JP2004147425A - Rotating electric machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a rotating electric machine wherein a rotational torque is improved with a simple configuration for a better rotational efficiency and less energy loss. <P>SOLUTION: An excitation coil 12 is so wound around each of salient poles 8 of a stator core 7 that the magnetic pole generated on the tip side of salient pole when energized has the same polarity as that of an adjoining fixed-side permanent magnet 9. Related to a stator magnetic pole, the magnetic flux generated from an electromagnet 13 caused by energization to the selected electromagnet 13 is superposed with the magnetic flux generated from the magnetic pole of the fixed-side permanent magnets 9 adjoining on both sides for action from a magnetic flux action surface 11 of the salient pole 8, and a rotor 1 is rotated by repelling to the rotor magnetic pole of the same polarity and attraction from the rotor magnetic pole of a different polarity. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
FIELD OF THE INVENTION
The present invention relates to a rotating electric machine applicable to a brushless motor or a generator represented by, for example, a stepping motor or a servomotor.
[0002]
[Prior art]
In a brushless motor represented by a stepping motor, a stator and a rotor are coaxially arranged, a rotor magnet is provided on a rotating shaft as a rotor, and an armature winding is provided on a stator core (laminated core) fixed to a housing as a stator. Is used. Generally, by generating and applying a pulse voltage having a desired frequency from an DC power source obtained by full-wave rectification of an AC power source through an inverter circuit, the magnet rotor rotates by a rotation angle proportional to the input pulse voltage. Has become.
[0003]
Also, a self-starting synchronous motor has been proposed as an electric motor constituted by only a magnetic material without using a magnet on the rotor side (for example, see Patent Document 1). In this electric motor, E-shaped magnetic yokes projecting in the axial direction with phases shifted by 90 degrees at the stator side are arranged at four positions. An exciting winding is wound around the center leg of each magnetic yoke, and a pair of magnetic substance attracting bases is joined to the inner end side of the leg. The magnetic material suction base has a hybrid structure in which a soft magnetic material is connected to both sides of a hard magnetic material, and the opposite side (inner surface) of the soft magnetic material opposite to the joint surface with the leg end surface is used as a magnetic flux acting surface. Is formed. The rotor is made of a cylindrical magnetic body, and has a plurality of tooth-shaped magnetic poles formed on the peripheral surface. The magnetic body attracting base on the stator side sequentially energizes the excitation winding of the magnetic yoke, and attracts the approaching magnetic poles of the rotor due to the magnetic flux acting surface of the soft magnetic body, thereby rotating the rotor. It is supposed to.
[0004]
[Patent Document 1]
JP 2001-258221 A (see FIG. 1)
[0005]
[Problems to be solved by the invention]
In the self-starting synchronous motor, the magnetic flux generated by the electromagnet in the magnetic yoke and the magnetic flux generated by the magnetic attraction base are superposed on each other to act on the magnetic pole (teeth type) approaching the rotor from the magnetic flux acting surface. It has become.
However, since the area of the magnetic flux acting surface of the tooth-shaped magnetic pole of the rotor and the magnetic flux acting surface of the magnetic yoke are small (in particular, only the soft magnetic material portion of the bar-shaped permanent magnet is used), the interaction with the electromagnet causes the magnetic flux to be generated. When the magnetic flux generated from the working surface is easily saturated, and as the number of magnetic poles increases or the rotor becomes larger, it is not possible to expect a significant improvement in rotational torque performance or rotational speed by only the suction effect. Also, since the exciting coil is wound around the center magnetic leg of the E-shaped magnetic yoke and the magnetic substance suction base is provided on the inner end side of the leg, the outer diameter of the stator side becomes larger than the rotor diameter. It is easy to increase the number of E-type magnetic yokes in the non-magnetic cylinder, and there is a limit in space, and it is difficult to perform high-definition energization control according to the rotational position of the rotor. Further, there is a problem that it is difficult to arrange and fix the E-type magnetic yoke in the nonmagnetic cylinder in a well-balanced manner in the circumferential direction, and the magnet having the hybrid structure joined to the magnetic pole tip (tip) of the magnetic yoke has a uniform magnetic material. It is more expensive than ordinary permanent magnets, and the manufacturing cost is high.
[0006]
SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned problems of the prior art, to provide a rotating electric machine that has improved rotational torque with a simple configuration, has high rotational efficiency, and has low energy loss.
[0007]
[Means for Solving the Problems]
In order to solve the above problems, the present invention has the following configuration.
That is, it has a movable permanent magnet fixed to the outer periphery of a cylindrical magnetic body fitted coaxially with the rotation axis at a regular interval via a non-magnetic portion, and magnetized in the N and S poles in the radial direction. A rotor and salient pole portions projecting in the axial direction on the inner wall side of a cylindrical stator core provided surrounding the rotor are formed at equal intervals in a circumferential direction, and a circumferential direction is formed between the salient pole portions. A fixed-side permanent magnet magnetized to the N pole and the S pole is provided with the same pole side facing each salient pole portion, and each salient pole portion is energized by energizing an exciting coil wound around each salient pole portion. A stator provided with an electromagnet that generates a magnetic flux acting on the rotor side from a magnetic flux acting surface formed on the tip end surface of the stator core, and the exciting coil wound around each salient pole portion of the stator core has a salient pole when energized. Is wound so that the magnetic pole generated on the tip side is the same as the magnetic pole of the adjacent fixed permanent magnet. The stator magnetic pole superimposes the magnetic flux generated from the magnetic pole of the fixed permanent magnet adjacent on both sides to the magnetic flux generated from the electromagnet by energizing the selected electromagnet, and acts from the magnetic flux acting surface of the salient pole portion, The rotor is rotationally driven by repulsion with the same-pole rotor magnetic pole and attraction with the different-pole rotor magnetic pole.
Specifically, when the excitation coil of the electromagnet at the position where the rotor magnetic pole has the same polarity as the opposing stator magnetic pole is selected and energized at the same time, the rotor magnetic pole repels, and the rotor magnetic pole is placed on the adjacent stator magnetic pole that is a different pole. By repeating the attracted energizing pattern, the rotor is urged in the rotational direction and driven to rotate.
Further, as another configuration, a movable permanent magnet magnetized to the N-pole and S-pole in the axial direction is provided on the periphery of a disc-shaped non-magnetic material provided to intersect with the rotation axis in the circumferential direction. A rotor arranged at intervals and a stator core having an U-shaped cross section in the axial direction are arranged at equal intervals in the circumferential direction surrounding the rotor with both leg portions directed in the axial direction, and at the body of each stator core. An electromagnet in which an exciting coil is wound; fixed permanent magnets provided on the outer sides of both leg portions of each stator core, which are magnetized to N-pole and S-pole in an axial direction; A stator having a ring-shaped yoke which is integrally superimposed on each other. Will be the same as the magnetic pole of the adjacent fixed permanent magnet The stator magnetic pole is superimposed on the magnetic flux generated from the magnetic pole of the fixed permanent magnet adjacent to the magnetic flux generated from the electromagnet by energizing the selected electromagnet, and is superimposed on the inner facing surfaces of both side legs. The rotor is driven by the repulsion with the same-pole rotor magnetic pole and the attraction with the different-pole rotor magnetic pole by acting from the formed magnetic flux action surface.
Specifically, when the excitation coil of the electromagnet at the position where the rotor magnetic pole has the same polarity as the opposing stator magnetic pole is selected and energized at the same time, the rotor magnetic pole repels, and the rotor magnetic pole is placed on the adjacent stator magnetic pole that is a different pole. By repeating the attracted energizing pattern, the rotor is urged in the rotational direction and driven to rotate.
[0008]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. As an embodiment of the rotating electric machine according to the present invention, an inner rotor type rotating electric machine applicable mainly to a brushless motor, for example, a stepping motor will be described.
[First embodiment]
1 is a schematic plan view of the rotating electric machine, FIG. 2 is a perspective explanatory view of the rotor, FIG. 3 is a partially enlarged plan view of the rotating electric machine in FIG. 1, and FIGS. 4 (a) to 4 (e) show the operating principle of the rotating electric machine. FIG. 5 is a timing chart exemplifying an energizing pattern to the exciting coil of the stator during one rotation of the rotor, and FIG. 6 is an explanatory diagram showing a rotor rotation position when energization switching of FIG. 5 is performed.
[0009]
First, a schematic configuration of the rotating electric machine will be described with reference to FIGS.
In FIG. 1, reference numeral 1 denotes a rotor. The rotor 1 has a cylindrical non-magnetic body 3 and a magnetic body 4 concentrically fitted outside the rotation shaft 2. Movable permanent magnets 5 are fixed at equal intervals around the outer periphery of the magnetic body 4 via a non-magnetic portion 3a. The movable permanent magnets 5 are arranged at positions that are shifted in phase by a predetermined angle in the circumferential direction. In the present embodiment, the movable permanent magnets 5 are provided at positions where the phases are different by 90 degrees for four poles. The movable permanent magnet 5 is magnetized in the radial direction with N and S poles, and the magnetic flux acting surface (outer peripheral surface) is arranged so that the N and S poles are alternated. As the movable permanent magnet 5, a rare earth magnet such as a neodymium magnet or a samarium magnet is preferably used.
[0010]
In FIG. 1, reference numeral 6 denotes a stator. The stator 6 includes a cylindrical stator core 7. As the stator core 7, a laminated core is used in which a plurality of metal magnetic plates such as a silicon steel plate punched out in a ring shape having a projection on the inside are laminated and pressed together. The stator core 7 has a salient pole portion 8 protruding from the inner peripheral side toward the axial direction. The salient pole portions 8 are provided at equal intervals (30-degree intervals) in the circumferential direction, and in the present embodiment, are protruded for 12 poles. On both sides of each salient pole portion 8, fixed-side permanent magnets 9, which are magnetized in the north and south poles in the circumferential direction, are attracted and fixed. The ratio of the number of magnetic poles between the rotor 1 and the stator 6 is configured to be 1: 3. Both side surfaces of each salient pole portion 8 adjacent to the fixed magnet 9 are formed on the inclined surface 10 in a C shape. Thereby, more magnetic flux generated from the fixed-side permanent magnet 9 can pass through the salient pole portion 8 and act on the rotor 1 from the magnetic flux acting surface (tip surface) 11. As the fixed permanent magnet 9, a rare earth magnet such as a neodymium magnet or a samarium magnet is preferably used.
[0011]
In FIG. 1, an exciting coil 12 is wound around the body of each salient pole portion 8 to form an electromagnet 13. Each electromagnet 13 generates a magnetic flux acting on the rotor 1 side from the magnetic flux acting surface 11 of each salient pole portion 8 by energizing the exciting coil 12. Each exciting coil 12 is wound so that the magnetic pole generated in the salient pole portion 8 by energization is the same as the magnetic pole of the adjacent fixed-side permanent magnet 9. Thereby, in FIG. 3, the magnetic flux generated from the magnetic poles of the fixed permanent magnets 9 adjacent on both sides is superimposed on the magnetic flux generated from the electromagnet 13 by energizing the selected electromagnet 13 of the stator core 7, and the salient pole portion 8 is formed. The rotor 1 is rotated by the repulsion with the same-pole rotor magnetic pole and the attraction with the different-pole rotor magnetic pole.
