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Optimization of multi-group energy structures for diffusion analyses of sodium-cooled fast reactors assisted by simulated annealing – Part I: methodology demonstration
Di Nora, V. A.;
Fridman, E.;
Nikitin, E.;
Bilodid, Y.;
Mikityuk, K.
MARC21 XML Export
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<subfield code="a"><p>This study presents an approach to the selection of optimal energy group structures for multi-group nodal diffusion analyses of Sodium-cooled Fast Reactor cores. The goal is to speed up calculations, particularly in transient calculations, while maintaining an acceptable accuracy of the results.<br>
In Part I of the paper, possible time-savings due to collapsing of energy groups are evaluated using 24-group energy structure as a reference. Afterwards, focusing on energy structures with a number of groups leading to significant calculation speedups, optimal grid configurations are identified. Depending on a number of possible energy grid configurations to explore, the optimization is conducted by either a direct search or applying the simulated annealing method. Speedup and optimization studies are performed on a selected case of the Superph&eacute;nix static neutronic benchmark by using the nodal diffusion DYN3D code. The results demonstrate noticeable improvements in DYN3D performance with a marginal deterioration of the accuracy.</p></subfield>
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- Publication date:
- November 26, 2020
- DOI:
-
- Keyword(s):
- Serpent XS condensation energy structure optimization simulated annealing
- Related identifiers:
- Identical to:
https://www.hzdr.de/publications/Publ-31706 - Referenced by:
10.1016/j.anucene.2021.108183, https://www.hzdr.de/publications/Publ-31688, https://www.hzdr.de/publications/Publ-32640 - Communities: