Abstract
Neutron irradiation embrittlement of reactor pressure vessel (RPV) steels has been of concern primarily for the pressurized water reactors (PWRs). After long operation experiences, we are now becoming aware of the situation that the neutron irradiation embrittlement is also of concern for some of the boiling water reactors (BWRs) particularly with Cu-containing RPV steels. The surveillance data of Cu-containing BWR RPV steels show relatively larger shift in ductile-to-brittle transition temperature of fracture toughness than predicted by the embrittlement correlation method developed in late eighties and early nineties. Accurate evaluation of the amount of embrittlement is now very important for long-term operation of BWRs. In this paper, we will describe the neutron irradiation embrittlement of BWR RPVs in Japan. Some of the materials that show relatively large transition temperature shifts are investigated to understand the causes of embrittlement using state-of-the-art microstructural characterization techniques. Furthermore, some archive materials of such RPVs are irradiated in a material testing reactor with high neutron flux to understand the effect of flux on transition temperature shifts and corresponding microstructural changes. Microstructural evolution under irradiation, solute clustering in particular could explain the differences in transition temperature shift of the analyzed specimens. Larger BWR RPVs, which have larger
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Asano, K;
Nishiyama, T;
[1]
Soneda, N;
Dohi, K;
Nishida, K;
Nomoto, A;
[2]
Ohta, T;
[3]
Ishimaru, Y;
[4]
Yoneda, H;
[5]
Lida, J;
[6]
Yuya, H
[7]
- TEPCO (Japan)
- CRIEPI (Japan)
- Japan Atomic Power Co. (Japan)
- Chugoku EPCO (Japan)
- Hokuriku EPCO (Japan)
- Tohoku EPCO (Japan)
- Chubu EPCO (Japan)
Citation Formats
Asano, K, Nishiyama, T, Soneda, N, Dohi, K, Nishida, K, Nomoto, A, Ohta, T, Ishimaru, Y, Yoneda, H, Lida, J, and Yuya, H.
Current understanding on the neutron irradiation embrittlement of BWR reactor pressure vessel steels in Japan.
France: N. p.,
2011.
Web.
Asano, K, Nishiyama, T, Soneda, N, Dohi, K, Nishida, K, Nomoto, A, Ohta, T, Ishimaru, Y, Yoneda, H, Lida, J, & Yuya, H.
Current understanding on the neutron irradiation embrittlement of BWR reactor pressure vessel steels in Japan.
France.
Asano, K, Nishiyama, T, Soneda, N, Dohi, K, Nishida, K, Nomoto, A, Ohta, T, Ishimaru, Y, Yoneda, H, Lida, J, and Yuya, H.
2011.
"Current understanding on the neutron irradiation embrittlement of BWR reactor pressure vessel steels in Japan."
France.
@misc{etde_21496649,
title = {Current understanding on the neutron irradiation embrittlement of BWR reactor pressure vessel steels in Japan}
author = {Asano, K, Nishiyama, T, Soneda, N, Dohi, K, Nishida, K, Nomoto, A, Ohta, T, Ishimaru, Y, Yoneda, H, Lida, J, and Yuya, H}
abstractNote = {Neutron irradiation embrittlement of reactor pressure vessel (RPV) steels has been of concern primarily for the pressurized water reactors (PWRs). After long operation experiences, we are now becoming aware of the situation that the neutron irradiation embrittlement is also of concern for some of the boiling water reactors (BWRs) particularly with Cu-containing RPV steels. The surveillance data of Cu-containing BWR RPV steels show relatively larger shift in ductile-to-brittle transition temperature of fracture toughness than predicted by the embrittlement correlation method developed in late eighties and early nineties. Accurate evaluation of the amount of embrittlement is now very important for long-term operation of BWRs. In this paper, we will describe the neutron irradiation embrittlement of BWR RPVs in Japan. Some of the materials that show relatively large transition temperature shifts are investigated to understand the causes of embrittlement using state-of-the-art microstructural characterization techniques. Furthermore, some archive materials of such RPVs are irradiated in a material testing reactor with high neutron flux to understand the effect of flux on transition temperature shifts and corresponding microstructural changes. Microstructural evolution under irradiation, solute clustering in particular could explain the differences in transition temperature shift of the analyzed specimens. Larger BWR RPVs, which have larger water gaps, receive less neutron irradiation and harmful impurities in steels such as copper are well controlled since 1980 so irradiation embrittlement in BWR vessels can now be considered a concern only in old and small plants. All the new information obtained through these activities was considered in the development of new embrittlement correlation that is now adopted in JEAC 4201- 2007 of Japan Electric Association}
place = {France}
year = {2011}
month = {Jul}
}
title = {Current understanding on the neutron irradiation embrittlement of BWR reactor pressure vessel steels in Japan}
author = {Asano, K, Nishiyama, T, Soneda, N, Dohi, K, Nishida, K, Nomoto, A, Ohta, T, Ishimaru, Y, Yoneda, H, Lida, J, and Yuya, H}
abstractNote = {Neutron irradiation embrittlement of reactor pressure vessel (RPV) steels has been of concern primarily for the pressurized water reactors (PWRs). After long operation experiences, we are now becoming aware of the situation that the neutron irradiation embrittlement is also of concern for some of the boiling water reactors (BWRs) particularly with Cu-containing RPV steels. The surveillance data of Cu-containing BWR RPV steels show relatively larger shift in ductile-to-brittle transition temperature of fracture toughness than predicted by the embrittlement correlation method developed in late eighties and early nineties. Accurate evaluation of the amount of embrittlement is now very important for long-term operation of BWRs. In this paper, we will describe the neutron irradiation embrittlement of BWR RPVs in Japan. Some of the materials that show relatively large transition temperature shifts are investigated to understand the causes of embrittlement using state-of-the-art microstructural characterization techniques. Furthermore, some archive materials of such RPVs are irradiated in a material testing reactor with high neutron flux to understand the effect of flux on transition temperature shifts and corresponding microstructural changes. Microstructural evolution under irradiation, solute clustering in particular could explain the differences in transition temperature shift of the analyzed specimens. Larger BWR RPVs, which have larger water gaps, receive less neutron irradiation and harmful impurities in steels such as copper are well controlled since 1980 so irradiation embrittlement in BWR vessels can now be considered a concern only in old and small plants. All the new information obtained through these activities was considered in the development of new embrittlement correlation that is now adopted in JEAC 4201- 2007 of Japan Electric Association}
place = {France}
year = {2011}
month = {Jul}
}