[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.1016/j.net.2021.12.005

Numerical evaluation of hypothetical core disruptive accident in full-scale model of sodium-cooled fast reactor

Guo, Zhihong (School of Aerospace Engineering, Beijing Institute of Technology)
Chen, Xiaodong (School of Aerospace Engineering, Beijing Institute of Technology)
Hu, Guoqing (Department of Engineering Mechanics, Zhejiang University)

Publication Information

Nuclear Engineering and Technology / v.54, no.6, 2022 , pp. 2120-2134 More about this Journal

Abstract

A hypothetical core destructive accident (HCDA) has received widespread attention as one of the most serious accidents in sodium-cooled fast reactors. This study combined recent advantages in numerical methods to realize realistic modeling of the complex fluid-structure interactions during HCDAs in a full-scale sodium-cooled fast reactor. The multi-material arbitrary Lagrangian-Eulerian method is used to describe the fluid-structure interactions inside the container. Both the structural deformations and plug rises occurring during HCDAs are evaluated. Two levels of expansion energy are considered with two different reactor models. The simulation results show that the container remains intact during an accident with small deformations. The plug on the top of the container rises to an acceptable level after the sealing between the it and its support is destroyed. The methodology established in this study provides a reliable approach for evaluating the safety feature of a container design.

Keywords

Hypothetical core destructive accidents; Sodium-cooled fast reactors; Multi-material arbitrary Lagrangian-Eulerian (MMALE) method; Fluid-structure interactions;

Citations & Related Records

Times Cited By KSCI : 1 (Citation Analysis)

Reference
Cited By KSCI

1	China Iron and Steel Industry Association, GB/T 5216-2014 Structural Steels with Specified Hardenability Bands, Standards Press of China, Bei Jing, 2014.
2	J.H. Ding, X.L. Jin, G.G. Li, et al., Three-dimensional cutting simulation by cutterhead of shield machine based on parallel computing, J. Syst. Simul. 19 (23) (2007), 5376-5375.
3	X.J. Wang, Z. Zong, Y. Zhao, et al., A numerical study of passenger side airbag deployment based on arbitrary Lagrangian-Eulerian method, Sci. China Technol. Sci. 58 (3) (2015) 397-404. DOI
4	M.F. Robbe, M. Lepareux, E. Treille, et al., Numerical simulation of an explosion in a simple scale model of a nuclear reactor, Comput. Assist. Mech. Eng. Sci. 9 (4) (2002) 489-517.
5	M.F. Robbe, M. Lepareux, E. Treille, Estimation of the mechanical effects of a core disruptive accident on a LMFBR, in: International Conference on Nuclear Engineering, Nice, Acropolis (France), 2001, pp. 8-12. April.
6	M. Cigarini, A. Daneri, G. Toselli, Applications of ASTARTE-4 code to explosive models with complex internal structure using the rezoning facility, in: Proceedings of the Seventh International Conference on Structural Mechanics in Reactor Technology, 1983. Paper B 9/3, Chicago, USA.
7	Y. Blanchet, P. Obry, J. Louvet, Treatment of fluid-structure interaction with the SIRIUS computer code, in: Proceedings of the Sixth International Conference on Structural Mechanics in Reactor Technology, 1981. Paper B 8/8, Paris, France.
8	M. Lepareux, H. Bung, A. Combescure, J. Aguilar, J.F. Flober, Analysis of an HCDA in a fast reactor with a multiphase and multicomponent behavior law, in: Proceedings of the 12th International Conference on Structural Mechanics in Reactor Integrity, 1993, pp. 197-202. Paper E 7/2, Stuttgart, Germany, August.
9	R.B. Nicholson, J.F. Jackson, A Sensitivity Study for Fast Reactor Disassembly Calculations. ANL-7952, 1974.
10	Z.T. Su, C.Y. Ye, F.W. Yan, Liquid-sodium Fast Breeder Reactor, Atomic Energy Press, Beijing, 1991 (in Chinese).
11	K.C. Kendall, D.J. Adnams, Experiments to Validate Structural Dynamics Code Used in Fast Reactor Safety Assessment. Science and Technology of Fast Reactor Safety, British Nuclear Energy Society, London, UK, 1986.
12	M.F. Robbe, M. Lepareux, E. Seinturier, Computation of a core disruptive accident in the MARS mock-up, Nucl. Eng. Des. 235 (13) (2005) 1403-1440. DOI
13	V. Faucher, P. Galon, A. Beccantini, et al., Hybrid parallel strategy for the simulation of fast transient accidental situations at reactor scale, in: International Conference on Supercomputing in Nuclear Applications, Monte Carlo, 2013.
14	H. Niwa, A comprehensive approach of reactor safety research aiming at elimination of recriticality in CDA for commercialization of LMFBR, Prog. Nucl. Energy 32 (3/4) (1998) 621-629. DOI
15	R.B. Nicholson, J.F. Jackson, VENUS-11: an LMFBR Disassembly Program, Argonne National Laboratory ANL, USA, 1972, p. 7952.
16	H. Yamano, S. Kubo, Y. Shimakawa, et al., Safety design and evaluation in a large-scale Japan sodium-cooled fast reactor, in: Science and technology of nuclear installation (PT.2):614973.1-61614973.14, 2012.
17	A.M. Tentner, Severe Accident Approach e Final Report Evaluation of Design Measures for Severe Accident Prevention and Consequence Mitigation, Argonne National Laboratory, Nuclear Engineering Division, 2010. http://www.osti.gov/bridge.
18	M. Falgayrettes, C. Fiche, P. Granet, et al., Response of a 1/20 scale mock-up of the Superphenix breeder reactor to an HCDA loading simulation, in: Proceedings of the Seventh International Conference on Structural Mechanics in Reactor Technology, 1983, pp. 157-166. Paper E 4/1, Chicago, USA.
19	T. Suzuki, T. Yoshiharu, K. Kenichi, et al., A preliminary evaluation of unprotected loss-of-flow accident for a prototype fast-breeder reactor, Nucl. Eng. Technol. 47 (3) (2015) 240-252. DOI
20	H.A. Bethe, J.H. Taite, An estimate of the order of magnitude of the explosion when the core of a fast reactor collapses, in: British Report UKAEA-RHM (56)/113, 1956.
21	M.F. Robbe, M. Lepareux, E. Treille, et al., Numerical simulation of a hypothetical core disruptive accident in a small-scale model of a nuclear reactor, Nucl. Eng. Des. 223 (2) (2003) 159-196. DOI
22	O.H. John, LS-DYNA Theoretical Manual, Livermore Software Technology Corporation, 2018.
23	J.L. Graveleau, P. Louvet, Calculation of fluid-structure interaction for reactor safety with the CASSIOPEE code, in: Proceedings of the Fifth International Conference on Structural Mechanics in Reactor Technology, 1979. Paper B 1/7, Berlin, Germany.
24	Y.W. Chang, Analysis of HCDA, Nucl. Eng. Des. 69 (1982) 345-358. DOI
25	P.H. West, N.E. Hoskin, Suggested simple test problems for examination of thin shell modelling and fluid structure coupling, in: Aldermaston Report AWRE/44/92/16, APRICOT-phase, 1980, p. 3.
26	R.J. Tobin, D.J. Cagliostro, D.W. Ploeger, Energetics of simulated HCDA bubble expansions: some potential attenuation mechanisms, Nucl. Eng. Des. 58 (1) (1979) 85-95. DOI
27	B.L. Smith, A. Yerkess, J. Adamson, Status of coupled fluid-structure dynamics code SEURBNUK, in: Proceedings of the Seventh International Conference on Structural Mechanics in Reactor Technology, 1983. Paper B 9/1, Chicago, USA.
28	A. Benuzzi, Comparison of different LMFBR primary containment codes applied to a benchmark problem, Nucl. Eng. Des. 100 (2) (1987) 239-249. DOI
29	M.F. Robbe, M. Lepareux, Y. Cariou, Numerical interpretation of the MARA 8 experiment simulating a hypothetical core disruptive accident, Nucl. Eng. Des. 220 (2) (2003) 119-158. DOI
30	Y. Cariou, J.P. Pirus, C. Avallet, LMR large accident analysis method, in: Proceedings of the 14th International Conference on Structural Mechanics in Reactor Technology, 1997, pp. 395-402. Paper P 3/7, Lyon, France, August.
31	J.L. Yang, X.J. Cai, C.H. Wu, Experimental and FEM study of windshield subjected to high speed bird impact, Acta Mech. Sin. 19 (6) (2003) 543-550. DOI
32	M. Souli, A. Ouahsine, L. Lewin, ALE formulation for fluid-structure interaction problems, Comput. Methods Appl. Mech. Eng. 190 (2000) 659-675. DOI
33	D.J. Benson, A mixture theory for contact in multi-material Eulerian formulations, Comput. Methods Appl. Mech. Eng. 140 (1) (1997).
34	H. Zhao, et al., LS-DYNA Dynamic Analysis Guide, Ordnance Industry Press, 2003 (in Chinese).
35	ASME Boiler & Pressure Vessel Code. II Materials, Part D. Properties, 2015.
36	T. Suzuki, K. Kamiyama, H. Yamano, et al., A scenario of core disruptive accident for Japan sodium-cooled fast reactor to achieve in-vessel retention, J. Nucl. Sci. Technol. 51 (4) (2014) 493-513. DOI
37	I.G. Cameron, B.C. Hankin, A.G.P. Warham, A. Benuzzi, A. Yerkess, The computer code SEURBNUK-2 for fast reactor explosion containment safety studies, in: Proceedings of the Fourth International Conference on Structural Mechanics in Reactor Technology, 1977. Paper B 2/1, San Francisco, USA.
38	H.C. Huang, et al., Thermal Technology Dictionary, vol. 467, Shanghai Lexicographical Publishing House, 1996.
39	L.E. Felton, C.H. Raeder, D.B. Knorr, The properties of tin-bismuth alloy solders, JOM (J. Occup. Med.) 45 (7) (1993) 28-32. DOI
40	G. Barras, M. Souli, N. Aquelet, et al., Numerical simulation of underwater explosions using an ALE method. The pulsating bubble phenomena, Ocean Eng. 41 (2012) 53-66. DOI