Hybrid magnetic suspension of a rotor

The invention claimed is: 1. A hybrid magnetic suspension of a rotor having a first compressor wheel at a first end thereof and a second compressor wheel at a second end thereof, comprising: a passive radial magnetic bearing comprising: at least first and second sets of permanent magnets integral to first and second rings shrunk fit onto the rotor in a vicinity of the first and second compressor wheels, the first and second sets of permanent magnets being retained by an outer non-magnetic ring coaxial with the rotor, at least third and fourth sets of permanent magnets integral to first and second stationary rings coaxially arranged with the rotor and associated with a resilient material in the vicinity of the first and second compressor wheels, the third and fourth sets of permanent magnets facing the first and second sets of permanent magnets respectively while providing a gap there-between to define the passive radial magnetic bearing; and an axial bearingless motor comprising: at least first and second coils respectively associated with first and second magnetic armatures and respectively facing first and second rotor parts located perpendicularly to the rotor, axial sensors configured for sensing an axial position of the rotor and providing outputs, wherein commanding currents are received in the at least first and second coils as a function of the outputs of the axial sensors, wherein each magnet of the first, second, third, and fourth sets of permanent magnets includes at least one insert made of an electrically conductive material, wherein the passive radial magnetic bearing and the axial bearingless motor exclude an implementation of auxiliary landing bearings. 2. The hybrid magnetic suspension according to claim 1 , wherein the electrically conductive material comprises aluminum or copper. 3. The hybrid magnetic suspension according to claim 1 , wherein the at least one insert is located in a center position between a pair of two individual permanent magnets, in a direction along a longitudinal axis of the rotor, the pair of two individual permanent magnets respectively being from the first and second sets of permanent magnets or from the third and fourth sets of permanent magnets. 4. The hybrid magnetic suspension according to claim 1 , wherein the at least one insert comprises two inserts made of the electrically conductive material, the two inserts being located at both sides of an individual permanent magnet in a direction along a longitudinal axis of the rotor, the individual permanent magnet being a magnet from the first, the second, the third, or the fourth sets of permanent magnets. 5. The hybrid magnetic suspension according to claim 1 , wherein the first and second shrunk fitted rings are constituted by a single hollow cylinder. 6. The hybrid magnetic suspension according to claim 1 , wherein the first and second shrunk fit rings define a thermal barrier. 7. The hybrid magnetic suspension according to claim 1 , wherein the axial bearingless motor further comprises the first and second rotor parts, each of the first and second rotor parts being a part made of an electrically conductive and magnetic alloy for defining an induction motor, a part made of a permanent magnet for defining a permanent magnet motor, or a part made of a hard magnetic material for defining a hysteresis motor or a reluctance motor. 8. The hybrid magnetic suspension according to claim 1 , wherein the first and second rotor parts are respectively located on first and second front faces of the first and second compressor wheels. 9. The hybrid magnetic suspension according to claim 1 , wherein the first and second rotor parts are respectively located on first and second front faces of a disc which is integrally located perpendicularly to the rotor between the first and second compressor wheels. 10. A tandem moto-compressor comprising: a hybrid magnetic suspension having; a passive radial magnetic bearing comprising: at least first and second sets of permanent magnets integral to first and second rings shrunk fit onto a rotor in a vicinity of first and second compressor wheels, the first and second sets of permanent magnets being retained by an outer non-magnetic ring coaxial with the rotor, at least third and fourth sets of permanent magnets integral to first and second stationary rings coaxially arranged with the rotor and associated with a resilient material in the vicinity of the first and second compressor wheels, the third and fourth sets of permanent magnets facing the first and second sets of permanent magnets respectively while providing a gap there-between to define the passive radial magnetic bearing; and an axial bearingless motor comprising: at least first and second coils respectively associated with first and second magnetic armatures and respectively facing first and second rotor parts located perpendicularly to the rotor, axial sensors configured for sensing an axial position of the rotor and providing outputs, wherein commanding currents are received in the at least first and second coils as a function of the outputs of the axial sensors, wherein the first and second rotor parts are respectively located on first and second front faces of the first and second compressor wheels, and wherein each magnet of the first, second, third, and fourth sets of permanent magnets includes at least one insert made of an electrically conductive material, wherein the passive radial magnetic bearing and the axial bearingless motor exclude an implementation of auxiliary landing bearings. 11. An electrically assisted turbocharger comprising: a hybrid magnetic suspension having; a passive radial magnetic bearing comprising: at least first and second sets of permanent magnets integral to first and second rings shrunk fit onto a rotor in a vicinity of first and second compressor wheels, the first and second sets of permanent magnets being retained by an outer non-magnetic ring coaxial with the rotor, at least third and fourth sets of permanent magnets integral to first and second stationary rings coaxially arranged with the rotor and associated with a resilient material in the vicinity of the first and second compressor wheels, the third and fourth sets of permanent magnets facing the first and second sets of permanent magnets respectively while providing a gap there-between to define the passive radial magnetic bearing; and an axial bearingless motor comprising: at least first and second coils respectively associated with first and second magnetic armatures and respectively facing first and second rotor parts located perpendicularly to the rotor, axial sensors configured for sensing an axial position of the rotor and providing outputs, wherein commanding currents are received in the at least first and second coils as a function of the outputs of the axial sensors, and wherein the first and second rotor parts are respectively located on first and second front faces of the first and second compressor wheels, and wherein each magnet of the first, second, third, and fourth sets of permanent magnets includes at least one insert made of an electrically conductive material, wherein the passive radial magnetic bearing and the axial bearingless motor exclude an implementation of auxiliary landing bearings. 12. A centrifugal moto-compressor comprising: a hybrid magnetic suspension having; a passive radial magnetic bearing comprising: at least first and second sets of permanent magnets integral to first and second rings shrunk fit onto a rotor in a vicinity of first and second compressor wheels, the first and second sets of permanent magnets being retained by an oute