When the electromagnet 13 of the stator 6 is not energized, the rotor 1 is stationary at a position where the magnetic resistance is the smallest, that is, at a position where each rotor magnetic pole and the salient pole portion face each other (see FIG. 1). Therefore, when the excitation coil 12 of the electromagnet (in this embodiment, the excitation coil 12 whose phase is shifted by 90 degrees) at the position where the rotor magnetic pole has the same polarity as the opposed stator magnetic pole is selected and energized simultaneously, the rotor magnetic pole repels. By repeating the energization pattern in which the rotor magnetic poles are attracted to adjacent stator magnetic poles having different polarities, the rotor 1 is urged in the rotational direction and driven to rotate.
[0012]
In FIG. 2, the movable permanent magnets 5 of the rotor 1 are attracted and fixed to the outer periphery of the magnetic body 4 at four locations. The movable-side permanent magnet 5 has a chamfered outer peripheral corner, and the chamfered portion 5a abuts on the tapered guide surface 3b of the non-magnetic portion 3a, thereby preventing the movable permanent magnet 5 from dropping or displacing radially outward. . In the non-magnetic portion 3a, a non-magnetic block piece is fixed to the cylindrical magnetic body 4 by a screw 14, for example. The non-magnetic block piece may be fixed by another method such as fitting or bonding instead of the screw 14.
[0013]
Here, the operation principle of the rotating electric machine described above will be described with reference to FIGS. In FIG. 4A, a bar magnet 16 magnetized in NS is interposed between bar-shaped iron pieces 15 arranged in parallel, and both-side iron pieces 15 are attracted to form a U-shaped first magnet 17. Is formed. When the magnetic body 18 (iron plate or the like) is brought close to the longitudinal end surfaces of the iron pieces 15 on both sides of the first magnet 17, the first magnet 17 is attracted. At this time, a magnetic path indicated by a dashed arrow A in the figure is formed in the first magnet 17 and the magnetic body 18. When the magnetic material 18 is attracted to the first magnet 17, a magnetic closed circuit is formed in which the magnetic flux generated from the bar magnet 16 is closed in a rectangular shape without leakage.
[0014]
Next, in FIG. 4B, a second magnet 20 is formed by attracting a horseshoe-shaped magnet 19 whose opposite magnetic pole is magnetized to NS from outside the iron piece 15 of the first magnet 17. The second magnet 20 is attracted such that the magnetic poles of the bar magnet 16 and the horseshoe-shaped magnet 19 face the same side from both sides of the iron piece 15. Magnetic poles are formed on the longitudinal end surfaces of the iron pieces 15 on both sides of the second magnet 20, and are attracted when the magnetic body 18 (such as an iron plate) is brought close. At this time, a magnetic path indicated by a dashed arrow B generated by the horseshoe-shaped magnet 19 is formed in the second magnet 20 and the magnetic body 18 in addition to a magnetic path indicated by a dashed arrow A generated by the bar magnet 16. Since the magnetic poles of the bar magnet 16 and the horseshoe-shaped magnet 19 are arranged opposite to each other, a magnetic flux passing through the iron piece 15 and the magnetic body 18 in the same direction is formed. When the magnetic body 18 is attracted to the second magnet 20, a magnetic closed circuit in which the magnetic flux generated from the bar magnet 16 and the horseshoe magnet 19 is closed without leakage is formed. Therefore, as the magnetic flux density passing through the magnetic body 18 increases, the magnetic body 18 can be more strongly attracted than the first magnet 17.
[0015]
In FIG. 4C, when the bar magnet 16 of the second magnet 20 is replaced with the bar-shaped iron piece 15, a magnetic path shown by a solid arrow C is formed, and the magnetic flux generated from the opposite magnetic pole of the horseshoe-shaped magnet 19 becomes: A magnetically closed circuit is formed by passing the block of the iron piece 15 linearly. For this reason, even if the magnetic body 18 (iron plate or the like) is brought close to the longitudinal end surfaces of the iron pieces 15 on both sides of the second magnet 20, no magnetic path is formed in the longitudinal direction of the iron pieces 15 on both sides, so that the magnetic substance 18 is attracted. Not done.
As described above, by selectively using the case where the bar magnet 16 is interposed between the iron pieces 15 and the case where the iron piece 15 is interposed, a magnetic field is generated or not generated at the longitudinal end face of the iron piece 15, and the magnetic material is not generated. 18 can be controlled to be adsorbed and released.
[0016]
Therefore, in FIG. 4D, in the configuration of the second magnet 20, an electromagnet 21 is provided instead of the bar magnet 16, so that the third magnet 22 having the functions of FIGS. 4B and 4C is formed. it can. That is, the exciting coil 24 is wound around the body 23b of the U-shaped yoke (yoke) 23, and the horseshoe-shaped magnet 19 is attracted from the outside of both side legs 23a. The exciting coil 24 is wound around the yoke 23 so as to have the same magnetic pole as the magnetic pole of the horseshoe joint magnet 19 facing when energized.
[0017]
Therefore, when the excitation coil 24 is energized in the third magnet 22, a magnetic field similar to that shown in FIG. 4B is generated, and the electromagnet 21 and the horseshoe magnet 19 are oriented in the same direction in the longitudinal direction of the two leg portions 23a of the yoke 23. Magnetic paths A and B are formed by the generated magnetic flux, and the magnetic body 18 can be attracted to the longitudinal end surfaces of both side legs 23a, which are the magnetic poles of the yoke 23, with a strong attractive force. When the excitation coil 24 is not energized, a magnetic field similar to that shown in FIG. 4C is generated, and the magnetic flux generated by the horseshoe magnet 19 passes straight through the body 23b of the yoke 23 to form a magnetic closed circuit. Is done. For this reason, even if the magnetic body 18 (such as an iron plate) is brought close to the longitudinal end surfaces of the both leg portions 23 a of the yoke 23, it is not attracted.
[0018]
The stator 6 of the present embodiment is an application of the configuration of the third magnet 22 shown in FIG. That is, in FIG. 3, the stator core 7 corresponding to the yoke 23 is provided with salient pole portions 8 projecting in the axial direction at equal intervals in the circumferential direction. An exciting coil 12 is wound around each salient pole portion 8 to form an electromagnet 13. In addition, instead of the horseshoe-shaped magnet 19, fixed permanent magnets 9 are fixedly provided on both ends of the salient pole portion 8. The magnetic pole of the fixed-side permanent magnet 9 has the same magnetic pole as the magnetic pole generated in the salient pole portion 8 when the excitation coil 12 of the electromagnet 13 is energized (for example, the N pole in the case of the stator pole P1, the P pole in the case of the stator pole P1 '). Is provided so as to face the salient pole portion 8.
[0019]
The magnetic circuit formed on the stator poles P1, P1 ', P2 of the stator core 7 will be described. As long as the excitation coil 12 of each electromagnet 8 provided on the stator magnetic poles P1 and P1'P2 is not energized, the magnetic flux generated from the NS magnetic pole of each fixed-side permanent magnet 9 between the salient poles 8 is adjacent to the adjacent salient pole 8 The magnetic closed circuits are formed in different directions from each other as shown by broken-line arrows L1, L1 ', and L6' in FIG. At this time, no magnetic flux leaks from the stator 6 side to the rotor 1.
[0020]
When only the exciting coil 12 of the stator magnetic pole P1 is energized, the magnetic circuits indicated by the dashed arrows L1 and L6 ′ are broken, and the electromagnet 13 magnetizes the tip side of the salient pole portion 8 to the N pole, and the magnetic flux generated by the electromagnet 13 (arrow) E) and the magnetic flux (arrow M) generated from the magnetic poles (N poles) of the fixed permanent magnets 9 on both sides are superimposed and act on the rotor 1 side from the magnetic flux acting surface (tip surface) 11 of the salient pole portion 8. It has become. Since the rear end side of the salient pole portion 8 of the stator magnetic pole P1 is magnetized to the S pole, the magnetic flux from the magnetic closed circuit L1'L6 (see FIG. 1) is also converged on the S pole side through the arc portion of the stator core 7. be able to. As a result, the rotor pole R1 of the same pole (N pole) facing the stator pole P1 repels and is attracted to the stator pole P2 '(see FIG. 1) magnetized by the adjacent pole (S pole). 3, a strong rotational torque is generated in the direction of the arrow in FIG.
[0021]
Next, an example of an energization pattern to the exciting coil of the stator 6 during one rotation of the rotor 1 of the rotating electric machine will be described based on a timing chart shown in FIG. 5 and with reference to a rotational position of the rotor of FIG. . In FIG. 5, the upper side shows the stator magnetic poles, and the lower side shows the rotor magnetic poles. The rotation direction of the rotor 1 is assumed to rotate in the direction of the arrow in FIG. 6 (clockwise direction), and the upper-stage stator poles are denoted by P1, P1 'to P6, P6', and the lower-stage The rotor magnetic poles will be described as R1 to R4. Note that arrows shown on the stator core 7 in FIG. 6 indicate directions of magnetic fluxes generated in the stator core 7.
[0022]
First, in FIG. 6A, when the rotor magnetic pole R1 is located at a position facing the stator magnetic poles P1, P1 ', the exciting coils 12 corresponding to the stator magnetic poles P1, P2', P4, P5 'in FIG. At the same time. At this time, the rotor magnetic poles R1 to R4 have the same polarity as the adjacent stator magnetic poles (R1 and P1, R2 and P2 ', R3 and P4, R4 and P5'), and the energized adjacent stator of the opposite pole side is repelled. The magnetic poles (R1 is at P2 ', R2 is at P4, R3 is at P5', and R4 is at P1) are rotated in the direction of the arrow.
As shown by arrows in FIG. 6 (a), between the stator poles that are not energized (P1 ′ and P2, P3 and P3 ′, P4 ′ and P5, P6 and P6 ′), A magnetically closed circuit is formed on the stator core 7 including the pole portions 8.
[0023]
Then, the rotor 1 rotates clockwise by 60 degrees and rotates to the position shown in FIG. Here, the excitation coils 12 corresponding to the stator magnetic poles P2, P3 ', P5, P6' in FIG. 5B are simultaneously energized. At this time, the rotor magnetic poles R1 to R4 have the same polarity (R1 and P2, R2 and P3 ', R3 and P4, R4 and P5') as the adjacent stator magnetic poles, and the energized adjacent different pole side stators are repelled. The magnetic poles (R1 is at P3 ', R2 is at P5, R3 is at P6', and R4 is at P2) are rotated in the direction of the arrow.
As shown by arrows in FIG. 6B, between the stator magnetic poles that are not energized (P1 and P1 ′, P2 ′ and P3, P4 and P4 ′, and P5 ′ and P6), A magnetically closed circuit is formed on the stator core 7 including the salient pole portions 8.
