Dynamic boil-off reduction with improved cryogenic vessel

The invention claimed is: 1. A cryogenic vessel for use in a magnetic resonance examination system to mount superconductive main coils, the cryogenic vessel comprising: an outer vessel, a radiation shield located inside the outer vessel, and an inner mounting structure for mounting the superconductive main coils, which is located within the radiation shield, whereby the radiation shield has at least one dry-friction area, where dry-friction is generated upon deformation of the radiation shield; wherein the at least one dry-friction area comprises at least two shield layers, which are stacked on each other in surface contact, whereby the at least two shield layers are locally connected to each other; and wherein one of the at least two shield layers comprising the dry-friction area is copper. 2. The cryogenic vessel according to claim 1 , whereby the at least two shield layers are locally connected to each other by spot welding. 3. The cryogenic vessel according to claim 1 , whereby the at least two shield layers are locally connected to each other by rolling. 4. The cryogenic vessel according to claim 1 , whereby at least one shield layer of the radiation shield is made of aluminum. 5. The cryogenic vessel according to claim 1 , whereby at least two shield layers of the radiation shield are made of different materials. 6. The cryogenic vessel according to claim 1 , whereby at least two shield layers of the radiation shield have a different thickness. 7. The cryogenic vessel according to claim 1 , wherein the radiation shield has at least one cylindrical wall and has a uniform thickness in the at least one cylindrical wall of the cryogenic vessel. 8. The cryogenic vessel according to claim 1 , whereby the at least one dry-friction area comprises a local patch, which is attached to the radiation shield. 9. The cryogenic vessel according to claim 1 , wherein the radiation shield has a cylindrical wall with longitudinal ends and the at least one dry-friction area is provided at one of the longitudinal ends of the cylindrical wall of the cryogenic vessel. 10. The cryogenic vessel according to claim 1 , whereby at least one dry-friction area is provided at one flange of the cryogenic vessel. 11. The cryogenic vessel according to claim 1 , whereby the inner mounting structure is provided as an inner vessel for mounting the superconductive main coils therein, whereby the inner vessel is adapted for containing a cryogen. 12. The cryogenic vessel of claim 1 , further including an inner vessel that is surrounded by the radiation shield. 13. The cryogenic vessel of claim 12 , wherein the inner mounting structure is mounted at an inner side of the inner vessel. 14. The cryogenic vessel according to claim 1 , wherein the at least one dry-friction area is provided locally in an area where local vibrations occur during operation of the magnetic resonance examination system. 15. The cryogenic vessel according to claim 1 , wherein the radiation shield is cooled by a cryo-cooling system comprising a cold head. 16. A superconductive magnet for a magnet resonance examination system, the super conductive magnet comprising: a cryogenic vessel; and a set of superconductive main coils which are arranged in the cryogenic vessel; wherein the cryogenic vessel includes: an outer vessel; a radiation shield located inside the outer vessel and cooled by a cryo-cooling system comprising a cold head; and an inner mounting structure on which are mounted the superconductive main coils, the inner mounting structure being located within an inner vessel inside the radiation shield, wherein the radiation shield has at least one dry-friction area, where dry-friction is generated upon deformation of the radiation shield; wherein the inner mounting structure is mounted to an inner cylindrical wall of the inner vessel and extends towards an outer cylindrical wall of the inner vessel. 17. A magnetic resonance examination system comprising: a superconductive magnet according to claim 16 ; and at least one magnetic field gradient coil. 18. The cryogenic vessel of claim 16 , wherein the at least one dry-friction area is provided locally at the location of the superconductive main coils. 19. The cryogenic vessel of claim 16 , wherein the at least one dry-friction area comprises at least two shield layers, which are stacked on each other in surface contact, whereby the at least two shield layers are locally connected to each other.