JP6485316B2 - Rotating electric machine - Google Patents

Description

  The present invention relates to a rotating electrical machine provided with a plurality of rotor torque generating surfaces with respect to a stator.

  In Patent Document 1, an annular stator having a stator core in which an armature winding is toroidally wound, a radial rotor facing radially inward with respect to the stator, and one axial direction of the rotation shaft with respect to the stator There is disclosed a rotating electrical machine that includes two axial rotors facing each other on the side and the other side, and has three rotor torque generating surfaces with respect to the stator.

  In each of the radial rotor and the two axial rotors of the rotating electrical machine disclosed in Patent Document 1, permanent magnets are arranged at predetermined intervals in the circumferential direction. This rotating electrical machine generates torque in the radial rotor and the two axial rotors by the interaction between the rotating magnetic field generated in the stator and the field magnetic fluxes of the permanent magnets of the radial rotor and the two axial rotors.

JP 2010-226808 A

  However, the rotating electrical machine disclosed in Patent Document 1 uses permanent magnets to form magnetic poles in the radial rotor and the two axial rotors. For this reason, when using rare earth magnets with a small reserve capacity and uneven mining locations as permanent magnets installed on the radial rotor and the two axial rotors, the material cost increases and stable resources There is a risk that supply cannot be secured.

  The present invention has been made in view of the above circumstances, and provides a rotating electrical machine that is excellent in cost and resource supply and that can improve torque density by increasing magnetomotive force of a rotor. Objective.

  In order to achieve the above object, the present invention is a rotating electrical machine including a stator that generates a magnetic flux by energizing a coil and a rotor that rotates by the passage of the magnetic flux, and the stator has a predetermined circumferential direction. An annular stator core having a plurality of stator teeth arranged at intervals, and an armature coil wound toroidally between adjacent stator teeth of the annular stator core, the rotor in the axial direction of the stator core A rotor core having a rotor tooth facing the stator teeth on both sides and a rotor tooth facing the stator teeth on the radially inner surface side of the stator core, wound on the rotor teeth and generated on the stator side An induction coil that induces an induced current by interlinkage of magnetic flux and wound around the rotor teeth A field coil that generates a magnetic field by energizing the induced current, and the rotor core has a pair of outer surfaces on the opposite side of the surface facing the stator core in the axial direction, and the field magnet The coil is folded to one of the pair of outer faces, and a field rotor in which the field coil folded to the outer face is wound around one of the pair of outer faces. A field stator for generating a magnetic field interlinking with the field coil is disposed so as to face the field coil that is provided with teeth and is turned back to the outer surface side.

  According to the present invention, it is possible to provide a rotating electrical machine that is excellent in terms of cost and resource supply and that can improve torque density by increasing the magnetomotive force of the rotor.

FIG. 1 is a diagram showing a rotating electrical machine according to an embodiment of the present invention, and is a perspective view showing an overall configuration of the rotating electrical machine. FIG. 2 is a diagram illustrating the rotating electrical machine according to the embodiment of the present invention, and is a cross-sectional view of the rotating electrical machine cut along a plane passing through the rotating shaft. FIG. 3 is a diagram showing a rotating electrical machine according to an embodiment of the present invention, and is a perspective view of a stator. FIG. 4 is a view showing a rotating electrical machine according to an embodiment of the present invention, and is a perspective view of a stator core. FIG. 5 is a diagram showing a rotating electrical machine according to an embodiment of the present invention, and is an exploded perspective view of a stator core. FIG. 6 is a view showing a rotating electrical machine according to an embodiment of the present invention, and is a perspective view showing a connecting structure of stator cores. FIG. 7 is a view showing a rotating electrical machine according to an embodiment of the present invention, and is a perspective view of an armature coil. FIG. 8 is a view showing a rotating electrical machine according to an embodiment of the present invention, and is a perspective view showing an example of a connection structure of armature coils. FIG. 9 is a diagram illustrating a rotating electrical machine according to an embodiment of the present invention, and is a diagram illustrating a magnetic flux distribution of a stator. FIG. 10 is a diagram showing a rotating electrical machine according to an embodiment of the present invention, and is a perspective view of a rotor. FIG. 11 is a diagram showing a rotating electrical machine according to an embodiment of the present invention, and is a perspective view of a rotor core. FIG. 12 is a view showing a rotating electrical machine according to an embodiment of the present invention, and is a perspective view of an induction coil. FIG. 13 is a view showing a rotating electrical machine according to an embodiment of the present invention, and is a perspective view of a field coil. FIG. 14 is a perspective view showing a field stator for a rotating electrical machine according to an embodiment of the present invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIGS. 1-14 is a figure explaining the rotary electric machine which concerns on one Embodiment of this invention.

(Schematic configuration of rotating electrical machine)
1 and 2, the rotating electrical machine 1 includes a stator 100 that generates a magnetic flux by energizing a coil, and a rotor 200 that rotates by the passage of the magnetic flux. The rotor 200 is disposed closer to the rotating shaft 1C than the stator 100. The rotation shaft 1 </ b> C is a rotation center line of the rotor 200.

  The rotating electrical machine 1 includes a shaft 20 on the rotating shaft 1C. The shaft 20 is fixed to the inner peripheral portion of the rotor 200 and rotates integrally with the rotor 200.

  Here, in FIGS. 1, 2, 3, 4, 5, 6, 8, 10, 11, and 14, one side in the axial direction of the rotating electrical machine 1 is a lower side of the drawing, The rotary electric machine 1 is illustrated with the other side in the axial direction of the rotary electric machine 1 as the upper side of the drawing.

  As will be described later in detail, the rotating electrical machine 1 generates an induced current in the induction coil I of the rotor 200 by a rotating magnetic field generated by energizing the armature coil 140 of the stator 100. And the rotary electric machine 1 makes the rotor 200 function as an electromagnet by energizing the field coil F of the rotor 200 with this induced current as a field current, and generates torque. Thus, the rotating electrical machine 1 is configured as a magnet-free self-excited wound field synchronous motor.

(Stator)
1 to 3, the stator 100 includes an annular stator core 110 and an armature coil 140 wound around the stator core 110. The stator core 110 is made of a high permeability magnetic material formed in an annular shape concentric with the rotating shaft 1C.

  As shown in FIG. 4, the stator core 110 includes an annular stator yoke 120 and a plurality of stator teeth 130 provided on the stator yoke 120 at predetermined intervals in the circumferential direction. The stator yoke 120 has a rectangular cross section.

  The stator teeth 130 are provided so as to protrude from the surface of the stator yoke 120 to both sides in the axial direction of the rotating electrical machine 1 and to the radially inner peripheral surface side, and are trapezoidal when viewed from the axial direction of the rotating electrical machine 1. As shown in FIG. 2, the circumferential cross section of the rotating electrical machine 1 is formed in a U-shape. Twelve stator teeth 130 are provided at predetermined intervals in the circumferential direction on the stator yoke 120.

  Specifically, the stator tooth 130 includes a first stator tooth 131, a second stator tooth 132, and a third stator tooth 133. The first stator teeth 131 are provided on one side of the stator yoke 120 in the axial direction of the rotating electrical machine 1, and project from the stator yoke 120 to one side of the rotating electrical machine 1 in the axial direction.

  The second stator teeth 132 are provided on the other side of the stator yoke 120 in the axial direction of the rotating electrical machine 1 and protrude from the stator yoke 120 to the other side of the rotating electrical machine 1 in the axial direction. The third stator teeth 133 are provided on the inner peripheral surface side of the rotating electrical machine 1 in the stator yoke 120 and protrude from the stator yoke 120 to the inner peripheral surface side of the rotating electrical machine 1.

  The stator 100 of the present embodiment includes a piece member 135 for attaching the stator 100 to a motor case (not shown). The piece member 135 is made of a nonmagnetic material such as stainless steel or aluminum. A bolt through hole 135a is formed at the outer end of the piece member 135 in the radial direction.

  In the present embodiment, the stator 100 is attached to the motor case by passing a bolt (not shown) through the bolt through hole 135a of the piece member 135 and directly fixing the bolt to a bracket or an inner wall of the motor case (not shown). Can be fixed.

  4 to 6, in the stator 100, the stator core 110 has a structure in which the stator yoke 120, the stator teeth 130, and the piece member 135 are divided.

  Specifically, as shown in FIGS. 5 and 6, the stator yoke 120 includes twelve divided yokes 121 divided in the circumferential direction of the stator yoke 120. Each divided yoke 121 is formed with a notch 121a and a notch 121b at one end and the other end in the circumferential direction. The direction in which the notch 121 a and the notch 121 b are cut out is opposite to the axial direction of the rotating electrical machine 1.

  The notch 121a of the split yoke 121 is fitted with the notch 121b of the split yoke 121 adjacent in the circumferential direction. At this time, a predetermined gap 121c is formed in the axial direction of the rotating electrical machine 1 between the notch 121a and the notch 121b as shown in FIG.

  A piece member 135 is fitted into the predetermined gap 121c. As shown in FIG. 2, the predetermined gap 121 c is located in the central portion of the stator yoke 120 in the axial direction. Here, the central portion of the stator yoke 120 in the axial direction has less influence on the magnetic circuit than other portions (see FIG. 9).

  Thereby, even if it is a case where the piece member 135 is fitted in the predetermined clearance 121c, the influence on a magnetic circuit can be suppressed to the minimum. Therefore, the stator 100 can be fixed to the motor case without degrading the performance of the rotating electrical machine 1.

  In addition, through holes 121d and 121e through which the bolts 136 pass are formed in the notch 121a and the notch 121b of the split yoke 121, respectively.

  Furthermore, a through hole 135b through which the bolt 136 is passed is formed at the radially inner end of the piece member 135. The bolt 136 is made of a nonmagnetic material such as stainless steel or aluminum.

  As shown in FIGS. 5 and 6, the stator teeth 130 have a U-shaped cross section, and the first stator teeth 131, the second stator teeth 132, and the third stator teeth 133 are integrally formed.

  The stator teeth 130 are fitted from the inner side in the radial direction to a connecting portion where the notched portions 121a and the notched portions 121b of the divided yokes 121 adjacent in the circumferential direction are fitted. Thereby, the connection part of the division | segmentation yoke 121 adjacent to the circumferential direction comes to be located in the inside of the stator teeth 130. FIG. For this reason, interference between the connecting portion of the split yoke 121 and the armature coil 140 can be avoided.

  The second stator teeth 132 of the stator teeth 130 are formed with through holes 132a through which the bolts 136 are passed. Further, the first stator teeth 131 of the stator teeth 130 are formed with fastening holes 131a to which the bolts 136 are fastened.

  The stator core 110 configured as described above is created by the following procedure. That is, first, the piece member 135 is inserted into the gap 121c from the outer side in the radial direction of the stator core 110 in a state where the notch 121a and the notch 121b of the adjacent divided yoke 121 are fitted together.

  Thereafter, the stator teeth 130 are fitted from the inner side in the radial direction to the connecting portion where the notched portion 121a and the notched portion 121b of the divided yoke 121 adjacent in the circumferential direction are fitted. Then, the bolts 136 are fastened to the fastening holes 131a through the through holes 132a, 121d, 135b, and 121e, so that the divided yokes 121 adjacent in the circumferential direction in a state where the stator teeth 130 and the piece member 135 are integrated. Connected.

  An annular stator core 110 is formed by sequentially performing such a connecting operation with respect to the other divided yokes 121. The armature coil 140 is attached to the stator yoke 120 in a state in which the armature coil 140 is preliminarily formed into a toroidal-wound shape each time the divided yokes 121 adjacent in the circumferential direction are connected. When all the divided yokes 121 are connected in a ring shape, the stator 100 as shown in FIG. 3 is formed.

