall 81, and the seal material 671 is provided between them. In addition, a housing cover 666 is attached to the hollow part of the boss 548 of the inverter housing 531, and a sealing material 667 is provided between the housing cover 666 and the rotary shaft 501. Has been. The external connection terminals 6 3 2 that compose the bus bar module 5 3 3 penetrate the inverter housing 5 3 1 and extend to the inside of the vehicle (lower side in the figure).

[0506] Further, the inverter housing 5 3 1 is provided with an inlet passage 5 7 1 and an outlet passage 5 7 2 which communicate with the cooling water passage 5 45, and the inlet passage 5 7 1 and the outlet passage 5 7 The waterway port 5 74 including the passage end of 7 2 is formed.

[0507] On the other hand, in the configuration shown in Fig. 7 4 (匕), the inverter housing 5 3

1 (specifically, the boss forming member 54 3) is formed with an annular convex portion 6 81 extending to the protruding side (inside the vehicle) of the rotating shaft 5 01, and the rotor cover 6 7 0 It is provided so as to surround the convex portion 681 of the housing 531. In other words, the end surface on the inner diameter side of the rotor cover 670 faces the outer peripheral surface of the convex portion 681. 〇 2020/175 222 133 卩 (: 170? 2020 /006141

A seal member 671 is provided between them. Also, the external connection terminals 6 3 2 that compose the bus bar module 5 3 3 penetrate the boss portion 5 4 8 of the inverter housing 5 3 1 and extend into the hollow area of the boss portion 5 4 8 and the housing cover 6 6 2. It passes through 6 and extends to the inside of the vehicle (lower side in the figure).

[0508] Further, the inverter housing 5 3 1 is formed with an inlet passage 5 7 1 and an outlet passage 5 7 2 which communicate with the cooling water passage 5 4 5, and these inlet passage 5 7 1 and outlet passage 5 5 7 2 extends in the hollow region of the boss portion 5 48 and extends to the inside of the vehicle (lower side in the figure) with respect to the housing cover 6 6 6 via the relay pipe 6 82. In this configuration, the pipe portion extending from the housing cover 6 66 to the inside of the vehicle is the waterway port 5 74.

[0509] According to the configurations of Fig. 7 4 ( ₃ ) and Fig. 7 4 (b ), the rotation of the rotor carrier 5 11 and the rotor cover 6 70 while maintaining the hermeticity of the internal space is prevented. The child carrier 5 11 and the rotor cover 6 70 can be suitably rotated with respect to the inverter housing 5 3 1.

[0510] Further, in particular, according to the configuration of Fig. 74 (13), the inner diameter of the rotor cover 670 is smaller than that of the configuration of Fig. 74 (a). Therefore, the inverter housing 5 3 1 and the rotor cover 6 70 are doubly provided in the axial direction at a position on the vehicle inner side of the electric module 5 32, which is a concern in the electric module 5 32. The inconvenience caused by the generated electromagnetic noise can be suppressed. Further, by reducing the inner diameter of the rotor cover 670, the sliding diameter of the seal material 617 is reduced, and mechanical loss in the rotary sliding portion can be suppressed.

[051 1] (Modification 4 of in-wheel motor)

A modification of the stator winding 5 21 will be described below. Figure 75 shows a modification of the stator winding 5 21.

[0512] As shown in Fig. 75, the stator winding 5 21 uses a conductor wire having a rectangular cross section, and is wound by wave winding with the long side of the conductor wire extending in the circumferential direction. It has been turned. In this case, the stator windings 5 2 1 〇 2020/175 222 134 卩(: 170? 2020/006141

The lines 52 3 are arranged at a predetermined pitch interval for each phase and are connected to each other at the coil end. In the coil side, the conductor wires 52 3, which are adjacent to each other in the circumferential direction, have their end faces in the circumferential direction abut each other, or are arranged in close proximity to each other with a minute gap.

[0513] Further, in the stator winding 5 21, the conductor wire is bent in the radial direction for each phase at the coil end. More specifically, the stator winding 5 2 1 (conductor wire) is bent inward in the radial direction at different positions for each phase in the axial direction, which results in winding of each phase of II phase, V phase, and phase. Mutual interference in the lines is avoided. In the configuration shown in the figure, the conductor wires are bent inward at a right angle in the radial direction for each phase, with each phase wire differing by the thickness of the conductor wire. It is preferable that the length dimension between both ends in the axial direction of the conductors 5 2 3 arranged in the circumferential direction be the same for each conductor 5 2 3.

[0514] When assembling the stator core 5 22 to the stator winding 5 21 to fabricate the stator 5 20, part of the circular ring in the stator winding 5 21 is not connected. The stator windings 5 2 1 in the shape of a circle, and after assembling the stator core 5 2 2 on the inner circumference side of the stator winding 5 2 1, disconnect it. It is advisable to connect the parts to each other and form the stator winding 5 2 1 in an annular shape.

[0515] In addition to the above, the stator core 5 22 is divided into a plurality (for example, three or more) in the circumferential direction, and the stator core 5 22 is attached to the inner peripheral side of the stator winding 5 21 formed in an annular shape. It is also possible to assemble a plurality of divided core pieces.

[0516] (Other modifications)

For example, as shown in Fig. 50, in the rotary electric machine 500, the inlet passage 5 7 1 and the outlet passage 5 7 2 of the cooling water passage 5 4 5 are collectively provided at one power station. The inlet passage 5 71 and the outlet passage 5 72 may be provided at different positions in the circumferential direction. For example, the inlet passage 5 71 and the outlet passage 5 72 may be provided at positions different by 180 degrees in the circumferential direction, or at least one of the inlet passage 5 71 and the outlet passage 5 72 may be provided in plural. May be.

[0517] In the wheel 400 of the above-described embodiment, the rotating electric machine 500 rotates to one side in the axial direction. 〇 2020/175 222 135 卩(: 170? 2020/006141

Although the configuration is such that the shaft 5 01 is projected, the configuration may be modified so that the rotation shaft 5 01 is projected in both axial directions. As a result, for example, a suitable configuration can be realized in a vehicle in which at least one of the front and rear of the vehicle has one wheel.

[0518] As the rotary electric machine 500 used for the wheel 400, it is possible to use an inner rotor type rotary electric machine.

[0519] (Modification 15)

Next, the rotating electric machine 700 according to the present modification will be described. The rotating electric machine 700 is used as a unit for driving a vehicle. An outline of the rotating electric machine 700 is shown in Fig. 76 to Fig. 78. FIG. 76 is a perspective view showing the entire rotating electric machine 700, FIG. 77 is a vertical cross-sectional view of the rotating electric machine 700, and FIG. 78 shows the components of the rotating electric machine 700. It is a disassembled disassembled sectional view.

[0520] The rotary electric machine 700 is an outer rotor type surface magnet type rotary electric machine. The rotating electric machine 700 is roughly classified into a rotating electric machine main body having a rotor 710, a stator 730, an inner unit 770 and a bus bar module 810, and a rotating electric machine main body surrounding the rotating electric machine main body. It is provided with a housing 831 and a cover 832 provided. All of these members are coaxially arranged with respect to a rotary shaft 7 01 provided integrally with the rotor 7 100, and the rotary electric machine 70 0 is configured by being assembled in the axial direction in a predetermined order. Has been done. The rotor 7 10 is cantilevered by a pair of bearings 7 9 1 and 7 9 2 provided inside the inner unit 7 70 in the radial direction, and is rotatable in that state. The rotating shaft 7 01 is integrally provided with a connecting shaft 7 05 which is fixed to an axle or a wheel of a vehicle.

[0521] In the rotating electric machine 700, the rotor 710 and the stator 7300 each have a cylindrical shape, and are arranged to face each other in the radial direction with an air gap therebetween. The rotor 7 1 0 rotates integrally with the rotating shaft 7 0 1, so that the rotor 7 1 0 rotates radially outside the stator 7 3 0. The rotor 71 0 corresponds to the “field element”, and the stator 7 30 corresponds to the “armature”.

[0522] As shown in Fig. 79, the rotor 710 is composed of a substantially cylindrical rotor carrier 711 and an annular magnet unit 711 fixed to the rotor carrier 711. To 〇 2020/175 222 136 卩(: 170? 2020/006141

Have The rotor carrier 7 11 has an end plate portion 7 13 and a tubular portion 7 14 that extends in the axial direction from the outer peripheral portion of the end plate portion 7 13. A through hole 7 1 3 3 is formed in the end plate portion 7 13 and the end plate portion 7 1 3 3 is tightened with a fastener such as a bolt 7 1 5 while being threaded into the through hole 7 1 3 3. The rotary shaft 701 is fixed to. The rotating shaft 701 has a flange 702 extending in a direction intersecting (orthogonal to) the axial direction at a portion where the rotor carrier 711 is fixed, and the flange 702 and the end plate. The rotor carrier 7 1 1 is fixed to the rotary shaft 7 0 1 in a state where the parts 7 13 are surface-bonded.

[0523] The magnet unit 7 1 2 includes a cylindrical magnet holder 7 2 1 and the magnet holder 7 1 2.

It has a magnet 7 2 2 fixed to the inner peripheral surface of 2 1 and end plates 7 2 3 fixed to the opposite side of the rotor carrier 7 1 1 on both axial sides of the magnet 7 2 2. .. The magnet holder 7 2 1 has the same length dimension as the magnet 7 2 2 in the axial direction. The magnet 7 22 is provided so as to be surrounded by the magnet holder 7 21 from the outside in the radial direction. The magnet holder 7 21 and the magnet 7 22 2 are fixed with one end of the axial ends abutting the rotor carrier 7 11 and the other end abutting the end plate 7 23. It is fixed.

[0524] The rotor carrier 7 11, the magnet holder 7 21 and the end plate 7 23 are all made of non-magnetic aluminum or non-magnetic stainless steel (for example, 3 II 3 3 0 4). Each of these members is preferably made of a light metal such as aluminum, but instead of this, it may be made of a synthetic resin. Each of these members may be joined by adhesion or welding.

[0525] Fig. 80 is a partial cross-sectional view showing the cross-sectional structure of the magnet unit 7 1 2. Figure 8

At 0, the easy axis of magnetization of the magnet 7 22 is indicated by an arrow.

[0526] In the magnet unit 7 1 2, the magnets 7 2 2 are arranged side by side so that the polarities thereof alternate along the circumferential direction of the rotor 7 10. As a result, the magnet 72 2 has a plurality of magnetic poles in the circumferential direction. The magnet 72 2 is a polar anisotropic permanent magnet, has an intrinsic coercive force of at least 400 [1 <8/○ 1 ], and has a residual magnetic flux density 〇 2020/175 222 137 卩(: 170? 2020/006141

It is constructed by using a sintered neodymium magnet whose "ga" is 1.0 or more.

[0527] The magnet 72 is provided with two magnets adjacent to each other in the circumferential direction, with one axis being the center of each magnet. In other words, the magnet 722 has one magnetic pole as one magnet, and the center in the circumferential direction is the axis. The radially inner peripheral surface of the magnet 7 22 is a magnetic flux transfer surface 7 2 4 on which magnetic flux is transferred. In the magnet 7 22, the direction of the easy axis of magnetization is different on the axis side (portion closer to the 1st axis) and on the 9th axis side (portion closer to the axis). The orientations are parallel, and on the axis side, the direction of the easy magnetization axis is orthogonal to the axis. In this case, an arc-shaped magnet magnetic path is formed along the direction of the easy axis of magnetization. In short, the magnet 72 is oriented so that the easy axis of magnetization is closer to the axis, which is the center of the magnetic pole, than the axis, which is the magnetic pole boundary.

[0528] According to the magnets 72 arranged in the circumferential direction, the magnetic flux of the magnet on the axis is strengthened and the change of the magnetic flux near the axis is suppressed. As a result, it is possible to preferably realize a magnet 72 2 in which the surface magnetic flux changes gently from axis to axis at each magnetic pole. The magnet 72 2 may have a structure having the center in the circumferential direction as the axis, instead of the structure having the center in the circumferential direction as the axis. Further, as the magnets 72, instead of using the same number of magnets as the number of magnetic poles, a magnet having an annular shape may be used.

[0529] It is desirable that the magnet 72 2 has the following configuration. In the magnet 7 22, the arc length of the magnetic flux transfer surface 7 2 4 between the _ 9 axes is longer than the radial thickness of the magnet 7 22. Also, as shown in Fig. 81, a circle whose center is 0 at the intersection of the axis and the magnetic flux transfer surface 7 2 4 in the magnet 7 22 and whose radius is the radial thickness of the magnet 7 22 When the orientation circle X that determines the easy axis of magnetization of the magnet 7 22 is set, the magnet 7 22 is configured to include a quarter circle of the orientation circle X. In other words, the magnet 7 22 has an arc-shaped easy axis of magnetization that crosses the 9-axis, and of the easy axis of magnetization, the circumferential surface on the side opposite to the magnetic flux transfer surface 7 24 in the radial direction. And the axis of easy magnetization passing through the intersection of the axis and the axis of orientation X 〇 2020/175 222 138 卩(: 170? 2020/006141

The strongest magnetic flux is generated by the easy axis. In this case, since the magnet 7 22 is configured to include a quarter circle of the orientation circle X, the length of the magnet magnetic path passing through the axis is ensured as the length specified by the orientation circle X, and It is possible to generate a magnetic flux.

[0530] Here, when the arc length of the magnetic flux transfer surface 7 2 4 between the 19 axes in the magnet 7 2 2 is longer than the radial thickness of the magnet 7 2 2, it is smaller than the magnet 7 2 2. There is a concern about magnetic flux leakage to the outside in the radial direction, that is, to the side opposite to the stator. However, in the configuration of this example, the influence of the magnetic flux leakage can be reduced by configuring the magnet holder 7 21 with a non-magnetic material.

[0531] Further, the magnet 7 22 has a concave portion 7 25 formed on the outer circumferential surface on the radially outer side within a predetermined range including the shaft, and the inner circumferential surface on the radially inner side includes the shaft. Recesses 7 26 are formed within a certain range. In this case, according to the direction of the easy axis of magnetization of the magnet 7 22, the magnet magnetic path becomes shorter near the axis on the outer peripheral surface of the magnet 7 22 and near the 9 axis on the inner peripheral surface of the magnet 7 22. The magnet magnetic path becomes shorter. Therefore, considering that it is difficult to generate a sufficient magnetic flux in the magnet 72 2 where the magnetic path length is short, the magnet is deleted in the place where the magnetic flux is weak.

[0532] The magnet holder 7 2 1 is provided on the outer side in the radial direction of each magnet 7 2 2 arranged in the circumferential direction. Further, the magnet holder 7 21 may be provided in a range including a space between the magnets 7 22 in the circumferential direction and a radially inner side of the magnets 7 22. That is, the magnet holder 7 21 may be provided so as to surround the magnet 7 22. When the magnet holder 7 2 1 has a radially outer portion and a radially inner portion of each magnet 7 2 2, the radially outer portion has higher strength than the radially inner portion. Good.

[0533] The magnet holder 7 21 has a convex portion 7 27 which is inserted into the concave portion 7 25 of the magnet 7 22. In this case, the position shift of the magnet 7 22 in the circumferential direction is suppressed by the engagement of the concave portion 7 25 of the magnet 7 22 and the convex portion 7 27 of the magnet holder 7 21. That is, the convex portion 7 2 7 of the magnet holder 7 2 1 〇 2020/175 222 139 卩(: 170? 2020/006141

Functions as a stop. If the magnet holder 7 2 1 has a portion that is radially inward of the magnet 7 2 2 (on the side of the stator 7 3 0), the concave portion 7 of the magnet 7 2 2 should be located in that portion. There may be provided a convex portion that enters into the inside of 26.

[0534] Next, the structure of the stator 7300 will be described.

[0535] The stator 730 has a stator winding 731 and a stator core 732.

FIG. 8 2 is a perspective view showing the structure of the stator 7 30 and FIG. 8 3 is an exploded perspective view showing the stator winding 7 3 1 and the stator core 7 3 2. 8 4 is a perspective view showing only the structure corresponding to the re-phase winding of the winding wire of each phase, and FIG. 8 5 is a vertical cross-sectional view of the stator 7 30.

[0536] The stator core 7 32 is composed of a plurality of core sheets 7 made of magnetic steel sheets that are magnetic materials.

A plurality of core sheets 7 3 2 3 are used to form a core sheet laminate in which 3 3 2 3 is axially laminated, and has a cylindrical shape having a predetermined thickness in the radial direction. A stator winding 7 31 is attached to the outer side of the stator core 7 32 on the rotor 7 10 side in the radial direction. The outer peripheral surface of the stator core 7 32 has a curved surface without unevenness. The stator core 7 32 functions as a back yoke. The stator core 7 32 is configured by stacking a plurality of core sheets 7 32 3 punched out in, for example, an annular plate shape in the axial direction. However, as the stator core 732, one having a helical core structure may be used. In the stator core 7 32 with a helical core structure, a strip-shaped core sheet is used, and the core sheet is formed into an annular shape and is axially laminated to form a cylindrical stator core 7 3 2 are configured.

[0537] End rings 733 are fixed to the end faces on both axial sides of the stator core 732. The end ring 7 3 3 is a positioning member having a function of holding the stator winding 7 3 1 at a predetermined position in the circumferential direction when the stator winding 7 3 1 is assembled to the stator core 7 32. is there. The stator core 7 32 and the end ring 7 33 are the base member 7 36.

[0538] On the outer peripheral surface of the end ring 7 3 3, the stator core 7 3 2 and the end ring 7 3

The engagement surface 7 3 4 is shaped in a direction that is inclined with respect to the tangent on a concentric circle that is concentric with 3 3. 〇 2020/175 222 140 卩 (: 170? 2020 /006141

Is made. The engaging surface 7 34 is provided by equally dividing the outer peripheral surface of the end ring 7 33 into a plurality of parts. In this example, the same number of engaging surfaces 7 3 4 as the conductor parts of the coil side (the straight part 7 4 4 of the coil module 7 40 described later) arranged in the circumferential direction on the stator winding 7 3 1 are arranged in the circumferential direction. It is provided. Further, in this example, since the inclination directions with respect to the tangent line are opposite to each other on the circumferentially adjacent engaging surfaces 7 34, the outer peripheral surface of the end ring 7 33 is tapered. A joint is formed. In this case, concave portions 735 are formed between the tapered convex portions.

[0539] In each of the end rings 7 33 on both sides in the axial direction, the positions of the concavities and convexities in the circumferential direction are the same on one end side and the other end side in the axial direction. In other words, the end ring 7 33 on the one end side in the axial direction and the end ring 7 33 on the other end side in the axial direction are arranged so that the positions of the convex tops by the engaging surfaces 7 34 coincide in the circumferential direction. Fixed to 3 2.

[0540] The inner diameter of the end ring 7 33 is the same as the inner diameter of the stator core 7 32. Also, the outer diameter of the end ring 7 33 is the same as the outer diameter of the stator core 7 32 at the maximum diameter part, and smaller than the outer diameter of the stator core 7 32 at the minimum diameter part. Has become.

