Winded field rotor

A ring-shaped member on the coil end portion of wound-field magnet rotors addresses the issue of displacement due to centrifugal force, ensuring stable positioning and improved performance.

JP7885703B2Active Publication Date: 2026-07-07DENSO CORP

Patent Information

Authority / Receiving Office
JP · JP
Patent Type
Patents
Current Assignee / Owner
DENSO CORP
Filing Date
2023-02-21
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

In wound-field magnet rotors, the field windings are prone to displacement due to centrifugal force during rotation, affecting the stability and positioning of the coil end portions.

Method used

A ring-shaped member is provided on the radially outer side of the coil end portion to suppress displacement of the field windings, ensuring they remain in an appropriate position despite centrifugal forces.

Benefits of technology

The configuration effectively maintains the field windings in place, enhancing the stability and positioning of the coil end portions, thereby improving the overall performance of the wound-field magnet rotor.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

To provide a wound-field rotor that can appropriately hold a field winding.SOLUTION: A rotor 60 is applied to a wound-field rotary electric machine, and has a rotor core 61 that has main pole parts 62 individually provided in magnetic poles arranged side by side in a circumferential direction and protruding in a radial direction, and field windings 70 that are individually wound around the main pole parts 62. The field winding 70 has a coil end part on the outside in an axial direction of the rotor core 61, and coil end covers 103, 104 are provided on the outside in a radial direction of the coil end part so as to surround the coil end part.SELECTED DRAWING: Figure 7
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Description

Technical Field

[0001] The disclosure in this specification relates to a wound-field magnet rotor.

Background Art

[0002] In a wound-field type rotating electric machine, a rotor (i.e., a wound-field magnet rotor) includes a rotor core having a plurality of main pole portions (magnetic salient pole portions) provided for each magnetic pole arranged in the circumferential direction, and a field winding wound around the main pole portions. For example, in Patent Document 1, a configuration is described in which a holding member is provided between the main pole portions adjacent to each other in the circumferential direction while being supported by the protruding end portions of the main pole portions, and the holding member restricts the field winding from moving radially outward.

Prior Art Documents

Patent Documents

[0003]

Patent Document 1

Summary of the Invention

Problems to be Solved by the Invention

[0004] However, in a wound-field magnet rotor, when centrifugal force acts on the field winding during rotor rotation, there is a concern that not only the coil side portions of the field winding that face the rotor core in the radial direction but also the coil end portions may move. In this regard, there is room for technical improvement.

[0005] The present invention has been made in view of the above circumstances, and an object thereof is to provide a wound-field magnet rotor capable of appropriately holding a field winding.

Means for Solving the Problems

[0006] The present invention is A wound-field rotor, applicable to a wound-field rotating electric machine, having a rotor core with main pole portions that protrude radially and are provided for each magnetic pole arranged in the circumferential direction, and field windings wound around the main pole portions, The field winding has a coil end portion that is axially outward from the rotor core, A ring-shaped member is provided on the radially outer side of the coil end portion, surrounding the coil end portion.

[0007] In a wound-field rotor, the field windings are assembled to the rotor core, wound around each main pole. Furthermore, an annular member is provided on the radially outer side of the coil end of each field winding. In this configuration, even when centrifugal force is generated on the field windings during rotation of the wound-field rotor, the annular member suppresses displacement of the coil end of the field windings. As a result, the field windings can be maintained in an appropriate position. [Brief explanation of the drawing]

[0008] [Figure 1] Overall configuration diagram of the control system for a rotating electric machine. [Figure 2] A diagram showing the inverter and its peripheral components. [Figure 3] Cross-sectional view of the rotor and stator. [Figure 4] A diagram showing the electrical circuitry of the rotor. [Figure 5] A diagram showing the changes in fundamental and harmonic currents. [Figure 6] A perspective view showing the overall configuration of the rotor. [Figure 7] Exploded perspective view of the rotor. [Figure 8] Longitudinal cross-section of the rotor. [Figure 9] A perspective view showing the winding unit disassembled within the rotor body. [Figure 10] Cross-sectional view of the rotor body. [Figure 11] A perspective view showing an example of a coil structure. [Figure 12] Perspective view of the circuit module. [Figure 13] Perspective view showing the disassembly of the component holder and electrical components of the circuit module. [Figure 14] Perspective view showing the configuration of the coil end cover. [Figure 15] Cross-sectional view showing an enlarged view of the configuration around the coil end portion. [Figure 16] Front view showing an example of the configuration of the coil end cover after balance adjustment. [Figure 17] Front view of the coil end cover. [Figure 18] View showing the configuration of the rotor cross-section. [Figure 19] Front view of the rotor body in another example. [Figure 20] View showing the configuration of the coil end cover in another example. [Figure 21] View showing the configuration of the coil end cover in another example. [Figure 22] View showing the configuration of the rotor core in another example.

Mode for Carrying Out the Invention

[0009] Hereinafter, an embodiment in which the rotating electric machine according to the present invention is embodied will be described with reference to the drawings. The rotating electric machine is used as a driving power source in an electric vehicle such as an electric vehicle or a hybrid vehicle, for example.

[0010] First, a control system including a rotating electric machine will be described using FIG. 1. The control system includes a DC power supply 10, an inverter 20, a control device 30, and a rotating electric machine 40. The rotating electric machine 40 is a wound-field synchronous machine. For example, the rotating electric machine 40, the inverter 20, and the control device 30 may be configured as an integrated drive device, or each of the rotating electric machine 40, the inverter 20, and the control device 30 may be composed of respective components.

[0011] The rotating electric machine 40 comprises a housing 41 and a stator 50 and a rotor 60 housed within the housing 41. The rotating electric machine 40 in this embodiment is an inner rotor type rotating electric machine in which the rotor 60 is positioned radially inward of the stator 50. The rotor 60 corresponds to a "winding field rotor".

[0012] The stator 50 comprises a stator core 51 and stator windings 52. The stator windings 52 are made of, for example, copper wire and include U, V, and W phase windings 52U, 52V, and 52W arranged at an electrical angle of 120° from each other.

[0013] The rotor 60 comprises a rotor core 61 and field windings 70. The field windings 70 may be made of, for example, aluminum wire, which has a low specific gravity and is easy to form. However, the field windings 70 are not limited to aluminum wire; they may also be made of, for example, copper wire or CNT (carbon nanotube). A rotating shaft 32 is assembled in the central hole of the rotor core 61. The rotating shaft 32 is rotatably supported in the housing 41 by bearings 42 and 43.

[0014] As shown in Figure 2, the inverter 20 comprises a series connection of U, V, W phase upper arm switches Sup, SVp, SWp and U, V, W phase lower arm switches SUn, SVn, SWn. In each phase, the first ends of the U, V, W phase windings 52U, 52V, 52W are connected to the connection point between the upper arm switches Sup, SVp, SWp and the lower arm switches SUn, SVn, SWn. The second ends of the U, V, W phase windings 52U, 52V, 52W are connected at the neutral point. In other words, in this embodiment, the stator winding 52 is star-connected. However, the stator winding 52 may be delta-connected. In this embodiment, each switch Sup to SWn is an IGBT. A freewheeling diode is connected in antiparallel to each switch Sup to SWn.

[0015] The collectors of the upper arm switches Sup, SVp, and SWp for each phase are connected to the positive terminals of the DC power supply 10. The emitters of the lower arm switches SUn, SVn, and SWn for each phase are connected to the negative terminals of the DC power supply 10. A smoothing capacitor 11 is connected in parallel to the DC power supply 10.

[0016] Next, we will explain the stator 50 and rotor 60 using Figure 3.

[0017] The stator 50 and rotor 60 are both arranged coaxially with the rotating shaft 32. In the following description, the direction in which the rotating shaft 32 extends is referred to as the axial direction, the direction extending radially from the center of the rotating shaft 32 is referred to as the radial direction, and the direction extending circumferentially with respect to the rotating shaft 32 is referred to as the circumferential direction.

[0018] The stator core 51 is made of laminated steel plates made of soft magnetic material and has an annular back yoke 51a and a plurality of teeth 51b that protrude radially inward from the back yoke 51a. A plurality of slots 54 are formed between adjacent teeth 51b, arranged in the circumferential direction. The stator windings 52 are formed by housing the phase windings of each phase in a predetermined order in each of these slots 54. For example, a segment coil structure using a plurality of conductor segments may be adopted in the stator 50. However, the structure of the stator windings 52 is arbitrary.

[0019] The rotor core 61 is made of a soft magnetic material, for example, laminated steel plates. The rotor core 61 has a cylindrical portion 61a and a plurality of main pole portions 62 that protrude radially outward from the cylindrical portion 61a. Field windings 70 are wound around the main pole portions 62 by concentrated winding. In this embodiment, eight main pole portions 62 are provided at equal intervals in the circumferential direction.

[0020] The field winding 70 comprises a first winding section 71a and a second winding section 71b. The first winding section 71a is wound radially outward around each main pole section 62, and the second winding section 71b is wound radially inward from the first winding section 71a. In each main pole section 62, the winding directions of the first winding section 71a and the second winding section 71b are the same. Furthermore, among circumferentially adjacent main pole sections 62, the winding directions of the winding sections 71a and 71b wound around one are opposite to those of the winding sections 71a and 71b wound around the other. As a result, the magnetization directions of circumferentially adjacent main pole sections 62 are opposite to each other. In the rotor 60, multiple magnetic poles (field poles) aligned in the circumferential direction are formed by each main pole section 62 in the rotor core 61 and the field winding 70 wound around each main pole section 62.

[0021] Figure 4 shows the electrical circuit on the rotor 60 side, which includes windings 71a and 71b wound around the main pole 62. The first winding 71a and the second winding 71b are connected in series, and a diode 81, acting as a rectifier, is connected between the ends of the series connection consisting of these windings 71a and 71b. That is, the first end of the first winding 71a is connected to the cathode of the diode 81, and the first end of the second winding 71b is connected to the second end of the first winding 71a. The anode of the diode 81 is connected to the second end of the second winding 71b. A capacitor 82 is connected in parallel to the second winding 71b. In Figure 4, L1 represents the inductance of the first winding 71a, L2 represents the inductance of the second winding 71b, and C represents the capacitance of the capacitor 82.

[0022] In this embodiment, a series resonant circuit is formed by the first winding section 71a, the capacitor 82, and the diode 81, and a parallel resonant circuit is formed by the second winding section 71b and the capacitor 82. If the first resonant frequency, which is the resonant frequency of the series resonant circuit, is f1, and the second resonant frequency, which is the resonant frequency of the parallel resonant circuit, is f2, then these resonant frequencies f1 and f2 are expressed by the following equations (1) and (2). f1 = 1 / (2π√(L1 × C)) …(1) f2 = 1 / (2π√(L2 × C)) …(2) When harmonic current flows through the stator winding 52, fluctuations in the main magnetic flux due to harmonics occur in the magnetic circuit including the stator core 51 and rotor core 61. These fluctuations in the main magnetic flux generate induced voltages in each winding section 71a and 71b, inducing currents in each section. If induced voltages of the same polarity are generated in each winding section 71a and 71b, the induced currents in each winding section 71a and 71b do not cancel each other out, resulting in an increase in induced current. The diode 81 rectifies the current flowing through each winding section 71a and 71b in one direction. As a result, field current flows through the field winding 70 in the direction rectified by the diode 81, exciting the field winding 70.

[0023] The control device 30 is mainly composed of a microcontroller (equivalent to a computer), and the microcontroller is equipped with a CPU. The control device 30 generates drive signals to turn each switch Sup to SWn that make up the inverter 20 on and off. Specifically, the control device 30 generates drive signals to turn each switch Sup to SWn on and off in order to convert the DC power output from the DC power supply 10 into AC power and supply it to the U, V, and W phase windings 52U, 52V, and 52W, and supplies the generated drive signals to the gates of each switch Sup to SWn.

[0024] The control device 30 switches Sup~SWn on and off to allow a combined current of the fundamental wave current and harmonic current to flow through each phase winding 52U, 52V, and 52W. The fundamental wave current is the current that primarily generates torque in the rotating electric machine 40. The harmonic current is the current that primarily excites the field winding 70. The phase currents flowing through each phase winding 52U, 52V, and 52W are shifted by 120° in electrical angle.

[0025] As shown in Figure 5, the envelope of the harmonic current has a period that is half that of the fundamental wave current. The envelope is shown as a dashed line in Figure 5(b). The values ​​on the vertical axis in Figure 5 show the relative relationship of the waveform magnitudes shown in Figures 5(a) and (b). The timing at which the envelope reaches its peak value is shifted from the timing at which the fundamental wave current reaches its peak value. Specifically, the timing at which the envelope reaches its peak value is considered to be the timing at which the fundamental wave current reaches its fluctuation center (0).

[0026] Furthermore, the timing at which the envelope of the harmonic current reaches its peak value may coincide with, for example, the timing at which the fundamental wave current reaches its peak value.

[0027] Next, the configuration of the rotor 60 will be described in more detail. Figure 6 is a perspective view showing the overall configuration of the rotor 60, Figure 7 is an exploded perspective view of the rotor 60, and Figure 8 is a longitudinal cross-sectional view of the rotor 60.

[0028] The rotor 60 is broadly composed of a rotor body 101, a circuit module 102 provided on one end of the rotor body 101 on either side of the axial direction, and coil end covers 103 and 104 as annular members attached to the axial ends of the rotor body 101. As explained in Figure 3, the rotor body 101 comprises a rotor core 61 and field windings 70, and a rotating shaft 32 is assembled in the central hole of the rotor core 61. The field windings 70 consist of a plurality of winding units 110 arranged in a circumferential direction. The circuit module 102 is fixed to the rotating shaft 32 with the rotating shaft 32 inserted through its hollow portion. As shown in Figure 8, in the field windings 70 (winding units 110), the portion facing radially toward the rotor core 61 is the coil side portion CS, and the portion axially outward from the rotor core 61 is the coil end portion CE.

[0029] The configuration of the rotor body 101 will be explained using Figures 9 and 10. Figure 9 is a perspective view showing the winding unit 110 disassembled in the rotor body 101, and Figure 10 is a cross-sectional view showing the cross-sectional structure of a part of the rotor body 101. Figure 10(a) shows the winding unit 110 assembled, and Figure 10(b) shows the winding unit 110 disassembled.

[0030] The rotor body 101 has a plurality of winding units 110 provided for each magnetic pole of the rotor 60. Each winding unit 110 is formed in an annular shape with its longitudinal direction in the axial direction, and is assembled to the rotor core 61 with the main pole portion 62 of the rotor core 61 inserted through its hollow portion.