  According to this embodiment, since the piece member 135 for attaching the stator 100 to a motor case (not shown) is made of a nonmagnetic material, the stator 100 can be attached to the motor case in a state of being magnetically cut off. Thereby, generation | occurrence | production of a leakage magnetic flux etc. can be suppressed, for example.

  As shown in FIGS. 1, 3, and 7, the armature coil 140 is toroidally wound around an annular stator yoke 120 (see FIG. 4) with slots between adjacent stator teeth 130 of the stator core 110. The toroidal winding is a method in which the winding 141 is wound around the stator yoke 120 alternately through the inside and the outside of the ring of the stator yoke 120.

  In the present embodiment, as shown in FIG. 7, the armature coil 140 is mounted on the split yoke 121 (see FIG. 6) of the stator yoke 120 in a state in which the armature coil 140 is preliminarily formed into a shape that is toroidally wound around the stator yoke 120. It has become so. After the armature coil 140 is mounted on the split yoke 121 of the stator yoke 120, another split yoke 121 adjacent in the circumferential direction is connected to the split yoke 121 together with the stator teeth 130. Thereby, as shown in FIG. 3, the armature coil 140 is toroidally wound in the slot of the stator core 110.

  Thus, in this embodiment, since it is not necessary to wind the armature coil 140 around the stator yoke 120 directly, the insulation of the armature coil 140 and the assembly of the stator 100 are improved.

  The armature coil 140 is disposed between the stator teeth 130 and an intermediate position between the stator teeth 130 that are adjacent to the stator teeth 130 in the circumferential direction. The armature coil 140 corresponds to any of the U-phase, V-phase, and W-phase of three-phase alternating current.

  The pair of armature coils 140 facing in the circumferential direction across the stator teeth 130 is composed of magnetic flux generated from one armature coil 140 and magnetic flux generated from the other armature coil 140, and the direction of the magnetic flux is circumferential. The winding direction and the energization direction are set so as to be opposite to each other.

  Thus, for example, when one armature coil 140 is in the U + phase and the other armature coil 140 is in the U− phase, the magnetic flux from one armature coil 140 and the other armature coil 140 toward the stator teeth 130 is increased. Occur.

  In FIG. 7, the winding 141 of the armature coil 140 is a rectangular wire having a rectangular cross section. The armature coil 140 is wound around the stator yoke 120 of the stator core 110 with the winding 141 in a toroidal winding state by edgewise winding. The edgewise winding is a method in which the winding 141 is wound vertically with the short side of the winding 141 facing the inner side and the outer side of the rotating electric machine 1 with respect to the stator yoke 120.

  Thereby, since the windings 141 adjacent to each other in the winding pitch direction are in surface contact with the long sides, the number of turns can be increased while maintaining the cross-sectional area corresponding to the current, so that the space factor of the armature coil 140 can be improved. The magnetomotive force of the stator 100 can be increased.

  Further, since the windings 141 adjacent to each other in the winding pitch direction are in surface contact with each other with long sides, heat conduction can be performed uniformly with a large area between the windings 141. Thereby, heat conduction is dispersed and heat dissipation can be improved.

  Further, since both end portions 141A and 141B that become the winding start or winding end of the winding 141 can be arranged on the same surface on the outer peripheral side of the stator 100, the connection of the plurality of armature coils 140 can be facilitated.

  For example, as shown in FIG. 8, by connecting both ends 141A and 141B of the winding 141 of the armature coil 140 to the inner peripheral surface of the annular connection ring 150 made of a conductive member, the armature coil 140 Connection can be facilitated. As a method for connecting both end portions 141A and 141B of the winding 141 and the inner peripheral surface of the connection ring 150, for example, soldering or welding is possible.

  In addition to this, for example, one of a female connector and a male connector is attached to both ends 141A and 141B of the winding 141, and the other of the female connector and the male connector is provided on the inner peripheral surface of the connection ring 150. The armature coil 140 may be connected using In this case, the female connector and the male connector are preferably structured to be fitted from the axial direction of the rotating electrical machine 1. Thus, the armature coil 140 can be more easily connected by using the female connector and the male connector.

  The connection ring 150 is integrated with a motor case (not shown) or is fitted and fixed to the inner wall surface of the motor case. Thereby, the enlargement of a motor case can be suppressed.

(Magnetic flux distribution of stator)
FIG. 9 is a diagram showing a magnetic flux distribution of the stator 100 obtained by electromagnetic field analysis. In FIG. 9, the stator core 110 and the rotor 200 are shown in a straight line for easy explanation. In FIG. 9, the first stator teeth 131, the second stator teeth 132, or the third stator teeth 133 are simply indicated as the stator teeth 130 without being distinguished from each other. FIG. 9 shows an analysis result when energization is performed with the V-phase current amplitude set to 1 as the reference value and the U-phase and W-phase current amplitude values set to −0.5, respectively.

  In FIG. 9, when one of a pair of armature coils 140 adjacent in the circumferential direction with the stator teeth 130 interposed therebetween is a V + phase and the other is a V− phase, the magnetic flux generated from the pair of armature coils 140 is a pair of armature coils 140. This occurs toward the stator teeth 130 sandwiched by the armature coils 140 and collides with the stator teeth 130. Then, the magnetic flux generated in the stator teeth 130 changes its direction in a direction perpendicular to the stator yoke 120 and travels from the stator teeth 130 to the rotor 200.

  A part of the magnetic flux directed toward the rotor 200 passes through a rotor core 210 (to be described later) of the rotor 200, and then travels toward the stator teeth 130 sandwiched between the pair of armature coils 140 of the W + phase and the W− phase. Further, the remaining part of the magnetic flux directed toward the rotor 200 passes through a rotor core 210 (to be described later) of the rotor 200, and then proceeds to the stator teeth 130 sandwiched between a pair of armature coils 140 of U + phase and U− phase.

  Thus, the magnetic circuit of the magnetic flux generated by the armature coil 140 is formed on the surface where the stator teeth 130 and the rotor 200 face each other. The rotating electrical machine 1 uses a surface on which the stator teeth 130 and the rotor 200 face each other as a torque generating surface.

  For this reason, the torque density can be increased by effectively using the magnetic flux generated by the armature coil 140 as the torque generation surface increases. Torque density means the magnitude of torque per volume.

  The rotor 200 is provided with three torque generating surfaces including both the axial side surfaces and the inner peripheral surface side of the rotating electrical machine 1 to increase the torque density. In this way, by increasing the torque generating surface, the rotating electrical machine 1 is small and can generate high torque, so that it can be particularly excellent as a rotating electrical machine mounted on a hybrid vehicle or the like.

(Rotor)
1, 2, 10, and 11, the rotor 200 includes a rotor core 210, an induction coil I, and a field coil F.

  The rotor core 210 includes two disk-shaped disk portions 211 and 212, and a cylindrical cylindrical portion 213 that connects the disk portion 211 and the disk portion 212 at the inward extension of the disk portions 211 and 212. .

  The disk portions 211 and 212 are arranged on a plane orthogonal to the rotation shaft 1 </ b> C so as to cover the stator core 110 from one side and the other side in the axial direction of the rotating electrical machine 1. An insertion hole 213 </ b> A is formed at the center of the cylindrical portion 213 in the radial direction. The insertion hole 213 </ b> A passes through the cylindrical portion 213 in the axial direction of the rotating electrical machine 1. The shaft 20 is inserted into the insertion hole 213A.

  The cylindrical portion 213 is disposed inside the stator core 110 in the radial direction. The rotor core 210 is made of a high permeability magnetic material.

  As described above, the rotor core 210 has a bobbin shape having flanges at both ends in the axial direction of the cylindrical portion 213 so as to face the stator 100 on the three surfaces of the stator 100 on both sides in the axial direction and the inner surface in the radial direction. Is formed. In other words, the rotor core 210 has a U-shaped cross section formed by the two disk portions 211 and 212 and the cylindrical portion 213 and is formed in an annular shape centering around the insertion hole 213A. It covers from the circumferential side toward the outer circumferential side.

  In addition, the rotor core 210 includes a first rotor tooth 231, a second rotor tooth 232, and a third rotor tooth 233 at the same circumferential position. The first rotor teeth 231, the second rotor teeth 232, and the third rotor teeth 233 have torque generating surfaces between the first stator teeth 131, the second stator teeth 132, and the third stator teeth 133 of the stator 100, respectively. Forming.

  The first rotor teeth 231 are provided on the other surface 211 </ b> A in the axial direction of the disk portion 211, and protrude from the disk portion 211 toward the other side in the axial direction toward the stator core 110. The first rotor teeth 231 face the first stator teeth 131 in the axial direction with a predetermined air gap.

  The second rotor teeth 232 are provided on one surface 212 </ b> A in the axial direction of the disk portion 212, and project from the disk portion 212 toward the stator core 110 in one axial direction. The second rotor teeth 232 are opposed to the second stator teeth 132 in the axial direction with a predetermined air gap therebetween.

  The third rotor teeth 233 are provided on the outer peripheral surface of the cylindrical portion 213, that is, on the radially outer surface of the cylindrical portion 213, and project outward in the radial direction from the cylindrical portion 213 toward the stator core 110. The third rotor teeth 233 are opposed to the third stator teeth 133 in the radial direction with a predetermined air gap therebetween.

  The radially inner end portion of the first rotor teeth 231 is continuous with the end portion on one side in the axial direction of the third rotor teeth 233. In addition, the radially inner end of the second rotor teeth 232 is continuous with the other end of the third rotor teeth 233 in the axial direction.

  Thus, the rotor core 210 has an integrated structure in which the first rotor teeth 231 and the third rotor teeth 233 on the first rotor core 210A side described later are continuous, and the second rotor teeth 232 and the second rotor core 210B described later. The third rotor teeth 233 on the side has a continuous structure. Therefore, as described later, in the rotor core 210 having a divided structure, when the first rotor core 210A and the second rotor core 210B are fastened, the first rotor teeth 231, the second rotor teeth 232, and the third rotor teeth 233 are integrated. One rotor tooth 230 is formed. The rotor core 210 is provided with a plurality of rotor teeth 230 at equal intervals in the circumferential direction.

  In addition, the rotor core 210 has a pair of outer surfaces 211B and 212B on the opposite side of the surface facing the stator core 110 in the axial direction of the stator core 110. That is, the rotor core 210 has an outer surface 211B on one side in the axial direction opposite to the other surface 211A in the axial direction of the disk portion 211. In addition, the rotor core 210 has an outer surface 212B on the other side in the axial direction opposite to the surface 212A on the one side in the axial direction of the disk portion 212.

  A field rotor tooth 241 that protrudes from the disk portion 211 to one side in the axial direction is provided on the outer surface 211B. Eight field rotor teeth 241 are provided at predetermined intervals in the circumferential direction of the rotor core 210. The field rotor teeth 241 are provided at the same position in the circumferential direction as the first rotor teeth 231.

  The field rotor teeth 241 are wound with a field coil Fi that is folded back toward the outer surface 211B of the rotor core 210 as will be described later. Here, the field coil Fi folded to the outer surface 211B side of the rotor core 210 refers to a portion of the field coil F folded to the outer surface 211B side as will be described later.

  The rotor core 210 configured as described above is fixed to the shaft 20 so as to be integrally rotatable. Specifically, the rotating electrical machine 1 includes a holding ring 4 </ b> B, and the holding ring 4 </ b> B is fitted or screwed into the shaft 20 to fix the rotor core 210 to the shaft 20.

  In addition, key grooves (not shown) are formed in the inner peripheral portion of the insertion hole 213A of the rotor core 210 and the outer peripheral portion of the shaft 20, respectively. The rotor core 210 is prevented from rotating with respect to the shaft 20 when the key is inserted into the key groove, and can rotate integrally.

  In the present embodiment, the rotor core 210 has a split structure in order to facilitate the assembly work of the stator 100 to the rotor 200.

  Specifically, as shown in FIG. 11, the rotor core 210 is divided into a first rotor core 210A on one side in the axial direction and a second rotor core 210B on the other side in the axial direction at an intermediate position in the axial direction. Yes. For this reason, the 3rd rotor teeth 233 are divided into the 1st rotor core 210A side and the 2nd rotor core 210B.

  The second rotor core 210B has four through-holes 216 through which the fastening bolts (not shown) are passed around the fitting holes 213A, and the first rotor core 210A has the fastening bolts through which the through-holes 216 are passed. Four fastening holes (not shown) are formed around the fitting holes 213A.

  Thus, the divided first rotor core 210A and second rotor core 210B are connected so as to sandwich the stator core 110 in the axial direction, and the first rotor core 210A and the second rotor core 210B are connected by four fastening bolts (not shown). The electric rotating machine 1 can be assembled by fastening.

  Since the through-hole 216 and the fastening hole described above are formed around the fitting hole 213A that is the inner diameter portion of the rotor core 210 that has little influence on the magnetic circuit, the performance of the rotating electrical machine 1 is not deteriorated. Assemblability of the is improved.

  Moreover, as a material of the fastening bolt described above, it is desirable to use a non-magnetic material such as stainless steel. Thereby, the mechanical strength of the rotating electrical machine 1 can be ensured, and the performance deterioration due to the influence on the magnetic circuit can be suppressed.

  Further, by adopting the divided structure as described above for the rotor core 210, it is also possible to adopt an integral (one-piece) annular structure that is not a divided structure as the stator core 110. The integrated stator core 110 is superior in strength to the case of the split structure, and has sufficient resistance against excitation vibration acting on the stator core 110. When the integrated stator core 110 having no split structure is employed, the rotating electrical machine 1 can be assembled by connecting the stator core 110 so as to be sandwiched in the axial direction in a state where the induction coil I and the field coil F are arranged.

(Induction coil, field coil)
As shown in FIGS. 10, 12, and 13, the winding Iw of the induction coil I and the winding Fw of the field coil F are made of a rectangular wire in which a copper wire having a rectangular cross-sectional shape is covered with an insulating material. The induction coil I and the field coil F are constituted by winding the windings Iw and Fw by α. Here, the α winding is a method in which the winding start and the winding end of the windings Iw and Fw are simultaneously wound outward.

  The induction coil I and the field coil F wound in this way have an improved space factor because the winding start side ends of the windings Iw and Fw are not left inside, and both ends of the windings Iw and Fw are improved. Since the part is disposed outside the induction coil I and the field coil F, the connection can be easily performed.

  In the present embodiment, the winding Iw of the induction coil I is wound in two rows in the winding pitch direction, and the end of the first row and the end of the second row of the winding Iw are on the same surface in the rotor 200. Pulled out to the side. Here, the winding Iw on the side facing the stator core 110 is the first winding Iw, and the winding Iw on the side facing the field coil F is the second winding Iw.

  Further, the winding Fw of the field coil F is wound in two rows in the winding pitch direction, and the end of the first row and the end of the second row of the winding Fw are on the same surface side in the rotor 200. Has been pulled out. Here, the winding Fw on the side facing the induction coil I is the first row of windings Fw, and the winding Fw on the side facing the rotor core 210 is the second row of windings Fw.

  Since the induction coil I and the field coil F wound in this way can be connected on the same surface by drawing the ends of the windings Iw and Fw to the same surface side in the rotor 200, Can be easily performed.

  In addition, the induction coil I and the field coil F are wound so that the short sides of the windings Iw and Fw made of a rectangular wire are perpendicular to the magnetic flux generation direction.

  Thereby, the cross-sectional areas of the windings Iw and Fw orthogonal to the magnetic flux linked to the rotor core 210 can be reduced, and eddy current loss generated in the windings Iw and Fw can be reduced.

  Furthermore, the induction coil I and the field coil F are formed in a shape obtained by bending α-wound windings Iw and Fw into a U-shape.

  Specifically, the field coil F is bent in a U-shape along the inner surface of the U-shaped rotor core 210 and around the base end portion of the rotor teeth 230. Part of the field coil F is folded back to the outer surface 211 </ b> B side of the rotor core 210.

  That is, in the field coil F, the winding Fw in the second row is folded back to the outer surface 211B side of the rotor core 210. The second row of windings Fw extends from the radially inner side of the rotor core 210 toward the outer side on one side in the axial direction of the rotating electrical machine 1, and radially extends on the outer side in the radial direction. It is folded toward the inward side.

  Thus, the field coil F includes a U-shaped portion that is not folded back to the outer surface 211B side of the rotor core 210 and a portion that is folded back to the outer surface 211B side of the rotor core 210. Hereinafter, the U-shaped portion of the rotor core 210 that is not folded back on the outer surface 211B side is referred to as “field coil Ff”, and the portion that is folded back on the outer surface 211B side is referred to as “field coil Fi”.

  On the other hand, the induction coil I is bent in a U shape along the inner surface of the U-shaped field coil F and around the tip of the rotor teeth 230.

  As described above, the induction coil I and the field coil F are arranged on the distal end side and the proximal end side of the rotor tooth 230 with respect to the same rotor tooth 230, respectively. Are arranged in layers. For this reason, the induction coil I is disposed closer to the stator 100 side of the rotor teeth 230 than the field coil F.

  The induction coil I configured as described above induces an induced current by linkage of magnetic flux generated on the stator 100 side when a rotating magnetic field is generated in the armature coil 140.

  Further, the field coil Fi folded back on the outer surface 211B side of the rotor core 210 induces an induced current by linkage of magnetic flux generated in the field stator 400 described later.

