The present invention relates to a motor.
In the prior art, as described in, for example, patent document 1, a permanent magnet motor such as a brushless motor includes a stator, which is formed by windings wound around a stator core, and a rotor, which uses permanent magnets opposing the stator, as magnetic poles. The windings of the stator are supplied with drive currents to generate a rotational magnetic field that rotates the rotor.
Patent Document 1: Japanese Laid-Open Patent Publication No. 2014-135852
In a permanent magnet motor such as that described above, when the rotor is driven to rotate at a higher speed, an increase in flux linkage resulting from the permanent magnets of the rotor increases the induced voltage generated at the windings of the stator. The induced voltage lowers the motor output and hinders rotation of the rotor at a higher speed.
It is an object of the present invention to provide a motor that allows for rotation at a higher speed.
To achieve the above object, a motor according to one aspect of the present invention includes a stator and a rotor. The stator includes windings, and the rotor is rotated by a rotation field generated when drive currents are supplied to the windings. The windings include a first winding and a second winding, in which the first winding and the second winding are synchronously excited by the drive currents and connected in series. The rotor includes a magnet pole, which includes a permanent magnet, and a flux toleration portion. The flux toleration portion is opposed to the second winding at a rotational position where the magnet pole opposes the first winding, and the flux toleration portion tolerates generation of a flux linkage resulting from a field weakening current at the second winding.
One embodiment of a motor will now be described.
As shown in
Structure of Stator
The stator 11 includes a stator core 12 and windings 13 wound around the stator core 12. The stator core 12 is substantially ring-shaped and formed from a magnetic metal. The stator core 12 includes twelve teeth 12a extending inward and arranged in the radial direction at equal angular intervals in the circumferential direction.
There are twelve windings 13, the number of which is the same as the teeth 12a. The windings 13 are wound as concentrated windings in the same direction around the teeth 12a, respectively. That is, the twelve windings 13 are arranged in the circumferential direction at equal angular intervals (thirty-degree intervals). The windings 13 are classified into three phases in accordance with the supplied drive currents of three phases (U-phase, V-phase, and W-phase) and indicated in order in the counterclockwise direction as U1, V1, W1, U2, V2, W2, U3, V3, W3, U4, V4, and W4 in
With regard to each phase, the U-phase windings U1 to U4 are arranged in the circumferential direction at equal angular intervals (ninety-degree intervals). In the same manner, the V-phase windings V1 to V4 are arranged in the circumferential direction at equal angular intervals (ninety-degree intervals). The W-phase windings W1 to W4 are also arranged in the circumferential direction at equal angular intervals (ninety-degree intervals).
As shown in
Structure of Rotor
As shown in
The N-magnet poles Mn and the S-magnet poles Ms each include a permanent magnet 25 fixed to the outer circumferential surface of the rotor core 22. Thus, the rotor 21 has a surface magnetic construction (SPM structure) in which four permanent magnets 25 are fixed to the outer circumferential surface of the rotor core 22. The permanent magnets 25 are identical in shape. The outer circumferential surface of each permanent magnet 25 is arcuate and extends about an axis L of the rotation shaft 23 as viewed in the direction of the axis L.
Each permanent magnet 25 is formed so that the magnetic orientation is directed in the radial direction. In further detail, each permanent magnet 25 having the N-magnet pole Mn is magnetized so that the magnetic pole formed at the outer circumference side is the N-pole, and each permanent magnet 25 having the S-magnet pole Ms is magnetized so that the magnetic pole formed at the outer circumference side is the S-pole. The permanent magnets 25 are, for example, anisotropic sintered magnets and configured by, for example, neodymium magnets, samarium-cobalt (SmCo) magnets, SmFeN magnets, ferrite magnets, alnico magnets, or the like. The permanent magnets 25 are arranged so that those of the same polarity are arranged in the circumferential direction at 180-degree opposing positions. That is, the N-magnet poles Mn are arranged at 180-degree opposing positions, and the S-magnet poles Ms are arranged at 180-degree opposing positions.
