Technical Note: Corrosion Fatigue Crack Growth of Forged Type 316NG Austenitic Stainless Steel in 325°C Water

被引:6
|
作者
Xiao, J. [1 ]
Chen, L. Y. [1 ]
Zhou, J. [1 ]
Qiu, S. Y. [1 ]
Chen, Y. [1 ]
机构
[1] Nucl Power Inst China, Sci & Technol Reactor Fuel & Mat Lab, Chengdu 610041, Sichuan, Peoples R China
来源
CORROSION | 2018年 / 74卷 / 04期
关键词
fatigue crack growth; pressurized water reactor; primary coolant pipe; Type 316NG austenitic stainless steel; LOW-CYCLE FATIGUE; TEMPERATURE; BEHAVIOR; LIFE; ENVIRONMENTS; MECHANISMS; INITIATION; DEFLECTION; PRESSURE;
D O I
10.5006/2647
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
Forged Type 316NG austenitic stainless steel is commonly used to fabricate primary coolant pipe in advanced pressurized water reactor systems, but it is subject to corrosion fatigue cracking in primary coolant environments. In this study, the fatigue crack growth of Type 316NG austenitic stainless steel in 325 degrees C water was investigated. The corrosion fatigue effect in 325 degrees C water was mainly correlated to the crack growth rate and load frequency. A maximum F-en (environment corrected factor) value up to 100 was observed at f = 0.005 Hz, Delta K = 13 MPa root m. The dissolved oxygen tended to have little influence on the fatigue crack growth. The crack path was deflected and branched. Most secondary cracks tended to be initiated from grain boundaries.
引用
收藏
页码:387 / 392
页数:6
相关论文
共 50 条
  • [41] Fatigue crack growth behavior of wire arc additively manufactured 316L austenitic stainless steel
    Chen, Yangyu
    Chen, Man-Tai
    Zhao, Ou
    Rossi, Barbara
    Ruan, Xiongfeng
    THIN-WALLED STRUCTURES, 2025, 212
  • [42] Corrosion fatigue and microstructural characterisation of Type 316 austenitic stainless steels tested in PWR primary water
    Mukahiwa, K.
    Scenini, F.
    Burke, M. G.
    Platts, N.
    Tice, D. R.
    Stairmand, J. W.
    CORROSION SCIENCE, 2018, 131 : 57 - 70
  • [43] Influence of texture on the short fatigue crack growth in austenitic stainless steel
    V. Mikulich
    C. Blochwitz
    W. Skrotzki
    W. Tirschler
    Materials Science, 2006, 42 : 514 - 526
  • [44] Influence of texture on the short fatigue crack growth in austenitic stainless steel
    Mikulich, V.
    Blochwitz, C.
    Skrotzki, W.
    Tirschler, W.
    MATERIALS SCIENCE, 2006, 42 (04) : 514 - 526
  • [45] INFLUENCE OF CL- CONCENTRATION ON CORROSION FATIGUE CRACK-GROWTH OF AN AUSTENITIC STAINLESS-STEEL
    ENDO, K
    KOMAI, K
    MURAYAMA, S
    BULLETIN OF THE JSME-JAPAN SOCIETY OF MECHANICAL ENGINEERS, 1983, 26 (218): : 1281 - 1287
  • [46] STRESS-CORROSION CRACK GROWTH IN AUSTENITIC STAINLESS-STEEL
    SPEIDEL, MO
    CORROSION, 1977, 33 (06) : 199 - 203
  • [47] FATIGUE CRACK GROWTH IN TYPE-316 STAINLESS-STEEL AT 593DEGREESC
    SMITH, HH
    WATSON, HE
    REPORT OF NRL PROGRESS, 1975, (OCT): : 8 - 9
  • [48] Corrosion fatigue crack growth of laser additively-manufactured 316L stainless steel in high temperature water
    Lou, Xiaoyuan
    Othon, Michelle A.
    Rebak, Raul B.
    CORROSION SCIENCE, 2017, 127 : 120 - 130
  • [49] Corrosion fatigue crack growth inhibition of duplex stainless steel
    Ahsan, M
    Gasem, Z
    DAMAGE AND FRACTURE MECHANICS VIII: COMPUTER AIDED ASSESSMENT AND CONTROL, 2004, 14 : 59 - 68
  • [50] Both short and long fatigue crack growth in an austenitic stainless steel at 650 degrees C
    Polvora, JP
    Drubay, YB
    Piques, R
    Martelet, YB
    ECF 11 - MECHANISMS AND MECHANICS OF DAMAGE AND FAILURE, VOLS I-III, 1996, : 1255 - 1260
12345