Patent Number: 059129336
Section: claims

1. A method for direct evaluation of an operating limit minimum critical power ratio (OLMCPR) of a boiling water reactor (BWR) using computer simulation(s) of postulated operational events, said reactor described by one or more parametric quantities indicative of design constraints and operating conditions, comprising the steps, executed by a computer, of: a) initializing said quantities to nominal values;  b) determining steady state initial conditions of reactor operation;  c) simulating an operational event for a plurality of fuel rods in a BWR core;  d) calculating a minimum critical power ratio (MCPR) for each fuel rod simulated in step (c);  e) determining a probability distribution P(MCPR) of potential MCPR values for each MCPR value obtained in step (d);  f) calculating a value for a total number of fuel rods subject to boiling transition (NRSBT) by summing portions of probability distributions corresponding to values for MCPR where MCPR&lt;1.0 for each probability distribution from step (e);  g) perturbing one or more of said parametric quantities and recalculating another value for NRSBT;  h) repeating steps (b) through (g) for a predetermined number of perturbations;  i) developing a histogram of NRSBT values calculated in steps (f) through (g);  j) calculating a nominal NRSBT value, based on a central tendency of an NRSBT distribution, from the histogram of NRSBT values compiled in step (i);  k) calculating a confidence interval for the nominal NRSBT value;  l) selecting an OLMCPR for the reactor as the initial minimal MCPR such that, for a simulation of the most limiting operational event the nominal NRSBT value at a prescribed level of confidence remains less than a predetermined cutoff value; and  m) effecting said BWR operation by applying the OLMCPR selected in step (l) as an operational control parameter.  (i) simulate an anticipated operational occurrence for the reactor;  (ii) determine a minimum critical power ratio (MCPR) for each individual fuel rod simulated;  (iii) calculate a probability distribution P(MCPR) of potential MCPR values for each MCPR value;  (iv) calculate a value for a number of fuel rods subject to boiling transition (NRSBT) by summing portions of probability distributions corresponding to values for MCPR where MCPR&lt;1.0 for all rods simulated, then repetitively calculate further values for NRSBT after perturbing one or more of said parametric quantities for a predetermined number of different perturbations;  (v) develop a histogram of calculated NRSBT values over all perturbations; and  (vi) select the OLMCPR from a minimal MCPR such that, for a simulation of the most limiting operational event, the nominal NRSBT value at a prescribed level of confidence as determined from analysis of the histogram determined from step (v) remains less than a predetermined cutoff value.  first instruction sequence means for performing a multi-dimensional simulation of reactor thermal hydraulics and power during an operational event in the reactor; and  second instruction sequence means, coupled to said first instruction means, for directly calculating an OLMCPR value based on a statistic evaluation of a minimum critical power ratio (MCPR) for each fuel rod, as obtained from said first instruction sequence means, and for developing a histogram of possible NRSBT (number of fuel rods subject to boiling transition) values calculated from perturbations of predetermined reactor plant state values and fuel rod modeling parameters.  a) setting a minimum critical power ratio (MCPR) for each of a plurality of individual nuclear fuel rods used in the reactor;  b) calculating a value for a total number of fuel rods subject to boiling transition (NRSBT);  c) perturbing one or more reactor plant state value and/or fuel rod modeling parameter and recalculating a value for NRSBT;  d) performing step (c) for a predetermined number of perturbations;  e) developing a histogram of NRSBT values determined in steps (b), (c) and (d); and  f) selecting the OLMCPR from a minimal MCPR such that, for a simulation of the most limiting operational event, the nominal NRSBT value at a prescribed level of confidence as determined from analysis of the histogram determined from step (v) remains less than a predetermined cutoff value.  determining a probability distribution P(MCPR) to each MCPR value set in step (a), said P(MCPR) indicative of a range of possible MCPR values resulting from various operational and design uncertainties; and  integrating the probability distribution for values of MCPR&lt;1.0 for each fuel rod and summing the integration results for all fuel rods.  a) developing in a memory of a computer system a histogram of NRSBT (number of fuel rods subject to boiling transition) values, corresponding to a plurality of computer simulations of a transient operational occurrence in a reactor, said simulations providing values for a critical power ratio (CPR) for one or more fuel rods for a multiple of different parametric quantities for said reactor;  b) selecting a nominal NRSBT value, based on a central tendency of NRSBT distribution, statistically determined by said computer system from the histogram of NRSBT values developed in step (a);  c) selecting a confidence interval for the nominal NRSBT value;  d) selecting an OLMCPR value from a minimal CPR such that during a simulation of a limiting transient operational occurrence the nominal NRSBT value remains less than a predetermined cutoff value; and  e) effecting said Boiling Water Reactor operation by applying the OLMCPR selected in step (d) as an operational control parameter.  a) developing in a memory of said computer a histogram of NRSBT (number of fuel rods subject to boiling transition) values, corresponding to a plurality of computer simulations of a transient operational occurrence in a reactor, said simulations providing values for a critical power ratio (CPR) for one or more fuel rods for a multiple of different parametric quantities for said reactor;  b) calculating a nominal NRSBT value, based on a central tendency of an NRSBT distribution, from the histogram of NRSBT values obtained in step (a);  c) selecting a confidence interval for the nominal NRSBT value;  d) selecting an OLMCPR for the reactor as the initial minimal MCPR such that during a simulation of a transient the nominal NRSBT value remains less than a predetermined cutoff value; and  e) effecting Boiling Water Reactor operation by applying the OLMCPR selected in step (d) as an operational control parameter.  a) programming a computer to determine an OLMCPR value for a boiling water reactor, said computer programmed at least to:  b) providing said OLMPCR value to an output device for display, recordation or storage.  a) using a computer to simulate transient operational occurrences which might occur during the operation of a Boiling Water Reactor;  developing a histogram of NRSBT values from a computer simulation of a transient operational occurrence in a Boiling Water Reactor, the simulation providing values for a critical power ratio (CPR) for one or more fuel rods;  c) determining a nominal NRSBT value, based on a central tendency of an NRSBT distribution, from the histogram of NRSBT values obtained in step (a);  d) selecting a confidence interval for the nominal NRSBT value; and  e) selecting an OLMCPR for the reactor as the initial minimal MCPR such that during a simulation of a transient the nominal NRSBT value remains less than a predetermined cutoff value. 2. The method of claim 1 wherein the operational event is a transient event associated with an Anticipated Operational Occurrence (AOO). 3. The method of claim 1, wherein multi-dimensional modeling of reactor thermal hydraulics and power is used to simulate an anticipated operational occurrence. 4. The method of claim 1, wherein the parametric quantities correspond to reactor plant state values and/or modeling parameters. 5. The method of claim 1, wherein step (c) the anticipated occurrence is simulated for a plurality of fuel rods simultaneously. 6. The method of claim 1, wherein said perturbing of one or more of said parametric quantities is accomplished using a Monte-Carlo statistical analysis approach. 7. A system for determining an operating limit minimum critical power ratio (OLMCPR) of a boiling water reactor (BWR), said system comprising a computer including a storage memory and I/O devices, said memory having stored therein rules for simultaneously simulating and evaluating thermal operating characteristics for a plurality of fuel rods during an anticipated operational occurrence of the reactor and a data base of one or more parametric quantities representing reactor plant operational state values and/or fuel rod modeling parameters, said computer programmed to: 8. The system of claim 7 wherein the operational event simulated is a transient event associated with an Anticipated Operational Occurrences (AOO). 9. The system of claim 7 wherein a multi-dimensional modeling of fuel rod thermal hydraulics and reactor power is used to simulate an anticipated operational occurrence. 10. The system of claim 7 wherein step said anticipated occurrence is simulated for a plurality of fuel rods simultaneously. 11. A computer program product embodied on a computer readable medium for determining an operating limit minimum critical power ratio (OLMCPR) for a Boiling Water Reactor (BWR), comprising: 12. The computer program of claim 11 wherein said means for performing a multi-dimensional simulation of reactor thermal hydraulics and power simulates a transient operational occurrence for a plurality of fuel rods simultaneously. 13. A method for evaluating the operating limit minimum critical power ratio (OLMCPR) of a boiling water reactor (BWR), comprising the steps, executed by a computer, of: 14. The method of claim 13 wherein the calculating of an NRSBT value in step (b) is accomplished by the steps of: 15. The method of claim 13 wherein the perturbing in step (c) of one or more reactor plant state value(s) and/or modeling parameter(s) is accomplished using randomly generated variations of said values and parameters. 16. For a nuclear fuel core of a Boiling Water Reactor, wherein fuel design and/or core configuration are contingent upon an operating margin for the reactor, said operating margin being determined by a process for evaluating an operating limit minimum critical power ratio (OLMCPR), an improved process for evaluating an OLMCPR and operating a Boiling Water Reactor which results in an improved operating margin for the reactor, comprising the steps of: 17. The method claim 16 wherein said histogram is developed on a data processing system using multi-dimensional modeling of transient operational occurrences, said data processing system including memory to store CPR data obtained from said simulations. 18. For a nuclear fuel core of a Boiling Water Reactor, wherein fuel rod design and/or core configuration are contingent upon an operating margin for the reactor, said operating margin being determined by a process for evaluating an operating limit minimum critical power ratio (OLMCPR), a improved process for evaluating an OLMCPR and operating a Boiling Water Reactor that results in an increased operating margin for the reactor, comprising the steps, executed by a computer, of: 19. A method for statistically demonstrating an operating limit minimum critical power ratio (OLMCPR) of a boiling water reactor (BWR) for compliance with licensing requirements, said reactor characterized by one or more parametric quantities indicative of design constraints and operating conditions, comprising the steps of: 20. For use in controlling a Boiling Water Reactor having a nuclear fueled core characterized by an operating limit minimum critical power ratio (OLMCPR) value, a method for determining said OLMCPR value comprising the steps of: