Modelling of PWR lower head failure under severe accident loading using improved shells of revolution theory

Titre de la revue : Nuclear Engineering and Design Volume : 238 N° : 9 Pagination : 2400-2410 Date de publication : 01/09/2008

In the study of severe pressurized water reactor accidents, the scenarios that describe the relocation of significant quantities of liquid corium at the bottom of the lower head are usually investigated from the mechanical point of view. In these scenarios, the risk of a breach and the possibility of a large quantity of corium being released from the lower head exists. This may lead to an out of vessel steam explosion or to direct heating of the containment; both which have the potential to lead to early containment failure. Within the framework of the OECD lower head failure programme, a simplified model based on the theory of shells of revolution under symmetrical loading was developed by IRSN. After successfully interpreting some other representative experiments on lower head failures, the model was recently integrated into the European integral severe accident computer ASTEC code. The model was also used to obtain the thermo-mechanical behaviour of a 900 MWe pressurized water reactor lower head, subjected to transient heat fluxes under severe accident conditions. The main objective of this paper is to present: 1) the full mathematical formulations used in the development of the model, including their matrices and integrals defined by analytical expressions; 2) the two creep laws implemented, one for the American steel SA533B1 and one for the French steel 16MND5; and 3) the various numerical interpretations of experiments using the simplified model. This paper can be considered as a theoretical manual to aid users of the simplified model during modelling of lower head failures under severe accident conditions. One of the applications presented in this paper concerns the determination of a diagram representing the vessel time to failure as a function of the pressure level and the heat flux intensity. This information has been used by IRSN in probabilistic safety assessment and severe accident management analyses.