Effects of superimposed cyclic operation on corrosion products activity in reactor cooling system of AP-1000 |
Mahmood, Fiaz
(School of Nuclear Science and Technology, Xi'an Jiaotong University)
Hu, Huasi (School of Nuclear Science and Technology, Xi'an Jiaotong University) Lu, Guichi (School of Nuclear Science and Technology, Xi'an Jiaotong University) Ni, Si (School of Nuclear Science and Technology, Xi'an Jiaotong University) Yuan, Jiaqi (School of Nuclear Science and Technology, Xi'an Jiaotong University) |
1 | M.P. Short, The particulate nature of the crud source term in light water reactors, J. Nuc. mat. 509 (2018) 478-481. DOI |
2 | F. Mahmood, H. Hu, L. Cao, Buildup and decay analysis of corrosion products activity in primary coolant loop of AP-1000, in: 26th International Conference on Nuclear Engineering London, England, 2018, pp. 22-26. July. |
3 | F. Mahmood, H. Hu, L. Cao, Dynamic response analysis of corrosion products activity under steady state operation and Mechanical Shim based power-maneuvering transients in AP-1000, Ann. Nucl. Energy 115 (2018) 16-26. DOI |
4 | F. Mahmood, H. Hu, L. Cao, G. Lu, S. Ni, J. Yuan, Evaluation of activated corrosion products in primary coolant circuit of AP-1000 under grid frequency stability mode, Ann. Nucl. Energy 125 (2019) 138-147. DOI |
5 | EUR, Europian utility Requirements for LWR nuclear power plants, vol. 2, Revisiones Cancer (2001). http://www.europeanutilityrequirements.org |
6 | World Nuclear News, Fourth Chinese AP1000 Connected to Grid [cited 2018 17-11-2018], 2018. Available from, http://world-nuclear-news.org/Articles/Fourth-Chinese-AP1000-connected-to-grid. |
7 | R. Loisel, V. Alexeeva, A. Zucker, D. Shropshire, Load-following with nuclear power: market effects and welfare implications, Prog. Nucl. Energy 109 (2018) 280-292. DOI |
8 | E. Chajduk, A. Bojanowska-Czajka, Corrosion mitigation in coolant systems in nuclear power plants, Prog. Nucl. Energy 88 (2016) 1-9. DOI |
9 | M. Rafique, N. Mirza, S. Mirza, M.J. Iqbal, Review of computer codes for modeling corrosion product transport and activity build-up in light water reactors, Nukleonika 55 (2010) 263-269. |
10 | IAEA, Modelling of Transport of Radioactive Substances in the Primary Circuit of Water-Cooled Reactors, IAEA-TECDOC-1672, Viana, Austria, 2012. |
11 | M. Benfarah, M. Zouiter, T. Jobert, F. Dacquait, M. Bultot, J.-B. Genin, PWR circuit contamination assessment tool. Use of OSCAR code for engineering studies at EDF, EPJ Nucl. Sci. Technol. 2 (2016) 1-5. DOI |
12 | R. Nasir, S.M. Mirza, N.M. Mirza, Evaluation of corrosion product activity in a typical PWR with extended cycles and flow rate perturbations, World J. Nucl. Sci. Technol. 07 (2017) 24-34. DOI |
13 | Y. Fu, J. Zhang, L. Li, Y. Chen, Solubility calculation of the corrosion products in water-cooled reactors and its application in CATE code, Fusion Eng. Des. 125 (2017) 664-668. DOI |
14 | Westinghouse, AP1000 design control document, Rev. 19 (2011). https://www.nrc.gov/docs/ML1117/ML11171A500.html. |
15 | Q. Guo, J. Zhang, S. Fang, Y. Chen, Calculation and analysis of water activation products source term in AP1000, Prog. Nucl. Energy 109 (2018) 66-73. DOI |
16 | F. Deeba, A.M. Mirza, N.M. Mirza, Modeling and simulation of corrosion product activity in pressurized water reactors under power perturbations, Ann. Nucl. Energy 26 (1999) 561-578. DOI |
17 | J.I. Malik, N.M. Mirza, S.M. Mirza, Time-dependent corrosion product activity in a typical PWR due to changes in coolant chemistry for long-term fuel cycles, Prog. Nucl. Energy 58 (2012) 100-107. DOI |
18 | O.N.R. Reactor, Chemistry Assessment of the Westinghouse AP1000 Reactor, Office for Nuclear Regulation, 2011. http://www.onr.org.uk/new-reactors. |
19 | J. Zhang, L. Li, S. He, W. Song, Y. Fu, B. Zhang, Y. Chen, Development of a three-zone transport model for activated corrosion products analysis of Tokamak Cooling Water System, Fusion Eng. Des. 109-111 (2016) 407-410. DOI |
20 | M. Rafique, N.M. Mirza, S.M. Mirza, Kinetic study of corrosion product activity in primary coolant pipes of a typical PWR under flow rate transients and linearly increasing corrosion rates, J. Nucl. Mater. 346 (2005) 282-292. DOI |
21 | S. Mo, J. Jia, B. Yichen, S. Xiuqiang, D. Wang, X. Xu, Y. Xie, H. Hu, Modelling of materials corrosion inside RCS based on mixed-conduction model, September, in: Proceedings of 8th International Symposium on Symbiotic Nuclear Power Systems for 21st Century, 2016, pp. 26-28. Chengdu, China. |
22 | J.S. Song, H.J. Cho, M.Y. Jung, S.H. Lee, A study on the application of CRUDTRAN code in primary systems of domestic pressurized heavy-water reactors for prediction of radiation source term, Nuclear Eng. Technol. 49 (2017) 638-644. DOI |
23 | A.S. Zhilkin, E.P. Popov, Modeling transport of radioactive products of corrosion in loops with sodium coolant, At. Energ. 119 (2015) 37-45. DOI |
24 | J.B. Genin, L. Brissonneau, T. Gilardi, OSCAR-Na, A new code for simulating corrosion product contamination in SFR, Metall. Mat. Trans. E. 3E (2016) 291-298. |
25 | J. Jia, Research on Modeling the Corrosion, Activity and Transport Proceeds in PWR Primary Circuits [Academic], Xi'an Jiaotong University, Xi'an, China, 2016. |