Patent Number: 051606968
Section: claims

1. An apparatus for producing power from fertile nuclear materials and transmuting wastes therefrom to less radioactive species, said apparatus comprising in combination: a. means for generating a high intensity, high-energy beam of protons;  b. a liquid-metal spallation target having an upwardly facing open surface for producing a high neutron flux upon being impacted by high-energy protons;  c. a substantially gas-tight enclosure surrounding said spallation target;  d. windowless means for directing the beam of protons onto the open surface of said spallation target;  e. neutron moderation means for thermalizing neutrons generated from said spallation target;  f. first means for containing the fertile nuclear material disposed within said neutron moderation means and spaced apart from and outside of said spallation target;  g. second means for containing materials to be transmuted disposed within said neutron moderation means and spaced apart and outside of said spallation target, yet closer thereto than said first containment means;  h. first flowing means for passing the fertile nuclear material and transmutation products thereof through said first containment means;  i. means for combining the fertile nuclear material with a molten salt eutectic and causing the combination formed thereby to flow through said first flowing means; and  j. means for extracting fission products from the molten salt eutectic flowing through said first flowing means, separating the stable and short-lived fission products therefrom, and introducing the remaining material into said second containment means for transmutation.  a. means for generating a high intensity, high-energy beam of protons;  b. a liquid-metal spallation target having an upwardly facing open surface for producing a high neutron flux upon being impacted by high-energy protons;  c. a substantially gas-tight enclosure surrounding said spallation target;  d. windowless means for directing the beam of protons onto the open surface of said spallation target;  e. neutron moderation means for thermalizing neutrons generated from said spallation target;  f. first means for containing the fissile nuclear materials disposed within said neutron moderation means and spaced apart from and outside of said spallation target;  g. second means for containing material to be transmuted disposed within said neutron moderation means and spaced apart and outside of said spallation target, yet closer thereto than said first containment means;  h. first flowing means for passing the fissile nuclear material and transmutation products thereof through said first containment means;  i. means for combining the fissile nuclear material with a molten salt eutectic and causing the combination formed thereby to flow through said first flowing means; and  j. means for extracting fission products from the molten salt eutectic flowing through said first flowing means, separating the stable and short-lived fission products therefrom, and introducing the remaining material into said second containment means for transmutation.  a. means for generating a high intensity, high-energy beam of protons;  b. a liquid-metal spallation target having an upwardly facing open surface for producing a high neutron flux upon being impacted by high-energy protons;  c. a substantially gas-tight enclosure surrounding said spallation target;  d. windowless means for directing the beam of protons onto the open surface of said spallation target;  e. neutron moderation means for thermalizing neutrons generated from said spallation target; and  f. first means for containing the material to be transmuted disposed within said neutron moderation means and spaced apart from and outside of said spallation target;  g. second means for containing material to be transmuted disposed within said neutron moderation means and spaced apart and outside of said spallation target, yet closer thereto than said first containment means;  h. first flowing means for passing the material to be transmuted and transmutation products thereof through said first containment means;  i. means for combining the material to be transmuted with a molten salt eutectic and causing the combination formed thereby to flow through said first flowing means; and  j. means for extracting transmutation products from the molten salt eutectic flowing through said first flowing means, separating the stable and short-lived fission products therefrom, and introducing the remaining material into said second containment means for transmutation.  a. means for generating a high intensity, high-energy beam of protons;  b. a liquid-metal spallation target having an upwardly facing open surface for producing a high neutron flux upon being impacted by high-energy protons;  c. a substantially gas-tight enclosure surrounding said spallation target;  d. windowless means for directing the beam of protons onto the open surface of said spallation target;  e. neutron moderation means for thermalizing neutrons generated from said spallation target;  f. first means for containing the higher actinide materials disposed within said neutron moderation means and spaced apart from and outside of said spallation target; and  g. means disposed within said neutron moderation means and spaced apart from said spallation target for holding materials which generate tritium upon interaction with neutrons;  h. second