[0031] The winding unit 110 has a first coil module 111 that is radially outward when mounted on the main pole portion 62, and a second coil module 112 that is radially inward. The first coil module 111 is a coil module corresponding to the first winding portion 71a, and the second coil module 112 is a coil module corresponding to the second winding portion 71b.

[0032] As shown in Figure 10(b), the first coil module 111 has an annular coil body 121 formed by winding a conductor made of flat rectangular wire multiple times in the circumferential and radial directions, and thin plate-shaped insulators 122a and 122b integrally provided on the coil body 121. The insulator 122a has a portion that extends in the circumferential direction and covers the radially outer outer circumference of the coil body 121, and a portion that extends in the radial direction and covers the hollow portion of the coil body 121. The insulator 122b has a portion that extends in the circumferential direction and covers the radially inner inner circumference of the coil body 121, and a portion that extends in the radial direction and covers the hollow portion of the coil body 121. The radially outer outer circumference, the radially inner inner circumference, and the hollow portion of the coil body 121 are insulated by the insulators 122a and 122b.

[0033] The second coil module 112 has an annular coil body 123 formed by winding a conductor made of flat rectangular wire multiple times in the circumferential and radial directions, and thin plate-shaped insulators 124a and 124b integrally provided on the coil body 123. Insulator 124a has a portion that extends in the circumferential direction and covers the radially outer outer circumference of the coil body 123, and a portion that extends in the radial direction and covers the hollow portion of the coil body 123. Insulator 124b has a portion that extends in the circumferential direction and covers the radially inner outer circumference of the coil body 123, and a portion that extends in the radial direction and covers the hollow portion of the coil body 123. The radially outer outer circumference, the radially inner inner circumference, and the hollow portion of the coil body 123 are insulated and covered by insulators 124a and 124b.

[0034] The flat rectangular wires used in coil bodies 121 and 123 have a roughly rectangular cross-section (specifically, a roughly rectangular shape), and each flat rectangular wire consists of a conductor made of aluminum or the like, and an insulating layer covering the conductor. However, it is also possible to use round wires with a circular cross-section as the conductor material.

[0035] The coil body 121 is an air-core coil configured as an α-winding coil, with two layers of windings arranged radially and integrally formed. The coil body 121 can also be described as a unit coil, with the inner and outer layers in the radial direction forming a single unit. In the coil body 121, the wire ends 125 and 126 are drawn out axially from the inner layer side and the outer layer side, respectively.

[0036] Figures 11(a) and (b) are perspective views showing examples of the configuration of the coil body 121 of the first coil module 111. Figure 11(a) shows a state in which two coil bodies 121 arranged in the circumferential direction are connected. The two coil bodies 121 shown in Figure 11(a) have different shapes of conductor ends 125 and 126, and here one of the two types of coil bodies 121 is referred to as "coil body 121A" and the other as "coil body 121B".

[0037] Coil body 121A has a conductor end 125A extending from the radially inner (inner layer side) circumferential portion and a conductor end 126A extending from the radially outer (outer layer side) circumferential portion. Coil body 121B has a conductor end 125B extending from the radially inner (inner layer side) circumferential portion and a conductor end 126B extending from the radially outer (outer layer side) circumferential portion. In each coil body 121A, 121B, one of the respective conductor ends 125, 125 extends axially from the circumferential portion of its own coil body 121, and the other extends axially from the circumferential portion of another coil body 121 adjacent in the circumferential direction. Coil body 121A has a configuration in which the wire end 125A extending from the radially inner circumferential portion extends to the adjacent coil body 121 in the circumferential direction, whereas coil body 121B has a configuration in which the wire end 126B extending from the radially outer circumferential portion extends to the adjacent coil body 121 in the circumferential direction. In coil bodies 121A and 121B, the winding direction of the wire material on the inner and outer layers is the same.

[0038] The coil bodies 121 arranged in the circumferential direction are connected in series in the circumferential direction by joining the wire ends 125 and 126 of adjacent coil bodies 121 in the circumferential direction by welding or the like. The first winding section 71a is formed by the series connection of the coil bodies 121 arranged in the circumferential direction. In this case, the wire ends 125 on the radially inner side and the wire ends 126 on the radially outer side of the coil bodies 121 are joined to each other. As a result, when the first winding section 71a is energized, current flows in opposite directions through the coil bodies 121 that are adjacent to each other in the circumferential direction.

[0039] Figure 11(b) shows the coil bodies 121 arranged in a ring shape by connecting them in the circumferential direction. Each coil body 121 is connected alternately in the circumferential direction by joining the conductor ends 125 on the inner layer sides and joining the conductor ends 126 on the outer layer sides. The conductor ends that terminate after one rotation of the rotor form a connecting section 127 that connects to the coil body of another coil module (in this case, the coil body 123 of the second coil module 112), and are shaped to extend radially inward with an offset.

[0040] As shown in Figure 10, the first coil module 111 has a configuration in which a coil body 121 is provided in one stage in the radial direction. In contrast, the second coil module 112 is composed of a coil body 123 in which the same α-wound air-core coil as the coil body 121 is provided in three stages in the radial direction. The first winding section 71a is composed of a series connection of one turn of the air-core coil (coil body 121), and the second winding section 71b is composed of a series connection of three turns of the air-core coil.

[0041] The coil bodies 121 and 123 of each coil module 111 and 112 have different numbers of windings in the circumferential direction (in other words, the number of arrangements of flat wires in the circumferential direction), with more windings on the radially outer side than on the radially inner side. This improves the space factor of the field winding 70. If space factor is disregarded, it is also possible to make the number of windings in the circumferential direction the same for all radially arranged coil bodies 121 and 123.

[0042] In the coil bodies 121 and 123 of each coil module 111 and 112, the number of radial stages of the α-wound air-core coil can be arbitrarily changed. For example, the first coil module 111 may have two or more stages of α-wound air-core coil, and the second coil module 112 may have two or fewer stages of α-wound air-core coil, or four or more stages.

[0043] Furthermore, the rotor body 101 has retaining plates 131 and 132 that hold the assembled state of the first coil module 111 and the second coil module 112 when they are assembled to the main pole portion 62. The retaining plate 131 is attached to the radially outer side of the first coil module 111, and the retaining plate 132 is attached between the first coil module 111 and the second coil module 112.

[0044] Specifically, as shown in Figure 10, each main pole portion 62 of the rotor core 61 is provided with recesses 63 and 64 at the radial tip position and the radial intermediate position, respectively. The recesses 63 and 64 are provided so as to extend in the axial direction. The retaining plates 131 and 132 are made of plate material with an arc-shaped cross-section. The retaining plate 131 is assembled to the rotor core 61 by inserting both circumferential ends into the recesses 63 of the main pole portion 62. The retaining plate 132 is assembled to the rotor core 61 by inserting both circumferential ends into the recesses 64 of the main pole portion 62. The retaining plates 131 and 132 are preferably made of a non-magnetic material, such as aluminum. The retaining plates 131 and 132 may also be made of synthetic resin.

[0045] When the coil modules 111, 112 and the retaining plates 131, 132 are assembled to the rotor core 61, the second coil module 112 is held in the space between the cylindrical portion 61a and the retaining plate 132 when viewed radially, and the first coil module 111 is held in the space between the retaining plates 131, 132 when viewed radially. The retaining plates 131, 132 hold the coil side portion CS of the field winding 70, which is the portion facing the rotor core 61 in the radial direction.

[0046] The retaining plate 131 corresponds to a "retaining member" that holds the coil side portion CS of the first winding portion 71a from the radially outer side between adjacent main pole portions 62 in the circumferential direction. The retaining plate 132 corresponds to an "intermediate retaining member" that holds the coil side portion CS of the second winding portion 71b from the radially outer side between adjacent main pole portions 62 in the circumferential direction.

[0047] As described above, in the first coil module 111, the outer and inner circumferences of the coil body 121 are insulated by insulators 122a and 122b, and in the second coil module 112, the outer and inner circumferences of the coil body 123 are insulated by insulators 124a and 124b. As a result, a resin coating layer is interposed between each coil body 121, 123 and each retaining plate 131, 132.

[0048] Next, the circuit module 102 will be described. Figure 12 is a perspective view of the circuit module 102, and Figure 13 is a perspective view showing the component holder 141 and electrical components of the circuit module 102 in an exploded state. Note that, as shown in Figure 7, the circuit module 102 has a resin molded portion 155 filled with synthetic resin on one side in the axial direction, but Figure 12 shows the circuit module with the resin molded portion 155 removed.

[0049] The circuit module 102 has a diode 81 and a capacitor 82 as the resonant circuits described above, as well as a component holder 141, a first busbar 151 and a second busbar 152. The component holder 141 is made of an electrically insulating material such as synthetic resin.

[0050] The component holder 141 comprises an annular main body 142 and a plurality of wire fixing parts 143 extending radially outward from the main body 142. The main body 142 has a first housing part 145 provided at one location in the circumferential direction, and a second housing part 146 in plan view that is C-shaped and provided along a virtual circle centered on the axis and passing through the first housing part 145. Each of these housing parts 145 and 146 is formed in a concave shape that is open to one side of the main body 142. Each of the housing parts 145 and 146 is a component housing part for housing electrical components. Specifically, the first housing part 145 houses a diode 81 and electrical wiring connected to the diode 81. The diode 81 is fixed by fasteners such as bolts. The second housing part 146 houses a plurality of capacitors 82 arranged in the circumferential direction and busbars 151 and 152 connected to the capacitors 82. Each capacitor 82 is either rectangular or cubic in shape.

[0051] The configuration for housing electrical components in the second housing section 146 will be further explained. The second housing section 146 houses a first bus bar 151 and a second bus bar 152, each forming an arc shape (specifically, a C shape), and a plurality of capacitors 82 sandwiched between the bus bars 151 and 152. The bus bars 151 and 152 are arranged to face each other in the axial direction. The first terminal of each capacitor 82 is connected to the first bus bar 151, and the second terminal of each capacitor 82 is connected to the second bus bar 152. As a result, the capacitors 82 are connected in parallel.

[0052] The first busbar 151 is a wiring member that connects the midpoint of the winding between the first winding section 71a and the second winding section 71b to the capacitor 82 in the resonant circuit of Figure 4. The second busbar 152 is a wiring member that connects the opposite end of the second winding section 71b from the midpoint of the winding to the capacitor 82 in the resonant circuit of Figure 4.

[0053] Furthermore, the second housing section 146 may also house a capacitor provided for noise reduction in the resonant circuit, separate from the capacitors 82 that constitute the resonant circuit described above. This capacitor may be connected in parallel with the diode 81 in Figure 4.

[0054] Furthermore, the number of wire fixing portions 143 in the component holder 141 is the same as the number of main pole portions 62, and more specifically, there are eight wire fixing portions, spaced equally in the circumferential direction. Each wire fixing portion 143 has a plurality of insertion holes 147 that penetrate in the axial direction, and the wire ends 125 and 126 extending in the axial direction from the coil bodies 121 and 123 of each coil module 111 and 112 are inserted into these insertion holes 147.

[0055] As shown in Figures 6 and 9, in the rotor body 101, wire ends 125 and 126 are drawn out from the axial ends of each coil module 111 and 112 in each winding unit 110, and these wire ends 125 and 126 are inserted into the respective insertion holes 147 of the wire fixing part 143. The wire ends 125 and wire ends 126 are then joined together by welding or other means, so that each coil module 111 and 112 is connected in series.

[0056] In the circuit module 102, electrical components such as diodes 81, capacitors 82, and busbars 151 and 152 are housed in each of the housing sections 145 and 146, and synthetic resin is then filled into each of the housing sections 145 and 146. As a result, a resin molded section 155 is formed in the circuit module 102 that covers the various electrical components that constitute the resonant circuit (see Figure 7).

[0057] Next, the configuration of the coil end covers 103 and 104 will be described. Figures 14(a) and (b) are perspective views showing the configuration of the coil end covers 103 and 104. Coil end cover 103 corresponds to the "first coil end cover" provided on one axial end side of the field winding 70, and coil end cover 104 corresponds to the "second coil end cover" provided on the other axial end side of the field winding 70. The coil end covers 103 and 104 are preferably made of a non-magnetic material, for example, aluminum. The coil end covers 103 and 104 may also be made of synthetic resin. The coil end covers 103 and 104 have different configurations, and here we will first describe the coil end cover 103.

[0058] As shown in Figure 14(a), the coil end cover 103 has an annular portion 161 that is perfectly circular in front view and an end plate portion 162 that extends radially inward from the annular portion 161, and the end plate portion 162 is provided with a plurality of openings 163 that penetrate in the thickness direction. The openings 163 are provided at predetermined intervals in the circumferential direction. However, in this embodiment, only one of the plurality of openings 163 is larger, and it is an opening that combines the size of two of the six openings 163 that are evenly arranged in the circumferential direction. Between each opening 163 in the end plate portion 162 there is a beam portion 162a that extends radially from the axial center side.

[0059] As shown in Figure 6, the coil end cover 103 is attached to the first end of the rotor body 101, which is on the side of the circuit module 102, at both ends in the axial direction. When the coil end cover 103 is attached to the rotor body 101, the coil end portion CE (see Figure 8) of the field winding 70 is surrounded from the radially outer side by the annular portion 161 of the coil end cover 103. The coil end cover 103 is also provided in a manner that covers the circuit module 102 from the axially outer side.

[0060] The coil end cover 103 is provided with openings 163 in the circumferential direction at the same intervals as the wire fixing portions 143 of the circuit module 102, and the wire fixing portions 143 are exposed axially outward through the openings 163. This configuration promotes heat dissipation from the field windings 70 from the wire ends 125 and 126.

[0061] Furthermore, as shown in Figure 14(b), the coil end cover 104 has an annular portion 171 that is perfectly circular in front view, and an end plate portion 172 that extends radially inward from the annular portion 171, with a plurality of openings 173 that penetrate axially in the end plate portion 172. The openings 173 are provided at predetermined intervals in the circumferential direction. Between each opening 173 in the end plate portion 172, there is a beam portion 172a that extends radially from the axial center side. The coil end cover 104 is attached to the second end side, which is the side opposite the circuit module 102, at both ends of the rotor body 101 in the axial direction. When the coil end cover 104 is attached to the rotor body 101, the coil end portion CE (see Figure 8) of the field winding 70 is surrounded radially from the outside by the annular portion 171 of the coil end cover 104.

[0062] The coil end covers 103 and 104 support the axial end of the retaining plate 131 from the radially outer side by the annular portions 161 and 171. This configuration will be explained using Figures 15(a) and (b). Figure 15(a) is an enlarged cross-sectional view showing the configuration around the coil end portion CE on the coil end cover 103 side, and Figure 15(b) is an enlarged cross-sectional view showing the configuration around the coil end portion CE on the coil end cover 104 side.

[0063] As shown in Figure 15(a), the retaining plate 131 has an extension portion 131a that extends from the coil side portion CS to the coil end portion CE. The coil end cover 103 is attached such that the annular portion 161 overlaps the extension portion 131a of the retaining plate 131 from the radially outer side. The end plate portion 162 of the coil end cover 103 is provided with a projection portion 164 that extends radially inward from the annular portion 161 and toward the axially inward side (i.e., toward the field winding 70 side). The projection portion 164 is preferably formed in an arc shape on the beam portion 162a of the coil end cover 103 so as to extend along a virtual circle centered on the axis of the rotor 60.

[0064] A coil end ring 181 is assembled between the coil end of the first coil module 111 and the coil end of the second coil module 112 as a separate annular member from the coil end cover 103. The coil end ring 181 in a state separated from the rotor body 101 is shown in Figure 7.

[0065] The coil end ring 181 is positioned in the gap of the coil end portion CE, which is formed by the interposition of the retaining plate 132 between the first coil module 111 and the second coil module 112 in the radial direction. The annular portion 161 of the coil end cover 103 and the coil end ring 181 are positioned to overlap each other both radially. Furthermore, the coil end ring 181 is positioned between the retaining plate 132 and the protruding portion 164 of the coil end cover 103 in the axial direction. As a result, the coil end ring 181 is positioned in a manner that is restricted in the axial direction by the retaining plate 132 and the coil end cover 103.

[0066] The coil end ring 181 is provided radially inward of the annular portion 161 of the coil end cover 103, so that the centrifugal force generated in each coil module 111, 112 when the rotor 60 rotates is distributed by the two annular members (coil end cover 103 and coil end ring 181).

[0067] In Figure 15(b), as in Figure 15(a), the retaining plate 131 has an extension portion 131a that extends from the coil side portion CS to the coil end portion CE. The coil end cover 104 is attached such that the annular portion 171 overlaps the extension portion 131a of the retaining plate 131 from the radially outer side. The end plate portion 172 of the coil end cover 104 is provided with a projection portion 174 that extends radially inward from the annular portion 171 and toward the axially inward side (i.e., toward the field winding 70 side). The projection portion 174 is inserted radially between the coil end portion of the first coil module 111 and the coil end portion of the second coil module 112. The projection portion 174 is preferably formed in an arc shape on the beam portion 172a of the coil end cover 104 so as to extend along a virtual circle centered on the axis of the rotor 60.

[0068] At the coil end portions of each coil module 111, 112, the annular portion 171 and the protruding portion 174 of the coil end cover 104 are provided in a double radial configuration. This allows the centrifugal force generated in each coil module 111, 112 during the rotation of the rotor 60 to be distributed by the two annular members (coil end cover 103 and coil end ring 181).

[0069] Furthermore, at both ends of the rotor 60 in the axial direction, on the coil end cover 103 side, the protruding portion 164 may be inserted radially between the coil end portion of the first coil module 111 and the coil end portion of the second coil module 112, similar to the coil end cover 104 side. Also, at both ends of the rotor 60 in the axial direction, on the coil end cover 104 side, a coil end ring 181 may be interposed radially between the coil end portion of the first coil module 111 and the coil end portion of the second coil module 112, similar to the coil end cover 103 side.

[0070] In this embodiment, the coil end cover 103 functions as a balance adjustment member for adjusting the circumferential weight balance in the rotor 60, and its configuration is described below. In other words, in a configuration where a circuit module 102 is provided so as to surround the rotating shaft 32 in the rotor 60 of a wound-field type rotating electric machine, there is a concern that rotational imbalance may occur due to the arrangement of electrical components in the circuit module 102 not being uniform in the circumferential direction. Therefore, in this embodiment, the coil end cover 103 is configured to adjust the weight balance by having a rotationally asymmetrical shape in the circumferential direction.

[0071] Figure 16 is a front view showing an example of the configuration of the coil end cover 103 after balance adjustment. Figure 16 shows a coil end cover 103 with the basic shape shown in Figure 14(a) in which the opening area of ​​one of the openings 163 has been expanded by cutting off a part of the end plate portion 162. In Figure 16, among the multiple openings 163, the six openings 163 that are evenly arranged in the circumferential direction before expansion are designated as openings A1 to A6, and the openings 163 before area expansion are shown with dashed lines.

[0072] In each configuration shown in Figure 16, the coil end cover 103 has a rotationally asymmetric shape in the circumferential direction because the opening area of ​​at least one of the multiple openings 163 is expanded. When n is an integer of 2 or more, a shape that matches when rotated (360 / n)° around the axis is defined as a rotationally symmetric shape, and a shape that does not match is defined as a rotationally asymmetric shape. In other words, a rotationally asymmetric shape is a shape in which the shape does not match when the coil end cover 103 is rotated around the axis of the rotating electric machine 40 except by a 360° rotation. The coil end cover 103 has a rotationally symmetric shape before a portion of the end plate portion 162 is cut off, and becomes a rotationally asymmetric shape after a portion of the end plate portion 162 is cut off.

[0073] In Figure 16(a), the opening area of ​​opening A3 among openings A1 to A6 is expanded, resulting in opening A3 being asymmetrical. Specifically, by cutting off a portion of the beam sections 162a adjacent to opening A3 in the circumferential direction, the weight near opening A3 in the coil end cover 103 is locally reduced, resulting in the coil end cover 103 having a rotationally asymmetrical shape.

[0074] In Figure 16(b), the coil end cover 103 has a rotationally asymmetric shape due to the expansion of the opening area of ​​openings A3 and A4 among the openings A1 to A6. Specifically, by removing a portion of the beam section 162a between openings A3 and A4, the weight of the coil end cover 103 near openings A3 and A4 is locally reduced, resulting in the rotationally asymmetric shape of the coil end cover 103.

[0075] In Figure 16(c), the coil end cover 103 has a rotationally asymmetrical shape due to the expansion of the opening area of ​​openings A2 to A5 among the openings A1 to A6. Specifically, the coil end cover 103 has a rotationally asymmetrical shape due to the cutting of beam sections 162a between openings A2 and A3, between A3 and A4, and between A4 and A5. In Figures 16(a) to (c), the parts of the coil end cover 103 where a portion of the end plate section 162 has been cut off are the weight-reduced adjustment sections.

[0076] During the manufacturing of the rotor 60, the completed rotor 60 shown in Figure 6 is set in a rotation measuring device, and the amount of unbalance and the unbalance angle of the rotor 60 are measured using this device. Then, the areas of the rotor 60 where weight imbalance occurs are balanced by machining or other processes.

[0077] The coil end cover 103 allows for cooling of the circuit module 102 and other components through the opening 163. Therefore, even if the opening area of ​​the opening 163 is enlarged, only the cooling of the circuit module 102 and other components will be increased, and the rotational balance can be adjusted without causing any problems.

[0078] It is also possible to use the coil end cover 104 on the opposite axial side from the coil end cover 103 as a balance adjustment member. In this case, it is sufficient that the coil end cover 104 has a rotationally asymmetric shape in the circumferential direction, by expanding the opening area of ​​at least one of the multiple openings 173 of the coil end cover 104.

