Application of FFTBM with signal mirroring to improve accuracy assessment of MELCOR code

•FFTBM-SM is an improved Fast Fourier Transform Base Method by signal mirroring.•FFTBM-SM has been applied to accuracy assessment of MELCOR code predictions.•The case studied was Station Black-Out accident in PSB-VVER integral test facility.•FFTBM-SM eliminates fluctuations of accuracy indices when...

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Bibliographic Details
Published in:Nuclear engineering and design 2016-11, Vol.308, p.238-251
Main Authors: Saghafi, Mahdi, Ghofrani, Mohammad Bagher, D’Auria, Francesco
Format: Article
Language:English
Subjects:
K. Thermal Hydraulics
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Summary:•FFTBM-SM is an improved Fast Fourier Transform Base Method by signal mirroring.•FFTBM-SM has been applied to accuracy assessment of MELCOR code predictions.•The case studied was Station Black-Out accident in PSB-VVER integral test facility.•FFTBM-SM eliminates fluctuations of accuracy indices when signals sharply change.•Accuracy assessment is performed in a more realistic and consistent way by FFTBM-SM. This paper deals with the application of Fast Fourier Transform Base Method (FFTBM) with signal mirroring (FFTBM-SM) to assess accuracy of MELCOR code. This provides deeper insights into how the accuracy of MELCOR code in predictions of thermal-hydraulic parameters varies during transients. The case studied was modeling of Station Black-Out (SBO) accident in PSB-VVER integral test facility by MELCOR code. The accuracy of this thermal-hydraulic modeling was previously quantified using original FFTBM in a few number of time-intervals, based on phenomenological windows of SBO accident. Accuracy indices calculated by original FFTBM in a series of time-intervals unreasonably fluctuate when the investigated signals sharply increase or decrease. In the current study, accuracy of MELCOR code is quantified using FFTBM-SM in a series of increasing time-intervals, and the results are compared to those with original FFTBM. Also, differences between the accuracy indices of original FFTBM and FFTBM-SM are investigated and correction factors calculated to eliminate unphysical effects in original FFTBM. The main findings are: (1) replacing limited number of phenomena-based time-intervals by a series of increasing time-intervals provides deeper insights about accuracy variation of the MELCOR calculations, and (2) application of FFTBM-SM for accuracy evaluation of the MELCOR predictions, provides more reliable results than original FFTBM by eliminating the fluctuations of accuracy indices when experimental signals sharply increase or decrease. These studies have been performed in the framework of a research project, aiming to develop an appropriate accident management support tool for Bushehr nuclear power plant.
ISSN:0029-5493
1872-759X
DOI:10.1016/j.nucengdes.2016.08.025