[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.1016/j.net.2022.02.003

Application of the SCIANTIX fission gas behaviour module to the integral pin performance in sodium fast reactor irradiation conditions

Magni, A. (Politecnico di Milano, Department of Energy, Nuclear Engineering Division)
Pizzocri, D. (Politecnico di Milano, Department of Energy, Nuclear Engineering Division)
Luzzi, L. (Politecnico di Milano, Department of Energy, Nuclear Engineering Division)
Lainet, M. (Commissariat a l'Energie Atomique et aux Energies Alternatives, CEA DEC/SESC)
Michel, B. (Commissariat a l'Energie Atomique et aux Energies Alternatives, CEA DEC/SESC)

Publication Information

Nuclear Engineering and Technology / v.54, no.7, 2022 , pp. 2395-2407 More about this Journal

Abstract

The sodium-cooled fast reactor is among the innovative nuclear technologies selected in the framework of the development of Generation IV concepts, allowing the irradiation of uranium-plutonium mixed oxide fuels (MOX). A fundamental step for the safety assessment of MOX-fuelled pins for fast reactor applications is the evaluation, by means of fuel performance codes, of the integral thermal-mechanical behaviour under irradiation, involving the fission gas behaviour and release in the fuel-cladding gap. This work is dedicated to the performance analysis of an inner-core fuel pin representative of the ASTRID sodium-cooled concept design, selected as case study for the benchmark between the GERMINAL and TRANSURANUS fuel performance codes. The focus is on fission gas-related mechanisms and integral outcomes as predicted by means of the SCIANTIX module (allowing the physics-based treatment of inert gas behaviour and release) coupled to both fuel performance codes. The benchmark activity involves the application of both GERMINAL and TRANSURANUS in their "pre-INSPYRE" versions, i.e., adopting the state-of-the-art recommended correlations available in the codes, compared with the "post-INSPYRE" code results, obtained by implementing novel models for MOX fuel properties and phenomena (SCIANTIX included) developed in the framework of the INSPYRE H2020 Project. The SCIANTIX modelling includes the consideration of burst releases of the fission gas stored at the grain boundaries occurring during power transients of shutdown and start-up, whose effect on a fast reactor fuel concept is analysed. A clear need to further extend and validate the SCIANTIX module for application to fast reactor MOX emerges from this work; nevertheless, the GERMINAL-TRANSURANUS benchmark on the ASTRID case study highlights the achieved code capabilities for fast reactor conditions and paves the way towards the proper application of fuel performance codes to safety evaluations on Generation IV reactor concepts.

Keywords

ASTRID case study; Fuel pin performance; Fission gas behaviour; SCIANTIX; GERMINAL; TRANSURANUS; Burst release;

Citations & Related Records

Times Cited By KSCI : 3 (Citation Analysis)

Reference
Cited By KSCI

1	GIF (Generation IV International Forum), GIF R&D Outlook for Generation IV Nuclear Energy Systems - 2018 Update, 2018.
2	C. Venard, C. Coquelet-Pascal, A. Conti, D. Gentet, P. Lamagnere, R. Lavastre, P. Gauthe, B. Bernardin, T. Beck, D. Lorenzo, A.-C. Scholer, B. Perrin, D. Verrier, in: The ASTRID Core at the End of the Conceptual Design Phase, FR17, 2017, 26-29 June, Yekaterinburg, Russia.
3	B. Michel, I. Ramiere, I. Viallard, C. Introini, M. Lainet, N. Chauvin, V. Marelle, A. Boulore, T. Helfer, R. Masson, J. Sercombe, J.C. Dumas, L. Noirot, S. Bernaud, Two fuel performance codes of the PLEIADES platform: ALCYONE and GERMINAL, in: J. Wang, X. Li, C. Allison, J. Hohorst (Eds.), Nuclear Power Plant Design and Analysis Codes - Development, Validation and Application Chap. 9, Woodhead Publishing Series in Energy, Elsevier, 2021, pp. 207-233.
4	D. Olander, Fundamental Aspects of Nuclear Reactor Fuel Elements, California University, Department of Nuclear Engineering, Berkeley, CA, USA, 1976.
5	D. Pizzocri, T. Barani, L. Luzzi, SCIANTIX: a new open source multi-scale code for fission gas behaviour modelling designed for nuclear fuel performance codes, J. Nucl. Mater. 532 (2020), 152042. DOI
6	P. Le Coz, J.F. Sauvage, J.P. Serpantie, Sodium-cooled fast reactors: the ASTRID plant project1, in: Proceedings of ICAPP 201, 2011.
7	B. Faure, P. Archier, J.-F. Vidal, J.M. Palau, L. Buiron, Neutronic calculation of an axially heterogeneous ASTRID fuel assembly with APOLLO3®: analysis of biases and foreseen improvements, Ann. Nucl. Energy 115 (2018) 88-104. DOI
8	EERA-JPNM, INSPYRE - Investigations Supporting MOX Fuel Licensing in ESNII Prototype Reactors [Online]. Available: http://www.eera-jpnm.eu/inspyre/, 2017.
9	L. Luzzi, T. Barani, A. Magni, D. Pizzocri, A. Schubert, P. Van Uffelen, V. Marelle, B. Michel, B. Boer, S. Lemehov, A. Del Nevo, Definition of Detailed Configurations of the Case Studies for the Fuel Performance Simulations in Task 7.3, INSPYRE Milestone MS16, 2019.
10	D. Pizzocri, T. Barani, L. Luzzi, SCIANTIX Code [Online]. Available: https://gitlab.com/poliminrg/sciantix, 2020.
11	A. Scolaro, I. Clifford, C. Fiorina, A. Pautz, The OFFBEAT multi-dimensional fuel behavior solver, Nucl. Eng. Des. 358 (2020), 110416. DOI
12	G. Pastore, L. Luzzi, V. Di Marcello, P. Van Uffelen, Physics-based modelling of fission gas swelling and release in UO₂ applied to integral fuel rod analysis, Nucl. Eng. Des. 256 (2013) 75-86. DOI
13	L. Cognini, A. Cechet, T. Barani, D. Pizzocri, P. Van Uffelen, L. Luzzi, Towards a physics-based description of intra-granular helium behaviour in oxide fuel for application in fuel performance codes, Nucl. Eng. Technol. 53 (2) (2021) 562-571. DOI
14	A. Cechet, S. Altieri, T. Barani, L. Cognini, S. Lorenzi, A. Magni, D. Pizzocri, L. Luzzi, A new burn-up module for application in fuel performance calculations targeting the helium production rate in (U,Pu)O₂ for fast reactors, Nucl. Eng. Technol. 53 (6) (2021) 1893-1908. DOI
15	A. Scolaro, Development of a Novel Finite Volume Methodology for Multi-Dimensional Fuel Performance Applications,, PhD Thesis,, EPFL, Switzerland, 2021.
16	C. Sari, Grain growth kinetics in uranium-plutonium mixed oxides, J. Nucl. Mater. 137 (2) (1986) 100-106. DOI
17	J.B. Ainscough, B.W. Oldfield, J.O. Ware, Isothermal grain growth kinetics in sintered UO₂ pellets, J. Nucl. Mater. 49 (2) (1973) 117-128. DOI
18	P. Botazzoli, Helium Production and Behaviour in LWR Oxide Nuclear Fuels, PhD Thesis,, Politecnico di Milano, Italy, 2011.
19	F. Verdolin, S. Novascone, D. Pizzocri, G. Pastore, T. Barani, L. Luzzi, Modelling fission gas behaviour in fast reactor (U,Pu)O2 fuel with BISON, J. Nucl. Mater. 547 (2021), 152728. DOI
20	S. Lemehov, New correlations of thermal expansion and Young's modulus based on existing literature and new data, INSPYRE Deliverable D6.3 (2020).
21	A. Magni, T. Barani, A. Del Nevo, D. Pizzocri, D. Staicu, P. Van Uffelen, L. Luzzi, Modelling and assessment of thermal conductivity and melting behaviour of MOX fuel for fast reactor applications, J. Nucl. Mater. 541 (2020), 152410. DOI
22	D. Pizzocri, G. Pastore, T. Barani, E. Bruschi, L. Luzzi, P. Van Uffelen, Modelling of burst release in oxide fuel and application to the transuranus code, in: Proceedings Of the 11th International Conference WWER Fuel Performance, Modelling and Experimental Support, 2015, 28 September - 02 October, Varna, Bulgaria.
23	G. Pastore, D. Pizzocri, C. Rabiti, T. Barani, P. Van Uffelen, L. Luzzi, An effective numerical algorithm for intra-granular fission gas release during non-equilibrium trapping and resolution, J. Nucl. Mater. 509 (2018) 687-699. DOI
24	A. Magni, L. Luzzi, P. Van Uffelen, D. Staicu, P. Console Camprini, P. Del Prete, A. Del Nevo, Report on the improved models of melting temperature and thermal conductivity for MOX fuels and JOG, INSPYRE Deliverable D6.2 version 2 (2020).
25	Y. Philipponneau, Thermal conductivity of (U, Pu)O_2-x mixed oxide fuel, J. Nucl. Mater. 188 (1992) 194-197. DOI
26	L. Luzzi, T. Barani, B. Boer, L. Cognini, A. Del Nevo, M. Lainet, S. Lemehov, A. Magni, V. Marelle, B. Michel, D. Pizzocri, A. Schubert, P. Van Uffelen, M. Bertolus, Assessment of three European fuel performance codes against the SUPERFACT-1 fast reactor irradiation experiment, Nucl. Eng. Technol. 53 (2021) 3367-3378. DOI
27	P. Van Uffelen, P. Botazzoli, L. Luzzi, S. Bremier, A. Schubert, P. Raison, R. Eloirdi, M.A. Barker, An experimental study of grain growth in mixed oxide samples with various microstructures and plutonium concentration, J. Nucl. Mater. 434 (1-3) (2013) 287-290. DOI
28	W. Dienst, I. Muelle-Lyda, H. Zimmermann, Swelling, densification and creep of oxide and carbide fuels under irradiation, in: International Conference on Fast Breeder Reactor Performance, 1979, 5-8 March, Monterey, CA, USA.
29	R.L. Williamson, K.A. Gamble, D.M. Perez, S.R. Novascone, G. Pastore, R.J. Gardner, J.D. Hales, W. Liu, A. Mai, Validating the BISON fuel performance code to integral LWR experiments, Nucl. Eng. Des. 301 (2016) 232-244. DOI
30	L. Luzzi, A. Cammi, V. Di Marcello, S. Lorenzi, D. Pizzocri, P. Van Uffelen, Application of the TRANSURANUS code for the fuel pin design process of the ALFRED reactor, Nucl. Eng. Des. 277 (2014) 173-187. DOI
31	T. Beck, V. Blanc, J.-M. Escleine, D. Haubensack, M. Pelletier, M. Phelip, B. Perrin, C. Venard, Conceptual design of ASTRID fuel sub-assemblies, Nucl. Eng. Des. 315 (2017) 51-60. DOI
32	R.J. Parrish, F. Cappia, A. Aitkaliyeva, Comparison of the radial effects of burnup on fast reactor MOX fuel microstructure and solid fission products, J. Nucl. Mater. 531 (2020), 152003. DOI
33	G. Pastore, D. Pizzocri, J.D. Hales, S.R. Novascone, D.M. Perez, B.W. Spencer, R.L. Williamson, P. Van Uffelen, Modeling of transient fission gas behavior in oxide fuel and application to the BISON code, in: Proc. of Enlarged Halden Programme Group Meeting, 2015. Roros, Norway.
34	K. Une, S. Kashibe, Fission gas release during post irradiation annealing of BWR fuels, J. Nucl. Sci. Technol. 27 (11) (1990) 1002-1016. DOI
35	F. Cappia, K. Tanaka, M. Kato, K. McClellan, J. Harp, Post-irradiation examinations of annular mixed oxide fuels with average burnup 4 and 5% FIMA, J. Nucl. Mater. 533 (2020), 152076. DOI
36	C. Venard, T. Beck, B. Bernardin, A. Conti, D. Gentet, P. Lamagnere, P. Sciora, D. Lorenzo, A. Tosello, M. Vanier, A.-C. Scholer, D. Verrier, F. Barjot, D. Schmitt, The ASTRID core at the midterm of the conceptual design phase (AVP2), in: ICAPP 2015 - International Congress on Advances in Nuclear Power Plants, 3-5 May 2015, Nice, France, 2015.
37	M. Pelletier, Y. Guerin, Fuel Performance of Fast Spectrum Oxide Fuel, in: Chap. 2.03, in: R.J.M. Konings, R.E. Stoller (Eds.), Comprehensive Nuclear Materials, 2, Elsevier, 2020, pp. 72-105.
38	GIF (Generation IV International Forum), Annual Report 2020, 2020.
39	A. Magni, A. Del Nevo, L. Luzzi, D. Rozzia, M. Adorni, A. Schubert, P. Van Uffelen, The TRANSURANUS fuel performance code, in: J. Wang, X. Li, C. Allison, J. Hohorst (Eds.), Nuclear Power Plant Design and Analysis Codes - Development, Validation and Application Chap. 8, Woodhead Publishing Series in Energy, Elsevier, 2021, pp. 161-205.
40	P. Van Uffelen, A. Schubert, L. Luzzi, T. Barani, A. Magni, D. Pizzocri, M. Lainet, V. Marelle, B. Michel, B. Boer, S. Lemehov, A. Del Nevo, Incorporation and verification of models and properties in fuel performance codes, INSPYRE Deliverable D7.2 (2020).
41	K. Lassmann, TRANSURANUS: a fuel rod analysis code ready for use, J. Nucl. Mater. 188 (C) (1992) 295-302. DOI
42	M. Lainet, B. Michel, J.C. Dumas, M. Pelletier, I. Ramiere, GERMINAL, a fuel performance code of the PLEIADES platform to simulate the in-pile behaviour of mixed oxide fuel pins for sodium-cooled fast reactors, J. Nucl. Mater. 516 (2019) 30-53. DOI
43	D. Pizzocri, G. Pastore, T. Barani, A. Magni, L. Luzzi, P. Van Uffelen, S.A. Pitts, A. Alfonsi, J.D. Hales, A model describing intra-granular fission gas behaviour in oxide fuel for advanced engineering tools, J. Nucl. Mater. 502 (2018) 323-330. DOI
44	T. Barani, E. Bruschi, D. Pizzocri, G. Pastore, P. Van Uffelen, R.L. Williamson, L. Luzzi, Analysis of transient fission gas behaviour in oxide fuel using BISON and TRANSURANUS, J. Nucl. Mater. 486 (2017) 96-110. DOI
45	M.S. Veshchunov, V.D. Ozrin, V.E. Shestak, V.I. Tarasov, R. Dubourg, G. Nicaise, Development of the mechanistic code MFPR for modelling fission-product release from irradiated UO₂ fuel, Nucl. Eng. Des. 236 (2) (2006) 179-200. DOI
46	M.S. Veshchunov, V.I. Tarasov, Modelling of irradiated UO₂ fuel behaviour under transient conditions, J. Nucl. Mater. 437 (1-3) (2013) 250-260. DOI
47	M.V. Speight, A calculation on the migration of fission gas in material exhibiting precipitation and Re-solution of gas atoms under irradiation, Nucl. Sci. Eng. 37 (1969) 180-185. DOI
48	J.A. Turnbull, The distribution of intragranular fission gas bubbles in UO₂ during irradation, J. Nucl. Mater. 38 (2) (1971) 203-212. DOI
49	D. Pizzocri, T. Barani, L. Cognini, L. Luzzi, A. Magni, A. Schubert, P. Van Uffelen, T. Wiss, Synthesis of the inert gas behaviour models developed in INSPYRE, INSPYRE Deliverable D6.4 (2020).
50	P. Botazzoli, L. Luzzi, S. Bremier, A. Schubert, P. Van Uffelen, Microstructural evolution in heterogeneous and homogeneous MOX fuels, in: NuMat 2010 - the Nuclear Materials Conference, 2010, 4-7 October, Karlsruhe, Germany.
51	B. Boer, J. Eysermans, S. Lemehov, L. Luzzi, T. Barani, L. Cognini, A. Magni, D. Pizzocri, A. Del Nevo, A. Schubert, P. Van Uffelen, M. Bertolus, M. Lainet, V. Marelle, B. Michel, Report describing the results of the benchmark between improved codes and previous versions on selected experimental cases, INSPYRE Deliverable D7.3 (2021).