초록 ▼

A synchronous reluctance machine is provided. The synchronous reluctance machine includes a stator having a stator core, the stator core including a number of fractional-slot concentrated windings wound around multiple stator teeth. The synchronous reluctance machine also includes a rotor having a r

A synchronous reluctance machine is provided. The synchronous reluctance machine includes a stator having a stator core, the stator core including a number of fractional-slot concentrated windings wound around multiple stator teeth. The synchronous reluctance machine also includes a rotor having a rotor core and disposed with an air gap inside and concentric with the stator, wherein the rotor core includes a number of laminated sheets, wherein each of the laminated sheets is axially skewed with respect to neighboring ones of the laminated sheets, and wherein each of the laminated sheets includes multiple ferromagnetic regions and multiple non-ferromagnetic regions formed of a single material.

대표청구항 ▼

The invention claimed is: 1. A synchronous reluctance machine comprising: a stator comprising a stator core, the stator core comprising a plurality of fractional-slot concentrated windings wound around a plurality of stator teeth; and a rotor comprising a rotor core and disposed with an air gap ins

The invention claimed is: 1. A synchronous reluctance machine comprising: a stator comprising a stator core, the stator core comprising a plurality of fractional-slot concentrated windings wound around a plurality of stator teeth; and a rotor comprising a rotor core and disposed with an air gap inside and concentric with the stator, wherein the rotor core comprises a plurality of laminated sheets, and wherein each of the laminated sheets is axially skewed with respect to neighboring ones of the laminated sheets, and wherein each of the laminated sheets comprises a plurality of ferromagnetic regions and a plurality of non-ferromagnetic regions formed of a single material, wherein the ferromagnetic and the non-ferromagnetic regions are selectively formed so as to reduce a lower order harmonic component of magnetic flux generated by the fractional-slot concentrated windings. 2. The synchronous reluctance machine of claim 1, wherein the laminated sheets have an integral structure, wherein the single material comprises a dual phase ferromagnetic material, and wherein the laminated sheets are subjected to a localized surface treatment to form the non-ferromagnetic regions respectively. 3. The synchronous reluctance machine of claim 1, wherein the laminated sheets are skewed in a straight pattern. 4. The synchronous reluctance machine of claim 1, wherein the laminated sheets are skewed in a herringbone pattern. 5. The synchronous reluctance machine of claim 1, wherein the ferromagnetic and the non-ferromagnetic regions are further selectively formed so as to enhance a synchronous component reluctance torque. 6. The synchronous reluctance machine of claim 5, wherein at least one of the non-ferromagnetic regions is formed around an inner surface of the rotor core to reduce the lower order harmonic component of magnetic flux. 7. A synchronous reluctance machine comprising: a stator comprising a stator core, the stator core comprising a plurality of fractional-slot concentrated windings wound around a plurality of stator teeth; and a rotor comprising a rotor core and disposed with an air gap outside and concentric with the stator, wherein the rotor core comprises a plurality of laminated sheets, wherein each of the laminated sheets is axially skewed with respect to neighboring ones of the laminated sheets, and wherein each of the laminated sheets comprises a plurality of ferromagnetic regions and a plurality of non-ferromagnetic regions formed of a single material, wherein the ferromagnetic and the non-ferromagnetic regions are selectively formed so as to reduce a lower order harmonic component of magnetic flux generated by the fractional-slot concentrated windings. 8. The synchronous reluctance machine of claim 7, wherein the laminated sheets have an integral structure, wherein the single material comprises a dual phase ferromagnetic material, and wherein the laminated sheets are subjected to a localized surface treatment to form the non-ferromagnetic regions. 9. The synchronous reluctance machine of claim 7, wherein the laminated sheets are skewed in a straight pattern. 10. The synchronous reluctance machine of claim 7, wherein the laminated sheets are skewed in a herringbone pattern. 11. The synchronous reluctance machine of claim 7, wherein the ferromagnetic and the non-ferromagnetic regions are further selectively formed so as to enhance a synchronous component reluctance torque. 12. The synchronous reluctance machine of claim 11, wherein at least one of the non-ferromagnetic regions is formed around an outer surface of the rotor core to reduce the lower order harmonic component of magnetic flux. 13. A synchronous reluctance machine comprising: a stator comprising an inner stator portion and an outer stator portion, wherein the inner stator portion comprises an inner surface and a plurality of inner fractional-slot windings wound around a plurality of inner stator teeth disposed on the inner surface, and wherein the outer stator portion is disposed concentrically around the inner stator portion and comprises an outer surface and a plurality of outer fractional-slot windings wound around a plurality of outer stator teeth disposed on the outer surface; and a rotor comprising an inner rotor core and an outer rotor core, wherein the stator is disposed concentrically between the inner and outer rotor cores about a central axis, wherein the outer rotor core comprises a plurality of outer laminated sheets, each of the outer laminated sheets being axially skewed with respect to neighboring ones of the outer laminated sheets and comprising a plurality of outer ferromagnetic regions and a plurality of outer non-ferromagnetic regions formed of a single material, wherein the outer ferromagnetic and the non-ferromagnetic regions are selectively formed so as to reduce a contribution of at least one harmonic component of magnetic flux generated by the outer fractional-slot concentrated windings, and wherein the inner rotor core comprises a plurality of inner laminated sheets, each of the inner laminated sheets being axially skewed with respect to neighboring ones of the inner laminated sheets and comprising a plurality of inner ferromagnetic regions and a plurality of inner non-ferromagnetic regions formed of a single material, wherein the inner ferromagnetic and the non-ferromagnetic regions are selectively formed so as to reduce a contribution of at least one harmonic component of magnetic flux generated by the inner fractional-slot concentrated windings. 14. The synchronous reluctance machine of claim 13, wherein the inner and the outer laminated sheets have an integral structure, wherein the single material comprises a dual phase ferromagnetic material, and wherein the inner and the outer laminated sheets are subjected to a localized surface treatment to form the inner and the outer non-ferromagnetic regions respectively. 15. The synchronous reluctance machine of claim 13, wherein the inner laminated sheets and the outer laminated sheets are skewed in a straight pattern. 16. The synchronous reluctance machine of claim 13, wherein the inner laminated sheets and the outer laminated sheets are skewed in a herringbone pattern. 17. The synchronous reluctance machine of claim 13, wherein the outer ferromagnetic and the outer non-ferromagnetic regions are further selectively formed so as to enhance a synchronous component reluctance torque, and wherein the inner ferromagnetic and the inner non-ferromagnetic regions are further selectively formed so as to enhance a synchronous component reluctance torque. 18. The synchronous reluctance machine of claim 17, wherein at least one of each of the inner and the outer non-ferromagnetic regions are formed around an inner or an outer surface of the rotor core to reduce a lower order harmonic component of magnetic flux. 19. A synchronous reluctance machine comprising: a stator comprising an inner stator portion and an outer stator portion, wherein the inner stator portion comprises an outer surface and a plurality of inner fractional-slot windings wound around a plurality of inner stator teeth disposed on the outer surface, and wherein the outer stator portion comprises an inner surface and a plurality of outer fractional-slot windings wound around a plurality of outer stator teeth disposed on the inner surface; and a double sided rotor comprising an inner rotor side and an outer rotor side, wherein the double sided rotor is concentrically disposed between the inner stator portion and the outer stator portion about a central axis, wherein the outer rotor side comprises a plurality of outer laminated sheets, each of the outer laminated sheets being axially skewed with respect to neighboring ones of the outer laminated sheets and comprising a plurality of outer ferromagnetic regions and a plurality of outer non-ferromagnetic regions formed of a single material, wherein the outer ferromagnetic and the non-ferromagnetic regions are selectively formed so as to reduce a contribution of at least one harmonic component of magnetic flux generated by the outer fractional-slot concentrated windings, and wherein the inner rotor side comprises a plurality of inner laminated sheets, each of the inner laminated sheets being axially skewed with respect to neighboring ones of the inner laminated sheets and comprising a plurality of inner ferromagnetic regions and a plurality of inner non-ferromagnetic regions formed of a single material, wherein the inner ferromagnetic and the non-ferromagnetic regions are selectively formed so as to reduce a contribution of at least one harmonic component of magnetic flux generated by the inner fractional-slot concentrated windings. 20. The synchronous reluctance machine of claim 19, wherein the inner and the outer laminated sheets have an integral structure, wherein the single material comprises a dual phase ferromagnetic material, and wherein the inner and the outer laminated sheets are subjected to a localized surface treatment to form the inner and the outer non-ferromagnetic regions respectively. 21. The synchronous reluctance machine of claim 19, wherein the inner and the outer laminated sheets are skewed in a straight pattern. 22. The synchronous reluctance machine of claim 19, wherein the inner and the outer laminated sheets are skewed in a herringbone pattern. 23. The synchronous reluctance machine of claim 19, wherein the outer ferromagnetic and the outer non-ferromagnetic regions are further selectively formed so as to enhance a synchronous component reluctance torque, and wherein the inner ferromagnetic and the inner non-ferromagnetic regions are further selectively formed so as to enhance a synchronous component reluctance torque. 24. The synchronous reluctance machine of claim 23, wherein at least one of each of the inner and the outer non-ferromagnetic regions are formed around an inner surface of the rotor core to reduce a lower order harmonic component of magnetic flux.