Nuclear Engineering and Technology

Korean Nuclear Society (한국원자력학회)
권호 표지
DOI QR코드

DOI QR Code

Adaptive energy group division in the few-group cross-section generation for full spectrum reactor modeling with deterministic method

  • Yichen Yang (School of Nuclear Science and Technology, Xi'an Jiaotong University) ;
  • Youqi Zheng (School of Nuclear Science and Technology, Xi'an Jiaotong University) ;
  • Xianan Du (School of Nuclear Science and Technology, Xi'an Jiaotong University) ;
  • Hongchun Wu (School of Nuclear Science and Technology, Xi'an Jiaotong University)
  • Received : 2023.08.18
  • Accepted : 2024.01.06
  • Published : 2024.06.25
Download PDF
⟨ Previous Next ⟩

Abstract

Advanced nuclear reactors, especially the newly developed small and micro-reactors have complex neutron spectrum, which makes the deterministic reactor core calculations sensitive to the energy group structure of few-group cross-sections. To avoid significantly increasing the cost of energy discretization in the core calculation, two energy group structures with 31 groups and 33 groups were adopted for typical thermal and fast reactor cores, respectively. Then, an adaptive scheme of group division for reactor cores with a medium neutron spectrum was proposed. The works were based on the full spectrum nuclear reactor analysis code SARAX/TULIP. An equivalent one-dimensional model of the core was proposed to capture the key neutron spectrum features of the reactor core. Such features were used to adaptively determine a few-group structure for the following reactor core calculations. Then, the neutron spectrum in different zones with more details was calculated. With this spectrum, the cross-sections were condensed into the determined energy groups. Three tests based on different neutron spectrum were calculated to verify the schemes. The results show that using the adaptive energy group division scheme, the following core calculation can meet the accuracy requirement of different reactors with different neutron spectra.

Keywords

Acknowledgement

This work is supported by the National Natural Science Foundation of China (approved number: U2167205).

References

  1. C. Lee, W.S. Yang, MC2-3: multigroup cross-section generation code for fast reactor analysis, Nucl. Sci. Eng. 187 (3) (2017) 268-290.
  2. K.S. Kim, M.L. Williams, et al., The SCALE/AMPX multigroup cross-section processing for fast reactor analysis, Ann. Nucl. Energy 132 (2019) 161-171.
  3. G. Zhang, W.S. Yang, Quadratic axial expansion function with sub-plane acceleration scheme for the high-fidelity transport code PROTEUS-MOC, Ann. Nucl. Energy 148 (2020) 107713.
  4. H. Subki, Advances in Small Modular Reactor Technology Developments, 2020.
  5. B.K. Jeon, W.S. Yang, et al., Extension of MC2-3 for generation of multigroup cross-sections in thermal energy range, Proceedings of the M&C (2017) 16-20.
  6. C. Lee, Y.S. Jung, et al., MC2-3: Multigroup Cross Section Generation Code for Fast Reactor Analysis Nuclear, Argonne National Lab.(ANL), Argonne, IL, 2018.
  7. J.A. Bucholz, SCALE: a Modular Code System for Performing Standardized Computer Analyses for Licensing Evaluation, Oak Ridge National Lab., TN, 1982.
  8. K.S. Kim, M.L. Williams, The method of characteristics for 2-D multigroup and pointwise transport calculations in SCALE/CENTRM, PHYSOR 2012 (2012) 15-20, 2012.
  9. D. Schneider, F. Dolci, et al., APOLLO3® CEA/DEN deterministic multi-purpose code for reactor physics analysis, in: PHYSOR 2016-Unifying Theory and Experiments in the 21st Century, 2016.
  10. R. Sanchez, I. Zmijarevi, et al., APOLLO2 year 2010, Nucl. Eng. Technol. 42 (5) (2010) 474-499.
  11. Y. Zheng, X. Du, et al., SARAX: a new code for fast reactor analysis part I: methods, Nucl. Eng. Des. 340 (2018) 421-430.
  12. Y. Zheng, L. Qiao, et al., SARAX: a new code for fast reactor analysis part II: verification, validation and uncertainty quantification, Nucl. Eng. Des. 331 (2018) 41-53.
  13. L. Wei, Y. Zheng, et al., Development of SARAX code system for full-range spectrum adaptability in advanced reactor analysis, Ann. Nucl. Energy 165 (2022) 108664.
  14. L. Wei, Y. Zheng, et al., Extension of SARAX code system for reactors with intermediate spectrum, Nucl. Eng. Des. 370 (2020) 110883.
  15. X. Du, Y. Yang, et al., The acceleration of improved Tone's method in advanced reactor lattice neutron spectrum calculation, Prog. Nucl. Energy 162 (2023) 104771.
  16. Reinaldo, Yrobel Lima, et al., Neutronic analysis of the ALLEGRO fast reactor core with deterministic ERANOS code and Monte Carlo Serpent code, Ann. Nucl. Energy 163 (2021) 108567.
  17. Abhitab Bachchan, et al., Neutronics simulation of China Experimental Fast Reactor start-up tests using FARCOB and ERANOS 2.1 code systems, Nucl. Eng. Des. 399 (2022) 112038.
  18. Xiaoqian Jia, et al., Verification of SARAX code system in the reactor core transient calculation based on the simplified EBR-II benchmark, Nucl. Eng. Technol. 54 (5) (2022) 1813-1824.
  19. X. Du, et al., Transient analysis of MOX-3600 and MET-1000 sodium-cooled fast reactor using SARAX code system, Ann. Nucl. Energy 121 (2018) 324-334, 2018.
  20. X. Du, et al., Validation of SARAX code system using the SFR operational tests, Ann. Nucl. Energy 147 (2020) 107744, 2020.
  21. M.N. Nikolaev, et al., The method of subgroups for considering the resonance structure of cross-sections in neutron calculations, Sov. Atom. Energy 30 (5) (1971) 528-533.