(Field stator)
As shown in FIGS. 1, 2, and 14, in the rotating electrical machine 1, an annular field stator 400 is disposed so as to face the field coil Fi that is folded back on the outer surface 211 </ b> B of the rotor core 210. The field stator 400 generates a magnetic field linked to the field coil Fi that is folded back on the outer surface 211B of the rotor core 210.

  Here, in the low rotation range where the rotational speed of the rotating electrical machine 1 is low, the fluctuation speed of the magnetic flux of the third-order harmonics (described later) linked from the armature coil 140 of the stator 100 to the induction coil I of the rotor 200 decreases. Therefore, the induced voltage of the induction coil I decreases. Thereby, in the low rotation region of the rotating electrical machine 1, the induced current induced in the induction coil I is reduced and the field current flowing in the field coil F is also reduced. As a result, the magnetic field generated in the rotor 200 is reduced, and the rotational torque generated on the torque generating surface between the stator 100 and the rotor 200 is reduced.

  Therefore, in the present embodiment, in addition to the induced current generated in the induction coil I, an induced current is supplied from the outside to the field coil F so that the rotational torque does not decrease even in the low rotation range of the rotating electrical machine 1 as described above. I was able to do it. That is, the rotating electrical machine 1 of the present embodiment includes a field stator 400 for inducing an induced current in the field coil Fi that is folded back to the outer surface 211B side of the rotor core 210.

  As shown in FIG. 2, the field stator 400 is supported on the shaft 20 via a ball bearing 25 at the radially inner periphery. Further, the field stator 400 is directly fixed to a bracket provided on an inner wall of a motor case (not shown) or an inner wall of the motor case, in the radial direction. Thereby, the field stator 400 is fixed to the motor case without rotating integrally with the shaft 20.

  Further, the field stator 400 may be configured such that one axial surface of the rotating electrical machine 1 is fixed to the axial side wall of the motor case or a bracket provided on the side wall with a bolt or the like. In this case, the ball bearing 25 is unnecessary.

  As shown in FIG. 14, the field stator 400 is provided with a core portion 401 that protrudes in the axial direction of the rotating electrical machine 1 facing the outer surface 211 </ b> B of the rotor core 210. Twenty-four core portions 401 are arranged at predetermined intervals in the circumferential direction of the field stator 400.

  Here, as will be described later, in addition to the induced current generated in the induction coil I, the induced current generated in the field coil Fi is supplied to the field coil Ff as the field current. For this reason, in order to maximize the field current flowing through the field coil Ff, the phase of the induction current generated in the induction coil I and that of the induction current generated in the field coil Fi need to match.

  In order to match the phase of the induced current generated in the induction coil I and the induced current generated in the field coil Fi, the period of the magnetic flux interlinking from the field stator 400 to the field coil Fi is set to the induction coil I. What is necessary is just to make it the same as the period of the magnetic flux of the 3rd time harmonic which generates an induced current. The period of the magnetic flux of the third time harmonic is one third of the period of the rotating magnetic field of the stator 100.

  Therefore, in order to make the period of the magnetic flux interlinking from the field stator 400 to the field coil Fi the same as the period of the third time harmonic magnetic flux, the number of the core parts 401 is set to the number of poles P ( The number may be 24, which is three times that of 8).

  As described above, in this embodiment, the number of the core portions 401 is set to 24, which is three times the number of poles P (8) of the rotor 200, and is generated by the induction current generated by the induction coil I and the field coil Fi. This is because the phase of the induced current is adjusted. Thereby, the field current flowing through the field coil Ff can be maximized.

  A DC coil 402 that generates a magnetic field is wound around the core portion 401 along the peripheral surface of the core portion 401. The DC coil 402 is formed of a flat wire in which a copper wire having a rectangular cross section is covered with an insulating material, and is wound edgewise around the core portion 401. The DC coil 402 is not limited to a rectangular wire and may be a round wire.

  A direct current is applied to the direct current coil 402 from a power source (not shown). As a result, the DC coil 402 generates a magnetic field that is linked to the field coil Fi that is folded back on the outer surface 211 </ b> B of the rotor core 210 by applying a direct current.

(Rectifier circuit)
Here, a diode (not shown) is provided as a rectifying element in the rotor 200, and the diode, the induction coil I, and the field coil F are connected so as to constitute a rectifying circuit. In this rectifier circuit, the alternating induction current generated in the induction coil I is rectified by the diode, and the rectified direct current is supplied to the field coil F as a field current. The field coil F generates a magnetic field when energized as a field current.

  In the present embodiment, a rectifier circuit such as a diode bridge (not shown) is connected between the field coil Ff and the field coil Fi. Therefore, the AC induced current generated in the field coil Fi due to the linkage of the magnetic flux generated in the field stator 400 is rectified by a rectifier circuit such as a diode bridge (not shown), and the rectified DC current is converted into the field current. Is supplied to the field coil Ff. Thereby, in addition to the induced current generated in the induction coil I, the induced current generated in the field coil Fi is supplied to the field coil Ff.

  For this reason, since the magnetic field generated in the rotor 200 is not reduced even in the low rotation range of the rotating electrical machine 1, the rotational torque generated on the torque generating surface between the stator 100 and the rotor 200 is reduced. There is no. The rotating electrical machine 1 according to the present embodiment can improve the torque density in the low rotation region as compared with the case where the field stator 400 is not provided.

  In the induction coil I and the field coil F wound in this way, the winding start and end of the windings Iw and Fw are arranged outside the induction coil I and the field coil F. For this reason, in the induction coil I and the field coil F, the winding start and the winding end of all the windings Iw and Fw can be arranged on the outer periphery of the rotor 200.

  Further, since the winding start and end of all the windings Iw and Fw of the induction coil I and the field coil F can be drawn out from the outer periphery side of the rotor 200 or from the outer periphery side to the other side in the axial direction, The connection can be performed on the same plane by using connection parts such as a connection board (not shown) arranged on the outer peripheral side or the other side in the axial direction.

