TY - JOUR
T1 - Transient and steady state crack growth kinetics for stress corrosion cracking of a cold worked 316L stainless steel in oxygenated pure water at different temperatures
AU - Lu, Zhanpeng
AU - Shoji, Tetsuo
AU - Takeda, Yoichi
AU - Ito, Yuzuru
AU - Kai, Akira
AU - Yamazaki, Seiya
N1 - Funding Information:
This work was performed as a part of the PEACE III program jointly supported by EDF, EPRI, SKI, TEPCO, KEPCO, TohokuEPCO, JAPCO, HITACHI Ltd., MHI Ltd., TOSHIBA Co., and IHI Ltd. A part of this work was also performed as a part of the SCCM project of Corrosion Center, Japanese Society of Corrosion Engineering, which has been financially sponsored by Japanese BWR Owner’s Group. This work has been performed under the support of Grant-in-Aid for Scientific Research (S) 17106002 and (C) 18560066, Japan Society for the Promotion of Science.
PY - 2008/2
Y1 - 2008/2
N2 - The stress corrosion cracking (SCC) growth kinetics for a cold worked 316L stainless steel was continuously monitored in high purity water at different temperatures and dissolved oxygen (DO) levels under a K (or Kmax) of 30 MPa m0.5. The total SCC test time was more than 8000 h to make sure the steady state crack growth rate under each test condition could be reached. Crack growth rate (CGR) increases with increasing temperature in the range 110-288 °C. A typical intergranular-cracking mode is identified. Depending on the previous test condition, especially the temperature, three kinds of crack growth kinetics, i.e., increasing with testing time then becoming steady, being constant during the whole period, or decreasing with test time then becoming steady, are identified and discussed. Time-dependent and testing history-dependent crack growth modes were confirmed in two series of tests in 2 ppm DO and 7.5 ppm DO pure water. The apparent activation energies are calculated and compared with other data in different environments under different applied loading levels for understanding the cracking mechanism.
AB - The stress corrosion cracking (SCC) growth kinetics for a cold worked 316L stainless steel was continuously monitored in high purity water at different temperatures and dissolved oxygen (DO) levels under a K (or Kmax) of 30 MPa m0.5. The total SCC test time was more than 8000 h to make sure the steady state crack growth rate under each test condition could be reached. Crack growth rate (CGR) increases with increasing temperature in the range 110-288 °C. A typical intergranular-cracking mode is identified. Depending on the previous test condition, especially the temperature, three kinds of crack growth kinetics, i.e., increasing with testing time then becoming steady, being constant during the whole period, or decreasing with test time then becoming steady, are identified and discussed. Time-dependent and testing history-dependent crack growth modes were confirmed in two series of tests in 2 ppm DO and 7.5 ppm DO pure water. The apparent activation energies are calculated and compared with other data in different environments under different applied loading levels for understanding the cracking mechanism.
KW - A. Cold work
KW - A. Low carbon stainless steel
KW - B. Boiling water reactor
KW - B. Contoured double cantilever beam specimen
KW - B. High temperature pure water
KW - C. Crack growth rate
KW - C. Stress corrosion cracking
KW - C. Thermal activation energy
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U2 - 10.1016/j.corsci.2007.08.005
DO - 10.1016/j.corsci.2007.08.005
M3 - Article
AN - SCOPUS:39149114404
SN - 0010-938X
VL - 50
SP - 561
EP - 575
JO - Corrosion Science
JF - Corrosion Science
IS - 2
ER -