[0541] The end ring 7 33 is made of, for example, a nonmagnetic material such as aluminum or copper. The end ring 7 3 3 is fixed to the stator core 7 3 2 by welding. Alternatively, the end ring 7333 may be mechanically fixed by pin insertion, key press fitting, or bolt fastening. By such mechanical fixation, the circumferential displacement of the end ring 7 33 with respect to the stator core 7 32 is suppressed.

[0542] As shown in Fig. 85, the stator 7 30 has a portion corresponding to the coil side 0 3 radially opposed to the magnet 7 2 2 in the rotor 7 10 in the axial direction, and It has a portion corresponding to the coil end 0 1, 0 2 which is the outside of the coil side 0 3 in the axial direction. In this case, the stator core 7 32 is coiled axially.

The end ring 7 3 3 is provided in the range corresponding to 〇 2020/175 222 141 卩 (: 170? 2020 /006141

One is provided at the coil end 0 at one end and the other at the coil end 0 at the other end in the direction. Coil end ○ 1 corresponds to the first coil end, and coil end ○ 2 corresponds to the second coil end. The configuration in a state where the end ring 7 33 is engaged with the stator winding 7 31 will be described later.

[0543] The stator winding 7 31 has a plurality of phase windings, and the phase windings of each phase are arranged in a predetermined order in the circumferential direction to form a cylindrical shape (annular shape). The stator core 7 3 2 is assembled on the radially inner side of the stator winding 7 3 1. In this example, by using phase windings of II phase, V phase, and phase, the stator winding 7 3 1 has a configuration having a 3-phase winding.

[0544] In the stator winding 7 3 1, each phase winding of each phase has a plurality of partial windings 7 4 1 (see Fig. 86), and the partial winding 7 4 1 is an individual coil. It is provided as module 740. In other words, the coil module 7440 is integrally provided with the partial windings 741 in the phase windings of each phase. By arranging the coil modules 7 40 of each phase side by side in a predetermined order in the circumferential direction, the conductor parts of each phase are arranged in a predetermined order in the coil side of the stator winding 7 31. ing. Figure 82 shows the order of the II, V, and phase conductors in the coil side. Further, in FIG. 84, only the coil module 740 that constitutes the II-phase winding is extracted and shown from the three-phase windings. In this example, the number of magnetic poles is 24, but the number is arbitrary.

[0545] In the stator winding 7 3 1, the phase winding of each phase is configured by connecting the partial winding 7 4 1 of each coil module 7 4 0 in parallel or in series for each phase. .. Fig. 86 is a circuit diagram showing the connection state of the partial windings 7 41 in each of the three-phase windings. In Fig. 86, the partial windings 7 41 of the phase windings of each phase are shown connected in parallel.

[0546] As shown in Fig. 85, the coil module 740 is assembled radially outside the stator core 732. The stator winding 7 3 1 is

And a part corresponding to the coil ends 0, 1 and 2, respectively. In this case, the coil module 74 〇 2020/175 222 142 卩 (: 170? 2020 /006141

It is assembled so that it protrudes axially outside of 7 32 (that is, the coil end side).

[0547] The coil module 740 is omitted because one of both axial ends bends radially! -It is formed in the shape of a letter, and due to its bending, the interference of the coil modules 740 adjacent to each other in the circumferential direction is suppressed. In this example, as the coil module 740, the coil module 740 is arranged so that the axially one end side portion is oriented radially outward, and the axially one end side portion is diametrically inwardly oriented. It is configured to use the coil module 740 arranged. In other words, the stator winding 731 is configured by using two types of coil modules 7408 and 7440. These coil modules 740,

The 7 40 s are assembled to the stator core 7 32 with their axial directions reversed.

[0548] As shown in Figure 82, multiple coil modules for stator core 7 32.

In the assembled state of the 740, restraint rings 760 are attached at two axial positions on the radially outer side of the coil module 740. The restraint ring 760 is a restraint member that restrains each coil module 740 (stator winding 731) in the radial direction. The restraint ring 760 is, for example, an annular ring made of metal. It is also possible to use a ring or multiple rings having both ends as free ends as the restraint ring 760, and connect the ends of the restraint ring 760 by welding or bonding. In this case, the restraining ring 760 is preferably elastic and has a diameter smaller than that of the stator winding 731 in a natural state.

[0549] A linear member such as a thread, a string, or a wire may be used as the restraint member, and the restraint member may be spirally wound around the outer circumference of the stator roll 731. In this case, for example, a string soaked with varnish may be used, and the varnish may be used to strengthen the string fixing.

[0550] Next, the configuration of the coil module 740 will be described in detail.

[0551] First, the coil module 7408 among the coil module 7408 and the coil module 7480 will be described. The coil module 〇 2020/175 222 143 卩(: 170? 2020/006141

Rule 740 is a subassembly having a partial winding 741 and a winding holder 742. In the following description, the partial winding 7 4 1 of the coil module 7 4 0 8 is also referred to as “partial winding 7 4 1 8”, and the winding holder 7 4 2 is also referred to as “strip wire holder 7 4 2 8”. The partial winding 7 4 1 of 7 40 is also referred to as a “partial winding 7 4 1 ”and the winding holder 7 4 2 is also referred to as a “rolling holder 7 4 2 ”. Partial winding 7 41 8 corresponds to the first partial winding, and partial winding 7 41 1 corresponds to the second partial winding.

[0552] Fig. 8 7 (3) is a perspective view of the coil module 7408, and Fig. 8 7 (匕) is a perspective view showing only the partial winding 7 4 18 of the coil module 7 48. Fig. 8 7 (○) is a perspective view showing only the winding holder 7 4 28 of the coil module 7 48, and Fig. 8 7 (○ ○ is a side view of the coil module 7 48 8). Figure 8 8 (3), () is a cross-sectional view showing the cross section of the coil module 7408, and Figure 8 8 (3) is the cross section of Figure 8 7 (8 8 8 8 Fig. 8 8 Eighteen cross-section, Fig. 8 8 (匕) is a cross-sectional view of Fig. 8 7 (No. 8 8 No. 1 8 8 No. 8). In Fig. 8 7 (¢1), the coil module is shown. The left side of 7480 is the stator core 732 side, and in Fig. 88 (a) and (匕), the lower side of the coil module 7408 is the stator core 732 side.

[0553] The coil module 7408 includes a partial winding 741 formed by multiple windings of a conductive wire 743, and an insulating winding wire wire integrally provided on the partial winding 741. Ruda 7 42. The winding holder 7 4 2 is provided to insulate the partial winding 7 4 18 from the surroundings, and particularly to insulate between the partial winding 7 4 18 and the stator core 7 3 2. It is provided. The coil module 740 is formed in a long annular shape whose longitudinal direction is the axial direction. The coil module 7408 has a pair of straight line portions 744 extending in parallel to each other in the axial direction, and a bent portion 7445 extending in a direction orthogonal to the axial direction on one end side on both sides in the axial direction. Have As a result, the coil module 740 is formed into a substantially 1-shaped shape as a whole.

[0554] The partial winding 7 4 1 is composed of a pair of intermediate conductors 7 4 6 that are parallel to each other and linearly arranged, and a first crossover that connects the pair of intermediate conductors 7 4 6 at one axial end side. 〇 2020/175 222 144 卩(: 170? 2020/006141

Part 7 47 and a second connecting part 7 48 connecting the pair of intermediate conducting wire parts 7 4 6 at the other end side in the axial direction, and the pair of intermediate conducting wire parts 7 4 6 and the first connecting part 7 4 6 It is formed in an annular shape by 7 4 7 and the second crossover 7 4 8. The pair of intermediate conductors 7 4 6 are provided at a predetermined coil pitch apart from each other, and between the pair of intermediate conductors 7 4 6 in the circumferential direction, the intermediate conductor of the partial winding 7 4 1 of another phase is provided. Parts 7 46 can be arranged. In this example, the pair of intermediate conductors 7 4 6 are provided with a spacing of 2 coil pitches, and between the pair of intermediate conductors 7 4 6 the intermediate conductor 7 4 6 are arranged one by one.

[0555] The first crossover section 7 47 and the second crossover section 7 48 are provided as portions corresponding to the coil ends 0, 1 and 2, respectively (see Fig. 85). That is, these crossovers 7 47, 7 48 are coil end conductors that connect the in-phase intermediate conductors 7 4 6 at two positions different in the circumferential direction at the coil ends 0 1 and 0 2. It is provided. In the partial winding 7 4 1, the first crossover 7 7 4 is the portion corresponding to the bend 7 4 5 in the coil module 7 4 0 8 and is oriented in the direction orthogonal to the intermediate conductor 7 4 6. It is provided so as to be bent in a direction orthogonal to the axial direction. On the other hand, the second connecting portion 7 48 is provided so as to extend in the same direction as the intermediate conducting wire portion 7 46 located axially inward thereof, that is, to extend linearly in the axial direction. As a result, the partial winding 7 4 1 8 is omitted as a whole! -It has a letter-shaped configuration. The coil size is shown in Fig. 87 ().

A boundary line 0 between the coil end and the coil ends ◯1 and ◯2 is indicated by a broken line.

[0556] In the partial winding 7 4 1, the first crossover portion 7 4 7 (the first crossover portion 7 4 7 on the coil end 〇mi 1 side in the partial winding 7 4 1) is bent radially outward. An outer bend 1 is provided. The partial winding 7 4 18 has a structure in which the outer bent portion 1 is provided on the coil end 0 1 side and is not bent in the radial direction on the coil end 0 2 side.

[0557] As shown in Fig. 88 (a), the partial winding 7 4 1 is formed by multiple winding of the conducting wire 7 4 3 so that the cross section becomes a quadrangle. Figure 88 (3) shows the middle 〇 2020/175 222 145 卩 (: 170? 2020 /006141

The cross section of the coil module 7480 at the inter-conductor section 7 46 is shown, and the conductor 7 4 3 is multiply wound so as to be lined up in the circumferential direction and the radial direction at the intermediate conductor section 7 46. ing. In the cross section of the partial winding 7 41, the circumferential length on the outer diameter side and the circumferential length on the inner diameter side are the same. In addition, in the crossovers 7 47, 7 48, in the part where the partial winding 7 4 18 is oriented along the circumferential direction, the conductors 7 4 3 are wound in multiple layers so as to be aligned in the axial direction and the radial direction. ing. In this example, partial winding 1

^ Is configured. However, the winding method of the conducting wire 7 4 3 is arbitrary, and the conducting wire 7 4 3 may be wound in multiple layers by alpha winding instead of concentric winding.

[0558] In the cross section of the partial winding 741, the partial winding 741 may have a substantially trapezoidal shape in which the circumferential length on the outer diameter side is larger than the circumferential length on the inner diameter side. This makes it possible to equalize the distance between the intermediate conductor portions 7 4 6 arranged in the circumferential direction while taking into consideration the difference in the circumferential length between the outer diameter side and the inner diameter side.

[0559] As shown in Fig. 8 7 (a ), in the partial winding 7 4 18 the wire from the side of the first crossover 7 47, more specifically from the tip of the bend 7 4 5 to the wire 7 4 3 The end is pulled out in the axial direction, and the end is the winding line end 7 4 3

It is 7 43. The winding wire end portions 7 4 3 3 and 7 4 3 13 are the winding start and winding end of the conducting wire 7 4 3, respectively. Of these, the end of the winding wire 7 43 3 is connected to the current input/output terminal, and the end of the winding 7 43 3 is connected to the neutral point.

[0560] The partial winding 7 41 8 is preferably configured such that a higher potential is applied toward the radially outer side. In other words, when comparing the radially outer side and the radially inner side of the partial coiled wire 7 41, the distance between the pair of intermediate conducting wire portions 7 46 becomes longer at the radially outer side. It is desirable that the higher potential is applied to the outer side in the radial direction. Figure 9 9 shows the winding sequence of the conductor 7 4 3 in the partial winding 7 4 1. In Fig. 99, the middle conductor wire portion 7 4 6 in the same partial winding 7 4 1 8 is shown by a solid line, and the intermediate conductor portion 7 4 1 in different windings (that is, the partial winding 7 4 1 in different phase) The conductor portion 7 46 is shown by a broken line.

[0561] In the partial winding 7 41, the transition from the radially outer side to the radially inner side is performed. 〇 2020/175 222 146 卩(: 170? 2020/006141

The conductor wire 7 4 3 is wound, and the winding start on the radially outer side is the winding wire end portion 7 4 3 ₃ . In addition, the winding end on the radially inner side is the edge of the winding line 743. In this case, the edge of the winding wire 7 4 3 ₃ is connected to the current input/output terminal, and the end of the winding wire 7 4 3 13 is connected to the neutral point, so that a higher potential is applied to the outer side in the radial direction. It has become. The winding order of the conductive wire 743 may be such that the winding start and winding end are opposite on the radially outer side and the radially inner side.

[0562] Further, in Fig. 99, the spacing distance between the intermediate conducting wire portions 7 46 of different phases adjacent to each other in the circumferential direction is different between the radially outer side and the radially inner side. In this case, if the radial distance on the outside is <1, and the radial distance on the inside is <2,

1>[< 2. In other words, the distance between the intermediate conductor portions 7 4 6 of different phases adjacent to each other in the circumferential direction increases as the distance to the outside in the radial direction increases. As a result, with respect to the distance between the intermediate conductor portions 7 46 that are adjacent in the circumferential direction, an appropriate distance according to the potential difference is secured.

[0563] The winding holder 7 42 has a bobbin shape and is made of an insulating material such as synthetic resin. The winding holder 7 4 2 as a whole is similar to the partial winding 7 4 1! -The structure is formed in the shape of a letter, the part provided along the middle conductor part 7 4 6 of the partial winding 7 4 1 and the part provided along each crossover part 7 4 7 7 4 8 And have.

[0564] As shown in Fig. 8 8 (a ), the winding holder 7 4 2 8 is provided so as to surround the partial winding 7 4 1 8 from three sides in the cross section of the partial winding 7 4 1 8. The first wall portion 7 5 1 on the side of the stator core 7 32, the second wall portion 7 52 on the side of the non-stator core, and the first wall portion 7 5 1 and the second wall portion 7 5 3 and a third wall portion 7 5 3 which connects the two. The first wall portion 7 51 corresponds to the back yoke side insulating wall, the second wall portion 75 2 corresponds to the non-back yoke side insulating wall, and the third wall portion 75 3 corresponds to the circumferential insulating wall. To do. The third wall portion 7 53 is provided on the inner side in the circumferential direction in the pair of straight line portions 7 4 4 arranged in the circumferential direction. The third wall portion 753 is provided so as to extend toward the center of the circle of the stator core 732.

[0565] Winding holder 7 42 8 is formed by the 1st to 3rd wall parts 7 5 1 to 7 5 3 〇 2020/175 222 147 卩(: 170? 2020/006141

It has an accommodating portion 7 54, and the partial winding 7 4 18 is provided while being accommodated in the accommodating portion 7 54. In this case, the partial winding 7 41 8 is insulated by the wall portions 7 5 1 to 7 5 3 on the three sides of the stator core 7 32 side, the non-stator core side and one side in the circumferential direction. That is, the first wall portion 751 insulates the intermediate conductor portion 746 from the stator core 732. The intermediate wall portion 7 46 is covered by the second wall portion 7 52 so as not to be exposed on the rotor 7 10 side (air gap side). The third wall portion 7 5 3 insulates the intermediate conductor portions 7 4 6 from each other in the circumferential direction.

[0566] In the winding holder 7 4 28, the thickness dimension of the first wall portion 7 5 1 in the wall thickness direction (radial direction) is set to 11 and the second wall portion 7 5 2 in the wall thickness direction ( If the thickness in the radial direction is Ding 12 and the thickness in the wall thickness direction (circumferential direction) of the third wall 7 5 3 is Ding 13 then the thickness of the second wall 7 5 2 is It is desirable that the size dimension 1 2 is smaller than the thickness dimension 1 1 of the first wall 7 5 1 (D 1 1 >D 1 2). In other words, the second wall portion 7 52 is an insulating wall on the magnet 7 22 2 side (air gap side), and the distance between the magnet 7 2 2 and the partial winding 7 4 1 is detailed because the insulating wall is thin. Can reduce the distance on the magnetic circuit and can be expected to improve performance. When the magnets 7 2 2 and the partial winding 7 4 1 are the same in distance, the thickness of the second wall 7 52 is reduced by the thickness dimension 1 2 2 and the coil module 7 4 0 ( The air gap (gap) between the holder surface) and the magnet 7 2 2 can be increased, and contact during rotation of the rotor 7 10 can be suppressed. In addition, in FIG. 100, the thickness dimension 1 1 of the first wall portion 7 51 is thicker than that in the configuration of FIG. 8 8 (a), and the thickness of the second wall portion 7 5 2 is larger. It is shown that the dimensions 1 and 2 are made thinner by making the dimensions 1 and 2 thinner.

[0567] Also, the thickness dimension 1 of the first wall portion 7 5 1 is the thickness dimension 1 of the second wall portion 7 5 2.

When it is larger than 2, the insulation distance from the stator core 7 32 is secured, and the insulation performance can be improved. However, Ding 1 1 = Ding 12 may be

[0568] Thickness of the third wall 7 5 3 For example, the thickness of the first wall 7 5 1 〇 2020/175 222 148 卩 (: 170? 2020 /006141

It is good that it is the same as the size dimension 1 1. However, Ding 13> Ding 11 or Ding 13 3 <Ding 11 may be satisfied.

[0569] As shown in FIG. 100, in the third wall portion 753, the thickness dimension D is different at each position of the radially inner side and the radially outer side, and the thickness outer side is more The thickness dimension 13 may be increased. That is, the third wall portion 753 has a tapered cross section that is wider toward the radially outer side. In this case, the thickness dimension of the third wall 753 is set to be larger on the radial outer side than on the radial inner side, so that the circumference on the radial inner side and the radial outer side is reduced. It is possible to properly arrange the intermediate conductor portions 7 46 arranged side by side in the circumferential direction, considering that the lengths are different. In other words, if the thickness dimension 13 of the third wall portion 7 53 is made uniform in the radial direction, when the cross section of the partial winding 7 41 is made into a quadrangular shape, it is possible to use two adjacent two in the circumferential direction. The middle conductor portion 7 46 is too close on the side of the third wall portion 7 53 and too far on the opposite side. Therefore, there is a concern that the rotating magnetic flux becomes uneven in the circumferential direction. On the other hand, in the configuration of this example, the rotating magnetic flux can be equalized in the circumferential direction. It also enables uniform insulation performance in the circumferential direction. Further, since it is possible to prevent an excessive gap from being formed between the intermediate conductor portion 7 46 and the third wall portion 7 53 on the radially outer side (outer peripheral side), the intermediate conductor portion 7 4 6 (partial It is also suitable for positioning and fixing the winding 7 4 18).

[0570] Regarding the relationship with the bent portion 7445 of the coil module 7480, in the pair of straight line portions 7454, the first wall portion 751 is on the opposite side to the bent portion 7445. The second wall 752 is a wall on the side of the bent portion 7445 (a wall on the outer side in the axial direction).