[0024]
Then, the rotor 1 further rotates clockwise by 60 degrees and rotates to the position shown in FIG. 6C. Here, the excitation coils 12 corresponding to the stator magnetic poles P1 ', P3, P4', and P6 in FIG. 5C are simultaneously energized. At this time, the rotor magnetic poles R1 to R4 have the same poles (R1 and P3, R2 and P4 ', R3 and P6, R4 and P1') as the adjacent stator poles, and the energized adjacent poles on the opposite pole side are repelled. The magnetic poles (R1 is at P4 ', R2 is at P6, R3 is at P1', and R4 is at P3) are rotated in the direction of the arrow.
As shown by arrows in FIG. 6 (c), between the stator poles that are not energized (P2 and P2 ', P3' and P4, P5 and P5 ', P6' and P1), A magnetically closed circuit is formed on the stator core 7 including the salient pole portions 8.
[0025]
Then, the rotor 1 further rotates clockwise by 60 degrees and rotates to the position shown in FIG. Here, the excitation coils 12 corresponding to the stator magnetic poles P1, P2 ', P4, P5' in FIG. 5D are simultaneously energized. At this time, the rotor magnetic poles R1 to R4 have the same poles (R1 and P4, R2 and P5 ', R3 and P1, R4 and P2') as the adjacent stator poles, and the energized adjacent stators on the opposite pole side are repelled. The magnetic poles (R1 at P5 ', R2 at P6', R3 at P2 ', and R4 at P4) rotate in the direction of the arrow.
As shown by arrows in FIG. 6D, between the stator magnetic poles (P1 'and P2, P3 and P3', P4 'and P5, and P6 and P6') that are not energized, the fixed-side permanent magnet 9 and A magnetically closed circuit is formed on the stator core 7 including the pole portions 8.
[0026]
Then, the rotor 1 further rotates clockwise by 60 degrees and rotates to the position shown in FIG. Here, the excitation coils 12 corresponding to the stator magnetic poles P2, P3 ', P5, P6' in FIG. 5E are simultaneously energized. At this time, the rotor magnetic poles R1 to R4 have the same polarity as the adjacent stator magnetic poles (R1 and P5, R2 and P6 ', R3 and P2, R4 and P3'), and the energized adjacent stators on the different pole side are repelled. The magnetic poles (R1 is at P6 ', R2 is at P2, R3 is at P3', and R4 is at P5) are rotated in the direction of the arrow.
As shown by the arrow in FIG. 6 (e), between the stator poles that are not energized (P1 and P1 ', P2' and P3, P4 and P4 ', P5' and P6), A magnetically closed circuit is formed on the stator core 7 including the pole portions 8.
[0027]
Then, the rotor 1 further rotates clockwise by 60 degrees and rotates to the position shown in FIG. Here, the excitation coils 12 corresponding to the stator magnetic poles P1 ', P3, P4', and P6 in FIG. 5F are simultaneously energized. At this time, the rotor magnetic poles R1 to R4 have the same polarity as the adjacent stator magnetic poles (R1 and P6, R2 and P1 ', R3 and P3, R4 and P4'), and the energized adjacent stators on the different pole side are repelled. The magnetic poles (R1 is at P1 ', R2 is at P3, R3 is at P4', and R4 is at P6) and rotate in the direction of the arrow.
As shown by arrows in FIG. 6 (f), between the stator poles that are not energized (P2 and P2 ', P3' and P4, P5 and P5 ', P6' and P1). A magnetically closed circuit is formed on the stator core 7 including the pole portions 8.
[0028]
When the rotor 1 further rotates by 60 degrees, the rotor 1 returns to the position shown in FIG. Thereafter, the above-described energization pattern for the excitation coil 12 of the stator 6 is repeatedly performed. The control of energization of each excitation coil 12 of the stator 6 is performed by a control unit (not shown) based on a rotational position of the rotor 1 based on a magnetic sensor such as a Hall element or a rotational position detection using a rotary encoder.
[0029]
[Second embodiment]
Next, another example in which the number of magnetic poles of the rotor 1 and the stator 6 is changed will be described with reference to FIGS. The same members as those in the first embodiment are denoted by the same reference numerals, and the description is used. 7 is a schematic plan view of the rotating electric machine, FIG. 8 is a timing chart illustrating an energization pattern to the stator coil during a half rotation of the rotor, and FIG. 9 is a rotation of the rotor when energization switching of FIG. 8 is performed. It is explanatory drawing which shows a position.
[0030]
FIG. 7 illustrates a case where the ratio of the number of magnetic poles between the rotor 1 and the stator 6 is set to 1: 2. In the rotor 1, the movable permanent magnets 5 are provided for eight poles R1 to R8 at positions shifted in phase by 45 degrees. The movable permanent magnet 5 is magnetized in the radial direction with N and S poles, and the magnetic flux acting surface (outer peripheral surface) is arranged so that the N and S poles are alternated. The salient pole portions 8 of the stator 6 are provided at equal intervals (22.5 degrees) in the circumferential direction. In the present embodiment, 16 poles are protruded from the stator magnetic poles P1, P1 'to P8, P8'. Have been. On both sides of each salient pole portion 8, fixed-side permanent magnets 9, which are magnetized to the N pole and the S pole in the circumferential direction, are fixed.
[0031]
Next, with respect to an example of an energization pattern to the exciting coil of the stator 6 during the rotation of the rotor 1 of the rotary electric machine by 回 転, refer to the rotational position of the rotor 1 in FIG. 9 based on a timing chart shown in FIG. I will explain it. 8, the upper side shows the stator magnetic poles, and the lower side shows the rotor magnetic poles. The rotation direction of the rotor 1 is assumed to rotate in the direction of the arrow (clockwise) in FIG. 9, and the upper-stage stator poles are denoted by P1, P1 ′ to P8, P8 ′, and the lower-stage The description will be made assuming that the rotor magnetic poles are R1 to R8. Note that arrows shown on the stator core 7 in FIG. 9 indicate directions of magnetic fluxes generated in the stator core 7.
[0032]
First, in FIG. 9A, when the electromagnet 13 of the stator 6 is not energized, the rotor 1 is stationary at a position where the magnetic resistance is the smallest, that is, a position where each rotor magnetic pole and the salient pole portion face each other. When the rotor magnetic pole R1 is located at a position facing the stator magnetic pole P1, the exciting coils 12 corresponding to the stator magnetic poles P1, P1 ', P3, P3', P5, P5 ', P7, P7' in FIG. Turn on electricity. At this time, the rotor magnetic poles R1 to R8 have the same polarity as the adjacent stator magnetic poles (R1 and P1, R2 and P1 ', R3 and P3, R4 and P3', R5 and P5, R6 and P5 ', R7 and P7, R8 And P7 ') are repelled, and attracted to the adjacent stator poles on the opposite pole side (R1 is set to P1', R3 is set to P3 ', R5 is set to P5', and R7 is set to P7 '). Rotate in the direction.
In addition, between the stator poles that are not energized (P2 and P2 ', P4 and P4', P6 and P6 ', P8 and P8'), the fixed-side permanent magnet 9 and the two-sided projecting magnets are indicated by arrows in FIG. A magnetically closed circuit is formed on the stator core 7 including the pole portions 8.
[0033]
Then, the rotor 1 rotates clockwise by 22.5 degrees and rotates to the position shown in FIG. 9B. Here, the exciting coils 12 corresponding to the stator magnetic poles P2 ', P3, P4', P5, P6 ', P7, P8', and P1 in FIG. 8B are simultaneously energized. At this time, the rotor magnetic poles R1 to R8 have the same polarity as the adjacent stator magnetic poles (R1 and P1, R2 and P2 ', R3 and P3, R4 and P4', R5 and P5, R6 and P6 ', R7 and P7, R8 And P8 ') are repelled, and attracted to the adjacent stator poles on the different pole side (R2 is set to P3, R4 is set to P5, R6 is set to P7, R8 is set to P1), and rotated in the direction of the arrow. .
In addition, between the stator poles that are not energized (P1 'and P2, P3' and P4, P5 'and P6, P7' and P8), as shown by the arrow in FIG. A magnetically closed circuit is formed on the stator core 7 including the pole portions 8.
[0034]
Then, the rotor 1 further rotates clockwise by 22.5 degrees to the position shown in FIG. 9C. Here, the exciting coils 12 corresponding to the stator magnetic poles P2, P2 ', P4, P4', P6, P6 ', P8, P8' in FIG. 8C are simultaneously energized. At this time, the rotor magnetic poles R1 to R8 have the same pole as the adjacent stator magnetic poles (R1 and P2, R2 and P2 ', R3 and P4, R4 and P4', R5 and P6, R6 and P6 ', R7 and P8, R8 And P8 ') are repelled, and are attracted to the energized adjacent stator poles (R1 to P2', R3 to P4 ', R5 to P6', and R7 to P8 '), and arrows Rotate in the direction.
In addition, between the stator poles that are not energized (P1 and P1 ', P3 and P3', P5 and P5 ', P7 and P7'), as shown by the arrow in FIG. A magnetically closed circuit is formed on the stator core 7 including the pole portions 8.
[0035]
Then, the rotor 1 further rotates clockwise by 22.5 degrees and rotates to the position shown in FIG. 9D (1/4 rotation). Here, the exciting coils 12 corresponding to the stator magnetic poles P1 ', P2, P3', P4, P5 ', P6, P7' and P8 in FIG. 8D are simultaneously energized. At this time, the rotor magnetic poles R1 to R8 have the same polarity as the adjacent stator magnetic poles (R1 and P3, R2 and P3 ', R3 and P4, R4 and P5', R5 and P5, R6 and P7 ', R7 and P8, R8 And P1 ') are repelled, and attracted to the adjacent stator poles on the different pole side (R2 is at P4, R4 is at P5, R6 is at P8, and R8 is at P2) and rotated in the direction of the arrow. .
In addition, between the stator poles (P2 'and P3, P4' and P5, P6 'and P7, P8' and P1) which are not energized, as shown by the arrow in FIG. A magnetically closed circuit is formed on the stator core 7 including the pole portions 8.
[0036]
Hereinafter, the energization patterns ((e) to (h) in FIG. 8) when the rotor 1 further rotates by 回 転 are the same as those in FIGS. 8 (a) to (d) described above, and description thereof will be omitted. The rotational positions of the rotor 1 at this time are shown in FIGS. By repeating such an energizing pattern four times, the rotor 1 makes one rotation. By increasing the number of magnetic poles of the rotor 1 and the stator 6, fine control of the rotation angle can be performed.
[0037]
[Third embodiment]
Next, another example of the rotating electric machine will be described with reference to FIGS. FIG. 10A is an exploded perspective view of the stator showing a state in which the permanent magnet and the yoke are removed from one leg of the stator core, FIG. 10B is a side view of the stator, and FIG. FIG. 10D is a perspective view of the rotor.
[0038]
In FIG. 10D, the rotor 25 is provided with a disc-shaped non-magnetic body 27 provided to intersect the rotation shaft 26. At the periphery of the non-magnetic member 27, eight movable permanent magnets 28 (eight poles), which are magnetized in the N and S poles in the axial direction, are arranged at equal intervals in the circumferential direction. The movable permanent magnets 28 are arranged such that the magnetic flux acting surfaces formed at both ends in the axial direction have N poles and S poles alternately. As the movable permanent magnet 28, a rare earth magnet such as a neodymium magnet or a samarium magnet is preferably used. In addition, the outer corner portion of the movable side permanent magnet 28 is chamfered, and the chamfered portion 28a abuts on the tapered guide surface 27a of the non-magnetic body 27 to suppress the radially outward drop and displacement. ing.
[0039]
Next, the configuration of the stator 29 will be described with reference to FIGS. Stator cores 30 each having a U-shaped cross section in the axial direction are disposed at 16 locations (for 16 poles) at equal intervals in the circumferential direction surrounding the rotor 25 with both leg portions 30a directed in the axial direction (FIG. 10). (A)). As the stator core 30, a laminated core in which a plurality of metal magnetic plates such as silicon steel plates are laminated and pressed together and a block-shaped core such as a yoke is used. An exciting coil 31 is wound around a body 30 b of each stator core 30 to form an electromagnet 32. Fixed permanent magnets 33, which are magnetized in the N- and S-poles in the axial direction, are provided outside both leg portions 30a of each stator core 30, respectively. As the fixed permanent magnet 33, a rare earth magnet such as a neodymium magnet or a samarium magnet is preferably used (see FIG. 10C). A ring-shaped yoke (yoke) 34 is provided on the outside of the fixed-side permanent magnet 33 so as to be integrated with each other. The ring-shaped yoke 34 connects the electromagnets 32 in the circumferential direction via the fixed-side permanent magnets 33 to form a magnetic closed circuit that connects the outer magnetic poles of the fixed-side permanent magnets 33 to each other. Thus, in a state in which the electromagnets 32 are not energized, the fixed permanent magnets 33 adjacent to each other in the circumferential direction form a magnetic closed circuit through the stator core 30 so that the magnetic flux generated from the fixed permanent magnets 33 does not leak outside. (See FIG. 10B).
[0040]
The exciting coil 31 wound around the body 30b of the stator core 30 is wound by energization so as to have the same polarity as the magnetic poles of the fixed permanent magnets 33 adjacent to the magnetic poles formed on both side legs 30a of the stator core 30. ing. For this reason, the stator magnetic pole superimposes the magnetic flux generated from the magnetic pole of the fixed permanent magnet 33 adjacent to the magnetic flux generated from the electromagnet 32 by energizing the selected electromagnet 32, and superimposes the magnetic flux generated on the inner facing surfaces of the both leg portions 30 a. The rotor 25 is rotated by the repulsion with the rotor magnetic pole of the same polarity and the attraction with the rotor magnetic pole of the different polarity.
When the electromagnet 32 of the stator 29 is not energized, the rotor 25 is stationary at a position where the magnetic resistance is the smallest, that is, at a position where each rotor magnetic pole and the salient pole portion face each other. Therefore, when the excitation coil 31 of the electromagnet (the excitation coil whose phase is shifted by 22.5 in this embodiment) 31 at the position where the rotor magnetic pole has the same polarity as the opposed stator magnetic pole is selected and energized simultaneously, the rotor magnetic pole repels. Then, by repeating the energization pattern in which the rotor magnetic pole is attracted to the adjacent stator magnetic pole having a different polarity, the rotor 25 is urged in the rotational direction and is driven to rotate. The energization pattern for the excitation coil 31 is the same as in the second embodiment, and a description thereof will be omitted.
[0041]
As described above, when the electromagnets 13 and 32 provided on the stators 6 and 29 are energized, the magnetic flux generated from the magnetic poles of the fixed permanent magnets 9 and 33 is superimposed on the magnetic flux generated from the electromagnets 13 and 32. A large rotating torque is obtained by acting on the stator magnetic poles to the rotor magnetic poles and utilizing the repulsive and attractive forces between the magnetic poles. Further, in the electromagnets 13 and 32 that are not energized, a magnetic closed circuit is formed through the stator cores 7 and 30 and no magnetic flux leaks, so that it is possible to provide a rotating electric machine with high rotation efficiency and low energy loss.
Also, when an excitation coil at a position where the rotor magnetic pole is the same as the opposed stator magnetic pole is selected and energized at the same time, the magnetic poles repel each other, and the energizing pattern attracted to the adjacent stator magnetic pole having a different polarity is repeated. Accordingly, it is possible to provide a rotating electric machine in which the rotors 1 and 25 are surely urged in the rotational direction and are driven to rotate, and the rotational position is easily controlled.
[0042]
The present invention is not limited to the above embodiments, and the number of poles of the rotor 1 and the stator 5 and the energization pattern can be arbitrarily changed. Of course, many modifications can be made without departing from the spirit of the law.
[0043]
【The invention's effect】
According to the configuration of the rotating electric machine according to the present invention, the electromagnet provided on the stator and the magnetic flux generated from the magnetic poles of the fixed permanent magnet are superimposed and act on the rotor magnetic poles without leakage through the stator magnetic poles, and the repulsive force between the magnetic poles and A large rotating torque can be obtained using the suction force. Further, in each electromagnet in which the stator is not energized, the magnetic flux generated from the fixed-side magnet forms a magnetically closed circuit through the stator core and the magnetic flux does not leak to the outside, so that it is possible to provide a rotating electric machine with high rotation efficiency and low energy loss. Also, when an excitation coil at a position where the rotor magnetic pole is the same as the opposed stator magnetic pole is selected and energized at the same time, the magnetic poles repel each other, and the energizing pattern attracted to the adjacent stator magnetic pole having a different polarity is repeated. Accordingly, it is possible to provide a rotating electric machine in which the rotor is reliably urged in the rotational direction and is driven to rotate, so that the rotational position can be easily controlled. Therefore, with a simple configuration, it is possible to provide a highly versatile brushless motor or generator such as a stepping motor or a servo motor that realizes high torque with energy saving.
[Brief description of the drawings]
FIG. 1 is a schematic plan view of a rotating electric machine according to a first embodiment.
FIG. 2 is an explanatory perspective view of a rotor.
FIG. 3 is a partially enlarged plan view of the rotating electric machine of FIG. 1;
FIG. 4 is an explanatory diagram illustrating an operation principle of the rotating electric machine.
FIG. 5 is a timing chart illustrating an energization pattern to an exciting coil of a stator during one rotation of a rotor.
FIG. 6 is an explanatory diagram showing a rotational position of a rotor when the energization switching of FIG. 5 is performed.
FIG. 7 is a schematic plan view of a rotating electric machine according to a second embodiment.
FIG. 8 is a timing chart illustrating an energization pattern to an excitation coil of a stator during a half rotation of a rotor.
FIG. 9 is an explanatory diagram showing the rotational position of the rotor when the energization switching of FIG. 8 is performed.
FIG. 10 is an exploded perspective view of a stator according to a third embodiment, a side view of the stator, a radial cross-sectional view of the stator, and a perspective view of a rotor.
[Explanation of symbols]
1,25 rotor
2,26 rotation axis
3,27 non-magnetic material
3a Non-magnetic part
4, 18 Magnetic material
5, 28 Movable permanent magnet
6, 29 Stator
7, 30 Stator core
8 salient pole
9, 33 Fixed permanent magnet
10 Slope
11, 30c Magnetic flux action surface
12, 24, 31 excitation coil
13,21,32 Electromagnet
14 screws
15 Iron pieces
16 bar magnet
17 First magnet
19 Horseshoe magnet
20 Second magnet
22 Third magnet
23, 34 York
30a leg
30b torso

Claims (5)

A rotor having a movable permanent magnet fixed to the outer periphery of a cylindrical magnetic body fitted coaxially with the rotation axis via a non-magnetic portion at equal intervals and radially magnetized to N and S poles; ,
Salient pole portions projecting in the axial direction are formed at equal intervals in the circumferential direction on the inner wall side of the cylindrical stator core provided surrounding the rotor, and N poles are circumferentially arranged between the salient pole portions. A fixed-side permanent magnet magnetized to the S pole is provided with the same pole side facing each salient pole portion, and the leading end surface of each salient pole portion is energized by energizing an exciting coil wound around each salient pole portion. A stator provided with an electromagnet that generates magnetic flux acting on the rotor side from the magnetic flux acting surface formed on the
The exciting coil wound around each salient pole portion of the stator core is wound so that a magnetic pole generated on the tip side of the salient pole portion by energization has the same pole as a magnetic pole of an adjacent fixed permanent magnet. The magnetic pole superimposes the magnetic flux generated from the magnetic pole of the fixed permanent magnet adjacent on both sides to the magnetic flux generated from the electromagnet by energizing the selected electromagnet, and acts from the magnetic flux acting surface of the salient pole portion to act on the same magnetic pole. A rotating electric machine wherein a rotor is driven to rotate by repulsion with a rotor magnetic pole and attraction with a different magnetic pole. An energization pattern in which the rotor magnetic pole repels when the excitation coil of the electromagnet at the position where the rotor magnetic pole is the same as the opposing stator magnetic pole is energized and energized at the same time, and the rotor magnetic pole is attracted to the adjacent stator magnetic pole which is a different pole. 2. The rotating electric machine according to claim 1, wherein the rotor is urged in a rotational direction and is driven to rotate by repeating the above. 3. The rotating electric machine according to claim 1, wherein both side surfaces of each salient pole portion adjacent to the fixed-side magnet are formed as inclined surfaces. 4. A rotor in which movable-side permanent magnets magnetized on the N-pole and S-pole in the axial direction are arranged at equal intervals in the circumferential direction on the periphery of a disc-shaped non-magnetic material provided to intersect with the rotation axis; ,
An electromagnet in which stator cores having a U-shaped cross section in the axial direction are disposed at equal intervals in the circumferential direction surrounding the rotor with both leg portions directed in the axial direction, and an exciting coil wound around the body of each stator core. And fixed permanent magnets provided on the outer sides of both legs of each stator core, the fixed permanent magnets being magnetized in the N- and S-poles in the axial direction, and rings integrally integrated on the outer sides of the fixed permanent magnets, respectively. A yoke and a stator with a yoke,
The exciting coil wound around the body of the stator core is wound so as to have the same polarity as the magnetic poles of the fixed permanent magnets adjacent on both sides to the magnetic poles formed on both side legs of the stator core by energization, The stator magnetic pole overlaps the magnetic flux generated from the selected permanent magnet with the magnetic flux generated from the fixed permanent magnet adjacent to the magnetic flux generated by energizing the selected electromagnet. A rotating electric machine wherein the rotor is driven to rotate by repulsion with a rotor magnetic pole of the same polarity and suction with a rotor magnetic pole of a different polarity. An energization pattern in which the rotor magnetic pole repels when the excitation coil of the electromagnet at the position where the rotor magnetic pole is the same as the opposing stator magnetic pole is energized and energized at the same time, and the rotor magnetic pole is attracted to the adjacent stator magnetic pole which is a different pole. 5. The rotating electric machine according to claim 4, wherein the rotor is urged in the rotational direction and is driven to rotate by repeating the above.

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