JP2010017030A - Rotor for rotating electric machine and electric motor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To block an eddy current generated between a connecting member and a magnetic member when a rotor of a rotating electrical machine is constituted by connecting a plurality of connecting members and a plurality of magnetic members in a circumferential direction.
A center ring 31 and a rotor flange arranged on a rotating shaft are connected by a plurality of connecting members 33 arranged at predetermined intervals in the circumferential direction, and an induction magnetic pole 38L is connected between two adjacent connecting members 33. , 38R is supported, and the surface where the connecting member 33 and the induction magnetic poles 38L, 38R come into contact with each other is insulated with an insulating coating. Thus, loss can be reduced. In particular, since the induction magnetic poles 38L and 38R are formed by laminating thin sheets of soft magnetic materials whose surfaces in contact with each other are insulated in the axial direction, eddy currents are circumferentially transferred from the induction magnetic poles 38L and 38R to the connecting member 33. The eddy current loop generated between the connecting member 33 and the induction magnetic poles 38L and 38R can be blocked by the insulating portion.
[Selection] FIG.

Description

  According to the present invention, a plurality of fixing members arranged on the rotating shaft and spaced apart in the axial direction and rotating integrally with the rotating shaft and two adjacent fixing members arranged at predetermined intervals in the circumferential direction are connected. The present invention relates to a rotor for a rotating electrical machine including a plurality of connecting members and a magnetic member supported between two connecting members adjacent in the circumferential direction, and an electric motor including the rotor for the rotating electrical machine.

  The rotor of the electric motor is composed of a cylindrical rotor body 31 and a pair of disk-like rotor covers 33, 33 coupled to both ends in the axial direction thereof. Japanese Patent Application No. 2007- 333899. The cylindrical rotor body 31 includes a plurality of first slits 31a extending from one end portion to an intermediate portion along the axial direction, and a plurality of second slits 31b extending from the other end portion to the intermediate portion along the axial direction. ..., and the first and second induction magnetic poles 38a ..., 38b ... are supported by the first and second slits 31a, 31b, respectively.

  By the way, the rotor of the above-described conventional electric motor is configured by laminating thin sheets of soft magnetic material in which the first and second induction magnetic poles 38a, ..., 38b ... are insulatively coated on the surfaces in contact with each other in the axial direction. Although the eddy current does not flow in the axial direction through the first and second induction magnetic poles 38a ..., 38b ..., the surface in contact with the rotor body 31 is not insulated, so the first and second induction magnetic poles 38a ..., 38b. ... and a closed loop of eddy current is formed between the rotor bodies 31 and there is a problem that loss occurs.

  The present invention has been made in view of the above circumstances, and occurs between a connecting member and a magnetic member when a rotor of a rotating electrical machine is configured by connecting a plurality of connecting members and a plurality of magnetic members in a circumferential direction. The purpose is to cut off eddy currents.

  In order to achieve the above object, according to the invention described in claim 1, a plurality of fixing members which are arranged on the rotating shaft so as to be spaced apart in the axial direction and rotate integrally with the rotating shaft, and a circumferential direction A plurality of connecting members that connect two adjacent fixing members that are arranged at a predetermined interval to each other, and a magnetic member that is supported between two connecting members that are adjacent in the circumferential direction. A rotor for a rotating electrical machine is proposed in which the surface with which the member contacts is insulated.

  According to the second aspect of the present invention, in addition to the structure of the first aspect, the magnetic member is formed by laminating thin sheets of soft magnetic materials whose surfaces in contact with each other are insulated in the axial direction. A rotor for a rotating electrical machine is proposed.

  According to the invention described in claim 3, in addition to the structure of claim 1 or claim 2, the connecting member is made of a non-conductive material or contacts the magnetic member of the connecting member. A rotor for a rotating electrical machine is proposed in which the surface to be insulated is coated.

  According to the invention described in claim 4, in addition to the configuration of any one of claims 1 to 3, the connecting member includes a lightening portion. Proposed.

  According to the invention described in claim 5, in addition to the configuration of any one of claims 1 to 4, a rod-like fastening member is disposed between the two fixing members and the two fixing members. A rotor for a rotating electrical machine is proposed in which the connecting member is penetrated and fixed.

  According to a sixth aspect of the present invention, in addition to the configuration of the fifth aspect, a rotor for a rotating electrical machine is proposed in which a surface that contacts the connecting member and the rod-like fastening member is insulated. The

  According to the invention described in claim 7, it is an electric motor comprising the rotor for a rotating electrical machine according to any one of claims 1 to 6, wherein the magnetic member is made of a soft magnetic material, An electric motor comprising a stator that generates a rotating magnetic field and a second rotor in which a plurality of permanent magnets are arranged in a circumferential direction is proposed on one and the other of the rotor radially inner side and radially outer side. The

  The outer rotor 13 of the embodiment corresponds to the rotor of the present invention, the inner rotor 14 of the embodiment corresponds to the second rotor of the present invention, and the center ring 31 and the first and second rotors of the embodiment. The flanges 32L and 32R correspond to the fixing member of the present invention, the first and second outer rotor shafts 34 and 36 of the embodiment correspond to the rotating shaft of the present invention, and the first and second induction magnetic poles of the embodiment. 38L and 38R correspond to the magnetic member of the present invention, and the bolt 39 of the embodiment corresponds to the rod-shaped fastening member of the present invention.

  According to the configuration of claim 1, two adjacent fixing members that are spaced apart in the axial direction on the rotation axis are connected by a plurality of connecting members that are arranged at predetermined intervals in the circumferential direction, and two adjacent members are connected. Since the magnetic member is supported between the connecting members and the surface where the connecting member and the magnetic member come in contact with each other, the eddy current loop generated between the connecting member and the magnetic member is cut off at the insulating portion to reduce the loss. Can do.

  According to the second aspect of the present invention, since the magnetic member is configured by laminating the soft magnetic thin plates whose surfaces that are in contact with each other are insulated in the axial direction, the eddy current may flow in the axial direction of the magnetic member. However, the eddy current loop generated between the connecting member and the magnetic member can be blocked by the insulating portion.

  According to the third aspect of the present invention, the connecting member is made of a non-conductive material, or the surface of the connecting member that contacts the magnetic member is insulatively coated so that the surface of the connecting member and the magnetic member that are in contact with each other can be reliably obtained. Can be insulated.

  According to the fourth aspect of the present invention, since the connecting member is provided with the thinned portion, the volume of the connecting member is reduced by the amount corresponding to the meat facing portion, thereby reducing the amount of eddy current generated and reducing the loss due to the eddy current. can do.

  According to the fifth aspect of the present invention, since the rod-like fastening member penetrates the two fixing members and the connecting member and fixes them, the fixing member and the connecting member can be firmly integrated.

  According to the sixth aspect of the present invention, since the surface where the connecting member and the rod-like fastening member come into contact is insulated, the eddy current loop flowing through the rod-like fastening member can be interrupted to reduce the loss.

  According to the configuration of claim 7, the magnetic member is made of a soft magnetic material, and a stator that generates a rotating magnetic field is provided on one and the other of the rotor radially inner side and the radially outer side, and a plurality of permanent magnets in the circumferential direction. Since the second rotor is disposed, either the rotor or the second rotor, or both the rotor and the second rotor can be rotated by energizing the stator.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

  FIGS. 1 to 21 show a first embodiment of the present invention. FIG. 1 is a front view of the electric motor viewed in the axial direction (sectional view taken along line 1-1 in FIG. 2), and FIG. FIG. 3 is a sectional view taken along line 3-3 in FIG. 2, FIG. 4 is a sectional view taken along line 4-4 in FIG. 2, FIG. 5 is an exploded perspective view of the electric motor, and FIG. 7 is an enlarged view of part 7 of FIG. 2, FIG. 8 is a sectional view taken along line 8-8 in FIG. 7, FIG. 9 is a sectional view taken along line 9-9 in FIG. 11 is a cross-sectional view taken along line 11-11 in FIG. 7, FIG. 12 is a partially exploded perspective view of the outer rotor, FIG. 13 is an enlarged view of 13 parts in FIG. 8, and FIG. 15 is a schematic diagram in which the electric motor is developed in the circumferential direction, FIG. 16 is an operation explanatory diagram when the inner rotor is fixed (part 1), and FIG. 17 is an operation explanatory diagram when the inner rotor is fixed (part 1). 2), FIG. 18 is an operation explanatory diagram when the inner rotor is fixed (part 3), FIG. 19 is an operation explanatory diagram when the outer rotor is fixed (part 1), and FIG. 20 is an example when the outer rotor is fixed FIG. 21 is a diagram showing an eddy current generated in the outer rotor.

  As shown in FIG. 5, the electric motor M of the present embodiment includes a casing 11 having a short octagonal cylindrical shape in the direction of the axis L, an annular stator 12 fixed to the inner periphery of the casing 11, and the interior of the stator 12. And the cylindrical outer rotor 13 that rotates about the axis L and the cylindrical inner rotor 14 that is stored inside the outer rotor 13 and rotates about the axis L. The outer rotor 13 The inner rotor 14 can rotate relative to the fixed stator 12, and the outer rotor 13 and the inner rotor 14 can rotate relative to each other.

  As is apparent from FIGS. 1 and 2, the casing 11 includes a bottomed octagonal cylindrical main body portion 15 and an octagonal plate-like lid portion 17 fixed to the opening of the main body portion 15 with a plurality of bolts 16. The main body 15 and the lid 17 are formed with a plurality of openings 15a,.

  As is apparent from FIGS. 1 to 5, the stator 12 includes a stator core 18 in which electromagnetic steel plates are laminated. A plurality (96 in the embodiment) of teeth 18 a. 96 slots in the embodiment) are alternately formed in the circumferential direction. The U-phase, V-phase, and W-phase coils 19 are distributedly wound around the slots 18b of the stator core 18, and the transition portions are exposed in a ring shape on both side surfaces in the axis L direction of the stator core 18. The stator 12 is fixed to the inner surface of the main body 15 of the casing 11 with a plurality of bolts 20 penetrating the stator core 18 in the axis L direction. The stator 12 is rotated by supplying a three-phase alternating current to the U-phase, V-phase, and W-phase coils 19 from the three terminals 23, 24, and 25 (see FIG. 1) provided on the main body portion 15 of the casing 11. A magnetic field can be generated.

  As clearly shown in FIG. 2, the stator core 18 made of the electromagnetic steel plate of the stator 12 includes a first stator core 18L and a second stator core 18R that are divided into two in the direction of the axis L, and the first and second stator cores 18L. , 18R, a spacer 22 made of a non-conductive member is sandwiched. The shapes of the first stator core 18L, the second stator core 18R, and the spacer 22 as viewed in the direction of the axis L are the same, and therefore, their manufacture becomes easy.

  Since the common coil 19 is wound around the first and second stator cores 18L and 18R of the stator 12 and the spacer 22, rotating magnetic fields having the same phase are generated in the first and second stator cores 18L and 18R.

  As apparent from FIGS. 2 and 5, the outer rotor 13 includes a center ring 31 formed of a weak magnetic material in an annular shape and a disk shape formed of a weak magnetic material on both sides of the center ring 31 in the axis L direction. The first and second rotor flanges 32L and 32R to be arranged, and a columnar shape made of a weak magnetic material and arranged at a predetermined interval in the circumferential direction. The center ring 31 and the first and second rotor flanges 32L and 32R are connected to each other. It is a cylindrical member provided with a plurality of connecting members 33 (each of which is 18 on the left and right sides in the embodiment). The connecting members 33 are bolts 39 and nuts 40 and are centered 31 and first and first. 2 Fixed to the rotor flanges 32L, 32R. A first outer rotor shaft 34 projecting from the center of the first rotor flange 32L to one side in the axis L direction is rotatably supported by the main body 15 of the casing 11 by a ball bearing 35, and the center of the second rotor flange 32R. A second outer rotor shaft 36 that protrudes to the other side in the axis L direction is supported by a ball bearing 37 on the lid portion 17 of the casing 11 so as to be freely rotatable.

  The weak magnetic material is a material that is not attracted to the magnet and includes, for example, resin, wood, etc. in addition to aluminum and the like, and is sometimes called a non-magnetic material.

  The first induction magnetic poles 38L made of a soft magnetic material are supported in spaces surrounded by the center ring 31, the first rotor flange 32L, and the connection members 33, respectively, and the center ring 31, the second rotor flange 32R, and the connection. The second induction magnetic poles 38R made of soft magnetic material are supported in the spaces surrounded by the members 33. The first and second induction magnetic poles 38L,..., 38R,... Are configured by laminating a plurality of thin sheets of soft magnetic material, whose surfaces that contact each other in order to reduce iron loss, are laminated in the axis L direction. The number is 16 on the left and right in the present embodiment.

  The soft magnetic material is a kind of magnetic material, which generates a magnetic pole when a magnetic force is applied, and disappears when the magnetic force is removed.

  As can be seen from FIG. 12, the center ring 31 made of a weak magnetic material protrudes alternately on both sides in the direction of the axis L, and on the radially inner side of the protrusions 31a. Are formed on the side opposite to the projecting direction of the bolt head fitting recesses 31b, and bolt holes 31c penetrating through the center of the bolt head fitting recesses 31b.

  The connecting member 33 made of a weak magnetic material has an outer peripheral surface 33a made of an arc surface having a large radius of curvature, a pair of convex portions 33b and 33b made of an arc surface having a small radius of curvature, and an intermediate portion in the circumferential direction in the radial direction. An inner peripheral surface 33c that bulges inward, and a bolt hole 33d penetrates the center in the direction of the axis L. On the inner peripheral surface of the connecting member 33, only the portion provided with the bolt hole 33d bulges inward in the radial direction and is thick in the radial direction, and the other portion is thin in the radial direction.