[0571] The partial winding 7 4 1 is provided in a state in which it is in contact with or close to each of the three walls 7 51 to 7 5 3 in the accommodating portion 7 54, and the third wall 7 5 7 in the circumferential direction. It is located on the opposite side of 3 from the end of the first wall portion 7 51 and the second wall portion 7 52 to the inside. That is, in the winding holder 7 4 28, the third wall portion 7 5 1 is provided on one side of the circumferential conductor sides 7 4 6 of the first wall portion 7 5 1 and the second wall portion 7 5 2 in the circumferential direction. 3 is provided, and on the other side, the 〇 2020/175 222 149 卩 (: 170? 2020 /006141

A protruding portion 7 5 1 7 5 2 3 protruding in the direction is provided. The protruding portions 7 5 1 3 and 7 5 2 3 are extra portions in the circumferential direction with respect to the partial winding 7 4 18. As a result, an empty area 3 in which the partial winding 7 4 18 is not accommodated is provided on one side in the circumferential direction in the accommodating portion 7 54. In this case, the vacant area 3 prevents the partial winding 7 4 1 8 in the accommodating portion 7 5 4 from protruding outside the winding line holder 7 4 2.

[0572] In short, the first wall portion 7 51 and the second wall portion 7 52 are arranged on both sides in the circumferential direction of the intermediate winding wire portion 7 4 6 of the partial winding 7 4 1 8 and the intermediate wire portion 7 4 6 thereof. Has an extension portion that extends in the circumferential direction, and one of the extension portions on both sides in the circumferential direction that extends radially from the first wall portion 7 51 and the second wall portion 7 52. 3 walls 7 53 are provided. Further, protruding portions 7 5 1 3 and 7 5 2 3 are provided on one side of the extended portions on both sides in the circumferential direction.

[0573] A resin material as an insulating material is filled in the accommodating portion 754, and the partial winding 741 is accommodated in a state of being molded with the resin material. As a result, the resin layer 7 5 5 is formed on the opposite side of the third wall portion 7 5 3 with the intermediate conductor portion 7 4 6 sandwiched in the accommodation portion 7 54. In this case, the resin material also enters the gaps between the conductors 7 4 3 of the partial winding 7 4 1 8 so that the multiple-wound conductor 7 4 3 comes close to the partial winding 7 4 1. Items are joined together using mold resin as a joining material. In this configuration, the adjacent conductors 7 4 3 that are multiply wound in the partial winding 7 4 1 are joined to each other by the bonding material, so that the conductor 7 7 in the partial winding 7 4 1 is 4 3 can maintain each other in a desired proximity state. In other words, it is possible to maintain the desired state of multiple winding in the partial winding 7 41. Similar to the third wall portion 7 53, the resin layer 75 5 has different thickness dimensions (circumferential dimension) at each position on the radially inner side and the radially outer side. It should be constructed so that the directional dimension becomes large (see Fig. 100). That is, it is preferable that the spacing between the intermediate conductor portions 7 46 of different phases adjacent to each other in the circumferential direction be different between the radially outer side and the radially inner side. As a result, the circumferential length is different on the radially inner side and the radially outer side. 〇 2020/175 222 150 卩(: 170? 2020/006141

In consideration of this, it is possible to properly arrange the intermediate conductor portions 7 46 arranged in the circumferential direction. Note that, in FIG. 100, the third wall portion 753 and the resin layer 755 correspond to the insulating portion in the circumferential direction.

[0574] Instead of the resin mold, the partial winding line 7 4 18 may be solidified by immersing an adhesive agent containing varnish in the containing portion 7 54. Further, both resin mold and varnish impregnation may be performed. Further, when the conductor 743 is a covered conductor whose conductor is covered with an insulating film, the conductors 743 may be fixed (joined) to each other by self-welding of the insulating film. However, it is also possible to adopt a configuration in which the housing portion 754 is not filled with a resin material or the like, that is, the vacant region 3 is provided as a space region.

[0575] The coil module 7408 is assembled from the outside in the radial direction with respect to the cylindrical stator core 7 32, and is the first wall 7 5 1 which is the stator core 7 32 side. Is formed in an arcuate surface with the same curvature as the outer peripheral surface of the stator core 732. This enhances the adhesion of the coil module 7480 to the stator core 732. The second wall part 7 52, which is the side opposite to the stator core, may be linear or arcuate, but in this example, it is concentric with the first wall part 7 5 1. Has been formed.

[0576] In addition, the coil module 7408 is mounted on the stator core 732 with the bent portion 7445 being radially outward, and is disposed on the side of the second wall portion 752 (that is, There is a bent portion 7445 on the side opposite to the first wall portion 7551). Further, in this case, the circumferential distance including the two second wall portions 752 in the pair of straight portions 744 is longer than the circumferential distance including the two first wall portions 751, A curved portion 745 that is radially outward is provided with the same dimension as the longer circumferential distance.

[0577] Also, as shown in Fig. 87 (), in the pair of straight line portions 744 of the coil module 7408, coil coil

In the vicinity of the boundary 0 between the coil end and the coil ends 0 1 and 0 2, there is a protrusion 7 5 that protrudes on the side opposite to the bent part 7 45, that is, on the radially inner side (stator core 7 3 2 side). 6 are provided in two places, upper and lower. 〇 2020/175 222 151 卩(: 170? 2020/006141

In the winding holder 7 4 28, a protrusion 7 5 6 is provided at a position that is the coil end 〇 min 1 on the side of the first crossover 7 4 7 and is axially outside of the boundary min 0. A projecting portion 7 5 6 is provided at a position that is the coil end ◯ 2 on the side of the second transitional portion 7 48 and is on the axially outer side of the boundary portion opening.

[0578] In other words, in the coil module 7408, the first wall portion 751 has a portion (outer portion of the yoke) that extends axially outward from the axial end surface of the stator core 732. In that portion, a projecting portion 7 5 6 projecting toward the stator core 7 32 side from the surface facing the stator core 7 32 in the circumferential direction is integrally formed. The protruding portion 7 56 is formed at the same time as the first wall portion 7 5 1 by injection molding of a resin material, for example.

[0579] When viewed in a cross section of the coil module 7408, as shown in Fig. 88 (slung), it projects so as to project from the first wall portion 7 5 1 on the stator core 7 3 2 side. Parts 7 5 6 are provided. The projecting portion 7 56 has a structure having an inclined surface 7 5 6 3 that is inclined to one side in a range from one end in the circumferential direction of the first wall portion 7 51 to the other end in the circumferential direction. In this example, the protrusions 7 5 6 are formed such that the inner end (inward in the circumferential direction) of the first wall 7 51 is higher in the pair of left and right straight portions 7 44. However, unlike the configuration shown in FIG. 8 8 (b), the protruding portion is formed by making the outer end portion (outer circumferential direction) of the first wall portion 7 5 1 higher in the pair of left and right linear portions 7 4 4. 7 5 6 may be formed.

[0580] Next, the coil module 740 will be described.

[0581] The coil module 7440 differs from the coil module 7408 in the radial direction in which the bent portion 7445 extends, and although there is a difference in the configuration, the basic configuration is The coil module is the same as the coil module 748, and therefore the differences from the coil module 740 will be mainly described here.

[0582] Fig. 89 (3) is a perspective view of the coil module 740, and Fig. 89 (匕) is a side view of the coil module 740. Also, Fig. 90 (3) and (匕) are cross-sectional views showing the cross section of the coil module 740, and Fig. 90 (3) is the 90 8 81 of Fig. 89 (b). 0 Eight line cross section, Fig. 90 〇 2020/175 222 152 卩(: 170? 2020/006141

FIG. 10 is a cross-sectional view of the 90° line of (10). In Fig. 89 (10), the left side of the coil module 740 is the stator core 732 side, and in Fig. 90 (a) and (b) the bottom of the coil module 740 is below. The side is the stator core 7 32 side.

[0583] The coil module 7440 has a partial winding 741 and a winding formed by winding the conductor 743 in multiple turns and an insulating roll integrally provided on the partial winding 741. It has a line holder 7 42. The coil module 7440 has a pair of linear portions 744 extending in parallel to each other in the axial direction, and a curved portion 744 extending in a direction orthogonal to the axial direction on one end side on both sides in the axial direction. It has 5 and is omitted as a whole! -It has a letter-shaped configuration.

[0584] The structure of the partial winding 7 4 1 is basically the same as that of the partial winding 7 4 1. That is, the partial winding 7 41 is similar to the partial winding 7 41 in that the pair of intermediate conductive wire portions 7 4 6 and the pair of intermediate conductive wire portions 7 4 6 are provided in parallel and in a straight line. 6 has a first connecting portion 7 47 connecting to one end in the axial direction and a second connecting portion 7 48 connecting the pair of intermediate conductor portions 7 46 to the other end in the axial direction. Is formed in an annular shape by the intermediate conducting wire portion 7 46, the first connecting portion 7 47 and the second connecting portion 7 48.

[0585] However, in the coil module 7408 and the coil module 74.0, the bending portions 7445 in the state assembled in the stator core 732 differ in the extending direction, and the axial direction is different. Are opposite to each other. As a result, the coil modules 740 and 740 have different configurations.

[0586] Partial winding 7 4 1 At the first crossover 7 4 7 (partial winding 7 4 1 At the coil end 0 1st crossover 7 4 7 on the side of coil 2), bend radially inward. Inward bend part 2 is provided. The partial winding 7 41 1 has an inner curved portion 2 on the coil end 0 2 side and is not bent in the radial direction on the coil end 0 1 side.

[0587] In the partial winding 7 41, from the side of the second crossover 7 48, in detail, from the tip on the side opposite to the bend 7 45, the end of the winding line 7 4 3 3 7 4 3 Have been pulled out. As a result, the coil modules 740 and 740 are assembled to the stator core 732. 〇 2020/175 222 153 卩(: 170? 2020/006141

In the attached state, the winding wire end portions 7 4 3 3 and 7 4 3 are drawn out to the same side in the axial direction (coil end 0 side 1 side).

[0588] Also, as shown in Fig. 90 (a), the winding holder 7 4 2

Similar to the structure of 4 28, the first wall 7 5 1 on the stator core 7 3 2 side, the second wall 7 5 2 on the anti-stable core side, and the first wall 7 5 1 and 2nd wall 7

It has a third wall portion 7 5 3 for connecting 5 2. Further, in the winding holder 7 42, unlike the structure of the winding holder 7 4 28, in the pair of straight portions 7 4 4, the first wall portion 7 5 1 is the wall portion on the bent portion 7 4 5 side. (The wall on the inner side in the axial direction), and the second wall 7 52 is the wall on the side opposite to the bent portion 7 45 (the wall on the outer side in the axial direction).

[0589] The coil module 7440 is to be assembled to the stator core 732 with the bent portion 7445 being radially inward, and is bent to the first wall portion 751 side. have. In this case, the circumferential distance including the two first wall portions 7 5 1 in the pair of straight portions 7 4 4 is shorter than the circumferential distance including the two second wall portions 7 52, which is shorter. A curved portion 7 45 that is radially inward is provided with the same dimension as the circumferential distance.

[0590] In addition, as shown in Fig. 89 (匕), the coil size of the coil module

In the vicinity of the boundary 0 between the coil end and the coil end 〇Mi 1 and 〇Mi 2, there is a protruding portion 7 5 6 that protrudes to the curved portion 7 4 5 side, that is, radially inward (stator core 7 3 2 side). It is provided in two places. In the winding line holder 7 42, the protruding portion 7 5 6 is provided at a position that is the coil end 〇 2 on the side of the first transitional portion 7 47 and is on the axial outer side of the boundary portion 0 0. The coil end on the side of the second crossover 748 is 0, and it is provided at a position on the outer side in the axial direction of the boundary, 0. The structure of the protruding portion 7 56 is similar to that of the winding holder 7 4 28 (see Fig. 90 (b)).

[0591] A method for manufacturing the coil module 7440 will be described. Here, a method for manufacturing the coil module 740 will be described, but the same applies to the coil module 740. First, the partial winding 7 4 18 is manufactured as an air-core winding coil. Concrete 〇 2020/175 222 154 卩 (: 170? 2020 /006141

Specifically, a conducting wire 743 is wound in multiple layers using a jig, and a partial winding 741 having the shape shown in FIG. Then, after the partial winding 7 4 1 is manufactured, the winding holder 7 4 2 can be assembled to the partial winding 7 4 1. At this time, the winding holder 7 4 2 may be individually assembled to the partial winding 7 4 1 in a state of being divided into a plurality. The winding holder 7 42 may be divided into two or three in the radial direction or the axial direction.

[0592] It is also possible to fabricate the coil module 7480 by winding the conducting wire 7443 multiplex around the winding holder 7428. In the winding holder 7 4 28, a protrusion or a groove for guiding the conducting wire 7 4 3 may be provided on the inner peripheral surface of the accommodating portion 7 5 4 for accommodating the partial winding 7 4 1. The partial winding 7 4 1 8 may be tied with an outer conductor 7 4 3 so as not to be unwound.

[0593] Then, in the winding holder 7 4 2 8 in which the partial winding 7 4 18 is integrated, resin is filled into the storage portion 7 5 4. As a result, the resin layer 7 5 5 is formed in the containing portion 7 5 4.

[0594] Next, the state where the coil modules 7408 and 7440 are assembled to the stator core 732 will be described.

[0595] Fig. 91 is a sectional view showing a vertical cross section of the stator 7300, and Fig. 92 is a sectional view of the stator.

FIG. 93 is a cross-sectional view showing a cross section of 730, and FIG. 93 is a cross-sectional view showing the stator core 732, the end ring 733, and the coil module 7408 separated from each other. Note that FIG. 92 is a cross-sectional view taken along the line 9 2 — 92 of FIG.

[0596] As shown in Fig. 91, in the coil modules 7408 and 7440, the bent portions 7445 are axially opposite to each other, and the bending directions are radial opposite to each other. And is assembled to the stator core 7 32. In this case, due to the position and orientation of the bent portion 7445 in each coil module 7408, 74, the interference between the coil modules 7408, 740 adjacent in the circumferential direction is avoided. It has become so. Speaking of partial winding 7 4 1 8 and 7 4 1 m, the partial winding 7 4 1 is provided with an outer bending part 1 and the partial winding 7 4 1 m is provided with an inner bending part 2 2. Are adjacent to each other in the circumferential direction. 〇 2020/175 222 155 卩 (: 170? 2020 /006141

Interference between the matching partial windings 7 4 1 8 and 7 4 1 is prevented. The outer curved portion 1 and the inner curved portion 2 correspond to the interference avoidance portion.

[0597] Supplementing with Fig. 85, the coil module on the coil end 0 side is located outside the coil module 7440 (the first crossover 747 of the partial winding 741) in the axial direction. 7 40 0 (partial winding 7 41 1 2nd transition part 7 48) is located. On the coil end 〇2 side, the coil module 740 (partial winding 7) is located on the axially outer side of the coil module 740 (first winding 741 of the partial winding 741). Each of the partial windings 7 4 1, 7 4 1 is arranged side by side in the circumferential direction while the second crossover 7 4 8) of the 4 18 is located. As a result, the partial windings 741 and 741 are properly arranged in the circumferential direction while avoiding interference with each other, and the size can be reduced.

[0598] Further, as shown in Fig. 91, end rings 7333 are provided at both ends in the axial direction of the stator core 732. Coil modules 740 and 740 are assembled to the stator core 732 with the parts 756 engaged. Here, the protrusions 756 of the coil modules 740 and 740 are axially overlapped with the axial end faces of the stator core 732 (upper end face and lower end face in the figure). It is protruding. As a result, the stator core 7 32 is axially sandwiched by the pair of protrusions 7 5 6 in each coil module 7408, 7440 (that is, it is pressed in the axial direction). State). In this case, the stator core 7 32 is constructed by stacking a plurality of core sheets 7 3 2 3 in the axial direction, and in the stacking direction of the core sheets 7 3 2 3 there is a pair of protrusions 7 5 6. The stator core 7 32 is sandwiched. As a result, the gap between the core sheets 7 3 2 3 is widened, and the disadvantage that the axial length dimension of the stator core 7 3 2 unintentionally increases is suppressed. The pair of protrusions 7 56 function as pressing portions that press the axial end surfaces of the stator core 7 32 in the axial direction from the outside in the axial direction.

[0599] It should be noted that the stator core 7 32 has a protrusion 7 5 6 on the inner side in the radial direction (that is, on the opposite side of the coil modules 7 48, 7 40 from the inner and outer radial directions). Apart from 〇 2020/175 222 156 卩(: 170? 2020/006141

It may stack holding structure for holding a plurality of stacked core sheets 7 3 2 ₃ is provided. In Fig. 91, the stack holding structure is provided at the 0 position indicated by the thick broken line. The laminated holding structure includes welding of core sheets 7 3 2 3 by welding, joining of core sheets 7 3 2 3 by crimping, joining by adhesive (including varnish), and press-fitting inside stator core 7 3 2 in the radial direction. It is conceivable that the outer cylindrical member 7 72 (cylindrical member) assembled by the above may be held in layers by frictional force. By providing the laminated holding structure on the inner side in the radial direction, the axial length dimension of the stator core 7 32 can be more appropriately reduced.

[0600] A restraint ring 760 is attached to the outer periphery of the coil modules 740 and 740. Due to the restraint of the restraint ring 760, the coil modules 740 and 740 are pressed in the direction in which the protruding portion 756 engages with the end ring 733. In particular, since the restraint ring 7600 is provided at a position that axially overlaps with the engaging portions of the end ring 733 and the protrusion 756, the end ring 733 and the protrusion 75 The engagement state of 6 is more reliably maintained.

[0601] The restraint ring 760 is provided on the radially outer side of the coil modules 740, 740, that is, on the side of the rotor 710 facing the magnet 722. Therefore, in order to avoid interference with the rotor 710 side, it is desirable that the radial thickness of the restraining ring 760 be as thin as possible. Further, the coil ends may not be provided in the region of the coil side 0 3 in the axial direction, but may be provided in the regions of the coil ends 0 1 and 0 2. In this case, it is advisable to provide the restraint ring 760 at a position where the coil ends are 〇跳1 and 〇跳2, and are located radially outside of the coil modules 740 and 740. .. However, the position where the restraint ring 760 is provided and the number of restraint rings 760 are arbitrary.

[0602] The restraint ring 760 is attached to the outside of the second wall 752 of the winding holder 742. In other words, the restraint ring 7600 is in contact with the winding holder 742 but is not in contact with the partial winding 741. As a result, even if a metal restraint ring 760 is used to increase the fixing strength, 〇 2020/175 222 157 卩(: 170? 2020/006141

, Insulation deterioration of the partial winding 7 41 can be suppressed.

[0603] Further, as shown in FIGS. 92 and 93, the inclined surface 755 6 3 of the protruding portion 7 5 6 is in contact with the engaging surface 7 34 of the end ring 7 33. The engaging surface 7 34 of the end ring 7 33 corresponds to the first engaging portion, and the protruding portion 7 5 6 of the coil module 7480, 740 corresponds to the second engaging portion. .. Further, the inclined surface 755 6 corresponds to the engaged surface. In this case, the end ring 7 33 is provided with a plurality of engaging surfaces 7 34 continuously in the circumferential direction such that the inclination directions thereof are different from each other, and two engaging surfaces 7 3 4 adjacent to each other in the circumferential direction are provided. The mating surface 7 3 4 forms a recess 7 3 5 (see Fig. 9 3). Then, the protrusions 756 of the two coil modules 740 and 740 are inserted into the recesses 735. The two protrusions 7 5 6 that enter one recess 7 35 have the top of the protrusion 7 5 6 reaching the bottom of the recess 7 35. As a result, the third wall portions 753 of the coil modules 7480 and 7440 contact each other in the circumferential direction. In addition, at the top formed by the two circumferentially adjacent engaging surfaces 7 34, the first wall portion 7 51 and the second wall portion of each coil module 7 48, 7 40 7 5 2 are in contact with or close to each other in the circumferential direction.

[0604] In the above configuration, the protrusions 7 of the two coil modules 740, 740

5 6 are guided in the circumferential direction toward each other by the two engagement surfaces 7 34 forming the recess 7 35. As a result, it is possible to suppress rattling between the two partial windings 7 4 1 that are adjacent to each other in the circumferential direction, and it is possible to preferably suppress the positional displacement of the stator winding 7 3 1 due to vibration or electromagnetic force. In addition, since it is possible to reduce the gap between the intermediate conductors 7 46, the space factor can be expected to improve.

[0605] In addition, each coil module 7408 and 7440 has protrusions 7 5 6 on two first wall portions 7 5 1 that are circumferentially separated from each other, and the protrusions 2 5 6 The part 7 56 abuts on the two engaging surfaces 7 34 of the end ring 7 33 whose inclination directions are opposite to each other. In this case, in each coil module 740, 740, two protrusions 756 are engaged with the end ring 733. 〇 2020/175 222 158 卩 (: 170? 2020 /006141

By engaging with the surface 734 side, it is possible to further reduce the positional displacement in the circumferential direction of the coil modules 7408 and 7440.

[0606] In addition, the restraint ring 7 is placed on the outer side in the radial direction of the coil module 7408, 740.

In the configuration in which 60 is attached, the inclined surface 755 6 3 of the protruding portion 7 56 comes into contact with the engaging surface 7 34 of the end ring 7 33 in a pressed state. As a result, the coil modules 7408 and 740 can be more firmly fixed to the stator core 732.

[0607] When the coil modules 740 and 740 are arranged side by side in the circumferential direction, in the linear portion 744 of each coil module 740 and 740, the storage portion 7 Partial windings 7 4 1 accommodated in 5 4 are arranged at positions separated from each other by a predetermined distance in the circumferential direction. More specifically, the circumferentially adjacent partial windings 7 4 1 are either separated from each other by the third wall 7 5 3 of the winding holder 7 4 2 or the receiving portion 7 4 2 of the winding holder 7 4 2. Separated from each other by free space 3 in 5 4. This ensures the insulation between the partial windings 7 4 1 of different phases that are adjacent to each other in the circumferential direction.

[0608] Two third wall portions 753 are interposed between the different-phase partial windings 741 adjacent in the circumferential direction. In this case, the insulating property at the stator winding 7 31 is further improved by stacking two third wall portions 75 3. Alternatively, two vacant regions 3 are interposed between the different-phase partial windings 7 41 that are adjacent to each other in the circumferential direction. In this case, the free space 3 in the accommodating part 7 5 4 is continuous in the circumferential direction, and more specifically, the free space 3 is resin-molded, so that the insulation in the stator winding 7 3 1 is prevented. The sex is further enhanced. That is, in the configuration shown, the third wall portion of the different winding holder 7 4 2 is provided between the intermediate conductor portions 7 4 6 that are adjacent to each other in the circumferential direction.

7 5 3 are provided consecutively in the circumferential direction, or different winding holders 7 4 2

7 5 2 3 are continuously provided in the circumferential direction.

[0609] Regarding the thickness dimension of the third wall portion 7 53 (see Fig. 88 ( ₃ )), the thickness dimension of the third wall portion 7 5 3 is 2 (ie, 2). It is preferable that the thickness of the claws 13) is larger than the thickness dimension of the first wall 751. That is, 2 X 1 1 3> Ding 1 1 〇 2020/175 222 159 卩(: 170? 2020/006141

Is good. In this case, even if there is a larger potential difference between the intermediate conductors 7 4 6 arranged in the circumferential direction than between the stator core 7 32 and the intermediate conductor 7 4 6, proper interphase insulation is performed. Has become.

[0610] A supplementary explanation will be given on the radial and circumferential insulation structures of the coil modules 740, 740. In the coil module 7408, 7440, the first wall portion 751 and the second wall portion 752 are connected to the intermediate wire portion 746 of the partial windings 741 and 741. While having the third wall portion 753 on one side on both sides in the circumferential direction,

Corresponding to the extended portion, between the intermediate conductor portions 7 46 adjacent to each other in the circumferential direction, the extension portions of different coil modules 7408 and 7440 are provided facing each other in the circumferential direction. .. In this case, the circumferentially adjacent intermediate conductor portions 7 46 are separated from each other by being separated from each other by the extension portion of the first wall portion 7 51 of each coil module 7408, 7440. Insulation is secured. Thereby, in addition to the insulation with the stator core 7 32 in the radial direction in the intermediate conductor portion 7 46, the interphase insulation in the circumferential direction can be suitably realized.

[061 1] In this example, in particular, on one side in the circumferential direction of the intermediate conductors 7 4 6 arranged in the circumferential direction, the third wall portions 7 5 3 of different coil modules 7 48, 7 4 0 are circumferentially arranged. On the other side in the circumferential direction of the intermediate conducting wire portions 7 46 arranged in the circumferential direction, the third wall portion 7 53 does not have the protruding portion.

It is separated by 7 5 2 3. In this case, one first wall portion 7 51 is provided between the stator core 7 32 and the intermediate conductor portion 7 46 arranged in the radial direction, while the intermediate conductor portion 7 4 arranged in the circumferential direction is arranged. Since there are two third wall parts 7 5 3 between the six, the stator core 7 3 2 and the middle conductor part 7 4 6 are provided between the middle conductor parts 7 4 6 arranged in the circumferential direction. It is possible to carry out appropriate interphase insulation while taking into consideration that a larger potential difference is generated than that between.

[0612] In addition, the coil modules 7408 and 74400 are attached to the stator core 732. 〇 2020/175 222 160 卩(: 170? 2020/006141

In the assembled state, the protrusions 756 of the coil modules 740, 740 and the end rings 733 are preferably fixed to each other with an adhesive such as varnish. Further, by filling a synthetic resin or varnish between the protrusions 756 of the coil modules 7480 and 740 and the end ring 7333, rattling may be suppressed. ..

[0613] The plurality of partial windings 741, 741 may have the same conductor cross-sectional area in the state of multiple winding and the number of multiple winding turns. In this case, in the phase windings of each phase, the interlinkage magnetic fluxes of the partial windings 7 4 1 8 7 14 1 forming the parallel circuit can be made uniform. As a result, the potential difference between the partial windings 7418 and 741 can be eliminated, and the generation of circulating current in the parallel circuit can be suppressed. In addition, it is possible to suppress deterioration of motor efficiency and thermal rating performance due to the generation of circulating current.

[0614] In addition, since the plurality of partial windings 7 4 1 and 7 4 1 have the same shape including the crossovers 7 4 7 and 7 48, the coil ends 0 1 and 0 2 are It is possible to equalize the interlinkage magnetic flux including the leakage magnetic flux. As a result, the potential difference between the partial windings 7 4 1 8 and 7 4 1 can be eliminated, and the circulating current in the parallel circuit can be suppressed.

[0615] The stator 7300 is preferably one using any of the following (8) to (○).

(8) In the stator 730, a conductor wire member is provided between each conductor wire portion (intermediate wire conductor portion 746) in the circumferential direction, and as the conductor wire member, the circumferential direction of the conductor wire member in one magnetic pole is used. Is I, the saturation magnetic flux density of the inter-conductor member is 3, and the circumferential width of the magnet 7 2 2 in one magnetic pole is \ZV rn, and the residual magnetic flux density of the magnet 7 2 2 is To X

We use magnetic materials that are related to "Minami".

(Mitsumi) In the stator 7300, an inter-conductor member is provided between the conductor portions (intermediate conductor portions 746) in the circumferential direction, and a non-magnetic material is used as the inter-conductor member. 〇 2020/175 222 161 卩(: 170? 2020/006141

(◯) In the stator 7300, the inter-conductor members are not provided between the conductor portions (intermediate conductor portions 746) in the circumferential direction.

[0616] Next, the inner unit 770 will be described.

[0617] FIGS. 94 and 95 are vertical cross-sectional views of the inner unit 770. Note that the figure

9 5 is a bearing 7 9 1, which supports the rotating shaft 7 01 on the inner unit 7 70.

7 9 2 shows the assembled state. For convenience, in the following description, the bearing 7 91 is also referred to as the first bearing 7 91 and the bearing 7 92 is also referred to as the second bearing 7 92. The first bearing 7 91 is a bearing provided on the base end side in the axial direction of the rotating shaft 7 01, that is, on the connecting shaft 7 05 side, and the second bearing 7 9 2 is the bearing of the rotating shaft 7 01. This is a bearing provided on the tip side.

[0618] The inner unit 770 has an inner housing 771. The inner housing 7 71 has a cylindrical outer cylinder member 7 72 and a cylindrical shape having an outer peripheral diameter smaller than that of the outer cylinder member 7 72, and is arranged inside the outer cylinder member 7 72 in the radial direction. It has an inner cylinder member 773, and a substantially disc-shaped end plate 774 fixed to one end side of the outer cylinder member 772 and the inner cylinder member 773 in the axial direction. Each of these members 772 to 774 may be made of a conductive material, such as carbon fiber reinforced plastic.

It is composed by. The outer cylinder member 7 72 and the end plate 7 74 have the same outer dimensions, and the inner cylinder member 7 7 3 is placed in the space formed by the outer cylinder member 7 72 and the end plate 7 74. Is provided. The inner tubular member 773 is fixed to the outer tubular member 772 and the end plate 774 by fasteners 775 such as bolts.

[0619] Inner housing 7 7 1 Outer cylinder member 7 7 2 Stator core 7

3 2 is fixed. As a result, the stator 7 30 and the inner unit 7 70 are integrated.

[0620] A refrigerant passage 777 through which a refrigerant such as cooling water flows is formed between the outer cylinder member 772 and the inner cylinder member 773. The refrigerant passage 7 77 is provided in an annular shape in the circumferential direction of the inner housing 7 71. Although illustration is omitted, a refrigerant pipe is connected to the refrigerant passage 777, and the refrigerant flowing from the refrigerant pipe passes through the refrigerant passage. 〇 2020/175 222 162 卩(: 170? 2020/006141

After exchanging heat in the passage 7 77, it is allowed to flow again into the refrigerant pipe.

[0621] An annular space is formed inside the inner tubular member 773 in the radial direction, and electrical components constituting an inverter as a power converter may be disposed in the annular space. The electric component is, for example, an electric module in which a semiconductor switching element and a capacitor are packaged. By disposing the electric module in a state of being in contact with the inner cylinder member 773, the electric module is cooled by the refrigerant flowing through the refrigerant passage 777.

[0622] The outer cylinder member 7 72 is a cylindrical boss portion 7 radially inward of the inner cylinder member 7 7 3.

Has 80. The boss portion 780 is provided in the shape of a hollow cylinder, and the rotary shaft 701 is passed through the hollow portion. The boss portion 780 serves as a bearing holding portion for holding the bearings 791, 792, and the bearings 791, 792 are fixed in the hollow portion (see Fig. 95). The bearings 79 1 and 7 92 are, for example, radial bodies having a tubular inner ring, a tubular outer ring arranged radially outside the inner ring, and a plurality of balls arranged between the inner ring and the outer ring. It is a ball bearing, and the outer ring is fixed to the boss 780 so that it is assembled to the inner unit 770.

[0623] In the hollow portion of the boss portion 7800, there are a first fixing portion 781 for fixing the first bearing 791 and a second fixing portion 782 for fixing the second bearing 792. It is provided. The first bearing 7 91 and the second bearing 7 92 have different physiques depending on the supporting position of the rotating shaft 7 01, considering the vibration of the rotor 7 10 and centrifugal load. The first bearing 7 91 that supports the base end side of 0 1 is a larger size bearing, that is, a bearing with a larger supporting load. Therefore, the first fixing portion 7 81 has a larger diameter than the second fixing portion 7 82.

[0624] Also, comparing the first bearing 7 91 and the second bearing 7 92, it can be seen that the first bearing 7 91 has a larger radial internal clearance, that is, a radial clearance, than the second bearing 7 92. It is big. The radial clearance is the amount of axial play between the inner ring, outer ring, and balls of the bearing. Here, the first bearing 7 91 is a bearing that is more susceptible to the vibration and centrifugal load of the rotor 7 10 than the second bearing 7 92. 〇 2020/175 222 163 卩(: 170? 2020/006141

By increasing the radial clearance of 1, the effect of load absorption is enhanced. As a result, the load acting on the boss portion 780 on the base end side of the rotating shaft 701 is reduced, and the runout on the tip side of the rotating shaft 701 is suppressed.

[0625] The first fixing portion 7 81 is a parallel surface 7 8 1 parallel to the axial direction in the boss portion 7 8 0.

3 and an orthogonal surface 7 8 1 which is orthogonal to the axial direction, and the first bearing 7 9 1 is fixed in contact with each of these surfaces. Further, the second fixing portion 7 82 is formed by a parallel surface 7 8 2 3 parallel to the axial direction in the boss portion 7 8 0 and an orthogonal surface 7 82 2 orthogonal to the axial direction. The second bearing 7 92 is fixed in the state of abutting against the surface.

[0626] Further, in the hollow portion of the boss portion 780, a resolver as a rotation sensor is provided on the side of the second fixed portion 782 of the first fixed portion 781 and the second fixed portion 782. A third fixed part 7 8 3 is provided for fixing 800. The third fixing portion 783 is formed by expanding the diameter of the second fixing portion 782 in a stepped shape.

[0627] As shown in FIG. 77, the resolver 800 is composed of a resolver rotor 801, which is fixed to a rotating shaft 701, and a resolver, which is arranged to face the resolver rotor 801 in the radial direction. And a stator 800. The resolver rotor 801 has a disc ring shape and is provided coaxially with the rotating shaft 701 with the rotating shaft 701 being passed through. The resolver stator 802 has a stator core and a stator coil (not shown), and is fixed to the third fixing portion 783 of the boss portion 780.

[0628] As shown in FIG. 94, in the hollow portion of the boss portion 780, at the position between the first fixed portion 781 and the second fixed portion 782 in the axial direction, these are formed. Reduced diameter portions 7 84, 7 8 5 having a diameter smaller than that of each fixed portion 7 81, 7 82 are provided. The reduced diameter portion 7 84 is a hole having a smaller diameter than the first fixed portion 7 81, and the reduced diameter portion 7 85 is a hole having a smaller diameter than the second fixed portion 7 8 2. In addition, the third fixing portion 783 for fixing the resolver 800 is located axially outside the second fixing portion 782, in other words, is located at the tip end side of the rotary shaft 7101. The diameter of the second fixed part is larger than 7 82 〇 2020/175 222 164 卩(: 170? 2020/006141

It is provided as a part. The second fixed portion 7 82 and the third fixed portion 7 83 are provided at positions adjacent to each other in the axial direction.

[0629] In this case, when the outer cylinder member 7 72 is bored by boring or the like, the second fixing portion 7 8 2 and the third fixing portion 7 8 3 are continuously machined coaxially from the same direction. It is possible to Therefore, the coaxiality between the second bearing 7 9 2 fixed to the second fixed portion 7 8 2 and the resolver stator 8 0 2 fixed to the third fixed portion 7 8 3 is increased, and by extension, the resolver rotor 8 0 1 This will increase the concentricity between the resolver stator and the resolver stator 802. In this case, the shake of the resolver stator 8O2 with respect to the resolver rotor 8O1 is reduced, and by extension, the angle detection error in the resolver 8O00 is reduced.

[0630] Next, the bus bar module 8 10 will be described. Busbar module

The 8 10 is electrically connected to the partial winding 7 4 1 of each coil module 7 4 0 in the stator winding 7 3 1, and one end of the partial winding 7 4 1 of each phase is connected in parallel for each phase. It is a winding wire connecting member that connects the other end of each of the partial windings 7 41 at a neutral point. FIG. 96 is a perspective view of the busbar module 810 and FIG. 97 is a cross-sectional view showing a part of a vertical cross section of the busbar module 810.

[0631] The busbar module 8 1 0 includes an annular portion 8 11 and an annular portion.

It has multiple connection terminals 8 1 2 extending from 8 1 1, 3 input/output terminals 8 1 3 provided for each phase winding, and a current detection terminal 8 1 4 connected to the current sensor of each phase. ing.

[0632] As shown in FIG. 97, the annular portion 811 is formed in an annular shape by an insulating member such as resin, and a plurality of bus bars 821 to 82 are embedded in the annular portion 811. 4 are provided. Each of the bus bars 8 2 1 to 8 2 4 includes a bus bar for phase II — 8 2 1, a bus bar for phase V 8 22 2, a bus bar for phase 8 2 3 and a bus bar for neutral point 8 2 4 And are arranged side by side in the axial direction with the plate surfaces facing each other. Then, the connection terminals 8 1 2 are connected to the respective bus bars 8 2 1 to 8 2 4 so as to project radially outward from the annular portion 8 11 1. As shown in Fig. 96, each connecting terminal 8 1 2 is 〇 2020/175 222 165 卩(: 170? 2020/006141

And are arranged so as to extend in the axial direction on the radially outer side.

[0633] In Fig. 98, the connection positions of the connection terminals 8 1 2 to the respective bus bars 8 2 1 to 8 2 4 are schematically shown. In Fig. 98, the left-right direction corresponds to the circumferential direction of the annular portion 811. In Fig. 98, 11 indicates a connection terminal 8 1 2 connected to the 11-phase winding, V indicates a connection terminal 8 1 2 connected to the V-phase winding, and is connected to the phase winding. Shows the connection terminal 8 1 2 connected to the neutral point, and M shows the connection terminal 8 1 2 connected to the neutral point.

[0634] As shown in Fig. 98, the connection terminals 8 1 2 (Min) connected to the neutral point are arranged every other in the circumferential direction, and the connection terminals connected to the phase II winding are arranged between them. Terminal 8 1 2 (ri), connection terminal 8 1 2 (V) connected to the V phase winding, and connection terminal 8 1 2 () connected to the phase winding are arranged one by one. These connecting terminals 8 1 2 are provided in the same number as the winding wire end portions 7 4 3 3 and 7 4 3 of each partial winding 7 4 1 in the coil module 7 40, and the connecting terminals 8 1 2 and The end portions of the line 7 4 3 ₃ and 7 4 3 are connected one by one. At least one of the connection terminal 8 1 2 and the winding wire end portions 7 4 3 3 and 7 4 3 6 is bent or curved in the radial direction as necessary to be in contact with each other. It is advisable to carry out joining by welding, adhesion or the like.

