Hydrazine and Hydrogen Coinjection to Mitigate Stress Corrosion Cracking of Structural Materials in Boiling Water Reactors (VII) : Effects of Bulk Water Chemistry on ECP Distribution inside a Crack
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概要
- 論文の詳細を見る
Water chemistry in a simulated crack (crack) has been studied to understand the mechanisms of stress corrosion cracking in a boiling water reactor environment. Electrochemical corrosion potential (ECP) in a crack made in an austenite type 304 stainless steel specimen was measured. The ECP distribution along the simulated crack was strongly affected by bulk water chemistry and bulk flow. When oxygen concentration was high in the bulk water, the potential difference between the crack tip and the outside of the crack (ΔE), which must be one motive force for crack growth, was about 0.3 V under a stagnant condition. When oxygen was removed from the bulk water, ECP inside and outside the crack became low and uniform and ΔE became small. The outside ECP was also lowered by depositing platinum on the steel specimen surface and adding stoichiometrically excess hydrogen to oxygen to lower ΔE. This was effective only when bulk water did not flow. Under the bulk water flow condition, water-borne oxygen caused an increase in ECP on the untreated surface inside the crack. This also caused a large ΔE. The ΔE effect was confirmed by crack growth rate measurements with a catalyst-treated specimen. Therefore, lowering the bulk oxidant concentration by such measures as hydrazine hydrogen coinjection, which is currently under development, is important for suppressing the crack growth.
- 社団法人 日本原子力学会の論文
- 2007-11-25
著者
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Fuse Motomasa
Hitachi Works, Hitachi-GE Nuclear Energy, Ltd.
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Wada Y
Energy And Environmental Systems Laboratory Hitachi Ltd.
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Wada Yoichi
Power And Industrial Systems R& D Division Hitachi Ltd.
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Fuse Motomasa
Hitachi Works Hitachi-ge Nuclear Energy Ltd.
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Wada Yoichi
Energy And Environmental Systems Lab. Hitachi Ltd.
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Wada Yoichi
Energy And Environmental Systems Laboratory Hitachi Ltd.
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Ishigure K
Department Of Quantum Engineering And Systems Science The University Of Tokyo
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TACHIBANA Masahiko
Power and Industrial Systems R&D Laboratory, Hitachi, Ltd.
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ISHIDA Kazushige
Power and Industrial Systems R&D Laboratory, Hitachi, Ltd.
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AIZAWA Motohiro
Hitachi-GE Nuclear Energy, Ltd.
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Iinuma Kouichi
Department Of Quantum Science And Energy Engineering Graduate School Of Engineering Tohoku Universit
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Fuse Motomasa
Hitachi-ge Nuclear Energy Ltd.
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Ishida Kazushige
Power And Industrial Systems R&d Laboratory Hitachi Ltd.
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Tachibana Masahiko
Energy And Environmental Systems Laboratory Hitachi Ltd.
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Aizawa Motohiro
Hitachi-ge Nuclear Energy Ltd.
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Aizawa Motohiro
Hitachi Engineering Co. Ltd.
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Ishida Kazushige
Energy And Environmental Systems Laboratory Hitachi Ltd.
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Ishida Kazushige
Power & Industrial Systems R&d Laboratory Hitachi Ltd.
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Wada Yoichi
Power & Industrial Systems R&d Laboratory Hitachi Ltd.
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