[0079] It is also possible to use both the coil end covers 103 and 104 on the axial end and the other end as balance adjustment members. Here, as shown in Figures 17(a) and (b), it is preferable that the multiple openings 163 provided in the coil end cover 103 and the multiple openings 173 provided in the coil end cover 104 have different circumferential positions. Specifically, in Figures 17(a) and (b), the circumferential center positions of each opening 163 and 173 are shown by dashed lines, and the coil end cover 103 and the coil end cover 104 are configured to include openings 163 and 173 with different circumferential center positions. In other words, the configuration is such that the center position of the beam portion 162a between the circumferential openings 163 and the center position of the beam portion 172a between the circumferential openings 173 are different.

[0080] In this case, after the amount of unbalance and the unbalance angle of the rotor 60 are measured by the rotation measuring device, it is determined which coil end cover will be subject to balance adjustment and at what position on the coil end cover to be adjusted, according to the amount of unbalance and the unbalance angle. Then, the opening area of ​​at least one of the openings 163,173 in at least one of the coil end cover 103 and coil end cover 104 is expanded, so that the coil end covers 103 and 104 have a rotationally asymmetrical shape.

[0081] In this configuration, where the positions of the openings 163 and 173 in the coil end cover 103 on one axial end and the coil end cover 104 on the other axial end are different in the circumferential direction, the positions of the material portions of the end plate sections 162 and 172 are staggered. Therefore, when removing material for balance adjustment, it is possible to suppress the inconvenience of not being able to remove material because the relevant area is open.

[0082] According to the embodiment described in detail above, the following excellent effects can be obtained.

[0083] In the rotor 60, coil end covers 103 and 104 are provided radially outside the coil end portion CE of the field winding 70, surrounding the coil end portion CE. In this configuration, even if centrifugal force is generated on the field winding 70 when the rotor 60 rotates, the displacement of the coil end portion CE of the field winding 70 is suppressed by the coil end covers 103 and 104. As a result, the field winding 70 can be held in an appropriate state in the rotor 60.

[0084] The coil end covers 103 and 104 have annular portions 161 and 171 surrounding the radially outer side of the coil end portion CE of the field winding 70, and end plate portions 162 and 172 extending radially inward from the annular portions 161 and 171, with multiple openings 163 and 173 provided in the end plate portions 162 and 172. This configuration reduces the weight of the coil end covers 103 and 104, while the beam portions 162a and 172a between each opening 163 and 173 ensure the strength to maintain the shape of the annular portions 161 and 171 in the coil end covers 103 and 104. This allows the field winding 70 to be held more properly.

[0085] Furthermore, by changing the size of the openings 163 and 173 in the end plate portions 162 and 172, that is, by removing material around the openings, the circumferential weight balance of the end plate portions 162 and 172 can be changed. In other words, the end plate portions 162 and 172 of the coil end covers 103 and 104 can be used as weight balance adjustment parts.

[0086] The coil end cover 103 is attached so as to cover the circuit module 102 from the axial outside. In this case, the coil end cover 103 protects the circuit module 102, and ventilation is provided through the openings 163 and 173 of the coil end cover 103 to the coil end portion CE of the field winding 70 and the area around the circuit module 102, allowing heat dissipation from the coil end portion CE and other parts.

[0087] The circuit module 102 is provided with multiple wire fixing parts 143, and the wire ends 125 and 126 of the winding unit 110 (each coil body 121 and 123) are fixed to these wire fixing parts 143, with the wire fixing parts 143 exposed axially outward through the opening 163 of the end plate part 162. This allows heat dissipation from the field winding 70 from the wire ends 125 and 126.

[0088] The rotor core 61 is configured such that a retaining plate 131 is attached between each main pole portion 62 to hold the coil side portion CS of the field winding 70 from the radially outer side. In addition, the axial end of the retaining plate 131 is supported from the radially outer side by the annular portions 161 and 171 of the coil end covers 103 and 104. With these configurations, radial outward displacement of the coil end portion CE and coil side portion CS of the field winding 70 can be suppressed, and the detachment of each retaining plate 131 from the rotor core 61 can be effectively suppressed.

[0089] In a configuration in which the field winding 70 has a first coil module 111 (first winding section 71a) and a second coil module 112 (second winding section 71b) located radially outward and radially inward, the protruding portion 174 of the coil end cover 104 is inserted between the coil end portion of the first coil module 111 and the coil end portion of the second coil module 112. This allows the centrifugal force generated in the first coil module 111 and the centrifugal force generated in the second coil module 112 to be distributed and absorbed by the annular portion 171 and the protruding portion 174 of the coil end cover 104, thereby enhancing the suppression effect against displacement of the field winding 70.

[0090] In the coil end portion CE of the field winding 70, a protrusion 174 is interposed between the first coil module 111 and the second coil module 112, and in the coil side portion CS of the field winding 70, a retaining plate 132 is interposed between the first coil module 111 and the second coil module 112. This configuration allows the radially inner and outer coil modules 111 and 112 to be held in an appropriate state in the coil end portion CE and coil side portion CS of the field winding 70.

[0091] A coil end ring 181 is fitted between the coil end of the first winding section 71a and the coil end of the second winding section 71b. This configuration allows the centrifugal force generated in the first winding section 71a and the centrifugal force generated in the second winding section 71b to be distributed and absorbed by the two annular members (coil end cover 103 and coil end ring 181), thereby enhancing the suppression effect against displacement of the field winding 70.

[0092] The coil end ring 181 is positioned in a manner that restricts its position in the axial direction between the retaining plate 132 between adjacent main pole portions 62 in the circumferential direction and the end plate portion 162 of the coil end cover 103 (specifically, the protruding portion 164 of the end plate portion 162). This configuration suppresses the inconvenience of the coil end ring 181 shifting in the axial direction.

[0093] An insulating layer (insulator 122a) is interposed between the coil end portion CE of the field winding 70 and the coil end covers 103 and 104. This ensures insulation between the coil end portion CE of the field winding 70 and the coil end covers 103 and 104.

[0094] The coil end covers 103 and 104 are constructed from non-magnetic material. This reduces eddy current losses due to magnetic flux from the stator winding 52. It also allows for reduced inertia and weight.

[0095] In the rotor 60, coil end covers 103 and 104 provided at the axial ends of the field windings 70 are used as balance adjustment members, and at least a portion of the circumferential direction of the coil end covers 103 and 104 is an adjustment section in which the weight is reduced or increased. As a result, proper rotation of the rotor 60, which rotates integrally with the circuit module 102, can be achieved.

[0096] The coil end covers 103 and 104 were given a rotationally asymmetrical shape by cutting off at least a portion of them. This makes it possible to effectively eliminate the rotational imbalance of the rotor 60 without adding any additional components.

[0097] In the coil end covers 103 and 104, at least one of the annular portions 161 and 171 and the end plate portions 162 and 172 is configured to have a rotationally asymmetric shape in the circumferential direction. In this case, by cutting off a part of the annular portion 161 and 171 or the end plate portion 162 and 172, the coil end covers 103 and 104 become rotationally asymmetric, and the desired balance adjustment can be achieved.

[0098] In the coil end covers 103 and 104, the area of ​​at least one of the multiple openings 163 and 173 provided in the end plate portions 162 and 172 is enlarged to give the coil end covers 103 and 104 a rotationally asymmetrical shape. In this case, proper balance adjustment is possible while ensuring the holding strength of the coil end portion CE of the field winding 70 by the annular portions 161 and 171.

[0099] In this case, the coil end cover 103 in particular allows for cooling of the circuit module 102 and other components through the opening 163. Therefore, even if the opening area of ​​the opening 163 is enlarged, only the cooling performance of the circuit module 102 and other components will be increased, and the rotational balance can be adjusted without causing any problems.

[0100] In a configuration where the positions of the openings 163 and 173 in the coil end cover 103 on one axial end and the coil end cover 104 on the other axial end are different in the circumferential direction, that is, where the circumferential centers of the openings 163 and 173 in each coil end cover 103 and 104 are different, the positions of the material portions of the end plate portions 162 and 172 are staggered. Therefore, when removing material for balance adjustment, it is possible to suppress the inconvenience of not being able to remove material because the relevant area is open.

[0101] (Other embodiments) The above embodiment may be modified as follows, for example.

[0102] In the rotor 60, in addition to the coil end covers 103 and 104, it is also possible to use the retaining plates 131 provided between each main pole portion 62 of the rotor core 61 as balance adjustment members. In this case, it is preferable that the retaining plates 131 arranged in the circumferential direction include some with different weights. Specifically, as shown in Figure 18, it is preferable to make one of the retaining plates 131 (for example, retaining plate 131X shown) have a different plate thickness (for example, a thicker plate) from the other retaining plates 131 to make it have a different weight. Alternatively, it is also possible to make a specific retaining plate 131 have a different weight by providing slits or holes in it, or by changing the material of a specific retaining plate 131 to make it have a different weight.

[0103] In this configuration, some of the retaining plates 131 arranged in the circumferential direction (for example, retaining plate 131X in Figure 18) have a different weight from the remaining retaining plates 131. In this case, the rotational balance of the rotor 60 can be adjusted by adjusting the weight at both the coil end portion CE and the coil side portion CS of the field winding 70.

[0104] In the rotor 60, it is possible to adopt both a configuration in which the coil end covers 103 and 104 are used as balance adjustment members and a configuration in which the retaining plate 131 is used as a balance adjustment member, but it is also possible to adopt only one of them.

[0105] As shown in Figure 19, the rotor 60 may have a configuration in which a tape-shaped or string-shaped winding member 182 is wound around the radially outer side of the coil end portion CE of the field winding 70 (winding unit 110) as an annular member. The winding member 182 is preferably made of an insulating material, and specifically, it may be a resin tape made of, for example, carbon fiber reinforced plastic (CFRP) or glass fiber reinforced plastic (GFRP). In this configuration as well, it is possible to suppress the movement of the coil end portion CE of the field winding 70 radially outward due to centrifugal force.

[0106] The winding member 182 may be provided in place of the coil end covers 103 and 104, but it is also possible to have a configuration in which the coil end cover 103 is provided on one axial end (for example, the circuit module 102 side) and the winding member 182 is provided on the other axial end.

[0107] In the coil end cover 103 of the rotor 60, at least a portion of the annular portion 161 may be cut off, resulting in the annular portion 161 having a rotationally asymmetrical shape. For example, as shown in Figure 20, a notch 183 such as a slit or hole may be formed in a specific circumferential portion (the portion targeted for balance adjustment) of the annular portion 161. In this case, the portion with the notch 183 corresponds to the adjustment portion where the weight has been increased. In addition, the coil end cover 103 may be configured in which both a portion of the end plate portion 162 and a portion of the annular portion 161 are cut off. The same applies to the coil end cover 104.

[0108] The coil end cover 103 may have a weight member fixed to at least one of the annular portion 161 and the end plate portion 162. Specifically, as shown in Figure 21(a), the weight member 184 may be attached to a specific circumferential portion (the portion to be adjusted for balance) on the annular portion 161 of the coil end cover 103. Alternatively, as shown in Figure 21(b), the weight member 184 may be attached to a specific circumferential portion (the portion to be adjusted for balance) on the end plate portion 162 of the coil end cover 103. Weight members may be provided on both the annular portion 161 and the end plate portion 162. In this case, the portion where the weight member 184 is provided is the adjustment portion where the weight is increased. The same applies to the coil end cover 104. This makes it possible to suitably eliminate the rotational imbalance of the rotor 60.

[0109] Furthermore, it is also possible to have a configuration in which a cut-out portion is provided on at least one of the coil end covers 103 and 104, and a weight member is attached to at least one of the coil end covers 103 and 104.

[0110] As shown in Figure 22, the rotor core 61 may have a separate cylindrical portion 61a and a main pole portion 62, and a retaining portion may be integrally provided at the tip side (radially outer end) of the main pole portion 62 to hold the coil end portion CE of the field winding 70 from the radially outer side. Specifically, the main pole portion 62 is provided with a flange-shaped retaining portion 191 at the radially outer tip and a protrusion 192 at the radially inner base end. The cylindrical portion 61a is provided with a recess 193 that opens radially outward. The rotor core 61 is formed by inserting the protrusion 192 of the main pole portion 62 into the recess 193 of the cylindrical portion 61a. In this case, when the field winding 70 is wound around the main pole portion 62, the coil side portion CS of the field winding 70 is held from the radially outer side by the retaining portion 191. This suppresses the radial outward movement of the coil side portion CS of the field winding 70 due to centrifugal force.

[0111] The capacitor 82 constituting the resonant circuit may be connected in parallel to the first winding section 71a instead of the second winding section 71b. Also, in the resonant circuit, the anode of the diode 81 may be connected to the first winding section 71a side and the cathode of the diode 81 may be connected to the second winding section 71b side of the series connection of the first and second winding sections 71a and 71b.

[0112] In the rotor 60, the second winding portion 71b may be positioned radially outward (towards the stator 50) than the first winding portion 71a.

[0113] The configuration for supplying field current to the field winding is not limited to the circuit shown in Figure 4. For example, a configuration comprising a brush electrically connected to the field winding and a power supply electrically connected to the brush may also be used. In this case, the control device 30 controls the field current flowing through the field winding by increasing the output voltage of the power supply electrically connected to the brush when the rotor 60 is rotating at high speed. When a brush is used, it is not necessary to supply a harmonic current to induce field current to the stator winding.

[0114] In the stator 50, the stator core may be a stator core without teeth.

[0115] The rotating electric machine is not limited to those used as vehicle-mounted main engines; for example, it may also be a rotating electric machine used as an ISG (Integrated Starter Generator), which is both an electric motor and a generator.

[0116] The mobile body on which the rotating electric system is mounted is not limited to a vehicle; for example, it may be an aircraft or a ship. Furthermore, the rotating electric system is not limited to a system mounted on a mobile body; it may be a stationary system.

[0117] The technical concepts extracted from the above-described embodiments are described below. [Configuration 1] A wound-field rotor (60) is applied to a wound-field rotating electric machine (40) and comprises a rotor core (61) having main pole portions (62) that are provided for each magnetic pole arranged in the circumferential direction and protrude radially, and a field winding (70) wound around the main pole portions, The field winding has a coil end portion that is axially outward from the rotor core, A wound field rotor is provided with annular members (103, 104, 182) on the radially outer side of the coil end portion, surrounding the coil end portion. [Configuration 2] The winding field rotor according to configuration 1, wherein the annular member has an annular portion (161, 171) surrounding the radially outer side of the coil end portion and an end plate portion (162, 172) extending radially inward from the annular portion, and the end plate portion is provided with a plurality of openings (163, 173) penetrating in the axial direction. [Configuration 3] A circuit module (102) electrically connected to the field winding is fixed to the axial end of the rotor core on the rotating shaft (32). The winding field rotor according to configuration 2, wherein the annular member is provided in such a manner that it covers the circuit module from the axial outside. [Structure 4] The field winding has a winding unit (110) provided for each of the main pole sections, The circuit module has a plurality of wire fixing parts (143) to which the wire ends (125, 126) extending radially outward from each winding unit are fixed. The winding field rotor according to configuration 3, wherein the wire fixing portion is exposed axially outward from the opening provided in the end plate portion. [Composition 5] The rotor core is fitted with a retaining member (131) between adjacent main pole portions in the circumferential direction, which holds the coil side portion of the field winding, which is the portion facing the rotor core, from the radially outer side. A wound field rotor according to any one of configurations 2 to 4, wherein the axial end of the retaining member is supported from the radially outer side by the annular portion. [Composition 6] The field winding has a first winding portion (71a) wound radially outward at the main pole portion and a second winding portion (71b) wound radially inward. The end plate portion of the annular member is provided with protrusions (164, 174) extending radially inward from the annular portion toward the field winding, A wound field rotor according to any one of configurations 2 to 5, wherein the protrusion is inserted radially between the coil end portion of the first winding portion and the coil end portion of the second winding portion. [Composition 7] An intermediate holding member (132) is attached to the rotor core at a position between adjacent main pole portions in the circumferential direction and between the first winding portion and the second winding portion in the radial direction, which holds the coil side portion of the second winding portion from the radially outer side. The wound field rotor according to configuration 6, wherein the protruding portion is interposed between the first winding portion and the second winding portion at the coil end portion of the field winding, and the intermediate holding member is interposed between the first winding portion and the second winding portion at the coil side portion of the field winding. [Structure 8] The field winding has a first winding portion (71a) wound radially outward at the main pole portion and a second winding portion (71b) wound radially inward. A wound field rotor according to any one of configurations 2 to 7, wherein a second annular member (181), which is different from the first annular member, is assembled radially between the coil end portion of the first winding portion and the coil end portion of the second winding portion. [Composition 9] An intermediate holding member (132) is attached to the rotor core at a position between adjacent main pole portions in the circumferential direction and between the first winding portion and the second winding portion in the radial direction, which holds the coil side portion of the second winding portion from the radially outer side. The winding field rotor according to configuration 8, wherein the second annular member is provided in a state where its position is restricted in the axial direction between the intermediate holding member and the end plate portion of the first annular member. [Configuration 10] A wound field rotor according to any one of configurations 1 to 9, wherein an insulating layer is interposed between the coil end portion of the field winding and the annular member. [Composition 11] A wound field rotor according to any one of configurations 1 to 10, wherein a tape-shaped or string-shaped winding member (182) is wound around the radially outer side of the coil end portion as the annular member. [Explanation of Symbols]

[0118] 40...Rotating electric machine, 60...Rotor, 61...Rotor core, 62...Main pole section, 70...Field winding, 103,104...Coil end cover, 182...Winding member.

Claims

1. A wound-field rotor (60) is applied to a wound-field rotating electric machine (40) and comprises a rotor core (61) having main pole portions (62) that are provided for each magnetic pole arranged in the circumferential direction and protrude radially, a field winding (70) wound around the main pole portions, and a circuit module (102) fixed to a rotating shaft (32) and electrically connected to the field winding at the axial end of the rotor core, The field winding has a winding unit (110) provided for each of the main pole sections, The circuit module has a plurality of wire fixing parts (143) to which the wire ends (125, 126) extending radially outward from each winding unit are fixed. The field winding has a coil end portion that is axially outward from the rotor core, Annular members (103, 104) are provided so as to surround the coil end portion from the radially outer side and cover the circuit module from the axially outer side. The annular member has an annular portion (161, 171) surrounding the radially outer side of the coil end portion and an end plate portion (162, 172) extending radially inward from the annular portion, and the end plate portion is provided with a plurality of openings (163, 173) that penetrate in the axial direction. A wound field rotor in which the wire fixing portion is exposed axially outward from the opening provided in the end plate portion.

2. A wound-field rotor (60) is applied to a wound-field rotating electric machine (40) and has a rotor core (61) having main pole portions (62) that are provided for each magnetic pole arranged in the circumferential direction and protrude radially, and a field winding (70) wound around the main pole portions, The field winding has a first winding portion (71a) wound radially outward at the main pole portion and a second winding portion (71b) wound radially inward. In the field winding, annular members (103, 104) are provided radially outward of the coil end portion that is axially outward from the rotor core, surrounding the coil end portion. The annular member has an annular portion (161, 171) that surrounds the radially outer side of the coil end portion, and an end plate portion (162, 172) that extends radially inward from the annular portion. The end plate portion of the annular member is provided with protrusions (164, 174) extending radially inward from the annular portion toward the field winding, A wound field rotor in which the protrusion is inserted radially between the coil end portion of the first winding and the coil end portion of the second winding.

3. An intermediate holding member (132) is attached to the rotor core at a position between adjacent main pole portions in the circumferential direction and between the first winding portion and the second winding portion in the radial direction, which holds the coil side portion of the second winding portion from the radially outer side. The wound field rotor according to claim 2, wherein the protruding portion is interposed between the first winding portion and the second winding portion at the coil end portion of the field winding, and the intermediate holding member is interposed between the first winding portion and the second winding portion at the coil side portion of the field winding.

4. A wound-field rotor (60) is applied to a wound-field rotating electric machine (40) and has a rotor core (61) having main pole portions (62) that are provided for each magnetic pole arranged in the circumferential direction and protrude radially, and a field winding (70) wound around the main pole portions, The field winding has a first winding portion (71a) wound radially outward at the main pole portion and a second winding portion (71b) wound radially inward. In the field winding, annular members (103, 104) are provided radially outward of the coil end portion that is axially outward from the rotor core, surrounding the coil end portion. The annular member has an annular portion (161, 171) that surrounds the radially outer side of the coil end portion, and an end plate portion (162, 172) that extends radially inward from the annular portion. A wound field rotor in which a second annular member (181), different from the first annular member, is assembled radially between the coil end portion of the first winding portion and the coil end portion of the second winding portion.

5. An intermediate holding member (132) is attached to the rotor core at a position between adjacent main pole portions in the circumferential direction and between the first winding portion and the second winding portion in the radial direction, which holds the coil side portion of the second winding portion from the radially outer side. The winding field rotor according to claim 4, wherein the second annular member is provided in a state where its position is restricted in the axial direction between the intermediate holding member and the end plate portion of the first annular member.

6. A circuit module (102) electrically connected to the field winding is fixed to the axial end of the rotor core on the rotating shaft (32). The wound field rotor according to any one of claims 2 to 5, wherein the annular member is provided in such a manner that it covers the circuit module from the axial outside.

7. The rotor core has a retaining member (131) attached between adjacent main pole portions in the circumferential direction, which holds the coil side portion of the field winding, which is the portion facing the rotor core, from the radially outer side. The winding field rotor according to any one of claims 1 to 5, wherein the axial end of the retaining member is supported from the radially outer side by the annular portion.

8. A wound field rotor according to any one of claims 1 to 5, wherein an insulating layer is interposed between the coil end portion of the field winding and the annular member.