The open angle (occupied angle) of the permanent magnets 25 about the axis L is set to (360/2n)°, where n represents the total number of the magnet poles Mn and Ms (number of permanent magnets 25). In the present embodiment, the total number of the magnet poles Mn and Ms is four. Thus, the open angle of each permanent magnet 25 is set to 45°. Further, the N-pole permanent magnet 25 and the S-pole permanent magnet 25 of each magnet pole pair P are arranged adjacent to each other in the circumferential direction. Thus, the open angle of each magnet pole pair P is set to 90° in correspondence with the two permanent magnets 25.
Each projection 24 of the rotor core 22 is formed projecting outward in the radial direction between the magnet pole pairs P in the circumferential direction. In other words, each projection 24 is configured so that one side in the circumferential direction is adjacent to an N-pole permanent magnet 25 and the other side in the circumferential direction is adjacent to an S-pole permanent magnet 25. Further, the outer circumferential surface of each projection 24 is arcuate about the axis L as viewed in the direction of the axis L of the rotation shaft 23, and the outer circumferential surfaces of the projections 24 are flush with the outer circumferential surfaces of the permanent magnets 25.
The two circumferential ends of each projection 24 are spaced apart by gaps K from the adjacent permanent magnets 25. The open angle about the axis L of each projection 24 is set to be smaller than the open angle of each magnet pole pair P (90°) by an amount corresponding to the gaps K
The operation of the present embodiment will now be described.
A drive circuit (not shown) supplies drive currents (AC) of three phases having phase differences of 120° to the U-phase windings U1 to U4, the V-phase windings V1 to V4, and the W-phase windings W1 to W4, respectively. Thus, in the windings U1 to W4, those of the same phase are synchronously excited. This generates a rotational magnetic field in the stator 11. The rotational magnetic field rotates the rotor 21. The supply of the three-phase drive currents forms poles in the stator 11 so that those having the same phases in the windings U1 to W4 have the same polarity. In the present embodiment, the number of the magnetic poles of the rotor 21 (number of magnet poles Mn and Ms) is four. However, in the windings U1 to W4, those of each phase is supplied with drive current set assuming that the number of poles of the rotor 21 is two times the number of the magnet poles Mn and Ms (eight poles in the present embodiment).
During high-speed rotation of the rotor 21, field weakening control is executed to supply the windings 13 with field weakening current (d-axis current). During high-speed rotation of the rotor 21 (during field weakening control), for example, as shown in
In this case, the U-phase windings U1 to U4 are each supplied with a field weakening current. However, in the U-phase windings U1 and U3, the opposing N-magnet poles Mn generate flux (flux toward outer side in radial direction) that exceeds the flux linkage resulting from the field weakening current (flux linkage toward radially inner side). This generates flux linkage ϕx that passes through the U-phase windings U1 and U3 toward the outer side in the radial direction.
In the U-phase windings U2 and U4, the opposing portions of the rotor 21 are the projections 24 of the rotor core 22 and not the magnet poles Mn. Thus, flux linkage ϕy resulting from the field current is not eliminated, and the flux linkage ϕy passes the U-phase windings U2 and U4 toward the inner side in the radial direction. In other words, the projections 24 of the rotor core 22, which are opposed to the U-phase windings U2 and U4, are configured as flux toleration portions that tolerate the generation of the flux linkage ϕy resulting from the field weakening current. Thus, the magnet poles Mn generate the flux linkage ϕy at the U-phase windings U2 and U4. The phase of the flux linkage ϕy is inverted from the phase of the flux linkage ϕx generated at the U-phase windings U1 and U3. The flux linkages ϕx and ϕy generate induced voltage at the U-phase windings U1 to U4. The effect described above also occurs when the S-magnet poles Ms are, for example, opposed to the U-phase windings U1 and U3.
