Patent Number: 051494914
Section: claims

1. A fuel management method for a dual-phase nuclear reactor, said method comprising: installing a fuel bundle at a first core location accessed by coolant through a relatively small aperture, each of said bundles having a predetermined group of fuel elements;  operating said reactor a first time;  shutting down said reactor;  reinstalling said fuel bundle at a second core location accessed by coolant through a relatively large aperture; and  operating said reactor a second time.  shutting down said reactor;  reinstalling said fuel bundle at a peripheral core location; and  operating said reactor a third time.  shutting down said reactor; and  disposing of said fuel bundle so that said fuel bundle is installed exactly three times in said reactor.  installing a fuel bundle at a first core location accessed by coolant through a relatively small aperture so as to establish a relatively low coolant flow rate and thus a relatively high conversion ratio in said bundle when said reactor is next operated;  operating said reactor a first time;  shutting down said reactor;  reinstalling said fuel bundle at a second core location accessed by coolant through a relatively large aperture so as to establish a relatively high coolant flow rate and thus a relatively low conversion ratio when said reactor is next operated, said second core location being radially inward of said first core location; and  operating said reactor a second time.  shutting down said reactor;  reinstalling said fuel bundle at a peripheral core location characterized by a relatively low coolant flow rate; and  operating said reactor a third time.  a core plate defining an array of fuel bundle locations, including conversion locations and power locations, said power locations being characterized by larger flow orifices than said conversion locations, said conversion locations being located radially outside said power locations;  fuel bundles with relatively large quantities of fertile fuel disposed at said conversion locations; and  fuel bundles with relatively large quantities of fissile conversion products at said power locations;  whereby, when an incorporating reactor is operating, said fuel bundles with relatively large quantities of fertile fuel are exposed to relatively large voids and thus to fast neutrons that promote conversion of fertile fuel to fissile fuel, said fuel bundles with relatively large quantities of fissile conversion products are exposed to relatively small voids so that moderation is greater and more thermal neutrons are present to promote fissioning.  fuel bundles with relatively little fissile fuel and relatively large quantities of fission byproducts at said peripheral locations, said fuel bundles at said peripheral locations each having a face not opposing any other of said fuel bundles in said core. 2. A method as recited in claim 1 wherein said second core location is radially inward of said first core location. 3. A method as recited in claim 2 further comprising additional steps following said step of operating said reactor a second time, said additional steps comprising: 4. A method as recited in claim 3 further comprising additional steps following said step of operating said reactor a third time, said additional steps comprising: 5. A fuel management method for a dual-phase nuclear reactor, said method comprising: 6. A method as recited in claim 5 further comprising additional steps following said step of operating said reactor a second time, said additional steps comprising: 7. A core for a dual-phase nuclear reactor comprising: 8. A reactor core as recited in claim 7 wherein said core plate also includes peripheral locations and said core further comprises: