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In a magnet-exciting rotating electric machine system, a rotor surface has magnetic salient poles and island-shaped magnetic poles alternately in circumferential direction, and the island-shaped magnetic poles are constituted so that magnetic flux coming from an external source does not flow through

In a magnet-exciting rotating electric machine system, a rotor surface has magnetic salient poles and island-shaped magnetic poles alternately in circumferential direction, and the island-shaped magnetic poles are constituted so that magnetic flux coming from an external source does not flow through. A magnetic excitation part magnetizes the island-shaped magnetic poles and the magnetic salient poles collectively in the same direction, and then control a flux amount flowing through an armature. The armature has armature coils that face the magnetic salient pole and the island-shaped magnetic pole simultaneously so that driving torque fluctuation or power generation voltage waveform distortion is controlled. The magnetic excitation part changes magnetization state of a field magnet irreversibly, or changes an excitation current to an excitation coil to control a flux crossing the armature.

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1. A rotating electric machine system having a rotor and an armature facing radially each other, the rotating electric machine system comprising: the rotor having island-shaped magnetic poles and magnetic salient poles alternately disposed in a circumferential direction on its plane facing the armat

1. A rotating electric machine system having a rotor and an armature facing radially each other, the rotating electric machine system comprising: the rotor having island-shaped magnetic poles and magnetic salient poles alternately disposed in a circumferential direction on its plane facing the armature;the armature having armature coils disposed in a circumferential direction on its plane facing the rotor, anda magnetic excitation part for magnetizing the island-shaped magnetic poles and the magnetic salient poles collectively in the same direction;wherein the rotor has an isolation member including a permanent magnet and/or a non-magnetic member at least within the island-shaped magnetic poles to prevent passage of magnetic flux coming from outside, thickness of the isolation member within the island-shaped magnetic pole is larger than a thickness of the isolation member within the magnetic salient pole so that magnetic flux coming from the magnetic excitation part should be hard to flow through the island-shaped magnetic pole;the island-shaped magnetic poles are configured so as to be magnetized in about a same axial direction by at least one of a permanent magnet adjacent to the island-shaped magnetic pole and a permanent magnet within the island-shaped magnetic pole;the armature coils are grouped into a first armature magnetic pole group and a second armature magnetic pole group, and in an armature coil pair of the same phase in the first armature magnetic pole group and the second armature magnetic pole group which armature coils are supplied with driving current simultaneously, the armature coils of the armature coil pair are arranged such that the armature coil of one of the armature coil pair opposes the island-shaped magnetic pole when the armature coil of the other one of the armature coil pair opposes the magnetic salient pole, and the armature coils of the armature coil pair are connected to generate magnetic fluxes of mutually opposite directions when current flows;the magnetic excitation part has either one of an excitation coil and a field magnet at least;both ends of the magnetic excitation part are magnetically coupled respectively with one of the rotor and the armature arranged at an outermost circumference and one of the rotor and the armature arranged at an innermost circumference so that a magnetic flux from one end of the magnetic excitation part may return to the other end thereof through the armature and the magnetic salient poles; andan amount of magnetic flux flowing through the armature is controlled by changing an amount of magnetic flux supplied from the magnetic excitation part in accordance with an output of the rotating electric machine system so that the output is optimized. 2. The rotating electric machine system according to claim 1, wherein the rotor faces the armature through a single air gap;the armature has the armature coils at a magnetic yoke in circumferential direction facing the rotor;the rotor has the island-shaped magnetic poles and the magnetic salient poles alternately at a cylindrical magnetic substrate in a circumferential direction facing the armature;both ends of the magnetic excitation part are magnetically coupled respectively with the cylindrical magnetic substrate of the rotor and the magnetic yoke so that a magnetic flux coming from one end of the magnetic excitation part flows through the cylindrical magnetic substrate and the magnetic salient poles, the magnetic yoke, and returns to other end of the magnetic excitation part. 3. The rotating electric machine system according to claim 1, wherein a first armature and a rotor and a second armature are disposed radially to make a line in the order as recited here;the rotor has the island-shaped magnetic poles and the magnetic salient poles alternately in a circumferential direction facing the first armature and the second armature;each of the first armature and the second armature has the armature coils at a magnetic yoke in a circumferential direction facing the rotor;both ends of the magnetic excitation part are magnetically coupled respectively with the magnetic yoke of two armatures so that a magnetic flux coming from one end of the magnetic excitation part flows through the magnetic yoke of the first armature, the magnetic salient poles, the magnetic yoke of the second armature, and returns to other end of the magnetic excitation part. 4. The rotating electric machine system according to claim 1, wherein the island-shaped magnetic poles and the magnetic salient poles are constituted so that the cylindrical magnetic substrate is sectioned into circumferential direction by one of a permanent magnet and a magnet assembly having magnetization in a circumferential direction, and are magnetized in different polarity each other. 