  The head 39a of the bolt 39 made of a weak magnetic material is formed in a substantially square shape that fits in the bolt head fitting recess 31b without any gap. The cross sections of the first and second induction magnetic poles 38L and 38R are an outer peripheral surface 38a made of an arc surface having a large curvature radius, a pair of flat side surfaces 38b and 38b, and an inner peripheral surface 38c made of an arc surface having a large curvature radius. And concave portions 38d and 38d made of circular arc surfaces having small radii of curvature formed on the pair of side surfaces 38b and 38b, respectively.

  As apparent from FIGS. 7 to 12, the bolts 39 inserted into the bolt holes 31 c from one end side of the center ring 31 have their heads 39 a formed in the bolt head fitting recesses 31 b of the center ring 31. The bolts 39 that are fitted and prevented from rotating and that protrude to the other end side of the center ring 31 are bolt holes formed in the bolt holes 33d of the connecting member 33 and the first rotor flange 32L or the second rotor flange 32R. 32a ... and is fastened by nuts 40 .... At this time, one end side of the outer peripheral surface 33a of the connecting member 33 is in close contact with the inner peripheral surface of the protrusion 31a of the center ring 31 (see FIG. 7), and the other end side of the outer peripheral surface 33a of the connecting member 33 is By closely contacting the inner peripheral surface of the protrusion 32b of the first rotor flange 32L or the second rotor flange 32R (see FIG. 7), the connecting member 33 is connected to the center ring 31 and the first and second rotor flanges 32L and 32R. Is accurately positioned.

  The protrusions 33b and 33b of the respective connecting members 33 are fitted into the recesses 38d and 38d of the side surfaces 38b and 38b of the first induction magnetic pole 38L or the second induction magnetic pole 38R adjacent in the circumferential direction, so that the first and first 2 The soft magnetic bodies 38L and 38R are held between the pair of connecting members 33 and 33.

  As is apparent from FIGS. 7 and 11, circular spring support holes 32c are formed on the inner surfaces of the first and second rotor flanges 32L and 32R, and circlip-like shapes are formed in the spring support holes 32c. The leaf spring-shaped pressing portions 41b of the resilient members 41 supported by the locking portions 41a press one end of the first and second induction magnetic poles 38L, 38R in the direction of the axis L, and the other end. The part is pressed against the center ring 31. Since the locking member 41a is stably held in the spring support hole 32c, the elastic member 41 prevents the elastic member 41 from dropping at the time of assembly and improves the assemblability.

  As shown in FIG. 13, the surface of the connecting member 33 is provided with an insulating coating 33e. By this insulating coating 33e, the convex portions 33b and 33b of the connecting member 33 are formed on the first and second induction magnetic poles 38L and 38R. The electrical continuity of the contact portion that fits into the recesses 38d, 38d is interrupted. As a result, the small loop eddy current generated between the connecting member 33 and the first and second induction magnetic poles 38L, 38R can be cut off to reduce the loss (see arrow A in FIG. 21).

  In particular, since the first and second induction magnetic poles 38L and 38R are formed by laminating thin plates of soft magnetic materials whose surfaces in contact with each other are insulated in the direction of the axis L, the eddy current is generated in the first and second induction magnetic poles 38L. , 38R cannot flow in the direction of the axis L, and tends to flow in the circumferential direction between the connecting member 33 and is generated between the connecting member 33 and the first and second induction magnetic poles 38L, 38R. The eddy current loop can be interrupted by the insulating coating 33e.

  In addition to the connecting member 33, the bolt 39 is also provided with an insulating coating 39b for interrupting eddy currents. By this insulating coating 39b, the connecting member 33 and the bolt 39 and the center ring 31 or the connecting member 33 and The conduction between the bolt 39 and the first and second rotor flanges 32L, 32R can be cut off, and loss due to eddy current can be reduced (see arrow B in FIG. 21).

  As shown in FIG. 7, at least a portion of the center ring 31 that contacts the connecting member 33 is provided with an insulating coating 31d, and the insulating coating 31d can block the eddy current loop to reduce the loss ( (See arrow C in FIG. 21). In addition, an insulating coating 32d is applied to at least a portion of the first and second rotor flanges 32L and 32R that contacts the connecting member 33, and the eddy current loop can be blocked by the insulating coating 32d to reduce the loss. (See arrow D in FIG. 21).

  In FIG. 14, the solid line indicates the shape of the concave portions 38 d and 38 d of the side surfaces 38 b and 38 b of the first and second induction magnetic poles 38 </ b> L and 38 </ b> R, and the chain line indicates the shape of the convex portions 33 b and 33 b of the connecting member 33. The concave portion 38d and the convex portion 33b are both arc-shaped, but the tightening margin γ is set by making the shapes of the two slightly different. The tightening margin γ is set in a direction in which the concave portions 38d of the first and second induction magnetic poles 38L and 38R are expanded radially inward and outward by fitting the convex portions 33b of the connecting member 33. And in the fitting state of the convex part 33b of the connecting member 33 and the concave part 38d of the first and second induction magnetic poles 38L and 38R, a gap δ is secured between the top part of the convex part 33b and the bottom part of the concave part 38d.

  As apparent from FIGS. 2 to 7, the inner rotor 14 includes a rotor body 45 formed in a cylindrical shape, an inner rotor shaft 47 splined 46 to a hub 45 a of the rotor body 45, and laminated electromagnetic steel plates. An annular first and second rotor cores 48L and 48R that are configured to be fitted to the outer periphery of the rotor body 45, and an annular spacer 49 that is configured of a weak magnetic material and is fitted to the outer periphery of the rotor body 45. Prepare. One end of the inner rotor shaft 47 is rotatably supported by the ball bearing 50 inside the first outer rotor shaft 34 on the axis L, and the other end of the inner rotor shaft 47 is placed inside the second outer rotor shaft 36 by a ball bearing. 51 is rotatably supported.

  The first and second rotor cores 48L and 48R press-fitted into the outer periphery of the rotor body 45 have the same structure, and a plurality (16 in the embodiment) of permanent magnet support holes 48a. 3 and FIG. 4), and first and second permanent magnets 52L,..., 52R are inserted in the direction of the axis L and fixed by adhesion. The polarities of the adjacent first permanent magnets 52L of the first rotor core 48L are alternately reversed, the polarities of the adjacent second permanent magnets 52R of the second rotor core 48R are alternately reversed, and the first rotor core The circumferential direction phase and polarity of the 48L first permanent magnets 52L ... and the circumferential direction phase and polarity of the second permanent magnets 52R ... of the second rotor core 48R are mutually offset so as to be shifted by 180 ° in electrical angle. They match (see FIGS. 3 and 4).

  A spacer 49 formed of a weak magnetic material in an annular shape is fitted in the center of the outer periphery of the rotor body 45 in the axis L direction, that is, between the first and second rotor cores 48L and 48R. A pair of permanent magnet support plates 53, 53 that prevent the first and second permanent magnets 52 </ b> L, 52 </ b> R from coming off are fitted on both sides in the direction of the axis L, respectively, and one permanent magnet support plate 53 is the axis of the rotor body 45. The other permanent magnet support plate 53 is supported by a stopper ring 54 that is press-fitted into the outer periphery on the other end side in the axis L direction of the rotor body 45.

