Patent Number: 052672760
Section: claims

1. A method for analyzing neutron transport including determining neutron collision/transfer cross-section in a nuclear reactor assembly, wherein said nuclear reactor assembly includes neutron moderating and neutron absorbing elements arranged in a given configuration and comprised of selected materials, said method comprising the steps of: determining appropriate geometric representations of the configuration and materials of said nuclear reactor assembly;  generating a fixed inner frame containing said geometric representations of said nuclear reactor assembly;  generating an outer frame comprised of a plurality of parallel equidistant rays, wherein each of said rays corresponds to a respective path of travel of a neutron;  rotating said outer frame relative to said fixed inner frame whereby said rays pass through the geometric representations of said nuclear reactor assembly to provide a mesh-independent ray trace of the neutrons in said nuclear reactor assembly;  calculating the collision/transfer probabilities and cross-section of the neutrons in said nuclear reactor assembly; and  applying said calculated collision/transfer probabilities and cross-section of the neutrons to said geometric representations of the configuration and materials of said nuclear reactor assembly.  determining appropriate geometric representations of the configuration and materials of said nuclear reactor assembly;  generating a fixed inner frame containing said geometric representations of said nuclear reactor assembly including utilizing a Monte Carlo code in describing the geometric configuration of said nuclear reactor assembly and employing combinatorial geometry wherein a predetermined set of geometric bodies are logically combined to provide a number of different shapes of said nuclear reactor assembly for analysis; generating an outer frame comprised of a plurality of parallel equidistant rays, wherein each of said rays corresponds to a respective path of travel of a neutron;  rotating said outer frame relative to said fixed inner frame whereby said rays pass through the geometric representations of said nuclear reactor assembly to provide a mesh-independent ray trace of the neutrons in said nuclear reactor assembly;  varying the energy of the neutrons being analyzed over a predetermined energy range;  calculating the collision/transfer probabilities and cross-section of the neutrons in said nuclear reactor assembly for various nuclear reactor assembly geometries over a range of neutron energies; and  applying said calculated collision/transfer probabilities and cross-section of the neutrons to said geometric representations of the configuration and materials of said nuclear reactor assembly.  first means for determining appropriate representation of the configuration and materials of said nuclear reactor assembly;  second combinatorial geometry means for generating a fixed inner frame containing said geometric representations of said nuclear reactor assembly by combining a predetermined set of geometric bodies to provide a number of different shapes of said nuclear reactor assembly;  third ray generating means for generating an outer frame comprised of a plurality of parallel equidistant rays, wherein each of said rays corresponds to a respective path of travel of a neutron;  fourth means for rotating said outer frame relative to said fixed inner frame whereby said rays pass through the geometric representations of said nuclear reactor assembly to provide a mesh-independent ray trace of the neutrons in said nuclear reactor assembly;  calculating means for determining the collision/transfer probabilities and cross-section of the neutrons in said nuclear reactor assembly; and  fifth means for applying said calculated collision/transfer probabilities and cross-section of the neutrons to said geometric representations of the configuration and materials of said nuclear reactor assembly.  first means for determining appropriate representations of the configuration and materials of said nuclear reactor assembly;  second Monte Carlo code and combinatorial geometry means for generating a fixed inner frame containing said geometric representations of said nuclear reactor assembly for describing the geometric configuration of said nuclear reactor assembly and for combining a predetermined set of geometric bodies to provide a number of different shapes of said nuclear reactor assembly for analysis;  third ray generating means for generating an outer frame comprised of a plurality of parallel equidistant rays, wherein each of said rays corresponds to a respective path of travel of a neutron;  fourth means for rotating said outer frame relative to said fixed inner frame whereby said rays pass through the geometric representations of said nuclear reactor assembly to provide a mesh-independent ray trace of the neutrons in said nuclear reactor assembly;  fifth means for varying the energy of the neutrons being analyzed over a predetermined energy range;  calculating means for determining the collision/transfer probabilities and cross-section of the neutrons in said nuclear reactor assembly for various nuclear reactor assembly geometries over a range of neutron energies; and  sixth means for applying said calculated collision/transfer probabilities and cross-section of the neutrons to said geometric representations of the configuration and materials of said nuclear reactor assembly. 2. The method of claim 1 wherein the step of generating said fixed inner frame containing geometric representations of said nuclear reactor assembly includes utilizing a Monte Carlo code in describing the geometric configuration of said nuclear reactor assembly. 3. The method of claim 2 wherein the step of generating said fixed inner frame further includes defining zone boundaries in said nuclear reactor assembly, said method further comprising the step of calculating an intercept of a neutron track with a zone boundary of said nuclear reactor assembly. 4. The method of claim 3 wherein the step of generating said fixed inner frame employs combinatorial geometry wherein a predetermined set of geometric bodies are logically combined to provide a number of different shapes of said nuclear reactor assembly for analysis. 5. The method of claim 1 further comprising the step of varying the energy of the neutrons over a predetermined energy range in calculating the collision/transfer probabilities and cross-section of the neutrons over said predetermined energy range. 6. The method of claim 1 wherein said fixed inner frame contains geometric representations of a boiling water reactor assembly. 7. The method of claim 1 wherein said fixed inner frame contains geometric representations of a helium cooled, graphite-moderated reactor assembly. 8. The method of claim 1 wherein the steps of generating said fixed inner frame and said outer frame and rotating said outer frame relative to said inner frame are independent of the calculation of collision/transfer probabilities and cross-section of the neutrons. 9. A method for analyzing neutron transport including determining neutron collision/transfer cross-section in a nuclear reactor assembly, wherein said nuclear reactor assembly includes neutron moderating and neutron absorbing elements arranged in a given configuration and comprised of selected materials, said method comprising the steps of: 10. Apparatus for analyzing neutron transport including determining neutron collision/transfer cross-section in a nuclear reactor assembly, wherein said nuclear reactor assembly includes neutron moderating and neutron absorbing elements arranged in a given configuration and comprised of selected materials, said apparatus comprising: 11. The apparatus of claim 10 wherein said second combinatorial geometry means for generating said fixed inner frame includes geometric representations of said nuclear reactor assembly utilizing a Monte Carlo code in describing the geometric configuration of said nuclear reactor assembly. 12. The apparatus of claim 11 wherein said second combinatorial geometry means for generating said fixed inner frame further includes zone boundaries of said nuclear reactor assembly, said apparatus further comprising means for calculating an intercept of a neutron track with a zone boundary of said nuclear reactor assembly. 13. The apparatus of claim 10 further comprising energy varying means for varying the energy of the neutrons over a predetermined energy range in calculating the collision/transfer probabilities and cross-section of the neutrons over said predetermined energy range. 14. The apparatus of claim 10 wherein said second combinatorial geometry means for generating said fixed inner frame contains geometric representations of a boiling water reactor assembly. 15. The apparatus of claim 10 wherein said second combinatorial geometry means for generating said fixed inner frame contains geometric representations of a helium cooled, graphite-moderated reactor assembly. 16. The apparatus of claim 10 wherein said second combinatorial geometry means for generating said fixed inner frame, said third ray generating means for generating said outer frame, and said fourth means for rotating said outer frame relative to said inner frame are independent of the calculation of collision/transfer probabilities and cross-section of the neutrons. 17. Apparatus for analyzing neutron transport including determining neutron collision/transfer cross-section in a nuclear reactor assembly, wherein said nuclear reactor assembly includes neutron moderating and neutron absorbing elements arranged in a given configuration and comprised of selected materials, said apparatus comprising: