Mesures de perturbations sur le réacteur CALIBAN : interprétation en terme de qualification des données nucléaires / Reactivity worth measurements on the CALIBAN reactor : interpretation of integral experiments for the nuclear data validation

Richard, Benoit

19 December 2012

La bonne connaissance des données nucléaires de base, grandeurs d’entrée pour les codes de calcul neutronique, constitue l’un des piliers fondamentaux de la réussite des grands programmes de l’industrie nucléaire. Ce travail a pour vocation d’apporter des informations nécessaires à la démarche de validation intégrale des données nucléaires. Des expériences de perturbations ont été effectuées auprès du réacteur Caliban, elles concernent quatre matériaux d’intérêt pour l’industrie nucléaire : or, lutécium, plutonium et uranium 238. D’autres expériences visant à caractériser le réacteur Caliban sont également présentées et discutées, ces dernières sont essentielles à la bonne interprétation des expériences de perturbations. Après définition des protocoles expérimentaux et des incertitudes associées, les résultats de mesures sont présentés et confrontés avec des résultats de calculs. La méthodologie utilisée dans les calculs numériques est décrite précisément, notamment la génération de données multigroupes pour les codes déterministes. La manière dont les expériences ont été modélisées est également présentée avec les incertitudes associées. Cette comparaison a permis d’aboutir à une interprétation en terme de qualification des bibliothèques de données nucléaires. Les écarts observés sont discutés et justifient la poursuite de telles expériences. / The good knowledge of nuclear data, input parameters for the neutron transport calculation codes, is necessary to support the advances of the nuclear industry. The purpose of this work is to bring pertinent information regarding the nuclear data integral validation process. Reactivity worth measurements have been performed on the Caliban reactor, they concern four materials of interest for the nuclear industry : gold, lutetium, plutonium and uranium 238. Experiments which have been conducted in order to improve the characterization of the core are also described and discussed, the latter are necessary to the good interpretation of reactivity worth measurements. The experimental procedures are described with their associated uncertainties, measurements are then compared to numerical results. The methods used in numerical calculations are reported, especially the multigroup cross sections generation for deterministic codes. The modeling of the experiments is presented along with the associated uncertainties. This comparison led to an interpretation concerning the qualification of nuclear data libraries. Discrepancies are reported, discussed and justify the need of such experiments.

Expériences intégrales

Données nucléaires

Caliban

Mesures de perturbations

Integral experiments

Nuclear data

Caliban

Perturbation measurements

Nuclear data uncertainty quantification and data assimilation for a lead-cooled fast reactor : Using integral experiments for improved accuracy

Alhassan, Erwin

January 2015

For the successful deployment of advanced nuclear systems and optimization of current reactor designs, high quality nuclear data are required. Before nuclear data can be used in applications they must first be evaluated, tested and validated against a set of integral experiments, and then converted into formats usable for applications. The evaluation process in the past was usually done by using differential experimental data which was then complemented with nuclear model calculations. This trend is fast changing due to the increase in computational power and tremendous improvements in nuclear reaction models over the last decade. Since these models have uncertain inputs, they are normally calibrated using experimental data. However, these experiments are themselves not exact. Therefore, the calculated quantities of model codes such as cross sections and angular distributions contain uncertainties. Since nuclear data are used in reactor transport codes as input for simulations, the output of transport codes contain uncertainties due to these data as well. Quantifying these uncertainties is important for setting safety margins; for providing confidence in the interpretation of results; and for deciding where additional efforts are needed to reduce these uncertainties. Also, regulatory bodies are now moving away from conservative evaluations to best estimate calculations that are accompanied by uncertainty evaluations. In this work, the Total Monte Carlo (TMC) method was applied to study the impact of nuclear data uncertainties from basic physics to macroscopic reactor parameters for the European Lead Cooled Training Reactor (ELECTRA). As part of the work, nuclear data uncertainties of actinides in the fuel, lead isotopes within the coolant, and some structural materials have been investigated. In the case of the lead coolant it was observed that the uncertainty in the keff and the coolant void worth (except in the case of 204Pb), were large, with the most significant contribution coming from 208Pb. New 208Pb and 206Pb random nuclear data libraries with realistic central values have been produced as part of this work. Also, a correlation based sensitivity method was used in this work, to determine parameter - cross section correlations for different isotopes and energy groups. Furthermore, an accept/reject method and a method of assigning file weights based on the likelihood function are proposed for uncertainty reduction using criticality benchmark experiments within the TMC method. It was observed from the study that a significant reduction in nuclear data uncertainty was obtained for some isotopes for ELECTRA after incorporating integral benchmark information. As a further objective of this thesis, a method for selecting benchmark for code validation for specific reactor applications was developed and applied to the ELECTRA reactor. Finally, a method for combining differential experiments and integral benchmark data for nuclear data adjustments is proposed and applied for the adjustment of neutron induced 208Pb nuclear data in the fast energy region.

Total Monte Carlo

ELECTRA

nuclear data

uncertainty propagation

integral experiments

nuclear data adjustment

uncertainty reduction