Effect of cold working on the corrosion resistance of JPCA stainless steel in flowing Pb-Bi at 450 degree C
Development of a high performance proton beam window material is one of the critical issues for the deployment of the accelerator-driven transmutation system (ADS) with liquid Pb-Bi eutectic as a spallation target and coolant. In the present study, we applied 20% cold work treatment to JPCA austenit...
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| Veröffentlicht in: | Journal of nuclear materials 2012-12, Vol.431 (1-3), p.97-104 |
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| container_title | Journal of nuclear materials |
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| creator | Rivai, Abu Saito, Shigeru Tezuka, Masao Kato, Chiaki Kikuchi, Kenji |
| description | Development of a high performance proton beam window material is one of the critical issues for the deployment of the accelerator-driven transmutation system (ADS) with liquid Pb-Bi eutectic as a spallation target and coolant. In the present study, we applied 20% cold work treatment to JPCA austenitic stainless steel and investigated it from the corrosion behavior viewpoint. The corrosion test of 20% cold-worked JPCA SS has been carried in the JLBL-1 (JAEA Lead-Bismuth Loop-1) apparatus. The maximum temperature, the temperature difference, the flow velocity and the exposure time of the liquid Pb-Bi were 450 degree C, 100 degree C, 1 m/s, and 1000 h, respectively. For comparison analysis, JPCA SS without cold working was also tested in the same time and conditions with the 20% cold-worked JPCA SS. The results showed a different corrosion behavior between the JPCA SS without and with cold working. As for the JPCA SS without cold working, Pb-Bi penetrated into the matrix through a ferrite layer which was formed because of constituent metals dissolution from the matrix into Pb-Bi. As for the 20% cold-worked JPCA SS, dissolution attack occurred only partially and formed localized superficial pitting corrosion. It was found that the different corrosion behavior occurred because the cold working induced a structure transformation from gamma -austenite to alpha '-martensite and affected the corrosion resistance of the JPCA SS in flowing Pb-Bi at 450 degree C. |
| doi_str_mv | 10.1016/j.jnucmat.2011.11.022 |
| format | Article |
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In the present study, we applied 20% cold work treatment to JPCA austenitic stainless steel and investigated it from the corrosion behavior viewpoint. The corrosion test of 20% cold-worked JPCA SS has been carried in the JLBL-1 (JAEA Lead-Bismuth Loop-1) apparatus. The maximum temperature, the temperature difference, the flow velocity and the exposure time of the liquid Pb-Bi were 450 degree C, 100 degree C, 1 m/s, and 1000 h, respectively. For comparison analysis, JPCA SS without cold working was also tested in the same time and conditions with the 20% cold-worked JPCA SS. The results showed a different corrosion behavior between the JPCA SS without and with cold working. As for the JPCA SS without cold working, Pb-Bi penetrated into the matrix through a ferrite layer which was formed because of constituent metals dissolution from the matrix into Pb-Bi. As for the 20% cold-worked JPCA SS, dissolution attack occurred only partially and formed localized superficial pitting corrosion. 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| ispartof | Journal of nuclear materials, 2012-12, Vol.431 (1-3), p.97-104 |
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| language | eng |
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| source | ScienceDirect Journals (5 years ago - present) |
| subjects | Cold working Corrosion Corrosion resistance Corrosion tests Dissolution Lead (metal) Liquids Pitting (corrosion) |
| title | Effect of cold working on the corrosion resistance of JPCA stainless steel in flowing Pb-Bi at 450 degree C |
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