means for containing material to be transmuted disposed within said neutron moderation means and spaced apart and outside of said spallation target, yet closer thereto than said first containment means;  i. first flowing means for passing the higher actinide materials to be transmuted and transmutation products thereof through said first containment means;  j. means for combining the higher actinide materials to be transmuted with a molten salt eutectic and causing the combination formed thereby to flow through said first flowing means; and  k. means for extracting transmutation products from the molten salt eutectic flowing through said first flowing means, separating the stable and short-lived fission products therefrom, and introducing the remaining material into said second containment means for transmutation. 2. The apparatus as described in claim 1, wherein the fertile nuclear materials are selected from the group consisting of .sup.238 U, .sup.232 Th, and mixtures thereof. 3. The apparatus as described in claim 1, wherein said spallation target includes high-Z material for production of neutrons by interaction with the high-energy beam of protons. 4. The apparatus as described in claim 3, wherein said liquid-metal spallation target includes a lead-bismuth eutectic mixture. 5. The apparatus as described in claim 4, further comprising first heat exchanger means through which the liquefied lead-bismuth eutectic is circulated in order to remove generated heat. 6. The apparatus as described in claim 1, wherein said high intensity, high-energy proton beam generation means provides protons having energies between 400 MeV and 10 GeV with an average proton beam current of greater than 10 ma. 7. The apparatus as described in claim 1, wherein said neutron moderation means includes heavy water. 8. The apparatus as described in claim 1, wherein said high intensity, high-energy proton beam generation means, said spallation target, and said neutron moderation means produce a thermal neutron flux sufficient to permit substantial two-neutron transmutation processes to occur in waste products resulting from producing power from the fertile nuclear material. 9. The apparatus as described in claim 1, further comprising second heat exchanger means for removing heat from the flowing molten salt eutectic and fertile nuclear material combination after the combination passes through said neutron moderation means. 10. The apparatus as described in claim 9, further comprising power generation means for generating electricity from heat removed by either or both of said first heat exchanger means and said second heat exchanger means, and for returning a portion of the electricity to said high intensity, high-energy proton beam generation means. 11. The apparatus as described in claim 1, wherein said windowless means for directing the high intensity, high-energy proton beam into said spallation target means includes a cooled, evacuated beam transport tube having one end thereof forming a substantially gas-tight seal to said gas-tight enclosure and disposed substantially vertically above said spallation target, the other end thereof forming a substantially gas-tight seal with said proton beam generating means; whereby volatile gases produced within said spallation target means may be removed from the vicinity of the high intensity, high-energy proton beam, and whereby the high intensity, high-energy proton beam may be directed substantially vertically and directly onto the open surface of said liquid-metal spallation target. 12. The apparatus as described in claim 5, wherein said gas-tight enclosure further comprises a convection air-cooled holding tank located below said first heat exchanger means into which the liquid-metal may drain, and normally-closed valve means responsive to a chosen operating condition demanding that said valve means be opened, thereby permitting the liquid metal to drain out of said first heat exchanger means and out of the region of said spallation target. 13. The apparatus as described in claim 1, further comprising means for sensing and maintaining the ion/fluoride valence balance in the molten salt eutectic. 14. The apparatus as described in claim 1, further comprising means for continuously removing .sup.233 Pa from the molten salt eutectic flowing through said flowing means in the event .sup.232 Th is utilized as a fertile material. 15. The apparatus as described in claim 1, further comprising second flowing means for passing the fission products through said second containment means. 16. An apparatus for producing power from fissile nuclear materials without necessity for long-term nuclear waste management, said apparatus comprising in combination: 17. The apparatus as described in claim 16, wherein the fissile nuclear materials are selected from the group consisting of .sup.235 U, .sup.239 Pu, and mixtures thereof. 18. The apparatus as described in claim 16, wherein said spallation target includes high-Z material for production of neutrons by interation with the high-energy beam of protons. 19. The apparatus as described in claim 18, wherein said liquid-metal spallation target includes a lead-bismuth eutectic mixture. 20. The apparatus as described in claim 19, further comprising first heat exchanger means through which the liquefied lead-bismuth eutectic is circulated in order to remove generated heat. 21. The apparatus as described in claim 16, wherein said high intensity, high-energy proton beam generation means provides protons having energies between 400 MeV and 10 GeV with an average proton beam current of greater than 10 ma. 22. The apparatus as described in claim 16, wherein said neutron moderation means includes heavy water. 23. The apparatus as described in claim 16, wherein said high intensity, high-energy proton beam generation means, said spallation target, and said neutron moderation means produce a thermal neutron flux sufficient to permit substantial two-neutron transmutation processes to occur in waste products resulting from producing power from the fissile nuclear material. 24. The apparatus as described in claim 16, further comprising second heat exchanger means for removing heat from the flowing molten salt eutectic and fissile nuclear material combination after the combination passes through said neutron moderation means. 25. The apparatus as described in claim 24, further comprising power generation means for generating electricity from heat removed by either or both of said first heat exchanger means and said second heat exchanger means, and for returning a portion of the electricity to said high intensity, high-energy proton beam generation means. 26. The apparatus as described in claim 16, wherein said windowless means for directing the high intensity, high-energy proton beam into said spallation target means includes a cooled, evacuated beam transport tube having one end thereof forming a substantially gas-tight seal to said gas-tight enclosure and disposed substantially vertically above said spallation target, the other end thereof forming a substantially gas-tight seal with said proton beam generating means; whereby volatile gases produced within said spallation target means may be removed from the vicinity of the high intensity, high-energy proton beam, and whereby the high intensity, high-energy proton beam may be directed substantially vertically and directly onto the open surface of said liquid-metal spallation target. 27. The apparatus as described in claim 20, wherein said gas-tight enclosure further comprises a convection air-cooled holding tank located below said first heat exchanger means into which the liquid-metal may drain, and normally-closed valve means responsive to a chosen operating condition demanding that said valve means be opened, thereby permitting the liquid metal to drain out of said first heat exchanger means and out of the region of said spallation target. 28. The apparatus as described in claim 16, further comprising means for sensing and maintaining the ion/fluoride valence balance in the molten salt eutectic. 29. The apparatus as described in claim 16, wherein said first fissile nuclear material containment means contains a sub-critical inventory of fissile material. 30. The apparatus as described in claim 1, further comprising second flowing means for passing the fission products through said second containment means. 31. An apparatus for transmuting higher actinide waste along with .sup.99 Tc, .sup.129 I, and other fission product waste, thereby eliminating necessity for long-term nuclear waste storage, said apparatus comprising in combination: 32. The apparatus as described in claim 31, wherein the higher actinide materials are selected from the group consisting of .sup.237 Np, .sup.241 Am, .sup.244 Cm, and mixtures thereof. 33. The apparatus as described in claim 31, wherein said spallation target includes high-Z material for production of neutrons by interaction with the high-energy beam of protons. 34. The apparatus as described in claim 33, wherein said liquid-metal spallation target includes a lead-bismuth eutectic mixture. 35. The apparatus as described in claim 34, further comprising first heat exchanger means through which the liquefied lead-bismuth eutectic is circulated in order to remove generated heat. 36. The apparatus as described in claim 31, wherein said high intensity, high-energy proton beam generation means provides protons having energies between 400 MeV and 10 GeV with an average proton beam current of greater than 10 ma. 37. The apparatus as described in claim 31, wherein said neutron moderation means includes heavy water. 38. The apparatus as described in claim 31, wherein said high intensity, high-energy proton beam generation means, said spallation target, and said neutron moderation means produce a thermal neutron flux sufficient to permit substantial two-neutron transmutation processes to occur in the material to be transmuted. 39. The apparatus as described in claim 31, further comprising second heat exchanger means for removing heat from the flowing molten salt eutectic and material to be transmuted combination after the combination passes through said neutron moderation means. 40. The apparatus as described in claim 39, further comprising power generation means for generating electricity from heat removed by either or both of said first heat exchanger means and said second heat exchanger means, and for returning a portion of the electricity to said high intensity, high-energy proton beam generation means. 