피로 균열 성장 지연에 대한 중성자 회절 응력 분석

서석호; E-Wen Huang; 우완측; 이수열; Sukho Seo; E-Wen Huang; Wanchuck Woo; Soo Yeol Lee

Korean Journal of Materials Research, Vol.28, No.7, 398-404, July, 2018

DOI10.3740/MRSK.2018.28.7.398 Export Citation

피로 균열 성장 지연에 대한 중성자 회절 응력 분석

Internal Stress/Strain Analysis during Fatigue Crack Growth Retardation Using Neutron Diffraction

서석호, E-Wen Huang¹, 우완측², 이수열^†

충남대학교
¹국립교통대학교
²한국원자력연구원

Sukho Seo, E-Wen Huang¹, Wanchuck Woo², and Soo Yeol Lee^†

Department of Materials Science and Engineering, Chungnam National University, Daejeon 34134, Republic of Korea
¹Department of Materials Science and Engineering, National Chiao Tung University, Hsinchu, 300, Taiwan(R.O.C.)
²Neutron Science Division, Korea Atomic Energy Research Institute, Daejeon 34057, Republic of Korea

E-mail:

Fatigue crack growth retardation of 304 L stainless steel is studied using a neutron diffraction method. Three orthogonal strain components(crack growth, crack opening, and through-thickness direction) are measured in the vicinity of the crack tip along the crack propagation direction. The residual strain profiles (1) at the mid-thickness and (2) at the 1.5 mm away from the mid-thickness of the compact tension(CT) specimen are compared. Residual lattice strains at the 1.5 mm location are slightly higher than at the mid-thickness. The CT specimen is deformed in situ under applied loads, thereby providing evolution of the internal stress fields around the crack tip. A tensile overload results in an increased magnitude of the compressive residual stress field. In the crack growth retardation, it is found that the stresses are dispersed in the crack-wake region, where the highest compressive residual stresses are measured. Our neutron diffraction mapping results reveal that the dominant mechanism is by interrupting the transfer of stress concentration at the crack tip.

Keywords:stainless steel;fatigue crack growth;retardation;stress field;neutron diffraction

[References]

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[2] Withers PJ, Bhadeshia HKDH, Mater. Sci. Technol., 17, 355 (2001)

[3] Hornbach DJ, Prevey PS, J. Press. Vessel Technol., 124, 359 (2002)

[4] Xu S, Wang C, Wang W, Eng. Fail. Anal., 51, 1 (2015)

[5] Steuwer A, Rahman M, Shterenlikht A, Fitzpatrick ME, Edwards L, Withers PJ, Acta Mater., 58, 4039 (2010)

[6] Lee SY, Liaw PK, Choo H, Rogge RB, Acta Mater., 59, 485 (2011)

[7] Lee SY, Choo H, Liaw PK, An K, Hubbard CR, Acta Mater., 59, 495 (2011)

[8] Barabash R, Gao Y, Sun Y, Lee SY, Choo H, Liaw PK, Brown DW, Ice GE, Philos. Mag. Lett., 88, 553 (2008)

[9] McEvily AJ, Ishihara S, Mutho Y, Int. J. Fatigue, 26, 1311 (2004)

[10] Wheatley G, Hu XZ, Estrin Y, Fatigue Fract. Engng. Mater. Struct., 22, 1041 (1999)

[11] Nikitin I, Besel M, Mater. Sci. Eng. A-Struct. Mater. Prop. Microstruct. Process., 491, 297 (2008)

[12] Lopez-Crespo P, Withers PJ, Yusof F, Dai H, Steuwer A, Kelleher JF, Buslaps T, Fatigue Fract. Engng. Mater. Struct., 36, 75 (2013)

[13] Hinds G, Wickstrom L, Mingard K, Turnbull A, Corrosion Sci., 71, 43 (2013)

[14] Lopez-Crespo P, Steuwer A, Buslaps T, Tai YH, Lopez-Moreno A, Yates JR, Withers PJ, Int. J. Fatigue, 71, 11 (2015)

[15] Croft M, Shukla V, Jisrawi NM, Zhong Z, Sadangi SK, Holtz RL, Pao PS, Horvath K, Sadananda K, Ignatov A, Skaritka J, Tsakalakos T, Int. J. Fatigue, 31, 1669 (2009)

[16] Huang EW, Lee SY, Woo W, Lee KW, Metall. Mater. Trans. A-Phys. Metall. Mater. Sci., 43, 2785 (2012)

[17] Choi GC, Lee MH, Huang EW, Woo W, Lee SY, Korean J. Mater. Res., 25(12), 690 (2015)

[18] Seo S, Huang EW, Woo W, Lee SY, Int. J. Fatigue, 104, 408 (2017)

[19] American Society for Testing and Materials (ASTM). Standard Test Method for Measurement of Fatigue Crack-Growth Rates; ASTM Standard E647-99; American Society for Testing Materials: West Conshohocken, PA, USA, 591 (2000).

[20] Pang JWL, Holden TM, Mason TE, Acta Mater., 46, 1503 (1998)