Rotating electrical machine with superconducting elements and cryogenic enclosures

The invention claimed is: 1. A rotating electric machine, comprising: at least one rotor comprising a set of superconducting axial magnetic flux barrier elements distributed in a plane perpendicular to an axis of rotation in a tangential direction about the axis of rotation, said superconducting axial magnetic flux barrier elements being spaced by axial magnetic flux passage areas distributed in the tangential direction about the axis of rotation, at least one armature, comprising armature windings distributed in the tangential direction about the axis of rotation, at least one superconducting inductor coil surrounding the superconducting axial magnetic flux barrier elements and the at least one armature in the tangential direction about the axis of rotation, the at least one superconducting inductor coil being able to induce an axial magnetic field directed along the axis of rotation, the at least one rotor being rotatably mounted on the axis of rotation with respect to the armature and to the at least one inductor coil, wherein the at least one rotor including: at least one first rotor and at least one second rotor, and the set of superconducting axial magnetic flux barrier elements including: superconducting axial magnetic flux barrier elements of the at least one first rotor, and superconducting axial magnetic flux barrier elements of the at least one second rotor, the at least one first rotor and the at least one second rotor being spaced from each other along the axis of rotation, the at least one armature being positioned between the at least one first rotor and the at least one second rotor, the superconducting axial magnetic flux barrier elements of the at least one first rotor being coaxial at least partly with the superconducting axial magnetic flux barrier elements of the at least one second rotor, the axial magnetic flux passage areas of the at least one first rotor being coaxial at least partly with the axial magnetic flux passage areas of the at least one second rotor, the rotating electric machine comprising a first cryogenic cooling enclosure that has an annular shape about the axis of rotation and is delimited radially by a first external wall and by a second internal annular wall, the at least one superconducting inductor coil being located in the first cryogenic cooling enclosure between the first external wall and the second internal annular wall, the rotating electric machine comprising a second cryogenic cooling enclosure that has a circular cylindrical shape about the axis of rotation and is delimited radially by a third external wall located inside the second internal annular wall, the at least one first rotor, the at least one second rotors and the at least one armature being located in the second cryogenic cooling enclosure. 2. A rotating electric machine, comprising: at least one rotor comprising a set of superconducting axial magnetic flux barrier elements distributed in a plane perpendicular to an axis of rotation in a tangential direction about the axis of rotation, said superconducting axial magnetic flux barrier elements being spaced by axial magnetic flux passage areas distributed in the tangential direction about the axis of rotation, at least one armature, comprising armature windings distributed in the tangential direction about the axis of rotation, at least one superconducting inductor coil surrounding the superconducting axial magnetic flux barrier elements and the at least one armature in the tangential direction about the axis of rotation, the at least one superconducting inductor coil being able to induce an axial magnetic field directed along the axis of rotation, the at least one rotor being rotatably mounted on the axis of rotation with respect to the armature and to the at least one inductor coil, wherein the at least one rotor including: at least one first rotor and at least one second rotor, and the set of superconducting axial magnetic flux barrier elements including: superconducting axial magnetic flux barrier elements of the at least one first rotor, and superconducting axial magnetic flux barrier elements of the at least one second rotor, the at least one first rotor and the at least one second rotor being spaced from each other along the axis of rotation, the at least one armature being positioned between the at least one first rotor and the at least one second rotor, the superconducting axial magnetic flux barrier elements of the at least one first rotor being coaxial at least partly with the superconducting axial magnetic flux barrier elements of the at least one second rotor, the axial magnetic flux passage areas of the at least one first rotor being coaxial at least partly with the axial magnetic flux passage areas of the at least one second rotor, the rotating electric machine comprising a first cryogenic cooling enclosure that has an annular shape about the axis of rotation and is delimited radially by a first external wall and by a second internal annular wall, the at least one superconducting inductor coil being located in the first cryogenic cooling enclosure between the first external wall and the second internal annular wall, the rotating electric machine comprising at least one second cryogenic cooling enclosure that has a circular cylindrical shape about the axis of rotation and which is delimited radially by a third external wall located inside the second internal annular wall, the at least one first rotor being located in the second cryogenic cooling enclosure, the rotating electric machine comprising at least one third cryogenic cooling enclosure that has a circular cylindrical shape about the axis of rotation, which wherein said at least one third cryogenic cooling enclosure is located axially at a distance from the second cryogenic cooling enclosure and is delimited radially by a fourth external wall located inside the second internal annular wall, the at least one second rotor being located in the third cryogenic cooling enclosure, the at least one armature being located between the second cryogenic cooling enclosure and the third cryogenic cooling enclosure. 3. The rotating electric machine according to claim 1 , wherein the at least one second rotor comprises an armature on either side. 4. The rotating electric machine according to claim 3 , comprising N rotors comprising on either side of each of the rotors an armature, N being a natural number greater than or equal to 2. 5. The rotating electric machine according to claim 1 , comprising N armatures comprising on either side of each of the armatures a rotor, N being a natural integer greater than or equal to 2. 6. The rotating electric machine according to claim 1 , wherein the superconducting axial magnetic flux barrier elements of the at least one first rotor are aligned along the axis of rotation with the superconducting axial magnetic flux barrier elements of the at least one second rotor, and the axial magnetic flux passage areas of the at least one first rotor are aligned along the axis of rotation with the axial magnetic flux passage areas of the at least one second rotor. 7. The rotating electric machine according to claim 1 , wherein the armature windings comprise at least one superconducting armature winding. 8. The rotating electric machine according to claim 1 , wherein the armature windings comprise at least one conductive winding. 9. The rotating electric machine according to claim 1 , wherein the at least one superconducting inductor coil has an axial extent that surrounds the plurality of the rotors and the at least one armature in the tangential direction about the axis of rotation. 10. The rotating electric machine according to claim 7 , wherein th