In the conventional structure, the uniform poles of the rotor generate flux linkage in the same direction at each of the U-phase windings U1 to U4. Thus, as shown in
In the present embodiment, as described above, the flux linkage ϕy, of which the phase is inverted from the phase of the flux linkage ϕx generated at the U-phase windings U1 and U3 by the magnet poles Mn and Ms, is generated at, for example, the U-phase windings U2 and U4 opposing the projections 24 of the rotor core 22. Thus, as shown in
Here, an example using the combined induced voltage vu of the U-phase windings U1 to U4 has been described. In the same manner, the projections 24 of the rotor core 22 also decrease the combined induced voltage at the V-phase windings V1 to V4 and the W-phase windings W1 to W4
The present embodiment has the advantages described below.
(1) In correspondence with the supplied drive currents of three phases, the windings 13 of the stator 11 include the four U-phase windings U1 to U4, the four V-phase windings V1 to V4, and the four W-phase windings W1 to W4. The four windings of each phase are connected in series. That is, the windings 13 of the stator 11 include at least two series-connected windings (first winding and second winding) for each phase.
The rotor 21 includes the magnet poles Mn and Ms, which include the permanent magnets 25, and the projections 24 of the rotor core 22 (flux toleration portion), which are opposed to the U-phase windings U2 and U4 at rotational positions where, for example, the magnet poles Mn (or magnet poles Ms) oppose the U-phase windings U1 and U3. The projections 24 of the rotor core 22 tolerate the generation of flux linkage ϕy resulting from the field weakening current at the opposing windings 13 (e.g., U-phase windings U2 and U4).
With this structure, the induced voltage vy generated by the flux linkage ϕy resulting from the field weakening current at the windings 13 opposing the projections 24 of the rotor core 22 has an inverted polarity with respect to the induced voltage vx generated at the windings 13 opposed to the magnet poles Mn (or magnet poles Ms) (refer to
When a winding construction connects the windings 13 of each phase in series like in the present embodiment, the sum of the induced voltage generated at each winding for each phase is the combined induced voltage. Accordingly, there is a tendency for the combined induced voltage to increase. Thus, in a construction in which the windings 13 of each phase are connected in series, the arrangement of the projections 24 on the rotor 21 increases the effect for reducing the combined induced voltage vu and allows the motor 10 to be rotated at a higher speed in an further optimal manner.
Further, the rotor 21 includes the projections 24. This reduces the field weakening current supplied to the windings 13. The reduced field weakening current limits demagnetization of the permanent magnet 25 during field weakening control and limits copper loss of the windings 13. In other words, the flux linkage amount that can be reduced by the same amount of field weakening current increases. This allows the field weakening control to further effectively increase the rotation speed.
(2) The magnet poles Mn and Ms are formed by fixing the permanent magnets 25 to the outer circumferential surface of the rotor core 22. That is, the rotor 21 has a surface magnet structure (SPM structure). This contributes to increasing the torque of the motor 10.
(3) The projections 24 of the rotor core 22 that serve as flux toleration portions are formed at the same positions in the radial direction as the permanent magnets 25. This structure allows the projections 24 of the rotor core 22 (flux toleration portion) to be opposed to the poles of the stator 11 (teeth 12a and windings 13) at a closer distance. Thus, the magnetic resistance (air gap) can be reduced between the teeth 12a and the projections 24 of the rotor core 22. This increases the flux linkage ϕy generated by the field weakening current at the windings 13 opposed to the projections 24 of the rotor core 22. As a result, the combined induced voltage vu can be reduced in a further optimal manner.
(4) A plurality of (two sets of) the magnet pole pairs P (magnet pole sets), each including the N-magnet pole Mn and the S-magnet pole Ms arranged adjacent to each other in the circumferential direction, are arranged at equal angular intervals in the circumferential direction. This allows the structure of the rotor 21 to be magnetically and mechanically well-balanced.
The above embodiment may be modified as described below.