41. The apparatus as described in claim 31, wherein said windowless means for directing the high intensity, high-energy proton beam into said spallation target means includes a cooled, evacuated beam transport tube having one end thereof forming a substantially gas-tight seal to said gas-tight enclosure and disposed substantially vertically above said spallation target, the other end thereof forming a substantially gas-tight seal with said proton beam generating means; whereby volatile gases produced within said spallation target means may be removed from the vicinity of the high intensity, high-energy proton beam, and whereby the high intensity, high-energy proton beam may be directed substantially vertically and directly onto the open surface of said liquid-metal spallation target. 42. The apparatus as described in claim 35, wherein said gas-tight enclosure further comprises a convection air-cooled holding tank located below said first heat exchanger means into which the liquid-metal may drain, and normally-closed valve means responsive to a chosen operating condition demanding that said valve means be opened, thereby permitting the liquid-metal to drain out of said first heat exchanger means and out of the region of said spallation target. 43. The apparatus as described in claim 31, further comprising means for sensing and maintaining the ion/fluoride valence balance in the molten salt eutectic. 44. The apparatus as described in claim 31, wherein a chosen quantity of .sup.239 Pu is added to the molten salt eutectic to generate sufficient heat to power said proton beam generating means, and to provide additional neutrons, while maintaining sub-criticality. 45. The apparatus as described in claim 31, further comprising second flowing means for passing the fission products through said second containment means. 46. An apparatus for simultaneously transmuting higher actinide materials and producing tritium without necessity for long-term nuclear waste storage, said apparatus comprising in combination: 47. The apparatus as described in claim 46, wherein the higher actinide materials are selected from the group consisting of .sup.237 Np, .sup.241 Am, .sup.244 Cm, and mixtures thereof. 48. The apparatus as describe in claim 46, wherein the materials which generate tritium upon interaction with neutrons are selected from the group consisting of .sup.3 He, .sup.6 Li, and mixtures thereof. 49. The apparatus as described in claim 46, wherein said spallation target includes high-Z material for production of neutrons by interation with the high-energy beam of protons. 50. The apparatus as described in claim 49, wherein said liquid-metal spallation target includes a lead-bismuth eutectic mixture. 51. The apparatus as described in claim 50, further comprising first heat exchanger means through which the liquefied lead-bismuth eutectic is circulated in order to remove generated heat. 52. The apparatus as described in claim 46, wherein said high intensity, high-energy proton beam generation means provides protons having energies between 400 MeV and 10 GeV with an average proton beam current of greater than 10 ma. 53. The apparatus as described in claim 46, wherein said neutron moderation means includes heavy water. 54. The apparatus as described in claim 46, wherein said high intensity, high-energy proton beam generation means, said spallation target, and said neutron moderation means produce a thermal neutron flux sufficient to permit substantial two-neutron transmutation processes to occur in the higher actinide materials. 55. The apparatus as described in claim 46, further comprising second heat exchanger means for removing heat from the flowing molten salt eutectic and higher actinide materials combination after the combination passes through said neutron moderation means. 56. The apparatus as described in claim 55, further comprising power generation means for generating electricity from heat removed by either or both of said first heat exchanger means and said second heat exchanger means, and for returning a portion of the electricity to said high intensity, high-energy proton beam generation means. 57. The apparatus as described in claim 46, wherein said windowless means for directing the high intensity, high-energy proton beam into said spallation target means includes a cooled, evacuated beam transport tube having one end thereof forming a substantially gas-tight seal to said gas-tight enclosure and disposed substantially vertically above said spallation target, the other end thereof forming a substantially gas-tight seal with said proton beam generating means; whereby volatile gases produced within said spallation target means may be removed from the vicinity of the high intensity, high-energy proton beam, and whereby the high intensity, high-energy proton beam may be directed substantially vertically and directly onto the open surface of said liquid-metal spallation target. 58. The apparatus as described in claim 51, wherein said gas-tight enclosure further comprises a convection air-cooled holding tank located below said first heat exchanger means into which the liquid-metal may drain, and normally-closed valve means responsive to a chosen operating condition demanding that said valve means be opened, thereby permitting the liquid metal to drain out of said first heat exchanger means and out of the region of said spallation target. 59. The apparatus as described in claim 46, further comprising means for sensing and maintaining the ion/fluoride valence balance in the molten salt eutectic. 60. The apparatus as described in claim 46, wherein sufficient .sup.239 Pu is added to the molten salt eutectic to generate sufficient heat to power said proton beam generating means, and to provide additional neutrons.