  8, the inner circumference of the teeth 18a of the stator core 18 is formed on the outer circumference of the first induction magnetic poles 38L exposed on the outer circumference of the outer rotor 13 through a slight air gap α. The outer peripheral surface of the first rotor core 48L of the inner rotor 14 is opposed to the inner peripheral surface of the first induction magnetic poles 38L ... exposed on the inner peripheral surface of the outer rotor 13 through a slight air gap β. Similarly, as shown in an enlarged view in FIG. 9, the inner circumference of the teeth 18a of the stator core 18 is formed on the outer circumference of the second induction magnetic poles 38R exposed on the outer circumference of the outer rotor 13 through a slight air gap α. The outer peripheral surface of the second rotor core 48R of the inner rotor 14 is opposed to the inner peripheral surface of the second induction magnetic poles 38R ... exposed on the inner peripheral surface of the outer rotor 13 through a slight air gap β.

  The thickness in the axis L direction of the spacer 22 of the stator 12, the thickness in the axis L direction excluding the protrusions 31 a of the center ring 31 of the outer rotor 13, and the thickness in the axis L direction of the spacer 49 of the inner rotor 14 are set substantially equal. (See FIG. 7).

  As is apparent from FIG. 7, the radial positions of the outer peripheral surfaces 38a of the first and second induction magnetic poles 38L and 38R are the radial positions of the outer peripheral surfaces of the center ring 31 and the first and second rotor flanges 32L and 32R. Accordingly, the air gap α between the first and second induction magnetic poles 38L and 38R and the inner peripheral surface of the stator core 18 can be set small. The radial positions of the outer peripheral surfaces 38a of the first and second induction magnetic poles 38L and 38R protrude radially outward from the radial positions of the outer peripheral surfaces of the center ring 31 and the first and second rotor flanges 32L and 32R. You may let them.

  Next, the operation principle of the electric motor M according to the first embodiment having the above configuration will be described.

  FIG. 15 schematically shows a state where the electric motor M is developed in the circumferential direction. 15 are shown first and second permanent magnets 52L, 52R,... Of the inner rotor 14, respectively. The first and second permanent magnets 52L, 52R,... Are alternately arranged with N and S poles at a predetermined pitch P in the circumferential direction (vertical direction in FIG. 15), and in the axis L direction (left and right in FIG. 15). Are arranged so that the polarities of the first permanent magnets 52L facing each other and the polarities of the second permanent magnets 52R facing each other are reversed.

  15, virtual permanent magnets 21 corresponding to the teeth 18a of the first and second stator cores 18L and 18R of the stator 12 are arranged at a predetermined pitch P in the circumferential direction. Actually, the number of teeth 18a ... of the first and second stator cores 18L, 18R is 96 each, and the number of first, second permanent magnets 52L ..., 52R ... of the inner rotor 14 is 16 each. Therefore, the pitch of the teeth 18a does not coincide with the pitch P of the first and second permanent magnets 52L, 52R,.

  However, since the teeth 18a of the first and second stator cores 18L and 18R each form a rotating magnetic field, the first and second stator cores 18L and 18R are arranged at a pitch P and rotated in the circumferential direction. These virtual permanent magnets 21 can be replaced. Hereinafter, the first and second stator cores 18L and 18R will be referred to as first and second virtual magnetic poles 18L and 18R of the virtual permanent magnets 21 and so on. The polarities of the first and second virtual magnetic poles 18L of the virtual permanent magnets 21 adjacent to each other in the circumferential direction are alternately reversed, and the first virtual magnetic poles 18L of the virtual permanent magnets 21 ... The two virtual magnetic poles 18R have the same polarity and are aligned in the axis L direction. The reason is that the first and second stator cores 18L and 18R are substantially a single stator core 18.

  The first and second induction magnetic poles 38L, 38R,... Of the outer rotor 13 are arranged between the first and second permanent magnets 52L, 52R,. The first and second induction magnetic poles 38L, 38R,... Are arranged at a pitch P in the circumferential direction, and the first induction magnetic poles 38L, ... and the second induction magnetic poles 38R, ... are displaced by half the pitch P in the circumferential direction. (See FIG. 5).

  As shown in FIG. 15, when the polarity of the first virtual magnetic pole 18 </ b> L of the virtual permanent magnet 21 is different from the polarity of the first permanent magnet 52 </ b> L facing (closest) to the first virtual magnetic pole 18 </ b> L, The polarity is the same as the polarity of the second permanent magnet 52R facing (closest) to it. When the polarity of the second virtual magnetic pole 18R of the virtual permanent magnet 21 is different from the polarity of the second permanent magnet 52R facing (closest) to it, the polarity of the first virtual magnetic pole 18L of the virtual permanent magnet 21 faces it. It becomes the same as the polarity of the (closest) first permanent magnet 52L (see FIG. 17G).

  First, the first and second stator cores 18L and 18R (first and second virtual magnetic poles 18L... 18R...) With the inner rotor 14 (first and second permanent magnets 52L,. ) To generate a rotating magnetic field, the operation when the outer rotor 13 (first and second induction magnetic poles 38L..., 38R...) Is rotationally driven will be described. In this case, it is fixed in the order of FIG. 16 (A) → FIG. 16 (B) → FIG. 16 (C) → FIG. 16 (D) → FIG. 17 (E) → FIG. 17 (F) → FIG. The virtual permanent magnets 21 ... rotate downward in the figure relative to the first and second permanent magnets 52L ... 52R ..., whereby the first and second induction magnetic poles 38L ... 38R ... rotate downward in the figure. .

  As shown in FIG. 16 (A), the first induction magnetic poles 38L are aligned and opposed to the first virtual poles 18L of the first permanent magnets 52L,. The virtual permanent magnets 21 are rotated downward in the figure from the state where the second induction magnetic poles 38R are shifted by a half pitch P / 2 with respect to the two virtual magnetic poles 18R and the second permanent magnets 52R. At the start of the rotation, the polarities of the first virtual magnetic poles 18L of the virtual permanent magnets 21 ... are different from the polarities of the first permanent magnets 52L ... opposed thereto, and the second virtual magnetic poles 18R of the virtual permanent magnets 21 ... The polarity of... Is the same as the polarity of the second permanent magnet 52R.

  Since the first induction magnetic poles 38L are disposed between the first permanent magnets 52L ... and the first virtual magnetic poles 18L of the virtual permanent magnets 21 ..., the first induction magnetic poles 38L ... are first permanent magnets 52L ... and first. Magnetized by the virtual magnetic poles 18L, and first magnetic lines of force G1 are generated between the first permanent magnets 52L, the first induction magnetic poles 38L, and the first virtual magnetic poles 18L. Similarly, since the second induction magnetic poles 38R are disposed between the second virtual magnetic poles 18R and the second permanent magnets 52R, the second induction magnetic poles 38R are the second virtual magnetic poles 18R and the second permanent magnets 52R. Are magnetized, and second magnetic lines of force G2 are generated between the second virtual magnetic poles 18R, second induction magnetic poles 38R, and second permanent magnets 52R.

  In the state shown in FIG. 16A, the first magnetic lines of force G1 are generated so as to connect the first permanent magnets 52L, the first induction magnetic poles 38L, and the first virtual magnetic poles 18L, and the second magnetic lines of force G2 are circular. Each of the two second virtual magnets 18R... Adjacent to each other in the circumferential direction and each of the two second permanent magnets 52R... Adjacent to each other in the circumferential direction so as to connect the second induction magnetic poles 38R. It is generated so as to connect the second induction magnetic poles 38R. As a result, a magnetic circuit as shown in FIG. In this state, since the first magnetic lines of force G1 are linear, no magnetic force that rotates in the circumferential direction acts on the first induction magnetic poles 38L. In addition, the bending degree and the total magnetic flux amount of the two second magnetic lines G2 between each of the two second virtual magnetic poles 18R... And the second induction magnetic poles 38R... Adjacent to each other in the circumferential direction are equal to each other. The bending degree and the total magnetic flux amount of the two second magnetic lines of force G2 between the two adjacent second permanent magnets 52R and the second induction magnetic poles 38R are also equal and balanced. Therefore, a magnetic force that rotates in the circumferential direction does not act on the second induction magnetic poles 38R.

  When the virtual permanent magnets 21 are rotated from the position shown in FIG. 16A to the position shown in FIG. 16B, the second virtual magnetic poles 18R, the second induction magnetic poles 38R, and the second permanent magnets 52R are moved. The second magnetic field lines G2 that are connected are generated, and the first magnetic field lines G1 between the first induction magnetic poles 38L and the first virtual magnetic poles 18L are bent. Accordingly, a magnetic circuit as shown in FIG. 18B is configured by the first and second magnetic lines of force G1, G2.

  In this state, although the degree of bending of the first magnetic lines of force G1 is small, the total magnetic flux amount is large, so that a relatively strong magnetic force acts on the first induction magnetic poles 38L. As a result, the first induction magnetic poles 38L are driven with a relatively large driving force in the rotation direction of the virtual permanent magnets 21, that is, the magnetic field rotation direction, and as a result, the outer rotor 13 rotates in the magnetic field rotation direction. Further, although the degree of bending of the second magnetic lines of force G2 is large, the total magnetic flux amount is small, so that a relatively weak magnetic force acts on the second induction magnetic poles 38R, so that the second induction magnetic poles 38R are relatively in the magnetic field rotation direction. Driven with a small driving force, the outer rotor 13 rotates in the direction of magnetic field rotation.

  Next, when the virtual permanent magnet 21 is sequentially rotated from the position shown in FIG. 16B to the positions shown in FIGS. 16C, 16D, 17E, and 17F, the first induction magnetic pole 38L. ... and the second induction magnetic poles 38R are driven in the direction of magnetic field rotation by the magnetic force caused by the first and second magnetic lines of force G1, G2, respectively. As a result, the outer rotor 13 rotates in the direction of magnetic field rotation. In the meantime, the magnetic force acting on the first induction magnetic poles 38L is gradually weakened by decreasing the total magnetic flux amount, although the bending degree of the first magnetic lines G1 is increased. The driving force for driving in the direction gradually decreases. Further, the magnetic force acting on the second induction magnetic poles 38R is gradually increased as the total magnetic flux amount is increased, although the degree of bending of the second magnetic lines G2 is reduced, and the second induction magnetic poles 38R are made to move in the magnetic field rotation direction. The driving force to drive gradually increases.

  And while the virtual permanent magnet 21 rotates from the position shown in FIG. 17 (E) to the position shown in FIG. 17 (F), the second magnetic lines of force G2 are bent and the total magnetic flux amount is close to the maximum. As a result, the strongest magnetic force acts on the second induction magnetic poles 38R, and the driving force acting on the second induction magnetic poles 38R is maximized. Thereafter, as shown in FIG. 17 (G), the virtual permanent magnet 21 is rotated by the pitch P from the initial position of FIG. 16 (A), whereby the first, second virtual magnetic poles 18L,. When 18R rotates to a position opposite to the first and second permanent magnets 52L, 52R, respectively, the state of FIG. 16A is reversed and the left and right are reversed, and only at that moment the outer rotor 13 is moved in the circumferential direction. The rotating magnetic force stops working.

  When the virtual permanent magnet 21 further rotates from this state, the first and second induction magnetic poles 38L, 38R,... Are driven in the magnetic field rotation direction by the magnetic force caused by the first and second magnetic lines G1, G2. The rotor 13 rotates in the magnetic field rotation direction. At that time, while the virtual permanent magnet 21 is rotated again to the position shown in FIG. 16A, the magnetic force acting on the first induction magnetic poles 38L... Is smaller in the degree of bending of the first magnetic line G1. However, as the total amount of magnetic flux increases, the strength increases and the driving force acting on the first induction magnetic poles 38L increases. On the contrary, the magnetic force acting on the second induction magnetic poles 38R... Is weakened by decreasing the total magnetic flux amount, although the bending degree of the second magnetic lines G2 is increased, and the driving force acting on the second induction magnetic poles 38R. Becomes smaller.

  16A and FIG. 17G, as the virtual permanent magnet 21 rotates by the pitch P, the first and second induction magnetic poles 38L,. Since it rotates only by the pitch P / 2, the outer rotor 13 rotates at a speed that is 1/2 the rotational speed of the rotating magnetic field of the first and second virtual magnetic poles 18L, 18R. This is because the first and second induction magnetic poles 38L,..., 38R... Are connected to the first permanent magnet 52L. This is to rotate while maintaining a state of being positioned in the middle of the first virtual magnetic pole 18L, and in the middle of the second permanent magnet 52R and the second virtual magnetic pole 18R connected by the second magnetic field line G2.

  Next, the operation of the electric motor M when the inner rotor 14 is rotated while the outer rotor 13 is fixed will be described with reference to FIGS. 19 and 20.

  First, as shown in FIG. 19A, the first induction magnetic poles 38L are opposed to the first permanent magnets 52L, and the second induction magnetic poles 38R are adjacent to each other two second permanent magnets 52R. .., The first and second rotating magnetic fields are rotated downward in the figure. At the start of the rotation, the polarities of the first virtual magnetic poles 18L ... are made different from the polarities of the first permanent magnets 52L ... facing each other, and the polarities of the second virtual magnetic poles 18R ... The same as the polarity of the two permanent magnets 52R.

  From this state, when the virtual permanent magnets 21 are rotated to the positions shown in FIG. 19B, the first magnetic lines of force G1 between the first induction magnetic poles 38L and the first virtual magnetic poles 18L are bent, and As the second virtual magnetic poles 18R approach the second induction magnetic poles 38R, second magnetic lines G2 that connect the second virtual magnetic poles 18R, the second induction magnetic poles 38R, and the second permanent magnets 52R are generated. As a result, in the first and second permanent magnets 52L, 52R, the virtual permanent magnet 21, and the first and second induction magnetic poles 38L, 38R, the magnetic circuit as shown in FIG. Composed.

  In this state, although the total magnetic flux of the first magnetic lines G1 between the first permanent magnets 52L and the first induction magnetic poles 38L is high, the first magnetic lines G1 are straight, so the first induction magnetic poles 38L. However, no magnetic force is generated to rotate the first permanent magnets 52L. Further, since the distance between the second permanent magnets 52R ... and the second virtual magnetic poles 18R ... having different polarities is relatively long, the second magnetic lines of force between the second induction magnetic poles 38R ... and the second permanent magnets 52R ... Although the total magnetic flux amount of G2 is relatively small, the bending degree is large, so that a magnetic force is applied to the second permanent magnets 52R, so as to bring them close to the second induction magnetic poles 38R. Thus, the second permanent magnets 52R are driven together with the first permanent magnets 52L in the rotational direction of the virtual permanent magnets 21, that is, in the direction opposite to the magnetic field rotational direction (upward in FIG. 19). Rotate toward the position shown in As a result, the inner rotor 14 rotates in the direction opposite to the magnetic field rotation direction.

  Then, while the first and second permanent magnets 52L, 52R,... Rotate from the position shown in FIG. 19B toward the position shown in FIG. 19C, the virtual permanent magnets 21. Rotate toward the position shown in As described above, as the second permanent magnets 52R approach the second induction magnetic poles 38R ..., the degree of bending of the second magnetic lines G2 between the second induction magnetic poles 38R ... and the second permanent magnets 52R ... becomes small. However, as the virtual permanent magnets 21 further approach the second induction magnetic poles 38R, the total magnetic flux amount of the second magnetic lines of force G2 increases. As a result, in this case as well, a magnetic force is applied to the second permanent magnets 52R... So as to bring them closer to the second induction magnetic poles 38R, thereby causing the second permanent magnets 52R. .. And the magnetic field rotation direction.

  Further, as the first permanent magnets 52L rotate in the direction opposite to the magnetic field rotation direction, the first permanent magnetic lines G1 between the first permanent magnets 52L ... and the first induction magnetic poles 38L ... A magnetic force is applied to the magnets 52L to bring them close to the first induction magnetic poles 38L. However, in this state, the magnetic force caused by the first magnetic field line G1 is weaker than the magnetic force caused by the second magnetic field line G2 because the degree of bending of the first magnetic field line G1 is smaller than that of the second magnetic field line G2. As a result, the second permanent magnets 52R are driven together with the first permanent magnets 52L in the direction opposite to the magnetic field rotation direction by the magnetic force corresponding to the difference between the two magnetic forces.

  As shown in FIG. 19D, the distance between the first permanent magnets 52L ... and the first induction magnetic poles 38L ... and the distance between the second induction magnetic poles 38R ... and the second permanent magnets 52R ... Are substantially equal to each other, the total magnetic flux amount and the degree of bending of the first magnetic lines G1 between the first permanent magnets 52L ... and the first induction magnetic poles 38L ... are the second induction magnetic poles 38R ... and the second permanent magnets 52R. Are approximately equal to the total amount of magnetic flux and the degree of bending of the second magnetic field lines G2 between them.

  As a result, the first and second permanent magnets 52L, 52R,... Are temporarily not driven when the magnetic forces caused by the first and second magnetic lines G1, G2 are substantially balanced with each other.

  When the virtual permanent magnets 21... Rotate from this state to the position shown in FIG. 20 (E), the generation state of the first magnetic lines of force G1 changes, and a magnetic circuit as shown in FIG. 20 (F) is configured. As a result, the magnetic force caused by the first magnetic field lines G1 hardly acts so as to bring the first permanent magnets 52L close to the first induction magnetic poles 38L, so that the second permanent magnets are caused by the magnetic force caused by the second magnetic field lines G2. 52R, together with the first permanent magnets 52L, are driven in the direction opposite to the magnetic field rotation direction to the position shown in FIG.

  When the virtual permanent magnets 21 are slightly rotated from the position shown in FIG. 20 (G), the first magnetic lines G1 between the first permanent magnets 52L and the first induction magnetic poles 38L are reversed from the above. The resulting magnetic force acts on the first permanent magnets 52L, so as to be close to the first induction magnetic poles 38L, so that the first permanent magnets 52L ... together with the second permanent magnets 52R ... Driven in the reverse direction, the inner rotor 14 rotates in the direction opposite to the magnetic field rotation direction. When the virtual permanent magnets 21 are further rotated, the magnetic force resulting from the first magnetic lines G1 between the first permanent magnets 52L and the first induction magnetic poles 38L, the second induction magnetic poles 38R and the second permanent magnets 52R. The first permanent magnets 52L are driven together with the second permanent magnets 52R in a direction opposite to the magnetic field rotation direction by a magnetic force corresponding to a difference in magnetic force caused by the second magnetic field lines G2 between the first permanent magnet 52L and the second permanent magnet 52R. After that, when the magnetic force caused by the second magnetic field lines G2 hardly acts so as to bring the second permanent magnets 52R to the second induction magnetic poles 38R ..., the first permanent magnets 52L are caused by the magnetic force caused by the first magnetic field lines G1. Are driven together with the second permanent magnets 52R.

  As described above, with the rotation of the first and second rotating magnetic fields, the magnetic force caused by the first magnetic field lines G1 between the first permanent magnets 52L and the first induction magnetic poles 38L, and the second induction magnetic poles 38R. The magnetic force caused by the second magnetic field line G2 between the first permanent magnets 52R and the second permanent magnets 52R, and the magnetic force corresponding to the difference between these magnetic forces are applied to the first and second permanent magnets 52L, 52R, that is, the inner rotor. 14, the inner rotor 14 rotates in the direction opposite to the magnetic field rotation direction. In addition, when the magnetic force, that is, the driving force acts alternately on the inner rotor 14 as described above, the torque of the inner rotor 14 becomes substantially constant.

  In this case, the inner rotor 14 rotates in reverse at the same speed as the first and second rotating magnetic fields. This is because the first and second induction magnetic poles 38L,..., 38R... Are intermediate between the first permanent magnets 52L and the first virtual magnetic poles 18L due to the magnetic force caused by the first and second magnetic lines of force G1 and G2. , And the second permanent magnets 52L, 52R,..., And the second virtual magnets 18R,.

  As described above, the case where the inner rotor 14 is fixed and the outer rotor 13 is rotated in the magnetic field rotation direction and the case where the outer rotor 13 is fixed and the inner rotor 14 is rotated in the direction opposite to the magnetic field rotation direction have been described separately. Of course, both the inner rotor 14 and the outer rotor 13 can be rotated in opposite directions.

  As described above, when rotating either one of the inner rotor 14 and the outer rotor 13 or both the inner rotor 14 and the outer rotor 13, depending on the relative rotational positions of the inner rotor 14 and the outer rotor 13, The magnetization states of the first and second induction magnetic poles 38L,..., 38R,... Can be rotated without causing slippage, and function as a synchronous machine. The first virtual magnetic poles 18L, the first permanent magnets 52L, and the first induction magnetic poles 38L are set to have the same number, the second virtual magnetic poles 18R, the second permanent magnets 52R, and the second induction magnetic poles. 38R is set to be equal to each other, the torque of the electric motor M can be sufficiently obtained when either the inner rotor 14 or the outer rotor 13 is driven.

  Next, the effect by the structure of the outer rotor 13 mentioned above is demonstrated.

  Since the convex portions 33b, 33b of the connecting member 33 and the concave portions 38d, 38d of the first and second induction magnetic poles 38L, 38R are coupled by press-fitting, the first and second induction magnetic poles 38L, 38R are accompanied by the rotation of the outer rotor 13. A radially outward centrifugal force acting on the first and second induction magnetic poles 38L and 38R is securely supported so as not to rattle by transmitting the radially outward centrifugal force to the connecting member 33 via the convex portions 33b and 33b and the concave portions 38d and 38d. can do. At this time, since the interference γ for press-fitting the convex portions 33b and 33b and the concave portions 38d and 38d is set in the radial direction (see FIG. 14), the connecting member 33 and the first and second induction magnetic poles 38L and 38R are radially formed. It is possible to prevent only the deformation in the circumferential direction by deformation only, and to prevent the deformation in the circumferential direction from accumulating and distorting the shape of the outer rotor 13.

  In addition, in the coupled state of the projections 33b and 33b and the recesses 38d and 38d, a gap δ is formed between the top of the projections 33b and 33b and the bottom of the recesses 38d and 38d (see FIG. 13). It is possible to prevent a large stress caused by the press-fitting load from acting on the induction magnetic poles 38L and 38R. Thereby, a fragile but strong magnetic material can be selected for the first and second induction magnetic poles 38L and 38R, and the degree of freedom in material selection can be increased.

  Further, since the cross-sectional shape of the first and second induction magnetic poles 38L and 38R in the direction orthogonal to the axis L is a trapezoid in which the circumferential length of the outer circumferential surface 38a is smaller than the circumferential length of the inner circumferential surface 38c, As the rotor 13 rotates, the radially outward centrifugal force acting on the first and second induction magnetic poles 38L and 38R is transmitted to the connecting member 33 so that the first and second induction magnetic poles 38L and 38R do not fall off. It can be reliably supported.

  Further, both end portions in the axis L direction of the outer peripheral surface 33a of the connecting member 33 are brought into contact with the protruding portions 31a provided on the center ring 31 and the protruding portions 32b and 32b provided on the first and second rotor flanges 32L and 32R. Therefore, the radially outward centrifugal force acting on the connecting member 33 as the outer rotor 13 rotates is transmitted to and supported by the center ring 31 and the first and second rotor flanges 32L, 32R, and the connecting member 33. Can be accurately positioned in the radial direction to increase the accuracy of the shape of the outer rotor 13.

  In addition, the first and second induction magnetic poles 38L and 38R are urged in the direction of the axis L by the resilient members 41 and 41 disposed between the first and second rotor flanges 32L and 32R and are pressed against the center ring 31. In addition, it is possible to absorb the variation in the dimension in the axis L direction of the first and second induction magnetic poles 38L and 38R due to the lamination of a large number of thin sheets of soft magnetic material, and to prevent the occurrence of backlash.

  Further, the center ring 31 and the first and second rotor flanges 32L and 32R on both sides in the axis L direction are connected by a plurality of connecting members 33 and bolts 39 arranged at predetermined intervals in the circumferential direction, and adjacent to each other. Since the first and second induction magnetic poles 38L and 38R are supported between the two connection members 33 and 33, the rigidity of the outer rotor 13 can be increased by the connection member 33, thereby the first and second induction magnetic poles 38L. ..., 38R ... can prevent deformation of the outer rotor 13 due to the centrifugal force acting on it.

  Further, when the connecting member 33 is fixed to the center ring 31 and the first and second rotor flanges 32L and 32R with the bolt 39 penetrating the connecting member 33, the vicinity of the bolt hole 33d on the inner peripheral surface 33c of the connecting member 33 is reduced in diameter. Since the bolt 39 can be inserted, the cross-sectional area of the connecting member 33 can be minimized, the eddy current flowing through the connecting member 33 can be minimized, and the loss can be reduced. it can.

  Further, since the thickness of the connecting member 33 in the radial direction is made larger than that of the other portions in the vicinity of the bolt hole 33d, the strength of the connecting member 33 is maintained to be large enough to receive the fastening load of the bolt 39, The volume of the connecting member 33 can be minimized to reduce the amount of eddy current generated, and loss due to eddy current can be reduced.

  Next, the effect by the structure of the stator 12 mentioned above is demonstrated.

  First and second induction magnetic poles 38L, 38R, which are juxtaposed in the axis L direction via the center ring 31 with the outer rotor 13, and first and second stator cores 18L, which are juxtaposed in the axis L direction via the spacer 22 with the stator 12. , 18R are opposed to each other, so that the first and second stator cores 18L, 18R are integrated without the spacer 22 to form the stator 12 having the same dimension in the axis L direction. Thus, the material of the first and second stator cores 18L and 18R can be reduced by the amount of the spacer 22, which can contribute to weight reduction and cost reduction.

  In addition, by integrating the first and second stator cores 18L and 18R via the spacers 22, the rigidity of the stator 12 can be improved and the winding cost of the coil 19 can be reduced. At this time, since the polarities of the first and second stator cores 18L and 18R located on both sides of the spacer 22 are the same in polarity, the spacer 22 is made of a weak magnetic material that hardly causes a magnetic short circuit. This eliminates the need to improve the freedom of material selection.

  In addition, since the common coil 19 is wound around the first and second stator cores 18L and 18R, not only can the structure be simplified and the winding cost can be reduced, but also the first and second stator cores 18L and 18R can face each other in the direction of the axis L. The polarity of the magnetic poles to be made can be the same, and a short circuit of the magnetic flux between the magnetic poles can be avoided. Furthermore, by configuring the spacer 22 with a non-conductive member, it is possible to prevent the eddy current from being generated in the spacer 22 and reduce the loss.

  Further, the center ring 31 is disposed between the first and second induction magnetic poles 38L, 38R,... Of the outer rotor 13, and the spacer 49 is disposed between the first, second permanent magnets 52L, 52R, of the inner rotor 14. Therefore, the center ring 31 and the spacer 49 are made to correspond to the spacer 22 between the first and second stator cores 38L and 38R, and the first and second induction magnetic poles 38L,. 1. The material of the second rotor cores 48L and 48R can be saved.

  Further, since the width of the center ring 31 of the outer rotor 13, the width of the spacer 49 of the inner rotor 14 and the width of the spacer 22 of the stator 12 are made substantially the same, the first and second induction magnetic poles 38L,. The first and second permanent magnets 52L, 52R,... Of the inner rotor 14 and the first and second stator cores 18L, 18R of the stator 12 are aligned in the radial direction so as not to be displaced in the direction of the axis L, and the magnetic flux between them is Delivery can be performed efficiently.

  Since the center ring 31 of the outer rotor 13 is made of a weak magnetic material, even if the polarities of the first and second induction magnetic poles 38L, 38R,. The occurrence of a magnetic short circuit can be prevented by the weakly magnetic center ring 31 having a large magnetic resistance disposed therebetween. Similarly, since the spacer 49 of the inner rotor 14 is made of a weak magnetic material, even if the polarities of the first and second permanent magnets 52L, 52R,. The occurrence of a magnetic short-circuit can be prevented by the weak magnetic spacer 49 having a large magnetic resistance disposed between them.

  Next, a second embodiment of the present invention will be described with reference to FIG.

  The elastic member 41 of the first embodiment is integrally provided with a leaf spring-shaped pressing portion 41b on a circlip-shaped locking portion 41a, but the elastic member 41 of the second embodiment is A coil spring-like pressing portion 41b is fixed to a circlip-like locking portion 41a by caulking or the like. Also according to the second embodiment, the same effect as that of the first embodiment can be achieved.

  Next, a third embodiment of the present invention will be described with reference to FIG.

  In the first embodiment, when the coupling member 33 is coupled to the first and second induction magnetic poles 38L and 38R, the projections 33b and 33b are provided on the coupling member 33 side, and the first and second induction magnetic poles 38L are provided. , 38R are provided with the recesses 38d, 38d. However, in the third embodiment, the relationship between the recesses and protrusions is reversed, and the recesses 33f, 33f are provided on the connecting member 33 side to provide the first and second induction magnetic poles 38L, 38R. Protrusions 38e, 38e are provided on the side.

  The relationship between the interference γ and the gap δ when press-fitting the concave portion 33f and the convex portion 38e is the same as that of the first embodiment (see FIGS. 13 and 14), and the same effect as that of the first embodiment. Can be achieved.

  Next, a fourth embodiment of the present invention will be described with reference to FIG.

  In the fourth embodiment, two lightening portions 33 g and 33 g penetrating in the direction of the axis L are formed on both ends of the connecting member 33 in the circumferential direction. Since the volume of the connecting member 33 is reduced by forming the thinned portions 33g and 33g, it is possible to reduce the eddy current generated accordingly and contribute to the reduction of the loss.

  The embodiments of the present invention have been described above, but various design changes can be made without departing from the scope of the present invention.

  For example, the rotating electrical machine of the present invention is not limited to the electric motor M of the embodiment, and may be any rotating electrical machine such as a generator.

  In the embodiment, the insulating coatings 31d and 32d are applied to the portions where the center ring 31 and the first and second rotor flanges 32L and 32R are in contact with the connecting members 33, but instead of applying the insulating coatings 31d and 32d, The center ring 31 and the first and second rotor flanges 32L and 32R may be made of a non-conductive material.

  In the embodiment, the connecting member 33 is provided with the insulating coating 33e on the portions where the connecting member 33 contacts the first and second induction magnetic poles 38L, 38R. Instead of applying the insulating coating 33e, the connecting member 33 is made of a non-conductive material. It may be configured.

  In the embodiment, the insulating coating 39c is applied to the portion where the bolt 39 contacts the connecting member 33. However, instead of applying the insulating coating 39c, the bolt 39 or the connecting member 33 may be made of a non-conductive material. .

The front view which looked at the electric motor which concerns on 1st Embodiment to the axial direction (1-1 sectional view taken on the line of FIG. 2). 2-2 sectional view of FIG. 3-3 sectional view of FIG. Sectional view along line 4-4 in FIG. Exploded perspective view of electric motor Disassembled perspective view of inner rotor 7 enlarged view of FIG. Sectional view taken along line 8-8 in FIG. Sectional view taken along line 9-9 in FIG. Sectional view taken along line 10-10 in FIG. Sectional view taken along line 11-11 in FIG. Partially exploded perspective view of outer rotor 13 enlarged view of FIG. Action explanatory diagram corresponding to FIG. Schematic diagram of electric motor deployed in the circumferential direction Explanation of the operation when the inner rotor is fixed (Part 1) Explanation of operation when inner rotor is fixed (Part 2) Explanation of operation when inner rotor is fixed (Part 3) (Part 1) of operation explanatory diagram when the outer rotor is fixed (2) of operation explanatory diagram when outer rotor is fixed Diagram showing eddy current generated in outer rotor The perspective view of the elastic member which concerns on 2nd Embodiment The figure corresponding to the said FIG. 8 based on 3rd Embodiment. The figure corresponding to the said FIG. 8 based on 4th Embodiment.

Explanation of symbols

12 Stator 13 Outer rotor (rotor)
14 Inner rotor (second rotor)
31 Center ring (fixing member)
31d Insulating coating 32L First rotor flange (fixing member)
32R 2nd rotor flange (fixing member)
32d Insulating coating 33 Connecting member 33e Insulating coating 33f Thinned portion 34 First outer rotor shaft (rotating shaft)
36 Second outer rotor shaft (rotating shaft)
38L 1st induction pole (magnetic member)
38R Second induction magnetic pole (magnetic member)
39 Bolt (rod-like fastening member)
L axis

Claims (7)

A plurality of fixing members (31; 32L, 32R) which are arranged on the rotating shafts (34, 36) in the axial line (L) direction and rotate integrally with the rotating shafts (34, 36), and the circumferential direction And a plurality of connecting members (33) for connecting two adjacent fixing members (31; 32L, 32R) arranged at a predetermined interval and two connecting members (33) adjacent in the circumferential direction. Magnetic members (38L, 38R),
The rotor for a rotating electrical machine, wherein a surface that contacts the connecting member (33) and the magnetic member (38L, 38R) is insulated.   The rotation according to claim 1, wherein the magnetic members (38L, 38R) are configured by laminating soft magnetic thin plates whose surfaces in contact with each other are insulated in an axis (L) direction. Electric rotor.   The connecting member (33) is made of a non-conductive material, or the surface of the connecting member (33) that contacts the magnetic member (38L, 38R) is provided with an insulating coating (33e). The rotor for rotating electrical machines according to claim 1 or claim 2.   The rotor for a rotating electrical machine according to any one of claims 1 to 3, wherein the connecting member (33) includes a lightening portion (33f).   The rod-shaped fastening member (39) penetrates and fixes the two fixing members (31; 32L, 32R) and the connecting member (33) arranged therebetween. The rotor for rotating electrical machines according to any one of claims 1 to 4.   6. The rotor for a rotating electrical machine according to claim 5, wherein a surface in contact with the connecting member and the rod-shaped fastening member is insulated. 7. It is an electric motor provided with the rotor for rotary electric machines (13) of any one of Claims 1-6,
The magnetic member (38L, 38R) is made of a soft magnetic material, and has a stator (12) that generates a rotating magnetic field on one and the other of the radially inner side and the radially outer side of the rotor (13), and a circumferential direction. An electric motor comprising: a second rotor (14) having a plurality of permanent magnets (52L, 52R) disposed therein.

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