In the above embodiment, the windings for each phase, namely, the U-phase windings U1 to U4, the V-phase windings V1 to V4, and the W-phase windings W1 to W4 are connected in series. However, there is no such limitation, and the winding arrangement may be changed when required.
For instance, in the example of
When applying the winding arrangement of
A case will now be considered in which the winding U2 and the winding U3 are exchanged with each other in the example of
As described above, when connecting the windings of each phase in series, the windings (e.g., U-phase winding U1 and U-phase winding U2) opposing the magnet poles Mn (magnet poles Ms) and the projections 24 at a predetermined rotational position of the rotor 21 are connected in series. Thus, the combined induced voltage is obtained by adding the induced voltages having inverted polarities (inverted phases) generated at the windings of the same phase that are connected in series. This effectively reduces the combined induced voltage of each phase.
In the example of
Further, in the example of
In the above embodiment (refer to
In the above embodiment, the projections 24 project from the rotor core 22 between the magnet pole pairs P in the circumferential direction. However, for example, as shown in
In the rotor 21 of the above embodiment, the magnet poles Mn and Ms (permanent magnets 25) are arranged so that those of the same polarity are arranged at 180-degree opposing positions. However, there is no limit to such an arrangement.
For example, as shown in
The rotor 21 of the above embodiment has an SPM structure in which the permanent magnets 25, which form the magnet poles Mn and Ms, are fixed to the outer circumferential surface of the rotor core 22. However, for example, as shown in
In the example of
The rotor 21 shown in
The rotor 21 shown in
The rotor 21 shown in
The rotor 21 shown in
This structure also allows for an increase in the volume of the outer circumferential core portion 22g at the outer circumferential sides of the two permanent magnets 31 in each of the magnet poles Mn and Ms. Thus, the reluctance torque can be increased. This contributes to further increasing the reluctance torque. Further, in this structure, each permanent magnet 31 has the form of a simple parallelepiped. This lowers the magnet processing cost.
The rotor 21 shown in
With such a structure, the outer circumferential core portion 22g of each of the magnet poles Mn and Ms can be increased in volume. This allows the reluctance torque to be increased and contributes to further increasing the torque. Further, with this structure, the number of permanent magnets can be reduced from the structure of
The rotor 21 shown in
The rotor 21 shown in
The rotor 21 shown in
In the above embodiment, the total number of the magnet poles Mn and Ms in the rotor 21 is four, and the number (slot number) of the windings 13 of the stator 11 is twelve. However, the total number of the magnet poles Mn and Ms and the number of the windings 13 may be changed in accordance with the structure. For example, the total number of the magnet poles Mn and Ms and the number of the windings 13 may be changed so that the total number of the magnet poles Mn and Ms and the number of the windings 13 have a relationship of n:3 (where n is an integer of 2 or larger). When the total number of the magnet poles Mn and Ms is an even number like in the above embodiment, the number of magnet poles Mn can be the same as the number of magnet poles Ms. This allows for a structure that is well-balanced in magnetic terms.
Further, the total number of the magnet poles Mn and Ms and the number of the windings 13 does not necessarily have to be in a relationship of n:3n (where n is an integer of 2 or greater). For example, the total number of the magnet poles Mn and Ms and the number of the windings 13 may have a relationship of 5:12, 7:12, or the like.
In the motor 30 shown in
The U-phase windings U1, U2, bar U1, and bar U2 are connected in series. In the same manner, the V-phase windings V1, V2, bar V1, and bar V2 are connected in series, The W-phase windings W1, W2, bar W1, and bar W2 are connected in series. The U-phase windings U1, U2, bar U1, bar U2 are supplied with a U-phase drive current. This constantly excites the U-phased windings bar U1 and bar U2, which are reverse windings, with an inverted polarity (inverted phase) with respect to the U-phase windings U1 and U2, which are forward windings. However, the excitation timing is the same. The same applies to the other phases (V-phase and W-phase). The windings of each phase are supplied with drive current that is set assuming that the pole number of the rotor 21 is two times the number of the magnet poles Mn and Ms (i.e., 10 poles in the present example).
The outer circumferential portion of the rotor 21 of the motor 30 includes a single pole set Pa, in which three magnet poles Ms and two magnet poles Mn are alternately arranged next to one another in the circumferential direction, and a single projection 24 of the rotor core 22.
The magnet poles Mn and Ms (permanent magnets 25) are set to have an equal open angle about the axis L. Further, the open angle of the magnet poles Mn and Ms (permanent magnet 25) is set to (360/2n)°, where n represents the total number of the magnet poles Mn and Ms (number of permanent magnets 25). In the permanent example, the total number of the magnet poles Mn and Ms is 5. Thus, the open angle of the magnet poles Mn and Ms (permanent magnet 25) is set to 36°, and the open angle of the pole set Pa is 180°.
More specifically, in the present example, one half of the outer circumference of the rotor 21 includes the pole set Pa, and the other half includes the projection 24 that is formed to have an open angle of substantially 180°. Thus, the rotor 21 is formed so that the projection 24 is located 180° opposite to the magnet poles Mn and Ms. The open angle of the projection 24 of the rotor core 22 is smaller than 180° for an amount corresponding to the gaps K extending from the magnet poles Ms (permanent magnets 25) that are adjacent in the circumferential direction.
In the above configuration, during high-speed rotation of the rotor 21 (during field weakening control), for example, when the U-phase winding U1 is opposed in the radial direction to the S-magnet pole Ms, the projection 24 of the rotor core 22 is opposed in the radial direction to the U-phase winding bar U1 (refer to
In this case, the U-phase windings U1 and bar U1 are supplied with field weakening current. However, in the U-phase winding U1, the flux of the opposing magnet pole Ms (flux toward radially inner side) exceeds the flux linkage (flux linkage toward radially outer side), and the flux linkage ϕx is generated passing through the U-phase winding U1 toward the radially inner side.
With regard to the U-phase winding bar U1, the opposing portion of the rotor 21 is the projection 24 of the rotor core 22. Thus, the flux linkage ϕy resulting from the field weakening current is not eliminated, and the flux linkage ϕy passes through the U-phase winding bar U1 toward the radially outer side. That is, the projection 24 of the rotor core 22 opposing the U-phase winding bar U1 serves as the flux toleration portion that tolerates the generation of the flux linkage ϕy resulting from the field weakening current. In this manner, the flux linkage ϕy is generated at the U-phase winding bar U1. The flux linkage ϕy has a phase inverted from the flux linkage ϕx generated at the U-phase winding U1 by the magnet pole Ms. As a result, the induced voltage generated at the U-phase winding bar U1 by the flux linkage ϕy has an inverted polarity (inverted phase) with respect to the induced voltage generated at the U-phase winding U1 by the flux linkage ϕx. This reduces the combined induced voltage at the U-phase windings U1 and bar U1. In this manner, the combined induced voltage of each phase is reduced. Thus, the rotation speed of the motor 30 can be increased.
The number of the magnet poles Mn and the number of the magnet poles Ms are not limited in the manner shown in the example of
Further, the arrangement of the magnet poles Mn and Ms and the projections 24 in the rotor 21 is not limited to the arrangement of the example shown in
In the structure of
In the stator 11, the U-phase windings U1, U2, bar U1, and bar U2 do not all have to be connected in series. Further, the windings U1 and bar U1 may form a series-connected pair that is separate from the series-connected pair of the windings U2 and bar U2. The same changes may be made for the V-phase and the W-phase.
Further,
The rotor 21 of the above embodiment may have an interior magnet structure (IPM structure) as shown in
With this structure, in each of the magnet poles Mn and Ms, portions of the rotor core 22 between the magnet receptacles 41 (inter-receptacle portion R1) form q-axis magnetic paths. This sufficiently increases the q-axis inductance. Further, in d-axis magnetic paths, the magnet receptacles 41 (and permanent magnets 42) produce magnetic resistance that sufficiently decreases the d-axis inductance. This increases the difference between the q-axis inductance and the d-axis inductance (salient-pole ratio). Thus, the reluctance torque can be increased, and the torque can be further increased.
In the structure of
In the example of
As shown in
In the structure of
Each flux toleration portion 22c includes two slit groups 43H, each formed by a plurality of (three in the example of
With such a structure, portions of the rotor core 22 between the slits 43 (inter-slit portions R2) form q-axis magnetic paths. This sufficiently increases the q-axis inductance. Further, in d-axis magnetic paths, the slits 43 produce magnetic resistance that sufficiently decreases the d-axis inductance. Accordingly, the difference between the q-axis inductance and the d-axis inductance (salient-pole ratio) can be increased. This produces the salient-poles 44 at the circumferentially center position of each flux toleration portion 22c (i.e., center position between slit groups 43H that are adjacent to each other in circumferential direction) and at the circumferentially center position between each slit group 43H and the adjacent one of the magnet poles Mn and Ms (magnet receptacles 41) in the circumferential direction. Thus, reluctance torque can be obtained at each of the salient-poles 44, and the torque can be further increased. The flux rectifying effect of the slits 43 in the rotor core 22 result in the salient-poles 44 acting as poles. The salient-poles 44 are not magnet poles of permanent magnets. Thus, even though the flux toleration portions 22c include the salient-poles 44, the flux toleration portions 22c function to tolerate the flux linkage ϕy (refer to
In the example shown in
The shape of the slits 43 in each slit group 43H of
As shown in
In the structure shown in
Further, in the structure shown in
In the above embodiment, the projections 24, which define the flux toleration portions, are formed integrally with the rotor core 22. In other words, the rotor core 22 is an integral component that includes the projections 24. Instead, the projections 24 may be separate bodies.
For example, in the structure shown in
An N-pole permanent magnet 25 and an S-pole permanent magnet 25, which are adjacent to each other in the circumferential direction, are fixed to each first fixing portion 53 of the core body 51. This forms the magnet pole pair P (N-magnet pole Mn and S-magnet pole Ms) on each first fixing portion 53 of the core body 51.
Each second fixing portion 54 is recessed inward in the radial direction from the outer circumferential surface of the core body 51 between the first fixing portions 53 in the circumferential direction. The separate core members 52 are fixed to the second fixing portion 54 through press-fitting or by an adhesive agent. Each separate core member 52 has a sectoral form extending about the axis L of the rotation shaft 23. Further, each separate core members 52 is formed by a material (e.g., amorphous metal, permalloy, or the like) having a higher magnetic permeability than the core body 51 (e.g., iron material).
The radially inner end of each separate core member 52 is fitted to the corresponding second fixing portion 54, and the part of the separate core member 52 other than the fitted part projects outward in the radial direction from the outer circumferential surface (first fixing portions 53) of the core body 51. One circumferential side of the part of each separate core member 52 projecting from the core body 51 is adjacent to an N-pole permanent magnet 25 with a gap K located in between, and the other circumferential side is adjacent to an S-pole permanent magnet 25 with a gap K located in between. The open angle of each separate core member 52 about the axis L is smaller by an amount corresponding to the gaps K than the open angle of each magnet pole pair P (90°). Further, in an axial view, the separate core members 52 are line-symmetric with respect to a center line L2 of the magnet pole pairs P in the circumferential direction, and the center line of the separate core members 52 in the circumferential direction (center line L2) and the center line L3 of the magnet pole pairs P in the circumferential direction (border line of adjacent magnet poles Mn and Ms) form an angle of 90°. The outer circumferential surface of each separate core member 52 is arcuate and extends about the axis L as viewed in the direction of the axis L of the rotation shaft 23. The outer circumferential surfaces of the separate core members 52 and the outer circumferential surfaces of the permanent magnets 25 lie along the same circle extending about the axis L.
