Method and apparatus for shutting down a superconducting magnet of a magnetic resonance device

The invention claimed is: 1. A method for shutting down a superconducting magnet of a magnetic resonance apparatus, comprising: with a monitoring processor, determining an amount of stored energy stored in an energy store at a first point-in-time; in said monitoring processor, determining a ramp energy that is required for shutting down said superconducting magnet; in said monitoring processor, determining a second point-in-time based the determined amount of stored energy and the ramp energy; and using a shutdown controller to begin shutting down said superconducting magnet at said second point-in-time, using said energy stored in said energy store. 2. A method as claimed in claim 1 comprising using said monitoring processor as said shutdown controller. 3. A method as claimed in claim 1 comprising, before beginning shutting down of said superconducting magnet, determining, in said monitoring processor, whether the superconducting magnet is connected to a further energy source, other than said energy store, and implementing shutting down of said superconducting magnet using energy stored in said energy store only in an absence of a further energy source. 4. A method as claimed in claim 2 comprising, in an absence of a further energy source, switching off said monitoring processor after determining said second point-in-time, and using a timer, as said shutdown controller, to trigger shutting down of said superconducting magnetic. 5. A method as claimed in claim 1 comprising determining said second point-in-time by determining a difference in energy between said stored energy in said energy store and said ramp energy. 6. A method as claimed in claim 1 comprising: in said monitoring processor, determining a ramp-monitoring energy required for monitoring said shutting down of said superconducting magnetic, and determining said second point-in-time dependent on a difference between said determined amount of said stored energy and the ramp energy; if said difference is larger than said ramp-monitoring energy, determining said second point-in-time so that, at said second point-in-time, said energy store contains said ramp energy and said ramp-monitoring energy; and if said difference is smaller than said ramp-monitoring energy, determining said second point-in-time so that, at said second point-in-time, said energy store contains said ramp energy. 7. A system for shutting down a superconducting magnetic of a magnetic resonance apparatus, said system comprising: an energy store in which energy is stored; a monitoring processor configured to determine an amount of stored energy stored in said energy store at a first point-in-time; said monitoring processor being configured to determine a ramp energy that is required for shutting down said superconducting magnet; said monitoring processor being configured to determine a second point-in-time based the determined amount of stored energy and the ramp energy; and using a shutdown controller configured to begin shutting down said superconducting magnet at said second point-in-time, using said energy stored in said energy store. 8. A system as claimed in claim 7 wherein said shutdown controller is said monitoring processor. 9. A system as claimed in claim 7 wherein said energy store comprises at least one of a battery, an accumulator, a super-capacitor, a micro-fuel cell, or a flywheel. 10. A system as claimed in claim 7 wherein said energy store comprises at least two energy storage units, wherein at least one of said at least two energy storage units is redundant with respect to other storage units among said at least two storage units. 11. A magnetic resonance apparatus comprising: a superconducting magnetic; an energy store in which energy is stored; a monitoring processor configured to determine an amount of stored energy stored in said energy store at a first point-in-time; said monitoring processor being configured to determine a ramp energy that is required for shutting down said superconducting magnet; said monitoring processor being configured to determine a second point-in-time based the determined amount of stored energy and the ramp energy; and using a shutdown controller configured to begin shutting down said superconducting magnet at said second point-in-time, using said energy stored in said energy store. 12. A non-transitory, computer-readable data storage medium encoded with programming instructions, said storage medium being loaded into a computer that is a component of, or is connected to, a magnetic resonance apparatus that comprises a superconducting magnetic and an energy store in which energy is stored, said programming instructions causing said computer to: determine an amount of stored energy stored in an energy store at a first point-in-time; determine a ramp energy that is required for shutting down said superconducting magnet; determine a second point-in-time based the determined amount of stored energy and the ramp energy; and begin shutting down said superconducting magnet at said second point-in-time, using said energy stored in said energy store.