Superconducting current pump

The invention claimed is: 1. A superconducting current pump arranged to cause a DC electrical current to flow through a superconducting circuit accommodated within a cryogenic enclosure of a cryostat, the superconducting circuit comprising a superconducting coil or coils and one or more superconducting elements, the current pump comprising a rotor external to the cryogenic enclosure and a stator within the cryogenic enclosure, the rotor and stator separated by a gap through which passes a thermally insulating wall of the cryogenic enclosure, the rotor comprising one or more magnetic field generating elements, and the rotor and the stator comprising at least in part a ferromagnetic material to concentrate magnetic flux in a magnetic circuit across the gap between the rotor and the stator and through the wall such that the magnetic flux penetrates through one or more superconducting element(s) of the superconducting circuit associated with the stator so that movement of the rotor external to the cryogenic enclosure relative to the stator within the cryogenic enclosure induces a DC transport current to flow around the superconducting circuit within the cryogenic enclosure. 2. A superconducting current pump according to claim 1 wherein the superconducting circuit passes between ferromagnetic flux-concentrating parts of the stator and rotor such that flux penetrates the superconductor in one direction relative to the direction of DC current flow in the superconducting circuit. 3. A superconducting current pump according to claim 1 wherein the superconducting circuit passes between the rotor and the stator and exits via a region at which the superconducting circuit experiences lower or no magnetic field. 4. A superconducting current pump according to claim 3 wherein the superconducting circuit exits through an aperture in the stator. 5. A superconducting current pump according to claim 1 wherein the superconducting coil or coils has sufficient inductance to incrementally accumulate electrical current through the circuit as the rotor moves. 6. A superconducting current pump according to claim 1 wherein the rotor and stator are displaced from each other in a direction in or substantially parallel to an axis of rotation of the rotor to define said gap. 7. A superconducting current pump according to claim 1 wherein the rotor and stator are arranged concentrically and said gap is around an axis of rotation of the rotor. 8. A superconducting current pump according to claim 7 wherein a cylindrical rotor assembly is located inside or outside a cylindrical stator assembly. 9. A superconducting current pump according to claim 1 wherein superconducting elements are arranged around the stator and the magnetic field generating elements are arranged around the rotor opposite the superconducting elements on the stator. 10. A superconducting current pump according to claim 1 wherein superconducting elements are wound around the stator including passing through apertures in the stator. 11. A superconducting current pump according to claim 1 wherein the one or more magnetic field generating elements comprise one or more permanent magnets or electromagnets. 12. A superconducting current pump according to claim 1 wherein the magnetic flux density in the gap is high enough to penetrate through a superconducting element disposed about the stator and form localized flux vortices at a microscopic scale but not eliminate a superconducting current path sufficient to carry the net DC transport current flowing through the superconducting circuit at a macroscopic level. 13. A superconducting current pump according to claim 1 comprising a motor control system arranged to control the speed of the rotor. 14. A superconducting current pump according to claim 13 wherein comprising a control system arranged to control a variable gap between the rotor and stator. 15. A superconducting current pump according to claim 14 further comprising a sensor arranged to provide a signal to the control system indicative of the current around the superconducting circuit. 16. A system including a superconducting current pump according to claim 1 wherein the cryostat includes a refrigeration system comprising a liquid cryogen operable to cool by latent heat of evaporation and/or a thermomechanical refrigerator. 17. A system including a superconducting current pump according to claim 1 wherein the cryostat wall disposed between the rotor and stator has low electrical conductivity. 18. A system including a superconducting current pump according to claim 1 wherein the cryostat is a rotating cryostat. 19. A system according to claim 18 wherein the stator and rotor rotate relative to each other around a common rotational axis with the rotating cryostat. 20. A superconducting current pump arranged to cause a DC electrical current to flow through a superconducting circuit accommodated within a cryogenic enclosure of a cryostat, the superconducting circuit comprising a superconducting coil or coils and one or more superconducting elements, the current pump comprising a rotor external to the cryogenic enclosure and a stator within the cryogenic enclosure so that relative movement of the rotor external to the cryogenic enclosure induces a DC transport current to flow around the superconducting circuit within the cryogenic enclosure.