With such a structure, the separate core members 52 function as flux toleration portions in the same manner as the projections 24 of the above embodiment. That is, field weakening flux (flux linkage generated by application of field weakening current) from the opposing windings 13 passes through the separate core members 52. It is desirable that the open angle (circumferential width) of the separate core members 52 be set to include the magnetic path of the field weakening flux (d-axis magnetic path Pd). More specifically, it is desirable that the open angle of the separate core members 52 be set to an angle (45° in the present example) that is obtained by equally dividing the rotor 21 in the circumferential direction by two times the total number of the magnet poles Mn and Ms (eight in the present example). In the example shown in
The separate core members 52, which form the flux tolerance portions, are separate from the core body 51 that includes the magnet pole pairs P (N-magnet pole Mn and S-magnet pole Ms). This limits interference between the magnetic path of the field weakening flux in the separate core members 52 (d-axis magnetic path Pd) and the magnetic path of the magnet poles Mn and Ms in the core body 51 (in particular, magnetic path of short-circuit flux between one magnet pole pair P and the other magnet pole pair P). As a result, the field weakening flux smoothly passes through the separate core members 52. This contributes to further increasing the rotation speed.
Further, in this structure, the separate core members 52 are formed from a material having a higher magnetic permeability than the core body 51. This allows for further smooth passage of the field weakening flux through the separate core members 52 and contributes to further increasing the rotation speed. Further, among the components of the rotor core 22, at least the separate core members 52 are formed from a material having high magnetic permeability, and the core body 51 is formed from an inexpensive material (iron or the like). Thus, the rotation speed can be increased while limiting increases in the manufacturing cost.
In the structure shown in
The magnet poles Mn and Ms each include a pair of permanent magnets 61 embedded in the core body 51. In each of the magnet poles Mn and Ms, the pair of permanent magnets 61 are arranged in a generally V-shaped layout that widens toward the outer circumference in an axial view. Further, the two permanent magnets 61 are in line-symmetry with respect to a pole center line (refer to line L1 in
In
The core body 51 includes magnetic resistance holes 62 at positions located toward the inner circumference from the pair of permanent magnets 61 in each of the magnet poles Mn and Ms. The magnetic resistance holes 62 are rectangular holes elongated in the radial direction in an axial view and located at circumferentially central positions in the magnet poles Mn and Ms. In the present example, the centers of the magnetic resistance holes 62 are spaced apart by 45° in the magnet poles Mn and Ms that are adjacent to each other in the circumferential direction. Each magnetic resistance hole 62 extends through the core body 51 in the axial direction, and the inside of each magnetic resistance hole 62 is a gap. As a result, the magnetic resistance holes 62 reduce short-circuit flux between the magnet poles Mn and Ms that are adjacent to each other in the circumferential direction. This contributes to increasing the torque.
Gaps K1 and K2 are respectively arranged at the inner circumference side and outer circumference side of each permanent magnet 61. The gaps K1 and K2 are portions of a magnet receptacle 63 formed in the core body 51 to receive the corresponding permanent magnet 61. Each permanent magnet 61 includes a side surface located at the inner circumference side that faces the corresponding gap K1 and a side surface located at the outer circumference side that faces the corresponding gap K2. More specifically, the gap K1 is located between each permanent magnet 61 and the radially inner end of the corresponding magnet receptacle 63, and the gap K2 is located between each permanent magnet 61 and the radially outer end of the corresponding magnet receptacle 63. The magnetic resistance of each of the gaps K1 and K2 reduces short-circuit flux in the permanent magnets 61 (short-circuit flux of each permanent magnet 61 between N and S poles through the core body 51). This contributes to increasing the torque.
Fixing recesses 64 are recessed inward in the radial direction from the outer circumferential surface of the core body 51 between the magnet pole pairs P of the core body 51. The two circumferential end surfaces of each fixing recess 64 is planar and extends in the radial direction, and the two end surfaces each include a connection projection 65 projecting in the circumferential direction into the fixing recess 64. Each connection projection 65 is tapered so that the width in the radial direction of the rotor 21 increases toward the distal end of the projection (circumferential distal end). Further, the circumferentially central portion in the radially inner surface of the fixing recess 64 includes a main body connection recess 67 to which a connection member 66 is connected.
Separate core members 52, which are separate from the core body 51, are fitted to the fixing recesses 64. The outer circumferential surface of each separate core member 52 is arcuate and extends about the axis L as viewed in the direction of the axis L of the rotation shaft 23. Further, the outer circumferential surfaces of the separate core members 52 are flush with the outer circumferential surface of the core body 51. The two circumferential end surfaces of each separate core member 52 are planar and extend in the radial direction. Further, the two circumferential end surfaces and radially inner surface of each separate core member 52 contact the two circumferential ends surfaces and radially inner surface of the corresponding fixing recess 64.
The two circumferential end surfaces of each separate core member 52 include first connection recesses 71. The connection projections 65 of the core body 51 are fitted to the first connection recesses 71. The first connection recesses 71 are identical in shape to the connection projections 65 of the core body 51. The circumferentially central portion in the radially inner surface of each fixing recess 64 includes a second connection recess 72. The connection member 66 is connected to the second connection recess 72.
The connection member 66 extends across the separate core member 52 and the core body 51 at the circumferentially inner side of the separate core member 52 and connects the separate core member 52 and the core body 51. In detail, the circumferential width of the connection member 66 increases in a tapered manner from the radially central portion toward the two radial ends. The radially inner half of the connection member 66 is fitted to the main body connection recess 67 in the core body 51, and the radially outer half of the connection member 66 is fitted to the second connection recess 72 in the separate core member 52. Preferably, the connection member 66 is formed from a material having higher magnetic resistance than the core body 51 and the separate core members 52 (e.g., resin, stainless steel, brass, or the like).
As described above, the separate core members 52 are fixed to the fixing recesses 64 of the core body 51 by fitting the connection projections 65 of the core body 51 to the first connection recesses 71 of the separate core members 52 and by fitting the connection members 66 to the main body connection recesses 67 and the second connection recesses 72. In an axial view, the separate core members 52 are in line-symmetry with respect to the center line L2 between the magnet pole pairs P in the circumferential direction, and the angle is 90° between the circumferential center line (center line L2) of the separate core members 52 and the circumferential center line L3 of the magnet pole pairs P (border line between adjacent magnet poles Mn and Ms). Further, in the structure of
In such a structure, portions of the rotor core 22 located between the magnet pole pairs P in the circumferential direction function as the flux toleration portions 22c in the same manner as the structure shown in
In the structure of
Further, in the structure of
Additionally, in the structure of
In the structures of
Further, in the structures of
In the above embodiment, the permanent magnets 25 are sintered magnets but instead may be, for example, bonded magnets.
In the above embodiment, the rotor 21 is embodied in an inner-rotor type motor 10 in which the stator 11 is located at the radially inner side. Instead, the rotor may be embodied in an outer-rotor type motor in which the rotor is located at the radially outer side of the stator.
In the above embodiment, the present invention is embodied in a radial-gap type motor 10 in which the stator 11 and the rotor 21 are opposed to each other in the radial direction. Instead, the present invention may be applied to an axial-gap type motor in which the stator and the rotor are opposed to each other in the axial direction
The above embodiment and the modified examples may be combined with one another.
Number | Date | Country | Kind |
---|---|---|---|
2015-144308 | Jul 2015 | JP | national |
2015-251812 | Dec 2015 | JP | national |
2016-050075 | Mar 2016 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2016/071104 | 7/19/2016 | WO | 00 |