Device and method for damped, non-contact support of a coolant feed line for superconducting machines

The invention claimed is: 1. A device for supporting a coolant feed line for a superconducting machine, comprising: a hollow shaft having a first area for connection to the superconducting machine and a second area for connection to a cooling unit, said hollow shaft having an interior for accommodating a coolant feed line for feeding coolant from the cooling unit to the superconducting machine, said coolant feed line being fixed in the second area of the hollow shaft; and a magnetic support arranged in the first area of the hollow shaft for exerting a radial force on the coolant feed line to effect damping or centering, said magnetic support having first and second magnetic cylinders, said first magnetic cylinder disposed on an outer jacket of the coolant feed line and made of a material with good electrical conductivity with ohmic resistance, and said second magnetic cylinder disposed on an inner side of the hollow shaft so that the first and second magnetic cylinders lie opposite one another in a radial direction. 2. The device of claim 1 , wherein the material is selected from the group consisting of copper, silver, gold, and aluminum. 3. The device of claim 1 , wherein the material is selected from the group consisting of highly-pure copper, silver, gold, and aluminum with a degree of purity greater than 99.9 percent by volume. 4. The device of claim 1 , wherein the material has a specific electrical resistance of less than 100 μΩcm 2 /m at a cryogenic temperature. 5. The device of claim 4 , wherein the cryogenic temperature is less than or equal to 77° K. 6. The device of claim 1 , wherein the material has a specific electrical resistance of less than 10 μΩcm 2 /m at a cryogenic temperature. 7. The device of claim 1 , wherein the second magnetic cylinder includes a plurality of concentric permanent magnet rings disposed axially next to one another. 8. The device of claim 7 , further comprising a further cylinder made of ferromagnetic material disposed between the inner side of the hollow shaft and the concentric permanent magnet rings. 9. The device of claim 7 , further comprising rings made of ferromagnetic material and disposed between axially adjacent ones of the permanent magnet rings so as to separate the permanent magnet rings from one another. 10. A method, comprising: connecting a first area of a hollow shaft to a superconducting machine and a second area of the hollow shaft to a cooling unit; feeding coolant through a coolant feed line inside the hollow shaft to the superconducting machine; and damping a mechanical movement of the coolant feed line relative to the hollow shaft by providing a magnetic support in the first area of the hollow shaft for exerting a radial force on the coolant feed line and forming the magnetic support of a first magnetic cylinder disposed on an outer jacket of the coolant feed line and made of a material with good electrical conductivity with ohmic resistance and a second magnetic cylinder disposed on an inner side of the hollow shaft so that the first and second magnetic cylinders lie opposite one another in a radial direction. 11. The method of claim 10 , wherein the mechanical movement is damped by movement-induced eddy currents in the electrically-conductive material of the first magnetic cylinder disposed on an outer jacket of the coolant feed line. 12. A superconducting machine, comprising device for supporting a coolant feed line for a superconducting machine, said device comprising a hollow shaft having a first area for connection to the superconducting machine and a second area for connection to a cooling unit, said hollow shaft having an interior for accommodating a coolant feed line for feeding coolant from the cooling unit to the superconducting machine, said coolant feed line being fixed in the second area of the hollow shaft, and a magnetic support arranged in the first area of the hollow shaft for exerting a radial force on the coolant feed line to effect damping or centering, said magnetic support having first and second magnetic cylinders, said first magnetic cylinder disposed on an outer jacket of the coolant feed line and made of a material with good electrical conductivity with ohmic resistance, and said second magnetic cylinder disposed on an inner side of the hollow shaft so that the first and second magnetic cylinders lie opposite one another in a radial direction. 13. The superconducting machine of claim 12 , wherein the material is selected from the group consisting of copper, silver, gold, and aluminum. 14. The superconducting machine of claim 12 , wherein the material is selected from the group consisting of highly-pure copper, silver, gold, and aluminum with a degree of purity greater than 99.9 percent by volume. 15. The superconducting machine of claim 12 , wherein the material has a specific electrical resistance of less than 100 μΩcm 2 /m at a cryogenic temperature. 16. The superconducting machine of claim 15 , wherein the cryogenic temperature is less than or equal to 77° K. 17. The superconducting machine of claim 12 , wherein the material has a specific electrical resistance of less than 10 μΩcm 2 /m at a cryogenic temperature. 18. The superconducting machine of claim 12 , wherein the second magnetic cylinder includes a plurality of concentric permanent magnet rings disposed axially next to one another. 19. The superconducting machine of claim 18 , wherein the device includes a further cylinder made of ferromagnetic material disposed between the inner side of the hollow shaft and the concentric permanent magnet rings. 20. The superconducting machine of claim 18 , further comprising rings made of ferromagnetic material and disposed between axially adjacent ones of the permanent magnet rings so as to separate the permanent magnets from one another.