Influence of inclusions on initiation of pitting corrosion and stress corrosion cracking of X70 steel in near-neutral pH environment

被引:176
作者
Wang, Liwei [1 ]
Xin, Juncheng [2 ]
Cheng, Lianjun [1 ]
Zhao, Kang [1 ]
Sun, Baozhuang [3 ]
Li, Junru [1 ]
Wang, Xin [2 ]
Cui, Zhongyu [2 ]
机构
[1] Qingdao Univ, Coll Electromech Engn, Qingdao 266071, Peoples R China
[2] Ocean Univ China, Sch Mat Sci & Engn, Qingdao 266100, Peoples R China
[3] Univ Sci & Technol Beijing, Ctr Corros & Protect, Beijing 100083, Peoples R China
来源
CORROSION SCIENCE | 2019年 / 147卷
基金
中国国家自然科学基金;
关键词
low alloy steel; SEM; pitting corrosion; stress corrosion; HYDROGEN-INDUCED CRACKING; PIPELINE STEEL; STAINLESS-STEEL; NONMETALLIC INCLUSIONS; IN-SITU; METALLURGICAL FACTORS; SULFIDE INCLUSIONS; CREVICE CORROSION; GRAIN-BOUNDARY; MNS INCLUSIONS;
D O I
10.1016/j.corsci.2018.11.007
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
In-situ 2D and 3D microscopic technologies are used to analyze the influence of inclusions on pitting and stress corrosion cracking initiation of X70 steel in near-neutral pH solution. The chemical dissolution of complex oxide inclusions or part of them induces corrosion pits. Circular protected region forms around Ds inclusions due to dissolution of CaS. The Si-enriched inclusions remain intact, but interstice forms at the inclusion/matrix interface due to the dissolution of the matrix. Both complex oxide inclusions and Si-enriched inclusions can induce initiation of SCC micro-cracks, but most of the micro-cracks are generated inside the ferrite grains.
引用
收藏
页码:108 / 127
页数:20
相关论文
共 91 条
[71]   Effect of impurity level and inclusions on the ductility and toughness of an ultra-high-strength steel [J].
Tervo, H. ;
Kaijalainen, A. ;
Pikkarainen, T. ;
Mehtonen, S. ;
Porter, D. .
MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING, 2017, 697 :184-193
[72]   Electrochemical corrosion, hydrogen permeation and stress corrosion cracking behavior of E690 steel in thiosulfate-containing artificial seawater [J].
Tian, Huiyun ;
Wang, Xin ;
Cui, Zhongyu ;
Lu, Qiankun ;
Wang, Liwei ;
Lei, Li ;
Li, Yong ;
Zhang, Dawei .
CORROSION SCIENCE, 2018, 144 :145-162
[73]  
Tsuyoshi M., 1969, ISIJ INT, V55, P1347
[74]   New insight into the pit-to-crack transition from finite element analysis of the stress and strain distribution around a corrosion pit [J].
Turnbull, A. ;
Wright, L. ;
Crocker, L. .
CORROSION SCIENCE, 2010, 52 (04) :1492-1498
[75]   Thermodynamics of chemical and electrochemical stability of corrosion active nonmetal inclusions [J].
Tyurin, A. G. ;
Pyshmintsev, I. Yu. ;
Kostitsyna, I. V. ;
Zubkova, I. M. .
PROTECTION OF METALS, 2007, 43 (01) :34-44
[76]   In situ corrosion characterization of simulated weld heat affected zone on API X80 pipeline steel [J].
Wang, L. W. ;
Liu, Z. Y. ;
Cui, Z. Y. ;
Du, C. W. ;
Wang, X. H. ;
Li, X. G. .
CORROSION SCIENCE, 2014, 85 :401-410
[77]   Influence of carbon on stress corrosion cracking of high strength pipeline steel [J].
Wang, L. W. ;
Du, C. W. ;
Liu, Z. Y. ;
Wang, X. H. ;
Li, X. G. .
CORROSION SCIENCE, 2013, 76 :486-493
[78]  
Wang L. W., 2018, MATERIALS, V465, P1
[79]   Observation of the pitting corrosion and uniform corrosion for X80 steel in 3.5 wt.% NaCl solutions using in-situ and 3-D measuring microscope [J].
Wang, Yafei ;
Cheng, Guangxu ;
Li, Yun .
CORROSION SCIENCE, 2016, 111 :508-517
[80]   The development of grain-orientation-dependent-residual stressess in a cyclically deformed alloy [J].
Wang, YD ;
Tian, HB ;
Stoica, AD ;
Wang, XL ;
Liaw, PK ;
Richardson, JW .
NATURE MATERIALS, 2003, 2 (02) :101-106
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