Patent Number: 
Section: claims

1. A hybrid molten salt reactor (HMSR) comprising:a source of energetic neutrons, the energetic neutrons having an average energy per neutron of 14 MeV or greater;a critical molten salt reactor comprising a reactor vessel;a loop comprising a path in the reactor vessel and around the source of energetic neutrons; anda molten salt comprising a dissolved mixture of salts of fissile actinides and fertile actinides, the molten salt circulating in the loop and having a sustained exothermic nuclear reaction comprising:the fissile and fertile actinides being irradiated by the energetic neutrons when exposed to the source of energetic neutrons, the energetic neutrons inducing subcritical nuclear fission and generating daughter neutrons;the fissile actinides undergoing critical nuclear fission when circulating through the vessel of the critical molten salt reactor and generating daughter neutrons; anda portion of the fertile actinides capturing a portion of the daughter neutrons, the captured daughter neutrons inducing transmutation of the portion of fertile actinides into fissile actinides. 2. The hybrid molten salt reactor of claim 1, further including a blanket of tanks surrounding the source of energetic neutrons, the molten salt circulating through the blanket of tanks, a thickness and an arrangement of the blanket of tanks enabling an adequate fraction of the energetic neutrons to be absorbed in the molten salt to maintain a sufficient inventory of fissile actinides in the molten salt to maintain criticality of the critical molten salt reactor. 3. The hybrid molten salt reactor of claim 2, wherein the thickness and the arrangement of the blanket of tanks enables the molten salt to absorb a portion of the energetic neutrons and generated daughter neutrons to maintain a desired fissile inventory. 4. The hybrid molten salt reactor of claim 2, wherein the blanket of tanks is chemically and mechanically compatible with the molten salt, each tank having separate plumbing connections for liquid inflow and outflow, the separate plumbing connections enabling draining the tank based on gravity. 5. The hybrid molten salt reactor of claim 1, further including a controller adjusting an average power level of the source of energetic neutrons to maintain fission criticality in the critical molten salt reactor, the fission induced by the energetic neutrons and absorption of the resulting fission daughter neutrons by fertile actinides maintaining fissile actinides in the molten salt at a concentration necessary for fission criticality in the molten salt reactor. 6. The hybrid molten salt reactor of claim 5, further including neutron absorbing control rods adapted to be partially inserted into the molten salt reactor to reduce a stable operating temperature of the molten salt reactor and adapted to be fully inserted into the molten salt to completely halt and preclude fission chain reactions. 7. The hybrid molten salt reactor of claim 1, further including a fission product removal system enabling removal of one or more fission products from the molten salt. 8. The hybrid molten salt reactor of claim 1, further including a fuel system adding actinide salts to the molten salt at a rate which compensates for the loss by fission of the actinides previously dissolved in the molten salt. 9. The hybrid molten salt reactor of claim 8, further including a fission product removal system enabling removal of one or more fission products from the molten salt, wherein the fission product removal system removes the fission products at a rate enabling indefinitely maintained fission critically in the critical molten salt reactor. 10. The hybrid molten salt reactor of claim 9, wherein actinide fueling and fission product removal is sufficient to enable 100% fission energy utilization of the fertile actinides. 11. The hybrid molten salt reactor of claim 1, further including a pump system to pump the molten salt around the source of energetic neutrons and through the vessel of the critical molten salt reactor. 12. The hybrid molten salt reactor of claim 11, further including a heat exchanger receiving heat produced by the HMSR, wherein the pump system pumps the molten salt through the heat exchanger. 13. The hybrid molten salt reactor of claim 1, wherein the critical molten salt reactor includes a moderator. 14. The hybrid molten salt reactor of claim 13, wherein the moderator is lithium hydride using the deuterium isotope of hydrogen and using lithium enriched in the lithium-7 isotope. 15. The hybrid molten salt reactor of claim 13, wherein the moderator is a graphite core. 16. The hybrid molten salt reactor of claim 1, wherein the molten salt contains lithium fluoride enriched in the lithium-7 isotope and sodium fluoride. 17. The hybrid molten salt reactor of claim 1, wherein the molten salt contains fertile thorium-232 and the daughter neutrons transmute the fertile thorium-232 into fissile uranium-233. 18. The hybrid molten salt reactor of claim 1, wherein the molten salt contains fertile uranium-238 and the daughter neutrons transmute the fertile uranium-238 into fissile plutonium-239. 19. The hybrid molten salt reactor of claim 1, wherein the source of energetic neutrons is a nuclear fusion device producing the energetic neutrons from the fusion of hydrogen isotopes and the hybrid molten salt reactor breeds tritium using a molten salt recipe that includes lithium having an isotopic composition ratio, lithium-6 to lithium-7, chosen to cause tritium production. 20. The hybrid molten salt reactor of claim 1, wherein the source of energetic neutrons is a spallation device producing the energetic neutrons by impacting energetic ions on a target material. 21. The hybrid molten salt reactor of claim 1, wherein the molten salt contains a mixture of one or more actinides from spent nuclear fuel wastes of one or more nuclear fission reactors, wherein absorption of neutrons either produced as fission daughters or resulting from (n,2n) and/or (n,3n) reactions fissions fissile actinides and converts fertile actinides into fissile actinides which then fission. 22. The hybrid molten salt reactor of claim 1, wherein the molten salt contains natural mined uranium which has not been isotopically enriched, the natural mined uranium containing fertile uranium-238 and fissile uranium-235, the fission daughter neutrons transmuting the fertile uranium-238 into fissile plutonium-239 and the fissile plutonium-239 undergoing fission with the uranium-235. 23. A method for integrating a source of energetic neutrons with a critical molten salt reactor, the energetic neutrons having an average energy per neutron of 14 MeV or greater, the method comprising:circulating a molten salt containing dissolved actinide salts through a core region of the critical molten salt reactor and around the source of energetic neutrons;irradiating the circulating molten salt with energetic neutrons, the energetic neutrons transmuting fertile actinides to fissile actinides in the molten salt;heating the circulating molten salt with fission in the core region of the critical molten salt reactor; andfeedback controlling an output of the source of energetic neutrons to be a fraction of a total output power and modulating that fraction to increase or decrease a fissile inventory of the molten salt and resulting keff criticality eigenvalue. 24. The method of claim 23, wherein circulating the molten salt around the source of energetic neutrons includes circulating the molten salt through a blanket of tanks surrounding the source of energetic neutrons. 25. The method of claim 23, wherein circulating the molten salt further includes circulating the molten salt through an external heat exchanger, the external heat exchanger cooling the molten salt by transferring heat to an intermediate fluid loop. 26. The method of claim 23, wherein circulating the molten salt further includes using heat in the intermediate fluid loop for electricity production. 27. The method of claim 23, further including:compensating for the loss by fission of the actinides previously dissolved in the molten salt by adding a mixture of new actinide salts to the circulating molten salt. 28. The method of claim 27, further including:maintaining criticality by removing fission product ash from the molten salt at a given rate, the given rate limiting fission product ash inventories in the molten salt. 29. The method of claim 28, further including:eliminating actinides from a waste stream; andstabilizing actinide inventories in the molten salt. 30. The method of claim 29, wherein fission energy utilization of actinides in the molten salt is 100 percent. 31. The method of claim 28, wherein the given removal rate of fission product ash enhances transmutation within the molten salt of long-lived radioactive isotopes into short-lived or stable isotopes and minimizes long-lived radioactivity in a waste stream without interrupting criticality of the critical molten salt reactor.