5. The rotating electric machine system according to claim 1, wherein the magnet assembly which, consisting of permanent magnets placed on two sides of a magnetic substance, is disposed between the island-shaped magnetic pole and the magnetic salient pole;the magnet assembly has a non-magnetic member so that magnetic flux coming from the magnetic excitation part should be hard to flow through the magnet assembly. 6. The rotating electric machine system according to claim 1, wherein a first armature having the first armature magnetic pole group faces the rotor, and a second armature having the second armature magnetic pole group faces the rotor;in an armature coil pair of the same phase in the first armature and the second armature, the armature coils of the armature coil pair are arranged such that the armature coil of one of the armature coil pair opposes the island-shaped magnetic pole when the armature coil of other one of the armature coil pair opposes the magnetic salient pole, and the armature coils of the armature coil pair are connected in series to generate magnetic flux of mutually opposite direction when current flows. 7. The rotating electric machine system according to claim 1, wherein the armature has the first armature magnetic pole group and the second armature magnetic pole group in a different circumferential position;in an armature coil pair of the same phase in the first armature magnetic pole group and the second armature magnetic pole group, the armature coils of the armature coil pair are arranged such that the armature coil of one of the armature coil pair opposes the island-shaped magnetic pole when the armature coil of other one of the armature coil pair opposes the magnetic salient pole, and the armature coils of the armature coil pair are connected in series to generate magnetic flux of mutually opposite direction when current flows. 8. The rotating electric machine system according to claim 1, wherein the magnetic excitation part has a field magnet and an exciting coil to change magnetization of the field magnet;the magnetic excitation part is constituted so that a magnetic flux coming from one of N pole and S pole of the field magnet returns to other pole of the field magnet through the armature and the magnetic salient poles of the rotor;an excitation current is supplied to the excitation coil, and a magnetization state of the field magnet is changed irreversibly, and an amount of the magnetic flux flowing through the armature is controlled according to an output of the rotating electric machine system so that the output is optimized. 9. The rotating electric machine system according to claim 8, wherein the field magnet has magnet elements having a different product of length and coercivity from each other disposed between a magnetic member;the magnet elements are connected in parallel by the magnetic member;the magnet element has one of a first magnetization and a second magnetization that are provided at opposite directions from each other;the magnet element having the first magnetization magnetizes the magnetic salient pole in opposite direction to the magnetization direction in the island-shaped magnetic pole. 10. The rotating electric machine system according to claim 8, wherein a main magnetic flux path and an excitation magnetic flux path are connected to the field magnet in parallel;the main magnetic flux path is a path in which a magnetic flux flowing from one of N pole and S pole of the field magnet returns to other pole of the field magnet through the magnetic salient poles and the armature, and the excitation magnetic flux path is a path in which a magnetic flux flowing from one pole of the field magnet returns to other pole of the field magnet mainly in the magnetic excitation part;the excitation coil is disposed to generate a magnetic flux in a path including the excitation magnetic flux path and the field magnet. 11. The rotating electric machine system according to claim 8, wherein the field magnet has a first magnet element and a second magnet element with mutually different coercivity and a magnetic member;the first magnet element and the second magnet element are connected in parallel by the magnetic member;the excitation coil is disposed to cause a magnetic flux in closed magnetic flux path composed of the first magnet element and the second magnet element and the magnetic member. 12. The rotating electric machine system according to claim 8, wherein a flux adjustment current of a degree which does not make the field magnet cause an irreversible magnetization change is supplied to the excitation coil in each magnetization state of the field magnet;an induced flux by the flux adjustment current is superimposed on a flux coming from the field magnet so that magnetic flux amount flowing through the armature is adjusted. 13. The rotating electric machine system according to claim 8, wherein a permanent magnet is disposed as the isolation member to prevent passage of magnetic flux coming from the magnetic excitation part within the island-shaped magnetic pole;an excitation current is supplied to an armature coil facing the island-shaped magnetic pole so that a magnetization of the permanent magnet is changed. 14. The rotating electric machine system according to claim 8, further comprising a control device; wherein a rotational force is an input;the control device supplies the excitation current to the excitation coil so that a magnetic pole area of the first magnetization is decreased when a power generation voltage induced in the armature coils is larger than a predetermined value and an amount of a magnetic flux flowing through the armature is to be reduced, and supplies the excitation current to the excitation coil so that a magnetic pole area of the first magnetization is increased when the power generation voltage induced in the armature coils is smaller than the predetermined value and an amount of a magnetic flux flowing through the armature is to be increased; andthe power generation voltage is controlled to be the predetermined value. 15. The rotating electric machine system according to claim 8, further comprising a control device; wherein a current supplied to the armature coils is an input, andthe control device supplies the excitation current to the excitation coil so that a magnetic pole area of the first magnetization is decreased when a rotational speed is larger than a predetermined value and an amount of a magnetic flux flowing through the armature is to be reduced, and supplies the excitation current to the excitation coil so that a magnetic pole area of the first magnetization is increased when the rotational speed is smaller than the predetermined value and an amount of a magnetic flux flowing through the armature is to be increased; andthereby a rotational force is optimally controlled. 16. The rotating electric machine system according to claim 8, further comprising a control device; wherein a current supplied to the armature coils is an input, a rotational force is an output,when a rotational speed is to be reduced, the control device connects a battery with the armature coils and supplies the excitation current to the excitation coil so that a magnetic pole area of the first magnetization is increased, and an amount of a magnetic flux flowing through the armature is increased; anda rotational energy is taken out as a power generation output. 17. The rotating electric machine system according to claim 1, wherein the magnetic excitation part has an excitation coil and an excitation flux path member;both ends of the excitation flux path member are magnetically coupled respectively with one of the rotor and the armature arranged at an outermost circumference and one of the rotor and the armature arranged at an innermost circumference;the excitation coil is constituted so as to induce a magnetic flux in a magnetic flux path including the excitation flux path member and the magnetic salient poles of the rotor and the armature; andan excitation current is supplied to the excitation coil, and a magnetic flux amount flowing through the armature is controlled according to an output of the rotating electric machine system so that the output is optimized. 18. The rotating electric machine system according to claim 17, wherein the magnetic excitation part has a magnetic gap in a magnetic flux path including the excitation flux path member so that magnetic flux from a permanent magnet in the island-shaped magnetic pole should not be short-circuited through the excitation flux path member. 19. A method for controlling a magnetic flux amount flowing through an armature of a rotating electric machine including a rotor and an armature facing radially each other, the rotor having island-shaped magnetic poles and magnetic salient poles separated by at least one of a magnetic gap and a permanent magnet in a circumferential direction on its plane facing the armature, the armature having armature coils disposed in a circumferential direction on its plane facing the rotor, and a magnetic excitation part for magnetizing the island-shaped magnetic poles and the magnetic salient poles collectively in same direction, said method comprising: arranging an isolation member including a permanent magnet and/or a non-magnetic member at least within the island-shaped magnetic poles to prevent passage of magnetic flux coming from outside, thickness of the isolation member within the island-shaped magnetic pole is larger than thickness of the isolation member within the magnetic salient pole so that magnetic flux coming from the magnetic excitation part should be hard to flow through the island-shaped magnetic pole;constituting the island-shaped magnetic poles so as to be magnetized in almost same radial direction by at least one of a permanent magnet adjacent to the island-shaped magnetic pole and a permanent magnet within the island-shaped magnetic pole;arranging a field magnet and an excitation coil to change magnetization of the field magnet in the magnetic excitation part;coupling magnetically both ends of the magnetic excitation part respectively with one of the rotor and the armature arranged at an outermost circumference and one of the rotor and the armature arranged at an innermost circumference so that magnetic flux from one of N pole and S pole of the field magnet returns to other pole of the field magnet through the magnetic salient poles and the armature; andsupplying an excitation current to the excitation coil, and changing the field magnet magnetization irreversibly to control an amount of magnetic flux flowing through the armature. 20. A method for controlling a magnetic flux amount flowing through an armature of a rotating electric machine including a rotor and an armature facing radially each other, the rotor having island-shaped magnetic poles and magnetic salient poles separated by at least one of a magnetic gap and a permanent magnet in a circumferential direction on its plane facing the armature, the armature having armature coils disposed in a circumferential direction on its plane facing the rotor, and a magnetic excitation part for magnetizing the island-shaped magnetic poles and the magnetic salient poles collectively in same direction, said method comprising: arranging an isolation member including a permanent magnet and/or a non-magnetic member at least within the island-shaped magnetic poles to prevent passage of magnetic flux coming from outside, thickness of the isolation member within the island-shaped magnetic pole is larger than thickness of the isolation member within the magnetic salient pole so that magnetic flux coming from the magnetic excitation part should be hard to flow through the island-shaped magnetic pole;constituting the island-shaped magnetic poles so as to be magnetized in almost same radial direction by at least one of a permanent magnet adjacent to the island-shaped magnetic pole and a permanent magnet within the island-shaped magnetic pole;arranging an excitation coil and an excitation flux path member in the magnetic excitation part;coupling magnetically both ends of the excitation flux path member respectively with one of the rotor and the armature arranged at an outermost circumference and one of the rotor and the armature arranged at an innermost circumference so as to induce a magnetic flux in a magnetic flux path including the magnetic salient poles and the armature and the excitation flux path member; andsupplying an excitation current to the excitation coil to control an amount of magnetic flux flowing through the armature.