초록 ▼

A freely oriented portable superconducting magnet is disclosed. Coolant is supplied to the superconducting magnet from a repository separate from the magnet, enabling portability of the magnet. A plurality of support assemblies structurally anchor and thermally isolate the magnet within a thermal sh

A freely oriented portable superconducting magnet is disclosed. Coolant is supplied to the superconducting magnet from a repository separate from the magnet, enabling portability of the magnet. A plurality of support assemblies structurally anchor and thermally isolate the magnet within a thermal shield. A plurality of support assemblies structurally anchor and thermally isolate the thermal shield within a vacuum vessel. The support assemblies restrain movement of the magnet resulting from energizing and cooldown, as well as from changes in orientation, enabling the magnet to be freely orientable.

대표청구항 ▼

I claim: 1. A superconducting magnet apparatus comprising: a toroidal shaped superconducting magnet; a bobbin in thermal contact with said magnet and upon which said magnet disposed, said bobbin and said magnet together comprising a magnet/bobbin subassembly; a toroidal shaped vacuum vessel in whic

I claim: 1. A superconducting magnet apparatus comprising: a toroidal shaped superconducting magnet; a bobbin in thermal contact with said magnet and upon which said magnet disposed, said bobbin and said magnet together comprising a magnet/bobbin subassembly; a toroidal shaped vacuum vessel in which said magnet/bobbin subassembly is disposed; one or more coolants, wherein said coolants are primarily selected based on their thermodynamic and transport properties providing the capability to remove adequate thermal energy in order to maintain said magnet in the superconducting state; one or more transport lines enabling delivery of said coolant to and from said vacuum vessel; at least three inner support assemblies (ISA) distributed circumferentially around said magnet/bobbin subassembly to anchor and support said magnet/bobbin subassembly within said vacuum vessel; each said ISA comprising a support ring and a plurality of restraint members, with said restraint members connecting said magnet/bobbin subassembly to said support ring, and said restraint members being selected from the group consisting of straps, rods/links, beams, and any combination of the foregoing; and one or more coolant flow paths within said vacuum vessel that brings said coolant into thermal contact with said bobbin to remove thermal energy from said magnet by a combination of conducting and convection; wherein the superconducting magnet apparatus further comprises: a toroidal shaped thermal shield within which said magnet/bobbin subassembly is disposed, wherein said inner support assemblies anchor and support said magnet/bobbin subassembly concentrically or off-centrically within said thermal shield, said ISA support rings being structurally attached to said thermal shield; and at least three outer support assemblies (OSA) distributed circumferentially around said thermal shield to anchor and support said thermal shield within said vacuum vessel, with each said OSA comprising a support ring and a plurality of restraint members, with said OSA restraint members connecting said thermal shield to said OSA support ring, said OSA support rings being structurally attached to said vacuum vessel, and wherein OSA restraint members are selected from the group consisting of straps, rods/links, beams, and any combination of the foregoing. 2. The superconducting magnet apparatus of claim 1 wherein: said support rings are structurally attached to said vacuum vessel. 3. The superconducting magnet apparatus of claim 1 wherein: said bobbin coolant flow paths are selected from the group consisting of tubes in thermal contact with said bobbin, channels in said bobbin, and any combination of the foregoing. 4. The superconducting magnet apparatus of claim 1 further comprising: one or more coolant flow paths within said vacuum vessel that brings said coolant into thermal contact with said thermal shield to remove thermal energy from said thermal shield. 5. The superconducting magnet apparatus of claim 4 wherein: said thermal shield coolant paths comprises one or more paths that receives coolant exiting from said bobbin coolant path whereby said coolant removes thermal energy from said thermal shield prior to exiting from said vacuum vessel. 6. The superconducting magnet apparatus of claim 4 wherein: said thermal shield coolant paths are selected from the group consisting of tubes in thermal contact with said thermal shield, channels in said thermal shield, and any combination of the foregoing. 7. The superconducting magnet apparatus of claim 1 further comprising: one or more coolant flow paths within said vacuum vessel that brings said coolant into thermal contact with the electrical leads of said magnet. 8. The superconducting magnet apparatus of claim 4 wherein: said coolants comprise coolant one and coolant two, with coolant one traversing said bobbin coolant path, and coolant two traversing said thermal shield coolant path. 9. The superconducting magnet apparatus of claim 1 further comprising: a bobbin bridge interposed between said magnet/bobbin subassembly and each ISA. 10. The superconducting magnet apparatus of claim 9 wherein: said ISA restraint members are straps, and each said ISA further comprises tension assembly ramps integral with said ISA support ring and tension assemblies, with said straps being wrapped concentrically around said bobbin bridge, and the ends of said straps being attached to said ISA support ring by said tension assemblies and tension assembly ramps. 11. The superconducting magnet apparatus of claim 1 further comprising: a thermal shield bridge interposed between said thermal shield and each OSA. 12. The superconducting magnet apparatus of claim 11 wherein: said OSA restraint members are straps, with said straps being wrapped concentrically around said thermal shield bridge, and the ends of said straps being attached to said OSA support ring. 13. The superconducting magnet apparatus of claim 1 wherein: said ISA restraint members are selected from the group consisting of rods/links and beams; and wherein said ISA restraint members emanate radially and azimuthally. 14. The superconducting magnet apparatus of claim 1 wherein: said OSA restraint members are selected from the group consisting of rods/links and beams; and wherein said OSA restraint members emanate radially and azimuthally. 15. The superconducting apparatus of claim 1 further comprising: a ferromagnetic core disposed in the center bore of said vacuum vessel; and a plurality of radial supports which secure said ferromagnetic core to said vacuum vessel. 16. A superconducting magnet apparatus comprising: a toroidal shaped superconducting magnet; a bobbin in thermal contact with said magnet and upon which said magnet is disposed, said bobbin and said magnet together comprising a magnet/bobbin subassembly, a toroidal shaped vacuum vessel in which said magnet/bobbin subassembly is disposed; one or more coolants, wherein said coolants are primarily selected based on their thermodynamic and transport properties providing the capability to remove adequate thermal energy in order to maintain said magnet in the superconducting state; one or more transport lines enabling delivery of said one or more coolants to and from said vacuum vessel; a toroidal shaped thermal shield within which said magnet/bobbin subassembly is disposed; at least three inner support assemblies (ISA) distributed circumferentially around said magnet/bobbin subassembly to anchor and support said magnet/bobbin subassembly within said thermal shield; a bobbin bridge interposed between said thermal shield and each said ISA; each said ISA comprising a support ring and a plurality of restraint members, said ISA support rings being structurally attached to said thermal vessel, with said restraint members connecting said bobbin bridge to said support ring, and said restraint members being selected from the group consisting of straps, rods/links, beams and any combination of the foregoing; one or more coolant flow paths within said vacuum vessel that brings said one or more coolants into thermal contact with said bobbin to remove thermal energy from said magnet by thermal conduction, and into thermal contact with said thermal shield to remove thermal energy from said thermal shield, wherein said bobbin and thermal shield coolant flow paths are selected from the group consisting of tubes in thermal contact with said bobbin, channels in said bobbin, and any combination of the foregoing; at least three outer support assemblies (OSA) distributed circumferentially around said thermal shield to anchor and support said thermal shield within said vacuum vessel; a thermal shield bridge interposed between said thermal shield and each said OSA; each said OSA comprising a support ring and a plurality of restraint members, said OSA support rings being structurally attached to said vacuum vessel, with said OSA restraint members connecting said thermal shield bridge to said OSA support ring, and wherein OSA restraint members are selected from the group consisting of straps, rods/links, beams and any combination of the foregoing. 17. The superconducting magnet apparatus of claim 16 wherein: said OSA restraint members are straps, with said straps being wrapped concentrically around said thermal shield bridge, and the ends of said strap being attached to said OSA support ring; said ISA restraint members are straps, and each said ISA further comprises tension assembly ramps integral with said ISA support ring and tension assemblies, with said straps being wrapped concentrically around said bobbin bridge, and the ends of said straps being attached to said ISA support ring by said tension assemblies and tension assembly ramps. 18. The superconducting magnet apparatus of claim 16 wherein: said coolants comprise coolant one and coolant two, with coolant one traversing said bobbin coolant path, and coolant two traversing said thermal shield coolant path. 19. The superconducting magnet apparatus of claim 16 wherein: said coolant traverses said bobbin coolant path first, then traverses said thermal shield coolant path.