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Modelling guidelines for core exit temperature simulations with system codes

•Core exit temperature is used in PWRs as an indication of core heat up.•Modelling guidelines of CET response with system codes.•Modelling of heat transfer processes in the core and UP regions. Core exit temperature (CET) measurements play an important role in the sequence of actions under accidenta...

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Bibliographic Details
Published in:Nuclear engineering and design 2015-05, Vol.286, p.116-129
Main Authors: Freixa, J., Martínez-Quiroga, V., Zerkak, O., Reventós, F.
Format: Article
Language:English
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Summary:•Core exit temperature is used in PWRs as an indication of core heat up.•Modelling guidelines of CET response with system codes.•Modelling of heat transfer processes in the core and UP regions. Core exit temperature (CET) measurements play an important role in the sequence of actions under accidental conditions in pressurized water reactors (PWR). Given the difficulties in placing measurements in the core region, CET readings are used as criterion for the initiation of accident management (AM) procedures because they can indicate a core heat up scenario. However, the CET responses have some limitation in detecting inadequate core cooling and core uncovery simply because the measurement is not placed inside the core. Therefore, it is of main importance in the field of nuclear safety for PWR power plants to assess the capabilities of system codes for simulating the relation between the CET and the peak cladding temperature (PCT). The work presented in this paper intends to address this open question by making use of experimental work at integral test facilities (ITF) where experiments related to the evolution of the CET and the PCT during transient conditions have been carried out. In particular, simulations of two experiments performed at the ROSA/LSTF and PKL facilities are presented. The two experiments are part of a counterpart exercise between the OECD/NEA ROSA-2 and OECD/NEA PKL-2 projects. The simulations are used to derive guidelines in how to correctly reproduce the CET response during a core heat up scenario. Three aspects have been identified to be of main importance: (1) the need for a 3-dimensional representation of the core and Upper Plenum (UP) regions in order to model the heterogeneity of the power zones and axial areas, (2) the detailed representation of the active and passive heat structures, and (3) the use of simulated thermocouples instead of steam temperatures to represent the CET readings.
ISSN:0029-5493
1872-759X
DOI:10.1016/j.nucengdes.2015.02.003