Advances on containment iodine chemistry
Titre du congrès :ERMSAR 2008 - 3rd European Review Meeting on Severe Accident Research
Ville du congrès :Nesseber
Date du congrès :23/09/2008
Type de document >
Mots clés >
chimie de l'iode, enceinte de confinement, enceinte réacteur
Unité de recherche >
ANDREO François, BALL Joanne, BOSLAND Loïc, CANTREL Laurent, DICKINSON S., DUCROS G., FUNKE Friedhelm, GIRAULT Nathalie, GUILBERT Séverine, HERRANZ Luis Enrique, HOLM Elis, HOUSIADAS Christos, KARKELA T., MUN Christian, SABROUX Jean-Christophe, WEBER G.
Date de publication >
The 5th FWP EURSAFE project highlighted iodine chemistry in the containment as one of the issues requiring further research in order to reduce source term uncertainties. Consequently, a series of studies was launched in the 6th FWP SARNET project aimed at improving the predictability of iodine behaviour during severe accidents via a better understanding of the complex chemical phenomena in the containment. In particular, SARNET has striven to foster common interpretation of integral and separate effect test data; production of new or improved models where necessary needed, and compilation of the existing knowledge of the subject. The work has been based on a substantial amount of experimental information made available from bench-scale projects (PARIS and EPICUR), via intermediate-scale tests (CAIMAIN) to large scale facilities (SISYPHE, THAI and PHEBUS-FP).
In the experimental field, particular attention has been paid to two specific issues: the effects of radiation on both aqueous and gaseous iodine chemistry, and the mass transfer of iodine between aqueous and gaseous phases. Comparisons between calculations and results of the EPICUR and CAIMAN experiments suggest that the aqueous phase chemistry is reasonably well understood, although there are still some areas of uncertainty. Interpretation of integral experiments, like PHEBUS-FPT2, indicated that radiation-induced conversion of molecular iodine into particulate species (IxOy) could be responsible for the gaseous iodine depletion observed in the long-term. However, the results of much simpler, small-scale experiments have shown that further improvements in understanding and modelling are still needed. These data will be further supplemented by those obtained in the forthcoming NROI project. Mass transfer modelling has been extended to cover evaporating sump conditions based on SISYPHE data; however, application of this model to the larger scale THAI experiments seems not to be straightforward. In addition to these two major issues, some specific studies have been carried out concerning the potential effect of passive autocatalytic hydrogen recombiners on iodine volatility. The RECI analytical experiments have shown that metal iodides (namely CsI and CdI2) are not stable and yield gaseous iodine when heated, in a humid atmosphere, at temperatures representative of recombiner operation.
Another important undertaking successfully carried out has been the compilation of an Iodine Data Book, which provides a critical review of the experimental data and modelling approaches that have been used in the development of iodine source term methodologies. This should assist in a proper use of such models, and inform their future development.
Finally, it should be emphasized that an important outcome of this iodine group in SARNET has been the establishment of links with other related projects, such as Phebus FP, ISTP, ISTC-EVAN, OECD-BIP and THAI. Collaborative studies based around data from these projects will facilitate the progressive resolution of the remaining issues in a potential follow-up programme.