Your search keyword '"S.L. Jeng"' showing total 3 results

1. Environmentally assisted cracking behavior of dissimilar metal weldments in simulated BWR coolant environments

Author

J.S. Huang, Jian Yu Huang, M.F. Chiang, S.L. Jeng, and R.C. Kuo

Subjects

Nuclear and High Energy Physics, Materials science, Metallurgy, Alloy, Welding, engineering.material, Coolant, law.invention, Carbide, Cracking, Nuclear Energy and Engineering, Corrosion fatigue, law, engineering, General Materials Science, Grain boundary, Base metal

Abstract

The environmentally assisted cracking behavior of dissimilar metal (DM) welds, including Alloy 52-A 508 and Alloy 82-A508, under simulated BWR coolant conditions was studied. Effects of postweld heat treatment and sulfur content of the base metal on the corrosion fatigue and SCC growth rates of DM welds were evaluated. The crack growth rates for the DM weld heat-treated at 621 °C for 24 h were observed to be faster than those for the as-welded. But the DM weld heat-treated at 621 °C for 8 h + 400 °C for 200 h showed better SCC resistance than the as-welded. The longer the heat treatment at 621 °C, the higher the chromium carbides density along the grain boundary was observed. Sulfur could diffuse out of the base metal and segregate along the grain boundaries of the dilution zone, leading to weakening the grain boundary strength and the SCC resistance of the Alloy 52-A508 weld.

Published

2013

2. Corrosion fatigue behavior of dissimilar metal weldments under nominal constant ΔK loading mode in a simulated BWR coolant environment

Author

S.L. Jeng, J.S. Huang, R.C. Kuo, J.C. Wang, Jian Yu Huang, M.F. Chiang, and R.F. Liu

Subjects

Materials science, General Chemical Engineering, Metallurgy, Alloy, General Chemistry, Welding, engineering.material, Coolant, Corrosion, law.invention, Crack closure, Corrosion fatigue, Residual stress, law, engineering, General Materials Science, Strain gauge

Abstract

Corrosion fatigue behavior of the dissimilar metal weldment, Alloy 52-A508, under a simulated BWR coolant condition was studied. Corrosion fatigue crack growth rates of the dissimilar metal weldments were observed to increase with crack extension under the nominal constant ΔK loading mode. It could be accounted for by a decrease in the Cr and Ni contents and the crack closure effect with the weld depth. Finite element analysis on the welding residual stress was performed. The trend of analytical results agreed well with that of the residual stress measurements obtained by a hole-drilling strain gauge method.

Published

2011

3. Corrosion fatigue behavior of low alloy steels under simulated BWR coolant conditions

Author

M.C. Young, Jian Yu Huang, J.J. Yeh, J.S. Huang, S.L. Jeng, and R.C. Kuo

Subjects

inorganic chemicals, Nuclear and High Energy Physics, Materials science, Hydrogen, fungi, Metallurgy, Alloy, technology, industry, and agriculture, chemistry.chemical_element, engineering.material, Sulfur, Coolant, Nuclear Energy and Engineering, chemistry, Corrosion fatigue, engineering, Water environment, Metallography, Boiling water reactor, General Materials Science

Abstract

The corrosion fatigue crack growth behavior of A533 and A508 low alloy steels under simulated boiling water reactor (BWR) coolant conditions was studied. Corrosion fatigue crack growth rates of A533B3 and A508 cl. 3 steels were significantly affected by the steel sulfur content, loading frequency and dissolved oxygen content of water environments. The data points outside the bound of Eason’s model could be attributed to the low frequency, higher steel sulfur content and high dissolved oxygen in water environments. The sulfur dissolved in the water environment from the higher-sulfur steels was sufficiently concentrated to acidify the crack tip chemistry even in the hydrogen water chemistry (HWC). Therefore, nitrogenated or HWC water showed little or no beneficiary effect on the high-sulfur steels. For the steel specimens of the same sulfur level, their corrosion fatigue crack growth rates were comparable in different orientations, which could be related to the exposure of fresh sulfides to the water environment. The percentages of sulfides per unit area, by quantitative metallography, were comparable for the steel specimens of both orientations. When the steel sulfur content was decreased to a critical sulfur content 0.005 wt.%, the crack growth rates decreased remarkably.

Published

2010