Selective permeability rotor structure for interior permanent magnet machine

What is claimed is: 1 . A radial flux electric motor comprising: a stator having a radially inner stator surface and stator windings arranged thereon; and a rotor mounted inside the stator and configured to rotate relative thereto about a rotational axis, wherein the rotor includes: a rotor core constructed from a ferromagnetic material having relatively high magnetic permeability and defined by a rotor outer surface establishing an airgap between the rotor and the stator; a plurality of magnetic poles set in the rotor core and configured to generate magnetic flux; and inserts constructed from a material having relatively low magnetic permeability in at least one geometric direction, wherein each insert is mechanically fixed to the rotor core to thereby control magnetic flux distribution and minimize flux leakage inside the rotor, and each insert defines a radial magnetic permeability and a circumferential magnetic permeability relative to the rotational axis, and wherein magnitude of the radial magnetic permeability is different from magnitude of the circumferential magnetic permeability. 2 . The radial flux electric motor according to claim 1 , wherein each insert is arranged on the rotor outer surface either between adjacent magnetic poles or across from individual magnetic poles. 3 . The radial flux electric motor according to claim 1 , wherein each insert has one of a hollow body and a solid body construction. 4 . The radial flux electric motor according to claim 1 , wherein each magnetic pole includes at least one rotor pocket having at least one permanent magnet embedded therein and configured to generate the magnetic flux, and wherein each rotor pocket has at least a portion thereof arranged proximate to at least one of the inserts. 5 . The radial flux electric motor according to claim 1 , wherein each insert is configured to define a structural bridge extending from at least one of the rotor pockets to the rotor outer surface thereby reinforcing the rotor core and minimizing leakage of the magnetic flux inside the rotor. 6 . The radial flux electric motor according to claim 5 , wherein the insert material is grain-oriented steel, and wherein orientation of the grain is perpendicular to direction of leakage of the magnetic flux between the rotor and stator and parallel to direction of linkage of the magnetic flux between adjacent magnetic poles. 7 . The radial flux electric motor according to claim 1 , wherein each insert is configured to minimize closure of a magnetic flux loop inside the rotor. 8 . The radial flux electric motor according to claim 1 , wherein the rotor core includes multiple adjacent rotor laminations arranged along the rotational axis, and wherein the inserts of adjacent rotor laminations are arranged out of phase relative to one another. 9 . The radial flux electric motor according to claim 8 , wherein the adjacent rotor laminations are electrically isolated from one another via a dielectric element. 10 . A motor vehicle comprising: a radial flux electric motor configured to generate torque for propulsion of the motor vehicle, the radial flux electric motor including: a stator having a radially inner stator surface and stator windings arranged thereon; and a rotor mounted inside the stator and configured to rotate relative thereto about a rotational axis, wherein the rotor includes: a rotor core constructed from a ferromagnetic material and defined by a rotor outer surface establishing an airgap between the rotor and the stator; a plurality of magnetic poles set in the rotor core and configured to generate magnetic flux; and inserts constructed from a material having relatively low magnetic permeability in at least one geometric direction, wherein each insert is mechanically fixed to the rotor core to thereby control magnetic flux distribution and minimize flux leakage inside the rotor, and each insert defines a radial magnetic permeability and a circumferential magnetic permeability relative to the rotational axis, and wherein magnitude of the radial magnetic permeability is different from magnitude of the circumferential magnetic permeability. 11 . The motor vehicle according to claim 10 , wherein each insert is arranged on the rotor outer surface either between adjacent magnetic poles or across from individual magnetic poles. 12 . The motor vehicle according to claim 10 , wherein each insert has one of a hollow body and a solid body construction and is configured to minimize closure of a magnetic flux loop inside the rotor. 13 . The motor vehicle according to claim 10 , wherein each magnetic pole includes at least one rotor pocket having at least one permanent magnet embedded therein and configured to generate the magnetic flux, and wherein each rotor pocket has at least a portion thereof arranged proximate to at least one of the inserts. 14 . The motor vehicle according to claim 10 , wherein each insert is configured to define a structural bridge extending from at least one of the rotor pockets to the rotor outer surface thereby reinforcing the rotor core and minimizing leakage of the magnetic flux inside the rotor. 15 . The motor vehicle according to claim 14 , wherein the insert material is grain-oriented steel, and wherein orientation of the grain is perpendicular to direction of leakage of the magnetic flux between the rotor and stator and parallel to direction of linkage of the magnetic flux between adjacent magnetic poles. 16 . The motor vehicle according to claim 10 , wherein the rotor core includes multiple adjacent rotor laminations arranged along the rotational axis, and wherein the inserts of adjacent rotor laminations are arranged out of phase with one another. 17 . The motor vehicle according to claim 16 , wherein the adjacent rotor laminations are electrically isolated from one another via a dielectric element. 18 . A radial flux electric motor comprising: a stator having a radially inner stator surface and stator windings arranged thereon; and a rotor mounted inside the stator and configured to rotate relative thereto about a rotational axis, wherein the rotor includes: a rotor core constructed from a ferromagnetic material having relatively high magnetic permeability and defined by a rotor outer surface establishing an airgap between the rotor and the stator, wherein: the rotor core includes multiple adjacent rotor laminations arranged along the rotational axis; and the adjacent rotor laminations are electrically isolated from one another via a dielectric element; a plurality of magnetic poles set in each of the adjacent rotor laminations and configured to generate magnetic flux; and inserts constructed from a material having relatively low magnetic permeability in at least one geometric direction, wherein: each insert is mechanically fixed to the rotor core to thereby control magnetic flux distribution and minimize flux leakage inside the rotor; each insert defines a radial magnetic permeability and a circumferential magnetic permeability relative to the rotational axis, and wherein magnitude of the radial magnetic permeability is different from magnitude of the circumferential magnetic permeability; and the inserts of adjacent rotor laminations are arranged out of phase with one another. 19 . The radial flux electric motor according to claim 18 , wherein each insert is configured to define a structural bridge extending from at least one of the rotor pockets to the rotor outer surface thereby reinforcing the rotor core and minimi