Patent Number: 059237171
Section: claims

1. A method for identifying a core loading arrangement for loading nuclear reactor fuel bundles into a reactor core, the core loading arrangement being required to satisfy predetermined design constraints, said method comprising the steps of: assigning each bundle a relative reactivity value within a loading range;  assigning each core location a relative reactivity value;  assigning values to each predetermined constraint;  creating rules for each reactor core location to specify a direction in which to move a bundle to maximize the cycle energy or satisfy a predetermined constraint, or both;  initially simulating a core loading wherein each bundle is loaded into the core location having a core location reactivity value equal to the bundle relative reactivity value; and  determining initial values for cycle energy and design constraints for the initial core loading arrangement.  selecting a first core location;  determining whether the initial core loading arrangement satisfies the design constraints at the first core location; and  if at least one design constraint is not satisfied at the first core location, then searching the rules to determine a direction in which the reactivity value of the first core location should be changed in order to satisfy the constraint.  searching the rules to determine a direction in which the reactivity value of the core location should be changed in order to improve cycle energy if all the design constraints are satisfied at the first core location.  (i) selecting a core location;  (ii) determining whether the initial core loading arrangement satisfies the design constraints at the selected core location;  (iii) if at least one design constraint is not satisfied at the selected core location, then searching the rules to determine a direction in which the reactivity value of the selected core location should be changed in order to satisfy the constraint;  (iv) if all the design constraints are satisfied at the selected core location, then searching the rules to determine a direction in which the reactivity value of the selected core location should be changed in order to improve cycle energy;  (v) if there is no rule for changing the first core location reactivity value, then randomly selecting a reactivity level change for the selected core location; and  (vi) determining new constraint values and cycle energy for the core loading arrangement which results from changing the reactivity value of the selected core location.  initially simulate a core loading in which each bundle is loaded into the respective core location having a core location reactivity value equal to the bundle relative reactivity value; and  determine initial values for cycle energy and the design constraints for the initial core loading arrangement.  select a first core location;  determine whether the initial core loading arrangement satisfies the design constraints at the first core location; and  search the rules to determine a direction in which the reactivity value of the core location should be changed in order to satisfy a design constraint if the design constraint is not satisfied at the first core location.  search the rules to determine a direction in which the reactivity value of the core location should be changed in order to improve cycle energy if all the design constraints are satisfied at the first core location.  determine new constraint values and cycle energy for the core loading arrangement which results from changing the reactivity value of the first core location.  (i) select a core location;  (ii) determine whether the initial core loading arrangement satisfies the design constraints at the selected core location;  (iii) if at least one design constraint is not satisfied at the selected core location, then search the rules to determine a direction in which the reactivity value of the selected core location should be changed in order to satisfy the constraint;  (iv) if all the design constraints are satisfied at the first core location, then search the rules to determine a direction in which the reactivity value of the selected core location should be changed in order to improve cycle energy;  (v) if there is no rule for changing the selected core location reactivity value, then randomly select a reactivity level change for the selected core location; and  (vi) determine new constraint values and cycle energy for the core loading arrangement which results from changing the reactivity value of the selected core location. 2. A method in accordance with claim 1 wherein each core location is assigned a relative reactivity value based on the acceptable reactivity level of each core location. 3. A method in accordance with claim 1 further comprising the step of identifying an optimum core loading arrangement based on the initial core loading arrangement. 4. A method in accordance with claim 3 wherein identifying the optimum core loading arrangement comprises the steps of: 5. A method in accordance with claim 4 further comprising the step of: 6. A method in accordance with claim 5 further comprising the step of randomly selecting a reactivity level change for the first core location if there is no rule for changing the first core location reactivity value. 7. A method in accordance with claim 5 further comprising the step of determining new constraint values and cycle energy for the core loading arrangement which results from changing the reactivity value of the first core location. 8. A method in accordance with claim 3 wherein identifying the optimum core loading arrangement comprises the steps of: 9. A method in accordance with claim 8 wherein each core location is selected and steps (ii)-(vi) are performed for each such selected core location. 10. A method in accordance with claim 9 wherein each core location is analyzed using a depth mode of operation, the depth mode providing that once a change has been made that results in an improved core loading arrangement, then any subsequent change is made to such alternative arrangement in performing steps (ii)-(vi). 11. The method in accordance with claim 9 wherein each core location is analyzed using a breadth mode of operation, the breadth mode providing that each alternative core loading arrangement is analyzed with respect to the initial core loading arrangement in performing steps (ii)-(iv). 12. The method in accordance with claim 9 further comprising the step of generating random core loading arrangements. 13. The method in accordance with claim 12 further comprising the step of selecting a core loading arrangement which satisfies all design constraints and has the highest cycle energy as a best case core loading arrangement. 14. A system for identifying a core loading arrangement for loading nuclear reactor fuel bundles into a reactor core, the core loading arrangement being required to satisfy predetermined design constraints, said system comprising a computer having a memory storage, said memory storage having stored therein a relative reactivity value within a loading range assigned to each bundle, a relative reactivity value assigned to each reactor core location, values assigned to each predetermined design constraint, and rules for each reactor core location which specify a direction in which to move the core location reactivity level to maximize the cycle energy or satisfy a predetermined constraint, or both, said computer programmed to: 15. A system in accordance with claim 14 wherein to identify an optimum core loading arrangement, said computer is further programmed to: 16. A system in accordance with claim 15 wherein said computer is further programmed to: 17. A system in accordance with claim 16 wherein said computer is further programmed to: 18. A system in accordance with claim 14 wherein to identify an optimum core loading arrangement said computer is programmed to: 19. A system in accordance with claim 18 wherein each core location is selected and steps (ii)-(vi) are performed for each such selected core location. 20. A system in accordance with claim 19 wherein said computer is programmed to select a core loading arrangement which satisfies all design constraints and has the highest cycle energy as a best case core loading arrangement.