Thermomagnetic apparatus for electric power generation and method thereof

The invention claimed is: 1. A thermomagnetic apparatus for electric power production, comprising: a hollow toric vessel delimited by a wall having an outer toric surface having a toroidal direction, wherein the toric wall encloses a volume containing a ferrofluid which comprises magnetic nanoparticles dispersed or suspended in a fluid carrier; a plurality of hydraulic conduits in thermal contact with the outer toric surface and arranged thereon along directions transverse to the toroidal direction, wherein near adjacent hydraulic conduits are spaced from each other in the toroidal direction so as to define on the outer toric surface a respective plurality of intermediate surface zones, each intermediate surface zone extending transversely to the toroidal direction; a magnetic field source coupled to the outer toric surface to generate a magnetic flux thereon, and an extraction coil which comprises a plurality of turns of electrical conductor wire arranged on the outer toric surface, the turns of the extraction coil being wound along directions transverse to the toroidal direction and arranged at at least a first sub-plurality of the plurality of intermediate surface zones. 2. According to claim 1 , wherein the magnetic field source comprises a plurality of permanent magnets arranged on the outer toric surface at at least a second sub-plurality of intermediate surface zones. 3. Apparatus according to claim 2 , wherein a sub-plurality of magnets of the plurality of magnets is arranged on each of the second sub-plurality of intermediate surface zones, each sub-plurality of magnets being arranged on the respective intermediate surface zone along a direction transverse to the toroidal direction and generally parallel to the transverse directions of arrangement of the hydraulic conduits. 4. Apparatus according to claim 2 , wherein the second sub-plurality of intermediate surface zones corresponds to the first sub-plurality of intermediate surface zones on which the turns of the extraction coil are arranged. 5. Apparatus according to claim 1 , wherein the magnetic field source is configured to create an external magnetic field having a direction tangent to the outer toric surface. 6. Apparatus according to claim 1 , wherein the turns of the extraction coil are wound around the outer toric surface along transverse directions generally parallel to each other and to the transverse directions of arrangement of the hydraulic conduits. 7. Apparatus according to claim 1 , wherein each conduit of the plurality of conduits is wound around the outer surface with at least one conduit winding extending along a respective direction transverse to the toroidal direction, and wherein the respective conduit windings of the plurality of conduits are arranged adjacent in an alternating fashion from one another so that near adjacent conduit windings are windings of two different conduits of the plurality of conduits. 8. Apparatus according to claim 7 , wherein the transverse directions of the conduit windings are generally parallel to each other and the plurality of conduits consists of an even number N of hydraulic conduits formed by N/2 odd conduits and by N/2 even conduits, the conduit windings of the odd conduits and of the even conduits being arranged alternately with each other, wherein each of the N/2 odd conduits contains a working fluid at a relatively lower temperature and each of the N/2 even conduits contains a working fluid at a relatively higher temperature, creating on the outer surface along the toroidal direction a plurality of surface zones alternating between the relatively lower temperature, at the windings of the N/2 odd conduits, and the relatively higher temperature, at the windings of the N/2 even conduits, said zones alternating along the toroidal direction, so as to create a plurality of temperature gradients at the respective intermediate surface zones. 9. Apparatus according to claim 1 , wherein each conduit of the plurality of conduits is wound around the outer surface with at least one conduit winding extending along a respective direction transverse to the toroidal direction, and wherein the respective conduit windings of the plurality of conduits are arranged adjacent in an alternating fashion from one another so that near adjacent conduit windings are windings of two different conduits of the plurality of conduits, the apparatus further comprising a thermal gradient generator assembly configured to control the temperature of a working fluid contained in each conduit of the plurality of conduits by varying cyclically over time the temperature of the working fluid of said conduit between the relatively higher temperature and the relatively lower temperature and vice versa. 10. Apparatus according to claim 9 , wherein the thermal gradient generator assembly is configured to vary the temperature of the working fluid between a first temperature T 1 and a second temperature T 2 , with T 2 >T 1 , and vice versa, simultaneously for each conduit of the plurality of conduits so as to change over time the sign of the difference between the first and second temperatures between each pair of near adjacent conduit windings of the plurality of conduits. 11. Apparatus according to claim 9 , wherein the plurality of conduits consists of an even number N of hydraulic conduits formed by N/2 odd conduits and by N/2 even conduits and wherein the thermal gradient generator comprises a first source of service fluid at a first temperature T 1 and a second source of service fluid at a second temperature T 2 and each conduit of the plurality of conduits comprises a first conduit portion consisting of one or more windings around the outer toric surface and a second non-wound conduit portion which is not in contact with the outer toric surface ( 31 a ) and extends externally from the vessel, the working fluid of the second conduit portion of each conduit of the N/2 odd conduits and the working fluid of the second conduit portion of each conduit of the N/2 even conduits being in thermal contact alternately with the service fluid at the first temperature T 1 or with the service fluid at the second temperature T 2 so as to achieve a heat exchange to maintain or to vary the temperature of the working fluid contained in the plurality of conduits. 12. Apparatus according to claim 1 , wherein the hollow vessel has the shape of a toroid with a through opening and the directrix of the toroid defines the toroidal direction and wherein the plurality of hydraulic conduits are wound around the outer toric surface along transverse directions generally parallel to each other. 13. A method for harvesting electric power using thermomagnetic energy, comprising: providing a hollow toric vessel delimited by a wall having an outer toric surface having a toroidal direction, wherein the toric wall encloses a volume containing a ferrofluid which comprises magnetic nanoparticles dispersed or suspended in a fluid carrier; generating a plurality of temperature gradients along the toroidal direction creating a plurality of surface zones extending on the outer toric surface transversely to the toroidal direction and in an alternating fashion between a relatively higher temperature and a relatively lower temperature, so as to create a difference in temperature in each pair of near adjacent surface zones, each temperature gradient of the plurality of gradients being represented by a vector tangent to the outer toric surface of scalar value equal to the temperature difference; generating a magnetic flux on the outer toric surface and having a vector direction tangent to the same surface, and harvesting electric curren