  In addition, since the induction coil I and the field coil F are wound around the rotor teeth 230, the thermal conductivity of the induction coil I and the field coil F becomes uniform, and the heat dissipation of the rotor 200 is improved.

  In addition, the induction coil I and the field coil F are formed so that the short sides of the windings Iw and Fw made of rectangular wires are perpendicular to the magnetic flux generation direction. The generation of eddy currents can be reduced.

(Field energy)
The rotating electrical machine 1 includes twelve stator teeth 130 and eight rotor teeth 230. For this reason, the component ratio S / P between the number of slots S (12) of the stator 100 and the number of magnetic poles P (8) of the rotor 200 is 3/2.

  Further, in the rotating electrical machine 1 of the present embodiment, since the armature coil 140 formed in toroidal winding is concentratedly wound, the magnetic flux of the fundamental frequency is spatially a secondary space in a stationary coordinate system as a leakage flux. Harmonics are superimposed about 50%.

  Therefore, by setting the composition ratio S / P to 3/2, the third-order harmonics are interlinked with the rotor 200 in terms of time in the rotating coordinate system. The third time harmonic generated in the rotating coordinate system has an asynchronous frequency with respect to the rotational speed of the rotor 200.

  For this reason, the induction coil I is wound around the rotor teeth 230 that are salient poles of the rotor 200 to generate an induced current by interlinking the third time harmonics in the induction coil I, and the induced current is rectified. By using the current as the field current, a field can be generated in the field coil F, and the rotor 200 can function as an electromagnet.

  Here, the high-order time harmonic magnetic flux such as the fourth order or the fifth order in the rotating coordinate system is only a waveform that vibrates only in the vicinity of the surface of the rotor core 210, so that an induction current is efficiently generated in the induction coil I. I can't. On the other hand, low-order spatial harmonics such as third-order time harmonics can be linked to the inside of the rotor core 210 because of the relatively low frequency magnetic flux.

  In the present embodiment, of the spatial harmonic components superimposed on the magnetic flux of the fundamental frequency, the third time harmonic is targeted for recovery, and this third time harmonic is the fundamental frequency input to the armature coil 140 or The frequency is higher than the second-order time harmonic and pulsates in a short period.

  For this reason, the loss energy of the spatial harmonic component can be efficiently recovered, the time change of the magnetic flux linked to the induction coil I can be increased, the induced current can be increased, and a large rotational torque can be obtained. .

  The effect of the rotary electric machine 1 of this embodiment demonstrated as mentioned above is demonstrated. In the rotating electrical machine 1 of the present embodiment, the stator 100 includes a toroidal winding between an annular stator core 110 having stator teeth 130 arranged at a predetermined interval in the circumferential direction and an adjacent stator tooth 130 of the annular stator core 110. Armature coil 140.

  The rotor 200 includes first and second rotor teeth 231 and 232 that face the stator teeth 130 on both axial sides of the stator core 110, and a first face that faces the stator teeth 130 on the radially inner side of the stator core 110. And a rotor core 210 having three rotor teeth 233.

  Further, the rotor 200 is wound around the rotor teeth 230, and is wound around the induction coil I that induces an induced current by the linkage of magnetic flux generated on the stator 100 side, and the rotor teeth 230, and is energized by the energization of the induced current. A field coil F for generating a magnetic field.

  According to the present embodiment, an induction current can be generated in the induction coil I by linkage of magnetic flux generated on the stator 100 side, and a field current is applied to the field coil F using a DC current obtained by rectifying the induction current as a field current. Therefore, the rotor 200 can function as an electromagnet, and the rotational torque of the rotor 200 can be obtained.

  For this reason, since the rotational torque of the rotor 200 can be obtained without using a permanent magnet, the use of a rare earth magnet as the permanent magnet can prevent the material cost from increasing or the resource supply from becoming unstable. Thereby, the rotary electric machine 1 excellent in terms of cost and resource supply can be provided.

  Further, according to the present embodiment, the magnetic flux generated on the stator 100 side is linked to the rotor teeth 230 on the three surfaces of the first rotor teeth 231, the second rotor teeth 232, and the third rotor teeth 233, so that torque is generated. The surface can be increased and the torque density can be improved.

  Furthermore, according to the present embodiment, among the spatial harmonic components superimposed on the magnetic flux of the fundamental frequency, the third-order harmonics are targeted for recovery, so that the harmonics generated in the stator 100 are effective for the rotor teeth 230. Thus, more field energy can be obtained.

  In the rotating electrical machine 1 of the present embodiment, the induction coil I and the field coil F are wound around the same rotor tooth 230, and the induction coil I is a field coil F in the rotor tooth 230. Rather than the stator 100 side.

  According to the present embodiment, since the induction coil I is disposed closer to the stator 100 than the field coil F, more harmonics are linked to the induction coil I and a large current is generated in the induction coil I. be able to. In addition, the induction coil I and the field coil F are wound around in the same rotor teeth 230, so that the induction coil I and the field coil F can be brought into close contact with each other. The space factor of F can be improved.

  In the rotating electrical machine 1 of the present embodiment, the rotor core 210 is divided into a first rotor core 210A on one axial side and a second rotor core 210B on the other axial side.

  According to the present embodiment, the rotating electrical machine 1 can be assembled by fastening the first rotor core 210A and the second rotor core 210B so as to sandwich the stator core 110 in the axial direction. Therefore, the stator 100 can be easily assembled to the rotor 200, and the rotating electrical machine 1 can be easily assembled.

  Further, in the rotating electrical machine 1 of the present embodiment, the rotor core 210 is formed in a bobbin shape in which the disk portions 211 and 212 are respectively integrated at both ends of the cylindrical portion 213 in the axial direction. Thereby, the rotor core 210 has the disk part 211 and the disk part 212 integrated with each other via the cylindrical part 213. For this reason, concentricity between the shaft 20 and the rotor core 210 inserted into the insertion hole 213A of the cylindrical portion 213 is ensured.

  In the rotating electrical machine 1 according to the present embodiment, the rotor core 210 has a pair of outer surfaces 211B and 212B on the opposite side of the surface facing the stator core 110 in the axial direction of the stator core 110.

  The field coil F is folded back to the outer surface 211B side of the rotor core 210. Further, a field rotor tooth 241 around which a field coil Fi folded back to the outer surface 211B is wound is provided on the outer surface 211B of the rotor core 210.

  Furthermore, a magnetic field interlinking with the field coil Fi is generated on one side in the axial direction of the rotating electrical machine 1 of the present embodiment so as to face the field coil Fi folded back on the outer surface 211B side of the rotor core 210. A field stator 400 is disposed.

  According to the present embodiment, an induced current can be induced in the field coil Fi by the field stator 400. For this reason, in addition to the induced current generated in the induction coil I, the induced current induced in the field coil Fi can be supplied to the field coil Ff. Thereby, the field current of the field coil F can be increased.

  Therefore, the rotating electrical machine 1 according to the present embodiment can increase the magnetomotive force of the rotor 200 as compared with the rotating electric machine 1 that does not include the field stator 400 even in the low rotation range. Thereby, even if the rotary electric machine 1 of this embodiment exists in a low rotation area, the rotational torque which generate | occur | produces on the torque generation surface between the stator 100 and the rotor 200 does not reduce. As a result, the rotating electrical machine 1 according to the present embodiment can improve the torque density in the low rotation region as compared with the case where the field stator 400 is not provided.

(Modification)
In this embodiment, an example in which a magnetic field is generated by the DC coil 402 as the field stator 400 has been described. However, the present invention is not limited to this, and the field stator 400 employs a structure that generates a magnetic field by a permanent magnet. Also good.

  The divided yoke 121 of the present embodiment and the divided yoke 321 of the above-described modification may be formed by a dust core in which fine powder of a ferromagnetic material is compressed and hardened. Since the powder magnetic core is formed by compressing and compacting a fine powder, it is necessary to use a large press as the size of the molded member increases, and the molding becomes difficult. On the other hand, the divided yoke 121 of the present embodiment and the divided yoke 321 of the above-described modification are smaller in size than the stator yoke having no divided structure. For this reason, the split yoke 121 and the split yoke 321 can be easily formed by the dust core without using a large press. Thereby, the productivity of the stator yoke can be improved.

  The windings of the armature coil 140, the induction coil I, and the field coil F are not limited to copper wires, and for example, aluminum conductors or high-frequency current twisted litz wires may be employed.

  Further, the rotating electrical machine 1 may be configured in a hybrid field type (hybrid type) in which a permanent magnet is disposed in the rotor 200 in addition to the field coil F. In this case, the permanent magnet and the field functioning as an electromagnet. Torque can be generated by effectively cooperating with the coil F. For this reason, the usage-amount of the rare earth magnet which raises a cost can be suppressed, and an equivalent output can be obtained, without enlarging.

  Further, the rectifying element is not limited to the diode, and other semiconductor elements such as switching elements may be employed. The rectifying element is not limited to the type housed in the diode case, and may be mounted inside the rotor 200.

  Moreover, the rotary electric machine 1 is not limited to vehicle-mounted use, For example, it can employ | adopt suitably as a generator for wind power generation, or an electric motor for machine tools.

  While embodiments of the invention have been disclosed, it will be apparent to those skilled in the art that changes may be made without departing from the scope of the invention. All such modifications and equivalents are intended to be included in the following claims.

DESCRIPTION OF SYMBOLS 1 Rotating electrical machine 100, 300 Stator 110, 310 Stator core 120, 320 Stator yoke 130, 330 Stator teeth 131, 331 1st stator teeth 132, 332 2nd stator teeth 133, 333 3rd stator teeth 140 Armature coil (coil)
200 rotor 210 rotor core 210A first rotor core 210B second rotor core 211B, 212B outer surface 230 rotor teeth 231 first rotor teeth (rotor teeth facing the stator teeth on both axial sides of the stator core)
232 Second rotor teeth (rotor teeth facing the stator teeth on both axial sides of the stator core)
233 Third rotor teeth (rotor teeth facing the stator teeth on the radially inner surface side of the stator core)
241 Field rotor teeth 400 Field stator 402 DC coil F Field coil I Inductive coil

Claims (4)

A rotating electrical machine comprising a stator that generates magnetic flux by energizing a coil, and a rotor that rotates by passage of the magnetic flux,
The stator is
An annular stator core having a plurality of stator teeth arranged at predetermined intervals in the circumferential direction;
An armature coil that is toroidally wound between adjacent stator teeth of the annular stator core;
The rotor is
A rotor core having a rotor tooth facing the stator teeth on both axial sides of the stator core and a rotor tooth facing the stator teeth on the radial inner surface side of the stator core;
An induction coil wound around the rotor teeth and inducing an induced current by linkage of magnetic flux generated on the stator side;
A field coil wound around the rotor teeth and generating a magnetic field by energization of the induced current;
The rotor core has a pair of outer surfaces on the side opposite to the surface facing the stator core in the axial direction;
The field coil is folded to one of the pair of outer surfaces on the outer surface side,
A field rotor tooth around which a field coil folded back to the outer surface side is wound is provided on one of the pair of outer surfaces,
A rotating electric machine comprising: a field stator that generates a magnetic field interlinking with the field coil so as to face the field coil folded back to the outer surface side.   2. The rotating electrical machine according to claim 1, wherein the field stator includes a coil that generates a magnetic field linked to the field coil folded back to the outer surface side by applying a direct current. 3. The induction coil and the field coil are wound around the same rotor teeth in layers,
The rotating electrical machine according to claim 1, wherein the induction coil is disposed closer to the stator than the field coil. 4. The rotor core according to claim 1, wherein the rotor core is divided into a first rotor core on one side in the axial direction of the rotor core and a second rotor core on the other side in the axial direction of the rotor core. The rotating electrical machine according to claim 1.