Justification and optimization of FNR transition to the closed fuel cycle mode

The «Proryv» project implies developing advanced nuclear technologies for next generation large-scale nuclear power based on fast neutron reactors (FRs) operating in a closed nuclear fuel cycle (NFC). All components of the closed NFC must be in agreement with the requirements for the product charact...

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Bibliographic Details
Published in:Journal of physics. Conference series 2020-03, Vol.1475 (1), p.12017
Main Authors: Khomyakov, Yu S, Rodina, E A, Shmidt, O V, Egorov, A V, Makeeva, I R, Popov, I S, Sokolov, V P
Format: Article
Language:English
Subjects:
Fast neutrons
Modules
Nuclear fuel cycle
Nuclear fuels
Nuclear reactor components
Nuclear reactors
Optimization
Physics
Reprocessing
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Summary:The «Proryv» project implies developing advanced nuclear technologies for next generation large-scale nuclear power based on fast neutron reactors (FRs) operating in a closed nuclear fuel cycle (NFC). All components of the closed NFC must be in agreement with the requirements for the product characteristics and optimized in accordance with the different stages of the fuel cycle. Different variants of the closed nuclear fuel cycle are being looked into with different types of FRs, fuel, and fuel cycle facility arrangement options (centralized or on-site). Many processes and technical solutions, which are being used to develop the fuel recycling technology, have never been applied on a commercial or laboratory scale. Successfully implementing this technology implies developing a system of codes within the «Proryv» project, which would allow researchers to model various closed NFC options using a hierarchical approach. Dedicated computer software is used for optimizing particular closed NFC modules (the reactor, fuel fabrication and reprocessing modules). Optimization criteria are selected based on the requirements for characteristics of the products (in relation to quality or production time), which are in turn obtained from calculating the system as a whole. The functional possibility of conducting correlated calculations for FR cores and back-end nuclear fuel cycle processes was developed, which enabled researchers to factor in the effect of variable reactor core arrangement, startup fuel characteristics, equilibrium state attainment strategies and SNF composition on technology components and closed nuclear fuel cycle management.
ISSN:1742-6588
1742-6596
DOI:10.1088/1742-6596/1475/1/012017