[0635] Further, the annular portion 811 has a plurality of fixed portions 815 on the inner peripheral side, and by attaching fasteners such as bolts to the fixed portions 815, The bus bar module 8 10 is fixed to the end plate 7 74 of the inner housing 7 71.

[0636] Input/output terminal 8 1 3 is the input/output terminal for II phase 8 1 3 II/V phase

8 13 V and phase input/output terminals 8 13 are connected to the bus bars 8 2 1 to 8 2 3 for each phase in the annular portion 8 11 1. Through each of these input/output terminals 81 3, power is input/output from/to an inverter (not shown) with respect to each phase winding of the stator winding 7 31.

[0637] In addition, the annular portion 811 is provided with a current sensor 816 for each phase, and the detection result of the current sensor 8116 is controlled via a current detection terminal 8114. 〇 2020/175 222 166 卩(: 170? 2020/006141

It is output to the device.

[0638] In the rotating electric machine 700 having the above-mentioned configuration, in the stator 7300, a conductor wire member (so-called teeth) is provided between conductor wire portions (intermediate wire conductors 7446) arranged at predetermined intervals in the circumferential direction. ) Is not provided, or even if an inter-conductor member is provided, it is magnetically fragile. Therefore, the magnetic flux of the magnet generated in the rotor 710 is directly linked to the conductor part of the stator winding 731, and there is a concern that the motor efficiency and thermal rating performance may decrease due to the increase of copper eddy loss. .. In particular, in the configuration in which the magnetic flux density is enhanced by the orientation as described above, there is a concern that the effect of copper eddy loss will occur more significantly.

[0639] With respect to this point, in the above configuration, in the stator winding 731, the partial winding 741 is wound in multiple layers between the in-phase conducting wire portions that are circumferentially separated from each other. Configured. The phase winding for each phase was constructed by connecting multiple partial windings 7 4 1 in parallel. This makes it possible to subdivide the cross-sectional area per conductor wire in the stator winding 7 3 1, suppress the generation of copper eddy loss, and improve the efficiency of the motor and the thermal rating performance. You can

[0640] In addition, the number of poles of the magnetic pole is determined by the number of partial windings 7 41 per phase and partial winding.

The number of poles is 4 X 1X1, and the number of poles is 4 x 1X1, and the number of poles is 1\1 for each phase 7 4 1 and 1\1 All of the partial windings 7 4 1 and 9 are connected in parallel. In this example, specifically, the number of partial windings 7 4 1 8, 7 4 1 (1\!) per phase is 6 and the number of poles is 2 4. For example, Fig. 84 shows a coil module 740 of one of the three phases, and six coil modules 740 as a coil module 740 with a partial winding 748. Eight and six coil modules 740 are shown as coil modules 740 with partial winding 740. In each phase winding, six partial windings 7 4 1 and 6 partial windings 7 4 1 are connected in parallel for each phase.

[0641] Speaking from Fig. 86, in the phase windings of the II and V phases, the number of parallels of the partial windings 7 41 is 1 2. In this case all partial windings 7 \¥02020/175 222 167 卩(: 17 2020/006141

By connecting 4 1/8 and 7 4 1 in parallel, the cross-sectional area of each conductor in the stator winding 7 3 1 can be minimized and copper eddy loss can be further reduced. ..

[0642] (Modification 1 6)

In this modification, the configuration of the stator winding 7 3 1 in the rotary electric machine 7 00 is changed. That is, in this example, in the stator winding 731, the coil module 850 shown in FIG. 101 or FIG. 103 is used in place of the coil module 740 described above. In the following, differences from Modification 15 are mainly described. The same components as those in Modification 15 are designated by the same reference numerals, and the description thereof will be omitted.

[0643] In the coil module 8500 of this example, instead of the structure in which the partial winding 741 is integrated into the winding wire holder 742, the partial winding 741 is composed of an insulating material. It is configured to be covered with resin. That is, the coil module 850 is formed by resin-molding the partial winding wire 741, which is an air-core winding coil. The coil module 850, like the coil module 740, is assembled to the stator core 732 so as to be circumferentially arranged radially outside thereof. For example, in FIG. 82, the coil module 750 in the figure is replaced with a coil module 850, which corresponds to the configuration of the stator 730 using the coil module 850.

[0644] The coil module 850 of this example also has two types of coil modules 850 and 850, like the coil module 740. The coil module 8508 among the module 8508 and the coil module 8500 will be described. In the coil module 8508 and 8500, the partial winding 741 is used as the partial winding 741 used in the coil module 7408 and the coil module 7400. Each of the windings 7 4 1 is used, and the same reference numerals are given here and the description is omitted as appropriate.

[0645] FIG. 10 1 (3) is a perspective view of the coil module 8508, and FIG. 〇 2020/175 222 168 卩(: 170? 2020/006141

(13) is a vertical cross-sectional view showing the inside of the coil module 8508. In addition, Fig. 102 (a) and (匕) are cross-sectional views showing the cross section of the coil module 8508, and Fig. 102 (3) is a cross-sectional view of Fig. 10 1 (匕). Fig. 2 8 1 10 2 8 cross section, Fig. 10 2 (匕) is a cross section of 1 0 2 1 1 10 2 in Fig. 10 1 (匕). The left side of the coil module 8508 is the stator core 732 side in Fig. 101 (well), and the coil module 8508 is shown in Fig. 10 (a) and (well). The lower side is the stator core 7 32 side.

[0646] The coil module 8508 has substantially the same shape as the coil module 7408, and is formed in a long annular shape whose longitudinal direction is the axial direction. The coil module 8 50 has a pair of straight portions 8 5 1 extending in parallel to each other in the axial direction, and has a bent portion 8 5 2 extending in a direction orthogonal to the axial direction on one end side on both sides in the axial direction. have. As a result, the coil module 850 is omitted as a whole! -It has a letter-shaped configuration. Partial winding 7 4 1 is embedded in a pair of straight line portion 8 5 1 and curved portion 8 52 of coil module 8 5 0 8. The first crossover section 7 4 7 of the partial winding 7 4 1 8 and the first crossover section 7 4 7 of the second crossover section 7 4 8 correspond to the bend section 8 5 2 of the coil module 8 50 8. As a corresponding portion, an outer bending portion 1 which is bent radially outward is provided.

[0647] As shown in Fig. 10 2 (a), the coil module 8508 is provided so as to surround the partial winding 7 4 1 8 from four sides in the cross section of the partial winding 7 4 1 8. The first wall portion 861 on the side of the stator core 732, the second wall portion 862 on the side of the non-stator core, and the first wall portion 861 and the second wall. It has a third wall portion 863 connecting the portion 862. The third wall portion 8 63 is composed of two wall portions that sandwich the partial winding 7 4 1 from both sides in the circumferential direction. The first wall portion 8 61 is a back yoke side insulating wall, the second wall portion 8 62 is an anti-back yoke side insulating wall, and the third wall portion 8 63 is a circumferential insulating wall. The third wall portion 863 is provided so as to extend toward the center of the circle of the stator core 732. The first wall portion 8 61 and the second wall portion 8 62 extend in the circumferential direction more than the intermediate conducting wire portion 7 46 of the partial winding 7 41. 〇 2020/175 222 169 卩(: 170? 2020/006141

Has a portion (corresponding to an extension portion), and the third wall portion 863 is formed so as to extend in the radial direction from the portion.

[0648] In the coil module 850, the partial winding 7 4 1 8 is covered with a covering portion 8 5 5 made of an insulating material, and the stator core 7 3 5 is covered in the covering portion 8 5 5. The insulating layer on the 2nd side is the first wall 8 61 (back yoke side insulating wall).

[0649] In the coil module 8508, the thickness dimension in the wall thickness direction (radial direction) of the first wall portion 861 is set to 11 and the wall thickness direction of the second wall portion 862 is set to ( If the thickness dimension in the radial direction is Ding 12 and the thickness dimension in the wall thickness direction (circumferential direction) of the third wall 8 6 3 is Ding 13 then the thickness of the second wall 8 6 2 is It is desirable that the thickness dimension 12 is smaller than the thickness dimension 1 1 of the first wall portion 8 6 1 (Ding 1 1 >Ding 12). In the case of this example, the thickness dimensions D11 to D13 are preferably the average thickness of the resin layer from the outer surface of the partial winding 741 to the outer surface of the module. In other words, the second wall 8 6 2 is an insulating wall on the magnet 7 2 2 side (air gap side), and the distance between the magnet 7 2 2 and the partial winding 7 4 1 can be reduced by the thin insulating wall. Can reduce the distance on the magnetic circuit and can be expected to improve performance. When the magnets 7 2 2 and the partial windings 7 4 1 have the same distance, the thickness of the second wall 8 6 2 is reduced by the thickness of the coil 7 The air gap (air gap) between the magnet 7 22 and the magnet 7 22 can be increased, and contact during rotation of the rotor 7 10 can be suppressed.

[0650] Also, the thickness dimension 1 of the first wall portion 8 61 is equal to that of the second wall portion 8 6 2

[0651] The thickness dimension of the third wall portion 863 is preferably the same as the thickness dimension of the first wall portion 861, for example. However, Ding 13> Ding 11 or Ding 13 3 <Ding 11 may be satisfied.

[0652] In the third wall portion 8 63, the thickness dimension 13 is set on the radially inner side and the radially outer side. 〇 2020/175 222 170 卩(: 170? 2020/006141

Differently, the thickness dimension 13 may be larger on the radially outer side. That is, the third wall portion 863 has a tapered cross section that is wider toward the radially outer side. It is preferable that the two third wall portions 7 53 have the same size in the circumferential direction sandwiching the intermediate conductor portion 7 46. In this case, the thickness dimension of the third wall portion 863 is set to be larger on the radial outer side than on the radial inner side, so that the radial inner side and the radial outer side are surrounded. It is possible to properly arrange the intermediate conductor portions 7 46 arranged in the circumferential direction while taking into account the different lengths. In other words, if the thickness dimensions of the third wall portion 8 63 are made uniform in the radial direction, when the partial winding 7 41 has a rectangular cross section, it is possible to use two adjacent windings in the circumferential direction. The intermediate conductor portion 7 46 is too close on the side of the third wall portion 8 63 and too far on the opposite side. Therefore, there is a concern that the rotating magnetic flux becomes uneven in the circumferential direction. On the other hand, with the configuration of this example, it is possible to equalize the rotating magnetic flux in the circumferential direction. Also, the insulation performance in the circumferential direction can be made uniform.

[0653] Regarding the relationship with the bent portion 852 of the coil module 8550, in the pair of straight line portions 851, the first wall portion 861 is opposite to the bent portion 852. Is a wall portion (a wall portion on the inner side in the axial direction), and the second wall portion 8 62 is a wall portion on the side of the bent portion 8 52 (a wall portion on the outer side in the axial direction).

[0654] The coil module 8550 is assembled from the outside in the radial direction with respect to the tubular stator core 732, and the first wall portion 861 which is the stator core 732 side. Is formed in an arcuate surface with the same curvature as the outer peripheral surface of the stator core 732. As a result, the adhesion of the coil module 8508 to the stator core 732 is enhanced. The second wall portion 8 62, which is the side opposite to the stator core, may be linear or arcuate, but in this example, it is concentric with the first wall portion 8 6 1. Has been formed.

[0655] Also, the coil module 8508 is to be assembled to the stator core 732 with the bent portion 852 being radially outward, and is located on the side of the second wall portion 862 (ie, There is a bent portion 852 on the opposite side of the first wall portion 861). Also, in this case, the circumferential distance including the two second wall portions 8 62 in the pair of straight portions 8 51 is 〇 2020/175 222 171 卩(: 170? 2020/006141

, And is longer than the circumferential distance including the two first wall portions 86 1 and has a bent portion 852 that is radially outward and has the same dimension as the longer circumferential distance.

[0656] In addition, as shown in Fig. 101 (匕), in the pair of straight portions 85 1 of the coil module

In the vicinity of the boundary 0 between the coil end and the coil end ◯1 and 〇2, there are two protrusions 866 on the opposite side of the curved portion 852, that is, on the inside in the radial direction (on the side of the stator core 732). Is provided

[0657] When viewed in a cross section of the coil module 8508, as shown in Fig. 102 (匕), the protruding portion 866 is provided so as to protrude from the first wall portion 86 1 on the stator core 732 side. ing. The protruding portion 866 is configured to have an inclined surface 8663 that is inclined to one side in the range from one circumferential end to the other circumferential end of the first wall 861. In this example, the protruding portion 866 is formed such that the inner end portion (the inner side in the circumferential direction) of the first wall portion 86 1 is higher in the pair of left and right linear portions 85 1. However, unlike the configuration shown in FIG. 102 (b), the protruding portion 866 is formed such that the outer end portion (outer circumferential direction) of the first wall portion 86 1 is higher in the pair of left and right straight portions 85 1. May be.

[0658] Next, the coil module 850M will be described.

[0659] The coil module 850M has the same basic configuration as the coil module 8508, although the bending direction of the bent portion 852 differs from that of the coil module 8508 in the radial direction. Therefore, the difference from the coil module 8508 will be mainly described here.

[0660] Fig. 103 (3) is a perspective view of the coil module 850, and Fig. 103 (13) is a vertical cross-sectional view showing the inside of the coil module 850. Fig. 104 (3), (is a cross-sectional view showing the cross section of the coil module 850, and Fig. 104 (3) is a cross-section taken along line 104-81 of Fig. 103 (b). Fig. 104 (匕) is a cross-sectional view of Fig. 103 (b), which shows the line 104 and line 104. In Fig. 103 (Fig. 103), the left side of the coil module 850 is the stator. 〇 2020/175 222 172 卩(: 170? 2020/006141

It is the core 7 32 side, and in Fig. 10 4 (a ), (b ), the coil module 8 5

The lower side of 0m is the stator core 7 32 side.

[0661] The coil module 8500 has substantially the same shape as the coil module 7400, and is formed in a long annular shape whose longitudinal direction is the axial direction. The coil module 8500 has a pair of straight portions 851 extending in parallel to each other in the axial direction, and has a bent portion 85 extending in a direction orthogonal to the axial direction at one end on both sides in the axial direction. Have two. As a result, the coil module 8500 is abbreviated as a whole! -It has a letter-shaped configuration. Partial winding 7 4 1 m is embedded in a pair of straight part 8 5 1 and curved part 8 52 of coil module 8 5 0 m. Partial winding 7 4 1 The first crossover section 7 4 7 and the second crossover section 7 4 8 of the Nomi, the first crossover section 7 4 7 is connected to the curved section 8 5 2 of the coil module 8 50. As a corresponding part, an inner bending part 2 which is bent inward in the radial direction is provided.

[0662] Also, as shown in Fig. 104 (a ), the coil module 8500 is arranged so that the partial winding 741 is surrounded from four sides in the cross section of the partial winding 741. Like the coil module 8508, the first wall portion 861 on the side of the stator core 732 and the second wall portion 862 on the side of the non-stator core are provided. It has a first wall portion 8 6 1 and a third wall portion 8 6 3 connecting the second wall portion 8 6 2. The third wall portion 8 63 is composed of two wall portions that sandwich the partial winding 7 41 1 from both sides in the circumferential direction.

[0663] The coil module 8500 is to be assembled to the stator core 732 with the bent portion 852 being radially inward, and is bent to the side of the first wall portion 861. have. In this case, the circumferential distance including the two first wall portions 8 61 in the pair of straight portions 8 51 is shorter than the circumferential distance including the two second wall portions 8 62, which is shorter. A curved portion 852 is provided on the inner side in the radial direction with the same dimension as the circumferential distance.

[0664] Also, as shown in Fig. 103 (匕), the coil die and the coil end 〇跳1 and 〇巳2 are connected to each other in the pair of straight line portions 851 of the coil module 850. 〇 2020/175 222 173 卩(: 170? 2020/006141

In the vicinity of the boundary part 0 of the above, protrusions 8 6 6 are provided at two upper and lower portions, which protrude to the curved portion 8 52 side, that is, the radially inner side (stator core 7 32 2 side). The structure of the protruding portion 8666 is also the same as that of the coil module 8508 (see Fig. 104 (depression)).

[0665] Next, a state in which the coil modules 8508 and 8500 are assembled to the stator core 732 will be described. In addition, in the assembled state, the configuration of the longitudinal cross section of the stator 730 is similar to the configuration using the coil modules 740 and 740, so refer to Fig. 91 for details. Also in the configuration of this example, as in the case of FIG. 91, the coil module 8 5 is attached to the stator core 7 32 while the upper and lower projections 8 6 6 are engaged with the end ring 7 33. 08,

8500 has been assembled. Further, the stator core 7 32 is in a state of being sandwiched in the axial direction by a pair of projecting portions 8 6 6 in each coil module 8508, 8500. The configuration of the transverse plane of the stator 7300 will be described below with reference to FIG.

[0666] As shown in Fig. 105, the engaging surface 734 of the end ring 733 has a sloping surface 866 on the protruding portion 866 of the coil module 8550, 8500. 3 is in contact. The inclined surface 866 3 corresponds to the engaged surface. Then, in the end ring 7 33, the two engaging surfaces 7 34 adjacent to each other in the circumferential direction are formed in the recess 7 35,

Each of the two coil modules 850 and 8500 has a protruding portion 8666 to be inserted therein. As a result, the third wall portions 863 of the coil modules 850 and 850 are in contact with each other in the circumferential direction.

[0667] When the coil modules 8550, 8500 are arranged side by side in the circumferential direction, the partial winding line 7 4 is formed in the straight line portion 8 5 4 of the coil modules 8508, 8500. 1 are arranged at positions separated from each other by a predetermined distance in the circumferential direction. More specifically, the circumferentially adjacent partial windings 7 4 1 are separated from each other by the third wall 8 6 3 of the coil modules 8 5 0 8 and 8 5 0. This ensures the insulation between the partial windings 7 4 1 of different phases that are adjacent in the circumferential direction. In this case, in particular, between the adjacent partial windings 7 41 in the circumferential direction, 〇 2020/175 222 174 卩(: 170? 2020/006141

By stacking two 3 wall portions 8 6 3 on top of each other, the insulation at the stator winding 7 3 1 is further enhanced.

[0668] (Modification 15 and Modification 16)

Hereinafter, a configuration in which a part of the rotating electric machine 700 shown in Modifications 15 and 16 is modified will be described.

[0669] The shape of the protrusions 7 5 6 may be changed in the coil module 7 40.

.. Here, the difference from the configuration of FIG. 92 will be described. For example, as shown in Fig. 106 (3), in each of the first wall portions 7 51, the protruding portions 7 56 may be configured to have one inclined surface inclined in the same direction in the circumferential direction. Good. Further, as shown in FIG. 106 (distance), the projecting portion 756 of each first wall portion 751 may have two inclined surfaces inclined in the circumferential direction. Further, as shown in FIG. 10 6 (○), the protruding portion 75 6 may be formed in a trapezoidal shape. In all of Figs. 10 6 (3) to (○), the engaging surface 7 of the end ring 7 3 3 is fitted to the shape of the protruding portion 7 5 6 so that the protruding portion 7 5 6 can be fitted. 3 4 are formed. It is to be noted that the holding strength is enhanced as the respective surfaces of the projecting portion 7 56 and the end ring 7 33 which engage with each other in the circumferential direction are provided at an angle parallel to the radial direction.

[0670] As shown in Fig. 107, the coil module 740 and the end ring 733 may be engaged indirectly instead of directly. Figure 10 7 ( ₃ ) is a cross-sectional view of the stator 7 30 with the coil modules 7408, 74 0 assembled to the stator core 7 32, and Figure 10 ( ₃ ). 10] is a cross-sectional view showing the stator core 7 32, the end ring 7 33, and the coil module 7408 separated from each other. In this case, the end ring 733 and coil module 740,

Recesses 841 and 842 are formed in the first wall portion 751 of 7440 respectively, and the surfaces on which the recesses 841 and 842 are formed face each other. There is. An insulating layer 843 made of an insulating material such as synthetic resin is provided between the facing surfaces. The recess 841 on the side of the end ring 733 corresponds to the first engaging portion, and the recess 842 on the coil module 7408, 740 side corresponds to the second engaging portion, and the insulation is provided. Layer 843 corresponds to the middle section. In addition, the concave portion 8 4 of the first wall portion 7 5 1 〇 2020/175 222 175 卩 (: 170? 2020 /006141

1 and the recess 842 on the side of the end ring 733 may be formed in different positions or shapes.

[0671] In short, the recess on the end ring 7 3 3 side 8 4 1 and the coil module 7 4

It is provided so as to face the concave portion 8 4 2 on the side of the 0 8 and 7 4 0 side in the radial direction in a separated state, and an insulating layer 8 4 3 is provided between the concave portions 8 4 1 and 8 4 2. ing. Then, with the recesses 841 and 842 engaged with the insulating layer 843 in the circumferential direction, the coil modules 7408 and 7440 are attached to the stator core 732. Tomomi is fixed.

[0672] In the stator core 7 3 2, coil modular Yule 7 4 0 engageable become engaging portion (first engagement portion), the core sheet 7 3 2 ₃ sheets outer edge formed concave convex It may be formed by a shape. Specifically, as shown in FIG. 1 0 8 (a), the core sheet 7 3 2 _3, the width direction of one waveform shape (irregular shape)

The other has a linear shape, and is laminated in the axial direction while being formed in an annular shape with its corrugated side radially outward. As a result, a cylindrical stator core 7 32 is formed as a whole. In this case, in the stator core 7 32, the core sheet 7 32 3 has an uneven shape in which unevenness is repeated at predetermined intervals in the circumferential direction on the radially outer side (that is, the side where the stator winding 7 31 is assembled). The layers are stacked with the positions of the irregularities slightly shifted in the axial direction. In the axial direction, it is preferable that the unevenness positions of the core sheet 7323 be displaced by a certain amount in the circumferential direction. As a result, the generation of cogging torque is suppressed.

[0673] Further, FIG. 1 0 8 (spoon), as shown in (〇), the stator core 7 3 2, the unevenness of co Ashito 7 3 2 ₃ recess 8 4 1 as a first engagement portion Has been formed. In addition, a recess 842 is formed as a second engaging portion in the first wall portion 751 of the coil module 7440. Then, an insulating layer 843 as an intermediate part was interposed between the recess 841 on the stator core 732 side and the recesses 842 on the coil module 7480, 7440 side. In this state, the coil modules 740 and 740 are assembled to the stator core 732. In this case the stator core 〇 2020/175 222 176 卩(: 170? 2020/006141

Since the unevenness of the core sheet laminated body in 7 32 is used as the first engaging portion to engage with the second engaging portion on the coil module 7 40 side, the cogging torque is suppressed. The circumferential positioning of the coil module 740 can be preferably performed.

[0674] In the configuration shown in Fig. 108, the stator core 732 does not have to have a helical core structure, and a plurality of core sheets 732 May be laminated in the axial direction. In this case, the core sheet 7 3 2 ₃ is a concave-convex irregularities are repeated at predetermined intervals in the circumferential direction at the outer peripheral side thereof, and the position of the irregularity in the axial direction in the circumferential Direction by a predetermined amount It is preferable that they are stacked in a shifted state.

[0675] The coil wire holder 7 4 2 of the coil module 7 4 0 may be configured to have only a part of the first wall portion 7 51, the second wall portion 7 52 and the third wall portion 7 53. Good. Specifically, as shown in Fig. 109 (a), in the coil wire holder 7 4 2 8 of the coil module 7 48, the first wall portion 7 5 1, the second wall portion 7 5 2 and the Of the three wall portions 753, the second wall portion 752 may be deleted and only the first wall portion 751 and the third wall portion 753 may be provided. In other words, the wall portion (second wall portion 752) on the side opposite to the stator core side may be removed in the winding holder 7424. In addition, in the configuration having only the first wall portion 751 and the third wall portion 753, the third wall portion 753 may be provided on the same side in the circumferential direction.

[0676] As shown in Fig. 109 (匕), in the coil wire holder 7 4 2 8 of the coil module 7 48, the first wall 7 5 1, the second wall 7 5 2 and the third wall Of the portions 753, the second wall portion 752 may be deleted, and the third wall portions 753 may be provided on both sides in the circumferential direction of the intermediate conductor portion 746.

[0677] Also, as shown in Fig. 109 (○), in the coil wire holder 7 4 2 8 of the coil module 7 4 0 8, the first wall 7 5 1, the second wall 7 5 2 and Of the third wall portion 753, the second wall portion 752 and the third wall portion 753 may be deleted and only the first wall portion 751 may be provided. In other words, in the winding holder 7 4 28, the wall portion on the side opposite to the stator core (the second wall portion 7 52) and the isolation wall in the circumferential direction (the third wall portion 7 5 3) are provided. 〇 2020/175 222 177 卩(: 170? 2020/006141

May be deleted. In this case, in the state where the coil modules 7408 and 7440 are assembled to the stator core 732, the partial windings 741 adjacent to each other in the circumferential direction should be insulated from each other. The circumferential width of the first wall 7 51 is made larger than the circumferential width of the partial winding 7 41, and the circumferential extension of the first wall 7 51 is partially wound. The structure is provided on both sides of 7 41 in the circumferential direction.

[0678] In the configurations of Fig. 109 ( ₃ ) to (○), the partial winding 7 4 1 is molded with a resin material as an insulating material, and the resin molding causes the wall of the winding holder 7 4 2 8 to have a wall. The part and the partial winding 7 41 are preferably integrated. When using the configurations shown in FIGS. 109 (3) to (◯), it is preferable that the coil module 740 and the coil module 740 both have the same configuration. However, it is also possible to use a combination of different configurations for the coil module 748 and the coil module 740.

[0679] The following configuration may be used as a configuration for engaging the coil module 7440 with the end ring 733. In the configuration shown in Fig. 110, a plurality of engaging holes 871 are formed as the first engaging portions in the end rings 733 on both sides in the axial direction, while the stator core 7 of the coil module 740 is formed. On the 32 side wall (first wall 751), engaging pins 872 are provided at two axial positions as second engaging parts. The engagement holes 871 are provided at predetermined intervals for each coil module 740, and are oriented so as to open radially outward. The engagement pin 872 is an insert member that is partly embedded in the coil module 740 (winding holder 742) and insert-molded into the coil module 740. In this configuration, with the engaging pin 872 of the coil module 7440 kneaded in the engaging hole 871 of the end ring 733, each coil module is attached to the stator core 732. 7 40 is assembled. In this state, the engagement pin 872 engages with the engagement hole 871 of the end ring 733 to improve the circumferential position accuracy of each coil module 740 with respect to the stator core 732. It is designed to be used. This configuration can also be applied to the coil module 850. 〇 2020/175 222 178 卩(: 170? 2020/006141

[0680] In the configuration shown in Fig. 1 1 1 (3), a plurality of recesses 8 73 are provided as the first engaging portions at the radially outer portions of the stator core 7 32 at both axial ends. ing. FIG. 1 11 (13) shows a plurality of recesses 8 73 provided at equal intervals in the circumferential direction in the front view of the stator core 7 32. The recessed portion 873 is provided for each coil module 7440. Also, the stator core 7 32 side wall portion (first wall portion 7 51) of the coil module 7 40 is provided with two engagement keys _ 8 7 4 at the two axial positions as the second engagement portions. Is provided. The engagement key 8 74 is an insert member that is part of the coil module 7 4 0 (winding holder 7 4 2) and is insert-molded into the coil module 7 4 0. In this configuration, with the engaging key 874 of the coil module 740 engaged in the recess 873 of the stator core 732, each coil module is attached to the stator core 732. Le 7 40 is assembled. In this state, the accuracy of the circumferential position of each coil module 7 4 0 with respect to the stator core 7 3 2 is improved by the engagement of the engagement key _ 8 7 4 with the recess 8 7 3 of the stator core 7 32. It is like this.

[0681] The engagement key _ 874 is preferably a magnetic body. By making the engaging key _ 8 7 4 a magnetic substance, the recess 8 7 3 of the stator core 7 3 2 It will be filled with a magnetic material. In this case, even in the configuration in which the recess 873 is formed in the stator core 732, it is possible to suppress the generation of cogging torque due to the formation of the recess. This configuration can also be applied to the coil module 850.

[0682] In the configuration shown in Fig. 1 12 (a), a plurality of axially extending concave portions 8 75 are provided as the first engaging portions on the outer peripheral surface of the stator core 7 32 on the radially outer side. Has been. FIG. 1 13 (8) shows a plurality of recesses 8 75 provided at equal intervals in the circumferential direction in the front view of the stator core 7 32. The recess 875 is provided linearly in each coil module 740 in a direction parallel to the axial direction. Also, on the wall portion (first wall portion 7 51) of the coil module 7 40 on the side of the stator core 7 32, as a second engaging portion, a convex engaging convex portion 8 7 extending in the axial direction is formed. 6 are provided. The engaging convex portion 8 7 6 is, for example, a part of the first wall portion 7 5 1 〇 2020/175 222 179 卩(: 170? 2020/006141

It is formed so as to extend inward. In this configuration, as shown in Fig. 11 (13), the stator core 7 3 2 is fixed with the engaging protrusions 8 7 6 of the coil module 7 4 0 engaged with the recesses 8 7 5. Each coil module 7 4 0 is assembled to the child core 7 32. In this state, by engaging the engaging projections 876 with the recesses 875 of the stator core 732, the circumferential position accuracy of each coil module 740 with respect to the stator core 732 is improved. It is designed to be used.

[0683] As shown in Fig. 1 13 (distance), the recesses 8 75 of the stator core 7 32 may be provided in a direction oblique to the axial direction. That is, the concave portion 875 is provided with a skew. The engaging projection 876 on the coil module 740 side is also oriented in the same direction. In this case, even if the stator core 7 32 is formed with the recess 875, generation of cogging torque due to the formation of the recess can be suppressed. This configuration can also be applied to the coil module 850.

[0684] In the configuration shown in Fig. 114, in the coil module 740, a plate-shaped pressing portion is provided at two axial locations on the stator core 732-side wall portion (first wall portion 751). Is provided with a pressure plate 877. The pressing plate 877 is partially inserted into the coil module 740 (winding holder 742) and insert-molded into the coil module 7470. In this configuration, in the state where each coil module 7 40 is assembled to the stator core 7 32, the pressing plate 8 7 7 of the coil module 7 40 contacts the axial end surface of the stator core 7 32. By making contact with each other, the minute gap between the core sheets in the stator core 7 32 can be made as small as possible, and in turn the axial length of the back yoke can be reduced. This configuration can also be applied to the coil module 850.

[0685] In the configuration shown in Fig. 1 15 ( ₃ ), the annular plate-shaped spacer 8 8 1 is fixed while being in contact with the axial end surface of the stator core 7 32. In addition, the coil module 740 has a wall portion (first wall portion 571) on the side of the stator core 732 that extends axially outward from the axial end surface of the stator core 732. The outer part) is provided with a protruding part 7 5 6 as a pressing part. The protruding portion 7 56 is smaller than the radial width of the stator core 7 32 (that is, the radial width of the core sheet). 〇 2020/175 222 180 卩(: 170? 2020/006141

While having a large protruding dimension, spacer 881 has the same radial width as stator core 732. That is, the spacer 881 is configured such that the amount of radial overlap with the axial end surface of the stator core 732 is larger than that of the protrusion 756. The spacer 881 is preferably thicker than the core sheet. Although not shown, both ends of the stator core 7 32 in the axial direction have the same structure.

[0686] As shown in Fig. 1 15 (匕), when the coil modules 7 40 are assembled to the stator core 7 32, the spacers 8 8 1 Are pressed in the axial direction. In this state, the spacer 881 uniformly presses the entire axial end surface of the stator core 732 in the axial direction. As a result, even if the protruding amount of the protruding portion 7 56 is relatively small, the warp of the edge portion of the core sheet at the stator core 7 32 is suppressed. The spacer 8 8 1 does not necessarily have to have the same radial width as the stator core 7 32, but the amount of radial overlap of the stator core 7 32 with respect to the axial end surface of the stator core 7 32 is a protrusion 7 5 2. Any configuration larger than 6 will do. This configuration can also be applied to the coil module 850.

[0687] A part of the configuration shown in Fig. 115 ( ₃ ) may be modified to obtain the configuration shown in Fig. 116 ( ₃ ). In this case, in the spacer 8 81, the axial end face, that is, the surface facing the protrusion 7 56 is formed with a recess 8 8 1 3 extending in the axial direction, and at the same time, in the radial outside (coil module 7 An inclined surface 8 81 is formed at the corner of the 40 side. The inclined surface 8 81 is formed in a linear shape or an arc shape protruding outward. On the other hand, the projecting portion 7 5 6 of the coil module 7 4 0 has a hook shape, and the tip of the protruding portion 7 5 6 is engaged with the recess 8 8 1 3 of the spacer 8 8 1. Part 7 5 7 3 is formed. Further, the projecting portion 7 56 is formed with an opposed inclined surface 75 7 facing the inclined surface 8 81 of the spacer 8 81.

[0688] As shown in Fig. 1 15 (匕), when each coil module 7 40 is assembled to the stator core 7 32, the engaging portion 7 5 7 of the protrusion 7 5 6 is 3 enters the recess 8 8 1 3 of the spacer 8 8 1 and is in an engaged state. By this, 〇 2020/175 222 181 卩(: 170? 2020/006141

The radial movement of the coil module 7400 with respect to the stator core 732 is restricted, and the axial pressing function of the stator core 732 by the coil module 740 can be suitably maintained.

[0689] Further, when the coil modules 740 are assembled, the slopes 8 8 1 of the spacers 8 8 1 are pressed by the opposing slopes 7 5 7 of the protrusions 7 5 6 to push the space. It is possible to properly exert the pressing force on the spacer 881.

[0690] The following configurations may be used as the assembly structure of the coil modules 7480, 740 and the coil modules 8508 and 8500 with respect to the stator core 732. Here, on the one axial side and on the other axial side of the stator core 7 32, the stator core 732 has different protrusions 756 (pressing portions) from the coil modules 7408 and 7440. It is configured to press the axial end face of 7 32.

[0691] Specifically, as shown in Fig. 117 (a), in the coil module 7408, the coil core 7408 is attached to the wall (first wall 751) on the stator core 732 side. Is provided only on the upper side of the figure with respect to both sides of the stator core 7 32 in the axial direction. Further, as shown in Fig. 117 (10), in the coil module 74, the stator core 7 3 2 side wall (first wall 7 5 1) has a stator core 7 The protrusions 7 5 6 are provided only on the lower side of the figure on both sides in the axial direction of 32. In both Fig. 1 17 (3) and (匕), the coil module 7408, 7440 has a protrusion 756 on the side opposite to the bend 7445.

[0692] Then, as shown in Fig. 11 (3), (匕), the axial direction of each coil module 740, 740 is adjusted so that the positions of the protrusions 756 are reversed. The coil modules 7408 and 7440 are mounted on the stator core 732 with their directions (the directions of the bent portions 7445) staggered. In this configuration as well, the axial end surface of the stator core 7 32 is pressed by the projecting portions 7 5 6 of the coil modules 7 48 and 7 40.

[0693] In this case, the coil module 7408 that presses the axial end surface from one axial side of the stator core 732 and the axial end from the other axial side of the stator core 732. 〇 2020/175 222 182 卩 (: 170? 2020 /006141

By adjusting the relative position in the axial direction with respect to the coil module 740 that presses the surface, it becomes possible to appropriately adjust the axial pressing force on the stator core 7 32. For example, even if there is a product thickness tolerance due to an error in the thickness of the core sheet or variations in the number of sheets in the stator core 7 32, apply a constant pressing force to the stator core 7 32. You can

[0694] Note that, as described above, the axially end faces on both sides of the stator core 7 32 are pressed by the projecting portions 7 56 of the different coil modules 7408 and 7440. Coil module 740 with two protrusions 756 in the direction,

It is also possible to use 7400. In this case, one of the two protruding portions 7 5 6 in the axial direction is brought into contact with the axial end surface of the stator core 7 32, and the other is not brought into contact with the axial end surface of the stator core 7 32. And it is sufficient.

[0695] Coil modules 7 40, 8 40 that are adjacent to each other in the circumferential direction, or each coil module 8 5 0, 8 50 It is also possible to adopt a configuration in which the four hundred eighty-four thousand or eighty eight thousand eighty eight and eight thousand five thousand coil modules are fixed to each other. Specifically, as shown in Fig. 118, which is a front view of the coil modules 7408 and 7440, as shown in FIG. A concave portion 883 is formed on the side surface, and a convex portion 884 is formed on the other side surface in the circumferential direction. These recesses 883 and protrusions 884 are coil module 7

3rd wall part of 480, 740 (or each coil module 850, 8)

It is recommended to be installed on the third wall 863) of Tomomi. When the coil modules 740 and 740 are assembled to the stator core 732, the adjacent coil modules are engaged by the recesses 883 and the protrusions 884. The relative movement in the axial direction is restricted.

[0696] With the above configuration, it is possible to suppress a decrease in the axial pressing force with respect to the core sheet, which is caused by the axial displacement of the coil modules 740 and 850. This makes it possible to more appropriately reduce the axial length of the stator core 7 32. 〇 2020/175 222 183 卩(: 170? 2020/006141

[0697] In the configuration shown in Fig. 119, when the coil modules 740, 740 are assembled to the stator core 732, the coil modules 740, 7 40 and the stator core 7 32 are integrally molded with an insulating material. That is, the stator core 7 32 and each coil module 748, 740 are integrally covered with the covering layer 886.

[0698] In this case, a plurality of coil modules 740, 740 and stator core 7 3

It can be suitably assembled to 2. In addition, the coil module 7408, 740, is partially wound between the first wall 751 (back yoke side insulating wall) and the covering layer 886 by partial winding 741/8, 741. It is possible to arrange them with 6 intervening, and it is possible to preferably realize radial insulation in the partial winding 7 4 1.

[0699] Further, in the configuration of Fig. 119, since the coating layer 886 is provided so as to cover the outer peripheral side of each coil module 7408, 740, the coating layer 886 is provided. This makes it possible to push each coil module 740, 740 in the radial direction. As a result, a plurality of coil modules 740,

It is possible to preferably maintain the state in which the 7 40 0 is assembled.

[0700] Also, in the configuration of Fig. 119, the axial end surface of the stator core 7 32 (the axial facing surface that faces the second engaging portion of the base member) and the projection of the first wall portion 7 5 1 It is said that resin as a filling material is filled between the part 7 56 (second engaging part). In this case, even if there is a gap between the axial end surface of the stator core 7 32 and the protruding portion 7 56 of the first wall portion 7 51, the gap is filled by the filling material, and the fixing The axial relative displacement of the coil modules 7408 and 7440 with respect to the child core 732 is suppressed. As a result, rattling of the coil modules 740 and 740 can be suppressed, and the coil modules 748 and 740 can be properly fixed to the stator core 732.

[0701] Range including stator core 7 32 and coil module 7 4 0 (partial winding 7 41) in the axial direction both ends thereof, and side part of coil module 7 40 opposite to the stator core side in ^_ body is resin-molded, of the cover portion which is formed by resin molding, covering the axial end surface of the stator core 7 3 2 in the axial direction on both sides 〇 2020/175 222 184 卩 (: 170? 2020 /006141

The end surface covering portion may be configured as a pressing portion that presses the axial end surface of the stator core 7 32 in the axial direction from the outside in the axial direction.

[0702] Specifically, as shown in Fig. 120 (a), both axial end surfaces of the stator core 732, which is a core sheet laminated body, are compressed and pressed by a pressing jig, and the pressure is applied. A plurality of coil modules 7 40 can be assembled on the outer side in the radial direction of the stator core 7 32 under pressure. Then, as shown in FIG. 1 2 0 (b), pressing left pressure state, and a resin molding the stator core 7 3 2 and the coil module 7 4 0 ^_ in the body, the axial direction of the stator core 7 3 2 The coating layer 8 88 is formed in a range including both end portions and a side surface portion on the outer peripheral side (opposite side of the stator core) of the coil module 740. After the molding resin has hardened, the “pressurizing jig” is removed and the compression and pressing by the pressing jig is released. In this case, the stator core should be

The end face covering portion 889 that covers the axial end face of 732 functions as a pressing portion.

[0703] In this configuration, the coating layer 8 88 formed by resin molding is formed so as to cover the end surface coating portions 8 8 9 that are both axial end portions thereof.

8 8 9 The distance between them is maintained without expanding. As a result, the end surface covering portion 889 can exert a function of pressing the stator core 732 in the axial direction.

[0704] In the stator 7 3 0 1 2 1, the stator core 7 3 2 radially inner (opposite the co Irumoju ^_ le 7 4 0), one axial direction of the stator core 7 3 2 The tubular member 8 91 is fixed from the side. The tubular member 8 91 corresponds to, for example, the outer tubular member 7 72 of the inner housing 7 7 described above. In the cylindrical member 8 91, the stator core 7 32 is assembled in the axial direction of the stator core 7 32 by projecting it toward the stator core 7 32 on the peripheral surface (outer peripheral surface) on the side where the stator core 7 32 is assembled. A stepped contact portion 892 that contacts the end face is provided. In this case, on the side where the abutting portion 8 92 of the tubular member 8 91 is provided in the axial direction, the bending portion 7 4 5 of the coil module 7 40 (the outer bending portion of the partial winding 7 4 1 is 1) is bent on the side opposite to the tubular member 8 91 in the radial inside and outside.

[0705] In the above configuration, the axial end surface of the stator core 7 32 is the contact portion of the tubular member 8 91. 〇 2020/175 222 185 卩(: 170? 2020/006141

Since it is in contact with the tubular member 8 9 1, the stator core 7 3 2 is suitable for the tubular member 8 9 1 in a state where the axial position of the tubular member 8 9 1 is determined. Can be fixed. In this case, on both sides in the axial direction, on the side of the contact portion 8 92 of the tubular member 8 91, the bent portion 7 45 of the coil module 7 40 is opposite to the tubular member 8 91 in the radial direction. Since it is bent to the side, the bent portion 7 45 hits the cylindrical member 8 91, which interferes with the contact between the axial end surface of the stator core 7 32 and the cylindrical member 8 91. It is possible to avoid inconvenience.

[0706] The coil modules 740, 850 are omitted because one of both axial ends bends radially! -A configuration other than the letter-shaped configuration may be used. Specifically, as shown in Fig. 122, the two types of coil modules 7440 and 74400 are both formed in a substantially letter-like shape by bending both axial ends in the radial direction. May be In this case, both axial ends of the coil modules 740 X and 740 are bent in opposite directions. The coil modules 740 X and 740 are arranged side by side in the circumferential direction with their relative positions displaced in the axial direction. The circumferential arrangement of the coil modules 740 and 740 is as described above. The coil modules 740 and 740 can use partial windings of the same structure, but the axial positions of the protrusions 756 differ from each other.

[0707] The stator winding 7 3 1 may have a configuration in which the coil module 7 4 0 and the coil module 8 5 0 are not used. For example, with a plurality of partial windings 7 4 1, 7 4 1 arranged in the circumferential direction on the outer side in the radial direction of the stator core 7 32, the partial windings 7 4 1 8, 7 4, 7 4 1 The structure may be such that the resin is molded. In this case, as shown in FIG. 123, the stator 7300 has a cylindrical shape entirely covered with a resin layer. Inside the resin layer, the stator core 7 32 and the partial winding 7 4 1 are insulated and each partial winding 7 4 1 is insulated in the same way as the configuration using the coil module 7 4 0 and the coil module 8 5 0. A plurality of partial windings 7 4 1 are arranged side by side in the circumferential direction in a state where insulation between the phases of 7 4 1 8 and 7 4 1 is provided. In this case, several partial windings 7 4 1, 7 4 1 〇 2020/175 222 186 卩(: 170? 2020/006141

The resin coating layer forms a radial insulation wall adjacent to the partial windings 7 4 1 and 7 4 1 in the radial direction and is adjacent to the partial windings 7 4 1 and 7 4 1 in the circumferential direction. A circumferential insulating wall is formed in contact therewith.

[0708] In addition, an insulating plate having a predetermined thickness may be arranged between each of the partial windings 741 and 741 adjacent to each other in the circumferential direction. In this case, on the outer side in the radial direction of the stator core 7 32, a plurality of partial windings 7 41 8, 7 41 and insulating plates are alternately arranged in the circumferential direction, and they are resin-molded. To form the stator 7 30. In this configuration, even if the partial windings 7 4 1, 8 and 7 4 8 M unintentionally move due to the injection pressure in the resin mold process, the insulation distance for the thickness of the insulation plate remains, so the ground/phase The required insulation distance can be secured.

[0709] In the above-described configuration, in the stator winding 7 3 1, all the partial windings 7 4 1 are connected in parallel for each phase winding, but this may be changed. For example, all the partial windings 7 41 for each phase winding may be divided into a plurality of parallel connection groups, and the plurality of parallel connection groups may be connected in series. In other words, all 12 partial windings 7 41 on each winding are divided into 6 groups of 2 parallel connection groups, and these are connected in series. Alternatively, in the stator winding 7 3 1, a plurality of partial windings 7 4 1 may be connected in series for each phase winding.

[071 0] (Modification 17)

In this modified example, in the rotating electric machine 700, the stator 7300 is replaced with a stator 900 shown in FIG. In this example as well, the above-described rotor 7100, inner unit 770, and bus bar module 810 are provided as the configuration of the rotating electric machine: 5 electric machines 7 00, but the description thereof is omitted here.

[071 1] The stator 900 has a stator winding 9011 and a stator core 900.

Fig. 1 2 4 is a perspective view showing the structure of the stator 900, Fig. 1 2 5 is a front view of the stator 900, and Fig. 1 2 6 is a longitudinal section of the stator 900. Fig. 1 2 7 is a cross-sectional view of the stator 900 (1 2 7-1 2 7 line cross-section of Fig. 1 2 5), and Fig. 1 2 8 shows the stator winding. 9 0 1 and stator core 90 2 are shown exploded 〇 2020/175 222 187 卩(: 170? 2020/006141

It is a perspective view.

[0712] The stator core 902 has a cylindrical shape in which a plurality of core sheets made of magnetic steel sheets, which are magnetic materials, are laminated in the axial direction and have a predetermined thickness in the radial direction. The stator winding 9 0 1 is assembled on the outer side in the radial direction on the rotor 7 10 side in 90 2. The outer peripheral surface of the stator core 90 2 has a curved surface with no irregularities. The stator core 902 functions as a back yoke. The stator core 902 is configured by axially stacking a plurality of core sheets punched and formed, for example, in an annular plate shape. However, as the stator core 902, one having a helical core structure may be used.

[0713] In the stator core 90 2, end rings 90 3 are fixed to the end faces on both sides in the axial direction. The end ring 903 is a positioning member having a function of holding the stator winding 901 in a predetermined position in the circumferential direction when the stator winding 901 is assembled to the stator core 902. is there. The stator core 90 2 and the end ring 90 3 are base members 90 4.

[0714] On the outer peripheral surface of the end ring 903, a plurality of recesses 905 are formed in the circumferential direction. In this example, the same number of recesses 90 5 as the coil modules 9 10 arranged in the circumferential direction are provided in the circumferential direction on the stator winding line 90 1. In each of the end rings 90 3 on both sides in the axial direction, the positions of the recessed portions 90 5 in the circumferential direction are aligned on the one end side and the other end side in the axial direction.

[0715] The end ring 903 is made of a non-magnetic material such as aluminum or copper. The end ring 903 is fixed to the stator core 902 by welding. Alternatively, the end ring 903 may be mechanically fixed by pin insertion, key press fitting, or bolt fastening. Due to such mechanical fixation, the circumferential displacement of the end ring 90 3 with respect to the stator core 90 2 is suppressed.

[0716] As shown in Fig. 125, the stator 900 has a portion corresponding to the coil side 0 3 radially opposed to the magnet 72 2 of the rotor 7 10 in the axial direction, and Coil end 0, which is outside the coil side 0 3, in the axial direction 0, 1 〇 2020/175 222 188 卩(: 170? 2020/006141

And a corresponding portion. In this case, the stator core 90 2 is provided in a range corresponding to the coil side 0 3 in the axial direction, and the end ring 90 3 is provided in the axial direction at one end of the coil end 0 1 and at the other end. The coil ends 0 and 2 are provided respectively.

[0717] The stator winding 901 has a plurality of phase windings, and the phase windings of each phase are arranged in a predetermined order in the circumferential direction to form a cylindrical shape (annular shape). The stator core 902 is assembled inside the stator winding 901 in the radial direction. In this example, by using phase windings of II phase, V phase, and phase, the stator winding 90 1 is configured to have a phase winding of 3 phases. In addition, as shown in Fig. 127, in the stator winding 901, the conductor parts arranged in the circumferential direction are arranged in two layers in the radial direction, and the stator coil wire 9011 is located inside and outside the radial direction. It is a two-layered line.

[0718] In the stator winding 9 01, each phase winding of each phase has a plurality of partial windings 9 1 1, and the partial winding 9 11 is provided individually as a coil module 9 1 0. Has been. That is, the coil module 910 is integrally provided with the partial winding 911 in each phase winding of each phase. By arranging the coil modules 910 of each phase side by side in the predetermined order in the circumferential direction, the conductor parts of each phase are arranged in the predetermined order in the coil side of the stator winding 910. ing. Figure 125 shows the order of arrangement of the II-phase, V-phase, and phase conductors in the coil side.

[0719] In the stator winding 9 01, each coil module 9 1 0 partial winding 9

By connecting 1 1 in parallel, the phase winding of each phase is formed. Fig. 129 is a circuit diagram showing the connection state of the partial windings 911 in each of the three-phase windings. Fig. 129 shows a state in which a plurality of partial windings 911 in each phase winding are connected in parallel.

[0720] Stator winding 9011 consists of multiple coil modules arranged side by side in the circumferential direction.

It is composed of 910. FIG. 130 is a perspective view of the coil module 910. In addition, Fig. 131 (8) is a vertical cross-sectional view of the coil module 910 when viewed from the front, and Fig. 313 (is a side view of the coil module 910. 〇 2020/175 222 189 卩(: 170? 2020/006141

It In addition, in Fig. 131 (slung), the left side of the coil module 910 is the stator core 902 side (radially inner side).

[0721] The coil module 910 has a partial winding wire 911 that is an air-core winding coil, and a coating layer 9112 that covers the partial winding wire 911. In this case, the partial winding 9 11 is entirely covered with the covering layer 9 1 2, and the covering layer 9 1 2 insulates the partial winding 9 11 from the stator core 90 2 and The partial windings 9 1 1 that are close to each other are insulated from each other. The partial winding 9 11 is composed of multiple windings of the conducting wire 9 11. The coating layer 9 12 is formed of, for example, a synthetic resin which is an insulating material.

[0722] The plurality of partial windings 9 1 1 may have the same conductor cross-sectional area in the state of multiple winding and the number of windings of multiple winding. In this case, in the phase windings of each phase, the interlinkage magnetic fluxes of the partial windings 9 11 forming the parallel circuit can be made uniform. As a result, the potential difference between the partial windings 9 11 can be eliminated, and the generation of circulating current in the parallel circuit can be suppressed. In addition, it is possible to suppress deterioration of motor efficiency and thermal rating performance due to generation of circulating current.

[0723] The coil module 9 10 includes a pair of straight line portions 9 2 that are parallel and extend linearly.

1 and a pair of linear portions 9 2 1 at one end side in the axial direction and at the other end side in the axial direction are provided with crossover portions 9 2 2 and 9 23. It is formed in an annular shape by the crossover portions 9 2 2 and 9 2 3 on both sides in the axial direction. The pair of straight line portions 9 2 1 are provided with a predetermined coil pitch apart, and between the pair of straight line portions 9 2 1 in the circumferential direction, the straight line portions 9 2 1 of the coil module 9 10 of another phase are provided. Can be placed. In this example, the pair of straight line portions 9 2 1 are provided with a distance of 2 coil pitches, and between the pair of straight line portions 9 2 1, the middle conductor wire portion 7 4 6 in the coil module 9 10 of the other two phases is provided. Are arranged one by one

[0724] Further, in this example, a pair of linear portions 9 2 1 is provided so as to be offset by one layer in the radial direction, and one of them is a stator winding 9 0 1 with two layers in the radial direction. Is placed on the inner layer side, and the other is placed on the outer side of the stator winding 9 〇 2020/175 222 190 卩(: 170? 2020/006141

It is arranged on the layer side. Then, a pair of straight line portions 9 2 1, which are respectively provided in different layers inside and outside in the radial direction, are annularly connected by the crossover portions 9 2 2 and 9 23. Specifically, one of the crossing portions 9 2 2 has a pair of inclined portions 9 2 2 3 extending in a direction oblique to the axial direction and extending toward each other, and a pair of the inclined portions 9 2 2 3 2. It has a sewn portion 9 2 2 which sewages in the radial direction. The other crossing portion 9 23 has a pair of inclined portions 9 2 3 3 extending obliquely with respect to the axial direction and extending toward each other, and the pair of inclined portions 9 2 3 3 in the radial direction. It has a sewage section 9 23. The transition parts 9 2 2 and 9 23 are also switching parts for switching the inner and outer layers.

[0725] The crossovers 9 2 2 and 9 2 3 are coil ends ◯mi 1 and 〇mi 2 (Fig. 12

(See 5)). That is, each of these crossover portions 9 2 2 and 9 23 is provided as a coil end connection portion that connects two in-phase conductor wire portions at different positions in the circumferential direction at the coil ends 0 1 and 0 2. ..

[0726] When the stator winding 9 0 1 is assembled to the stator core 9 02, one straight line portion 9 2 1 of the pair of straight line portions 9 2 1 and each inclined portion 9 2 2 on both sides in the axial direction thereof. 3 and 9 2 3 3 are arranged on the outer layer side of the two radial layers, and the other straight portion 9 2 1 and each inclined portion 9 2 2 3 and 9 2 3 3 on both sides in the axial direction It is located on the inner layer side of the layers.

[0727] As shown in Fig. 1 3 1 (Slung), a pair of linear parts 9 of the coil module 9 10

In the straight part 9 2 1 on the inner layer side of 2 1 (the straight part 9 21 on the left side of the figure), the coating layer 9 on the stator core 9 0 2 side (left side of the figure) with respect to the partial winding 9 11 1 2 is an insulating layer 9 1 2 3 between the partial winding 9 1 1 and the stator core 9 0 2. This insulating layer 9 1 2 3 corresponds to the insulating wall on the back yoke side.

[0728] In addition, the coil module 910 is provided with projecting portions 925 that engage with the recessed portions 905 of the end ring 903 at one end side and the other end side in the axial direction. The projecting portion 9 25 is provided so as to extend inward in the radial direction from the ridges 9 2 2 13 9 3 2 3 of the bridging portions 9 2 2 and 9 23. 〇 2020/175 222 191 卩(: 170? 2020/006141

As shown in FIG. 1 3 1 (a ), in the coil module 9 10, the partial winding 9 11 is provided so as to be entirely covered with the coating layer 9 12. The partial winding 9 11 has a pair of intermediate conductor portions 9 15 as a portion along the pair of straight portions 9 21 of the coil module 9 10 and also has a crossover portion 9 2 2 of the coil module 9 10. , 9 23 have crossovers 9 16 and 9 17. The supplementary description of the partial winding 9 11 is that the partial winding 9 11 includes a pair of intermediate conductive wire portions 9 15 that are parallel to each other and a straight line, and a pair of intermediate conductive wire portions 9 15 that are located at one end side in the axial direction. And a connecting portion 9 16 and 9 17 connected at the other end in the axial direction, and formed in an annular shape by a pair of these intermediate conductor portions 9 15 and connecting portions 9 16 and 9 17 ing. The pair of intermediate conductors 9 15 are provided with a predetermined coil pitch apart, and between the pair of intermediate conductors 9 15 in the circumferential direction, the intermediate conductors of the partial winding 9 11 of another phase are provided. Parts 9 15 can be placed. In this example, the pair of intermediate conductors 9 15 are provided separated by 2 coil pitches, and the intermediate conductors in the other two-phase partial windings 9 11 are placed between the pair of intermediate conductors 9 15. The parts 9 15 are arranged one by one.

[0730] The partial winding 9 11 is formed by multiple windings of a conducting wire 9 1 3 so that the cross section becomes a quadrangle, and the insulation layer consisting of a coating layer 9 1 2 is formed on each side of the cross section. It is covered with a wall. In this example, the partial winding 9 11 is formed by winding the conducting wire 9 13 by concentric winding. However, the winding method of the conducting wire 9 13 is arbitrary, and instead of the concentric winding, the conducting wire 9 13 may be multiply wound by alpha winding.

[0731] As shown in Fig. 130, in each coil module 91 0, the end of the conductor 9 13 of the partial winding 9 11 is pulled out in the axial direction, and the end is the winding wire. The end is 9 1 3 3, 9 13 The end portions of the winding wire 9 1 3 3 and 9 1 3 are the winding start and winding end of the conducting wire 9 13 respectively. The edge of the winding wire 9 1 3 3 is connected to the current output terminal, and the end of the winding wire 9 1 3 6 is connected to the neutral point.

[0732] Next, the state where the coil module 9 10 is assembled to the stator core 90 2 〇 2020/175 222 192 卩(: 170? 2020/006141

The state will be described.

[0733] FIG. 1 3 2 is a perspective view showing a state in which a plurality of coil modules 9 10 are arranged in the circumferential direction, and FIG. 13 3 shows a state in which a plurality of coil modules 9 10 are arranged in the circumferential direction. It is a figure which shows the cross section in. In addition, in Fig. 133, a dot is attached to the coil module 91 0 of the same phase (for example, II phase).

[0734] As shown in Fig. 13 2, all of the coil modules 9 10 have the same shape, and the connecting portions 9 2 2 and 9 2 3 are connected to each other. Three swallows are arranged side by side in the circumferential direction so that they extend in the radial direction. In this case, the crossover portions 9 2 2 and 9 2 3 extending in the radial direction prevent interference between the coil modules 9 10 adjacent to each other in the circumferential direction. The crossover sections 9 2 2 and 9 2 3 of the coil module 9 10 (the crossover sections 9 16 and 9 17 of the partial winding 9 11) correspond to the interference avoidance section.

[0735] When the coil module 9 10 is assembled to the stator core 90 2, the recesses 9 0 5 provided in the end rings 90 3 at both axial ends of the stator core 9 02 (Fig. 12 28) (See), the protruding portion 9 25 of the coil module 9 10 is engaged. This makes it possible to assemble the coil module 910 to the stator core 902 while improving the positional accuracy in the circumferential direction. The concave portion 90 5 of the end ring 90 3 and the projecting portion 9 25 of the coil module 9 10 are such that the engaging surfaces facing each other are inclined surfaces (on a concentric circle that is concentric with the stator core 90 2 ). It may be an inclined surface that inclines with respect to the tangent line. The recessed portion 90 5 of the end ring 90 3 corresponds to the first engaging portion, and the protruding portion 9 25 of the coil module 9 10 corresponds to the second engaging portion.

[0736] On both sides in the axial direction, the protrusions 9 25 of the coil module 9 10 axially face the recesses 9 05 of the end ring 9 03, and the end rings 9 0 3 are formed by the protrusions 9 25. Is preferably pressed in the axial direction. In this case, the end ring 903 is pressed in the axial direction by the protrusion 925, so that the stator core 902 presses the core sheet in the axial direction, in other words, the core sheet in the axial direction. Can provide a biasing force that resists trying to move away from each other. 〇 2020/175 222 193 卩(: 170? 2020/006141

It As a result, the minute gaps between the core sheets can be made as small as possible, and the axial length of the stator core 902 can be reduced. The protruding portion 9 25 corresponds to the pressing portion.

[0737] The plurality of coil modules 910 are arranged in a state of being separated from each other without making contact with each other in the circumferential direction. In this state, resin molding may be performed so as to cover all the coil modules 910. As a result, it is possible to suppress inconveniences such as the coil modules 910 coming off. It should be noted that a restraint member such as a restraint ring may be provided on the outer peripheral side of the coil module 910 and the pressing force in the radial direction may be applied by restraining the restraint member.

[0738] As shown in Fig. 133, the coil modules 910 of the respective phases are arranged side by side in the circumferential direction in a predetermined order. Each coil module 9 1 0 is provided with a pair of linear portions 9 2 1 spaced apart by 2 coil pitches, and between the pair of linear portions 9 2 1, the linear portions of the other 2 phase coil modules 9 1 0 are provided. Since 9 2 1 are arranged one by one, the in-phase straight line portions 9 2 1 are arranged inside and outside in the radial direction.

[0739] The partial winding 9 1 1 1 has the following structure. The partial winding 9 11 has, as a pair of intermediate conductive wire portions 9 15, an inner conductive wire portion located on the inner side of the two radial layers and an outer conductive wire portion located on the outer side of the two radial layers. Then, the inner conductor portion and the outer conductor portion are connected by the transition portions 9 16 and 9 17 at one end side and the other end side in the axial direction, respectively. The phase windings of each phase have partial windings 9 1 1 of the same shape, and the crossovers 9 1 6 and 9 17 are arranged in the same direction in the circumferential direction on the one end side and the other end side in the axial direction. The partial windings 9 1 1 are arranged side by side in the circumferential direction in an aligned state. In this case, the partial windings 9 11 which are adjacent to each other in the circumferential direction are properly arranged in the circumferential direction while avoiding mutual interference. Also, it has been assumed that productivity is enhanced with the use of a part component windings 9 1 1 of the ^_ form.

[0740] The stator 900 may use any one of the following (8) to (○).

(8) In the stator 900, a conductor wire member is provided between each conductor wire portion (intermediate conductor wire portion 915) in the circumferential direction, and as the conductor wire member, a conductor in one magnetic pole is used. 〇 2020/175 222 194 卩 (: 170? 2020 /006141

The width of the wire member in the circumferential direction is I, the saturation magnetic flux density of the wire member is 3, and the width of the magnet 7 2 2 in one magnetic pole in the circumferential direction is \ZV rn, and the residual magnetic flux density of the magnet 7 2 2 is Is defined as

We use magnetic materials that are related to "Minami".

(Mitsumi) In the stator 900, an inter-conductor member is provided between each conductor portion (intermediate conductor portion 915) in the circumferential direction, and a non-magnetic material is used as the inter-conductor member.

(◯) In the stator 900, the inter-conductor members are not provided between the conductor portions (intermediate conductor portions 9 15) in the circumferential direction.

[0741] In the rotating electric machine 700 of this example, an inter-conductor member (so-called tooth) is provided between the conductor portions (intermediate conductor portions 9 15) arranged at predetermined intervals in the circumferential direction in the stator 900. Is not provided, or even if an inter-conductor member is provided, the structure is magnetically weak. Therefore, the magnetic flux of the magnet generated in the rotor 710 is directly linked to the conductor part of the stator winding 9001, and there is concern that the motor efficiency and the thermal rating performance may decrease with the increase of copper eddy loss. .. In particular, in the configuration in which the magnetic flux density is enhanced by the orientation as described above, there is a concern that the influence of copper eddy loss will occur more significantly.

[0742] In this regard, in the above configuration, in the stator winding 901, the partial winding 911 is wound multiple times between the in-phase conducting wire portions that are provided in the circumferential direction and are separated from each other. Configured. The phase winding for each phase was constructed by connecting multiple partial windings 9 1 1 in parallel. This makes it possible to subdivide the cross-sectional area per conductor wire in the stator winding 901, suppress copper eddy loss, and improve the efficiency of the motor and the thermal rating performance. You can

[0743] When the number of poles of the magnetic pole is 1\1 and the number of partial windings 9 1 per phase is 1\1, the number of poles is 1\!. All 1\1 partial windings 9 1 1 are connected in parallel. In this example, specifically, the number of partial winding lines 9 1 1 per phase (1\○ is 4 8 and the number of poles is 4 8. For example, in Fig. 1 29, II, In the phase winding of each phase of V, 〇 2020/175 222 195 卩(: 170? 2020/006141

The gap is also 48. In this case, by connecting all the partial windings 9 1 1 in parallel for each phase, the cross-sectional area of each conductor in the stator winding 9 0 1 can be minimized, further reducing copper eddy loss. Can be planned.

[0744] It is also possible to use the following configuration as the partial winding 911. As shown in Fig. 1 34, the partial winding 9 11 uses a complex conducting wire 9 30 composed of multiple thin wires 9 31 connected in parallel, and the complex conducting wire 9 30 is wound in multiple layers. It consists of In FIG. 1 34, the composite conducting wire 930 is configured as a bundle wire having, for example, three thin wires 9 3 13 3, 9 3 1 13 and 9 31 0. For convenience of explanation, in FIG. 1 3 4, the same thin line 9 3 1 has the same cross section notation, and different thin line 9 3 1 has different cross section notation. The number of thin wires 9 3 1 in the composite conducting wire 9 30 is arbitrary as long as it is 2 or more.

[0745] Then, in the intermediate conductor portion 9 15 of the partial winding 9 11 the composite conductor 9 30 is arranged such that the fine wires 9 3 1 3 to 9 3 1 0 are arranged in the same circumferential direction. ing. Specifically, as shown in Fig. 1 34, in the middle conductor wire portion 9 15 the composite conductor wire 9 30 is formed with the thin wires 9 3 1 _{3 to} 9 3 1 0 arranged in a line in the radial direction. It is wound in four rows in the circumferential direction and in two steps in the radial direction. In this case, the rows of thin wires 9 3 1 are the same in any row as viewed in the circumferential direction.

[0746] In the above configuration, by using a composite conductor 930 in which a plurality of thin wires 931 are connected in parallel, and the composite conductor 930 is multi-turned, in other words, in one conductor. By further subdividing the conductor, the cross-sectional area of the conductor in the stator winding 9011 can be further reduced, and the effect of reducing copper eddy loss is enhanced. Also, in the conductor part of the partial winding 911, arrange the composite conductor 930 such that the multiple thin wires 931 are arranged in the same circumferential direction (that is, evenly arranged in the circumferential direction). Thus, it is possible to suppress the generation of the circulating current in the composite conductor 930, and to reduce the copper eddy loss and the circulating current loss.

[0747] The lengths or cross-sectional areas of the conductors of the thin wires 931 connected in parallel are set so that their electric resistances are substantially equal to each other. As a result, it is possible to suppress the deviation of the current in the parallel circuit and the resulting deterioration of the loss. 〇 2020/175 222 196 卩(: 170? 2020/006141

[0748] In addition, in the conductor portion of the partial winding 911, the composite conductor 930 is arranged such that a plurality of thin wires 931 are arranged in the same circumferential direction in the circumferential direction. The configuration may be other than the configuration in which 31 is arranged in one row in the radial direction. The point is that the current may be biased in the circumferential direction in comparison with the radial direction.

[0749] The composite conducting wire 9300 is preferably formed by twisting a plurality of thin wires 931. As a result, it is possible to eliminate the potential difference between the plurality of thin wires 931 in the composite conductor 930 and suppress the circulating current in the composite conductor 930.

[0750] Specifically, as shown in Fig. 135 ( ₃ ), the composite conducting wire 9300 is preferably a stranded wire formed by twisting a plurality of thin wires 931 in the circumferential direction. .. Alternatively, as shown in FIG. 135(b), the composite conducting wire 9300 may be a stranded wire formed by weaving a plurality of thin wires 931 together. In addition, it is preferable that all the thin wires 9 3 1 are woven together. In this case, it is possible to eliminate the potential difference between the plurality of parallel thin wires 931 and suppress the circulating current in the composite conductor 930.

[0751] (Another example of modification 17)

-As the configuration of the coil module 910, a configuration in which the partial winding 911 is integrally provided on the bobbin-shaped winding holder may be adopted. In this case, the winding wire holder has at least the insulating wall on the side of the stator core 90 2 of the four sides surrounding the partial winding 9 1 1, or the insulating wall on the side of the stator core 90 2 and the opposite stator. Any material having an insulating wall on the core side may be used. In this case, all of the four sides surrounding the partial roll line 9 1 1 need not be surrounded by insulating walls, but some of them may be exposed.

[0752] Instead of the configuration in which the projection 9 25 of the coil module 9 10 engages with the recess 9 05 of the end ring 90 3 fixed to the stator core 90 2, the stator core 9 The projection 925 of the coil module 910 may be engaged with the recess formed in the coil 02.

[0753] The pair of linear portions 9 2 1 of the coil module 9 1 0 (the pair of intermediate conductor portions 9 1 5 of the partial winding line 9 1 1) may not be parallel to the axial direction but may be inclined in the axial direction. 〇 2020/175 222 197 卩(: 170? 2020/006141

.. In this case, the skew structure of the stator winding 901 can be realized.

[0754] (Other modified examples of Modifications 15 to 17)

-The stator winding 7 3 1 and the stator winding 9 0 1 in the rotating electric machine 7 00 may have a two-phase winding (re-phase winding and V-phase winding). In this case, for example, in the partial winding 7 41, a pair of intermediate conducting wire portions 7 46 are provided with a distance of one coil pitch, and between the pair of intermediate conducting wire portions 7 46, the partial winding of the other 1 phase is provided. It suffices that the intermediate conductor portion 7 4 6 of 7 4 1 is arranged.

[0755] Up to this point, the outer rotor type surface magnet type rotary electric machine has been described as the rotary electric machines 70 of Modifications 15 to 17; however, instead of this, a concrete example of an inner rotor type surface magnet type rotary electric machine is given. It is also possible to convert. In the case of the inner rotor type, a plurality of coil modules 7 4 0 and coil modules 8 5 0 may be arranged side by side inside the stator 7 30 in the radial direction of the stator core 7 32. Alternatively, in the stator 900, a plurality of coil modules 910 may be arranged side by side inside the stator core 902 in the radial direction.

[0756] The stators 7300 and 900 used in the rotating electric machine 700 may have protrusions (for example, teeth) extending from the back yoke. Also in this case, it is sufficient that the coil module 740 and the like are assembled to the stator core on the back yoke.

[0757] The rotating electric machine is not limited to the star connection, but may be the Δ connection.

[0758] As the rotating electric machine 700, a rotating armature-type rotating electric machine having an armature as a rotor can be adopted instead of a rotating field-type rotating electric machine having a field element as a rotor. Is.

[0759] The disclosure herein is not limited to the illustrated embodiments. The disclosure includes the illustrated embodiments and variations thereof by one of ordinary skill in the art based on them. For example, the disclosure is not limited to the combination of parts and/or elements shown in the embodiments. The disclosure can be implemented in various combinations. The disclosure may have additional parts that may be added to the embodiments. Disclosure 〇 2020/175 222 198 卩 (: 170? 2020 /006141

Includes parts and/or elements of the embodiment omitted. The disclosure encompasses replacements or combinations of parts and/or elements between one embodiment and another. The technical scope disclosed is not limited to the description of the embodiments. It is to be understood that some technical scopes disclosed are shown by the description of the claims, and further include meanings equivalent to the description of the claims and all modifications within the scope.

Claims

〇 2020/175222 199 卩(: 170? 2020/006141 Claims

[Claim 1] A multiphase armature winding (73 1, 901) having a phase winding consisting of a plurality of partial windings (74 1, 9 1 1) per phase,

A base member (7 36, 904) including a cylindrical back yoke (732, 902) that is a core sheet laminated body in which a core sheet (7323) is laminated in the axial direction, and

An armature (730, 900) having

The plurality of partial winding lines are arranged side by side in the circumferential direction on the radially inner side or the radially outer side of the base member,

An armature provided with a pressing portion (756, 866, 925) that is provided integrally with the partial coiled line and that presses the axial end surface of the back yoke axially from the outside in the axial direction.

[Claim 2] The armature winding wire includes the partial winding wire and the back yoke of the partial winding wire.

— Having a plurality of coil modules (740, 850, 9 1 0) including the back yoke side insulating wall (75 1, 86 1, 9 1 2 3) provided on the

By arranging the plurality of coil modules side by side in the circumferential direction on the radially inner side or the radially outer side of the base member, the plurality of partial windings are arranged,

The armature according to claim 1, wherein the pressing portion is provided on the back yoke-side insulating wall.

[Claim 3] The back yoke-side insulating wall includes axially opposite sides of the back yoke.

The armature according to claim 2, wherein the pressing portion that presses the axial end surface of the back yoke from the axial outside is provided.

[Claim 4] The axial end surface of the back yoke is pressed by the pressing portions of the different coil modules on one axial side and the other axial side of the back yoke. Armature.

[Claim 5] The back yoke-side insulating wall is provided on both sides in the axial direction of the back yoke. 〇 2020/175 222 200 卩(: 170? 2020/006141

The pressing portion is provided on one side,

By mounting the plurality of coil modules in the axial direction with respect to each other in the axial direction, the axial end surfaces of the back yoke are pressed by the pressing portions from both axial sides of the back yoke. The armature according to claim 2, which has.

[Claim 6] The armature according to any one of claims 2 to 5, wherein the coil modules that are circumferentially adjacent to each other are fixed so that the coil modules cannot move relative to each other in the axial direction.

7. The coil module in the coil module, wherein the back yoke-side insulating wall has a yoke outer portion that extends axially outward from an axial end surface of the back yoke, and the yoke outer portion has the yoke outer portion. The armature according to any one of claims 2 to 6, wherein the pressing portion is integrally formed so as to protrude toward the back yoke side with respect to a surface facing the yoke in the circumferential direction.

8. The back yoke holds the stacked state of the core sheets at positions on the inner side and the outer side in the radial direction opposite to the insulating layer on the back yoke side, separately from the pressing portion. The armature according to any one of claims 2 to 7, which is provided with a laminated holding structure for carrying out.

[Claim 9] In the insulating wall on the side of the / yoke, between the pressing portion provided on the outer portion of the yoke extending axially outside the axial end surface of the / yoke and the axial end surface of the back yoke, A plate-shaped spacer (8 8 1) is provided which is in contact with the end face in the axial direction,

The spacer has a larger amount of radial overlap with the axial end surface of the back yoke than the pressing portion, and the axial end surface of the / yoke is pressed by the pressing portion via the spacer. An armature according to any one of claims 2 to 8.

10. A spacer (8 8 13) extending in the axial direction is formed on a surface of the spacer facing the pressing portion, and a part of the pressing portion enters the recess. The armature according to claim 9, wherein 〇 2020/175 222 201 卩(: 170? 2020/006141

[Claim 11] The base member has an end ring (7 3 3, 90 3) fixed to an axial end face of the back yoke, and the end ring has the end ring with the portion of the back yoke. Recesses (7 3 5, 9 0 5) are formed by denting from the radial surface on the winding side.

The pressing portion is provided so as to face the concave portion in a radial direction, and is engaged with the base member in the circumferential direction in the concave portion. The armature according to the item.

[Claim 12] The / Isuzu ^'Kkuyoku and the partial windings, the / ^Isuzu' includes an axial end portions, and side portions of the anti back yoke side of the partial windings of the portion fraction winding and Kkuyoku ^_ body are resin-molded in a range,

The end face coating portion (889) covering the axial end face of the back yoke on both axial sides of the coating portion (888) formed by the resin mold functions as the pressing portion. The listed armature.

[Claim 13] The armature (73 0, 900) according to any one of claims 1 to 12 and a field element (7) having a plurality of magnetic poles having alternating polarities in the circumferential direction. And a rotating electric machine (700) in which one of the field element and the armature rotates together with a rotating shaft (710).