The Pitting Corrosion Behavior of the Austenitic Stainless Steel 308L-316L Welded Joint

被引:7
|
作者
He, Jinshan [1 ]
Xu, Shiguang [1 ]
Ti, Wenxin [1 ,2 ]
Han, Yaolei [2 ]
Mei, Jinna [2 ]
Wang, Xitao [1 ,3 ]
机构
[1] Univ Sci & Technol Beijing, Collaborat Innovat Ctr Steel Technol, Beijing 100083, Peoples R China
[2] Suzhou Nucl Power Res Inst, Suzhou 215004, Peoples R China
[3] Qilu Univ Technol, Adv Mat Inst, Shandong Prov Key Lab High Strength Lightweight M, Shandong Acad Sci, Jinan 250353, Peoples R China
来源
METALS | 2020年 / 10卷 / 09期
关键词
308L-316L welded joint; microstructure; pitting corrosion; residual strain; HEAT-AFFECTED ZONE; GRAIN-BOUNDARY; RESISTANCE; MICROSTRUCTURE; CRACKING; METAL;
D O I
10.3390/met10091258
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
The pitting corrosion resistance of the austenitic stainless steel 308L-316L welded joint was investigated by electrochemical tests. It is found that the weld zone was the most critical for pits to initiate in the welded joint due to relatively instable passive film with few Mo and inhomogeneous passive film induced by multiple (Mn, Al, and Si) oxides and continuous network of 13.94 vol.% delta ferrites. By statistical analysis, 53.8% pits initiated at (Mn, Al, and Si) oxides, 23.0% in austenite, and 23.2% at interface between ferrite and austenite. In addition, heat-affected zone was prone to have pitting corrosion compared with the base metal since residual strain was much higher in the region.
引用
收藏
页码:1 / 12
页数:12
相关论文
共 50 条
  • [41] Corrosion of 316L austenitic stainless steel under desalination plant conditions
    Saricimen, H., 1600, Inst of Materials, London, United Kingdom (29):
  • [42] Comparison of corrosion behavior on laser welded austenitic stainless steel
    Gnanarathinam, A.
    Palanisamy, D.
    Manikandan, N.
    Devaraju, A.
    Arulkirubakaran, D.
    MATERIALS TODAY-PROCEEDINGS, 2021, 39 : 649 - 653
  • [43] Texture analyses of friction stir welded austenitic stainless steel AISI-316L
    Meshram, Manish P.
    Tamboli, Rameez R.
    Kodli, Basanth K.
    Yebaji, Sushil G.
    Dey, Suhash R.
    ADVANCES IN MATERIALS AND PROCESSING TECHNOLOGIES, 2018, 4 (02) : 244 - 254
  • [44] Corrosion resistance enhancement and microstructural analysis of hull structural steel/316L stainless steel dissimilar welded joint
    Liu, Zhiwei
    Huang, Wenjun
    Wu, Manhang
    Li, Chen
    Kong, Jizhou
    Wang, Qianzhi
    Zhou, Fei
    MATERIALS TODAY COMMUNICATIONS, 2025, 42
  • [45] Microbially initiated pitting on 316L stainless steel
    Geiser, M
    Avci, R
    Lewandowski, Z
    INTERNATIONAL BIODETERIORATION & BIODEGRADATION, 2002, 49 (04) : 235 - 243
  • [46] Comparison of Nitriding Behavior for Austenitic Stainless Steel 316Ti and Super Austenitic Stainless Steel 904L
    Maendl, Stephan
    Manova, Darina
    METALS, 2024, 14 (06)
  • [47] EFFECTS OF TRITIUM ON CORROSION OF WELDED TYPE-316L STAINLESS-STEEL
    BELLANGER, G
    FUSION TECHNOLOGY, 1995, 27 (01): : 46 - 58
  • [48] An impedance study on corrosion of AISI 316L stainless steel in the passive and pitting regions
    Polo, JL
    Torres, CL
    Cano, E
    Bastidas, JM
    REVISTA DE METALURGIA, 1999, 35 (06) : 368 - 378
  • [49] Impedance study on corrosion of AISI 316L stainless steel in the passive and pitting regions
    Polo, José Luis
    Torres, Conceta Luz
    Cano, Emilio
    Bastidas, José María
    Revista de Metalurgia (Madrid), 35 (06): : 368 - 378
  • [50] Role of Te-RE alloying on the passive film and pitting corrosion behavior of 316L stainless steel
    Che, Zhichao
    Revilla, Reynier I.
    Li, Can
    Liu, Jing
    Liu, Wei
    Wouters, Benny
    Marcoen, Kristof
    Cheng, Xuequn
    Liu, Chao
    Li, Xiaogang
    CORROSION SCIENCE, 2024, 240
12345