Enhanced Fatigue Property of Welded S355J2W Steel by Forming a Gradient Nanostructured Surface Layer

doi:10.1007/s40195-020-01046-8

Abstract

Abstract:

Welded joints are usually characterized by microstructural and compositional inhomogeneities, which may significantly degrade their fatigue properties and result in unpredictable failures. The present work demonstrates a novel and simple method to effectively optimize the microstructure in the surface layer and promote the fatigue properties of welded specimens. By a recently developed approach—surface mechanical rolling treatment (SMRT), a gradient nanostructured surface layer is formed on welded S355J2W steel specimens. The mean grain size is refined to nanometer scale, and the hardness is significantly enhanced in the SMRT surface layer. Independent of the initially inhomogeneous microstructure and hardness distributions, the microstructure and hardness distributions in the surface layers are comparable on different zones of a welded specimen after SMRT with the same procedure. Consequently, fatigue property of the SMRT specimens is significantly enhanced relative to that of the as-welded specimens within the high cycle fatigue regime.

Key words: Gradient nanostructured, Surface mechanical rolling treatment, S355J2W steel, Welded, Fatigue

Lu An, Yan-Tao Sun, Shan-Ping Lu, Zhen-Bo Wang. Enhanced Fatigue Property of Welded S355J2W Steel by Forming a Gradient Nanostructured Surface Layer[J]. Acta Metallurgica Sinica (English Letters), 2020, 33(9): 1252-1258.

Figures/Tables 9

Table 1 Chemical compositions of the BM and welding wire (wt%)

Material	C	Si	Mn	Ni	Cu	Cr	P	S	Ti	Nb	Fe
BM	0.075	0.29	1.26	0.2	0.3	0.45	0.007	0.007	0.014	0.016	Bal
Welding wire	0.044	0.43	1.07	0.89	0.43	0.016	0.006	0.004	0.052	0.01	Bal

Fig. 1 Schematic illustrations of a a welded plate of S355J2W steel, b a cylinder dog-bone-shaped fatigue sample cut from a, c the SMRT process. The red dot line on b marks the position for surface hardness measurements in Fig. 6. WM and HAZ denote weld metal and heat-affected zone, respectively (unit: mm)

Fig. 2 Typical SEM morphologies of different regions (as indicated in Fig. 1) in the as-welded S355J2W steel plate: a BM, b HAZ, c WM

Fig. 3 Cross-sectional SEM morphologies of different regions in the SMRT sample: a BM, b HAZ, c WM

Fig. 4 Typical TEM images of the topmost surface layers of different regions in the SMRT sample: a, b BM, c, d HAZ, e, f WM. a, c, e are bright-field TEM images with corresponding SAED patterns inserted. b, d, f are dark-field TEM images taken from the (110) diffraction of ferrite (the first ring of the SAED pattern) in a, c, e, respectively

Fig. 5 Variations of microhardness with the distance from the treated surface for different regions in the SMRT sample: a BM, b HAZ, c WM. Measurements were taken on the surface layer from a cross-sectional view. Each point denotes an independent measurement

Fig. 6 Distributions of surface hardness along the distance from the welded-joint center on the SMRT and as-welded samples. Measurements were taken on the sample surface from a planar view, along the red dot line marked in Fig. 1b. Each point was averaged from at least 3 measurements

Fig. 7 S-N curves of the SMRT and as-welded samples. Open symbols (with arrows) indicate tests terminated without fracture after 2 × 106 cycles

Fig. 8 SEM morphologies of fracture surface of a the SMRT sample fatigued at 320 MPa, b the as-welded sample fatigued at 280 MPa. The regions of crack initiation, crack propagation, and instant rupture are marked by A, B, and C, respectively

References 25

[1]	S.P. Lu, X. Wang, W.C. Dong, Y.Y. Li, ISIJ Int. 53, 96 (2013) DOI URL
[2]	H. Kokawa, M. Shimada, M. Michluchi, Z.J. Wang, Y.S. Sato, Acta Mater. 55, 5401 (2007) DOI URL
[3]	D. Li, H.N. Chen, H. Xu, Surf. Eng. 25, 15 (2009)
[4]	H. Atwa, N.M. Mawsouf, M.Y.A. Younan, Eng. Fract. Mech. 44, 921 (1993)
[5]	B.L. He, Y.X. Yu, H.H. Yu, J.P. Shi, Y.F. Zhu, Curr. Nanosci. 8, 17 (2012)
[6]	J.S. Kim, Eng. Fail. Anal. 13, 1326 (2006)
[7]	T. Dahle, Int. J. Fatigue 20, 677 (1998)
[8]	S. Malarvizhi, V. Balasubramanian, Mater. Des. 32, 1205 (2011)
[9]	S.H. Han, J.W. Han, Y.Y. Nam, I.H. Cho, Fatigue Fract. Eng. Mater. Struct. 32, 573 (2009)
[10]	L.L. Shaw, J.-W. Tian, A.L. Ortiz, K. Dai, J.C. Villegas, P.K. Liaw, R. Ren, D.L. Klarstrom, Mater. Sci. Eng. A 527, 986 (2010)
[11]	H.W. Huang, Z.B. Wang, J. Lu, K. Lu, Acta Mater. 87, 150 (2015)
[12]	Y.B. Lei, Z.B. Wang, J.L. Xu, K. Lu, Acta Mater. 168, 133 (2019) DOI URL
[13]	K. Zhang, Z.B. Wang, K. Lu, Mater. Res. Lett. 5, 258 (2017) DOI URL
[14]	M.S. Suh, C.M. Suh, Y.S. Pyun, Fatigue Fract. Eng. Mater. Struct. 36, 769 (2013)
[15]	K. Zhang, Z.B. Wang, J. Mater. Sci. Technol. 34, 1676 (2018)
[16]	H.W. Huang, Z.B. Wang, X.P. Yong, K. Lu, Mater. Sci. Technol. 29, 1200 (2013) DOI URL
[17]	N.R. Tao, Z.B. Wang, W.P. Tong, M.L. Sui, J. Lu, K. Lu, Acta Mater. 50, 4603 (2002) DOI URL
[18]	S.D. Lu, Z.B. Wang, K. Lu, J. Mater. Sci. Technol. 26, 258 (2010) DOI URL
[19]	L.C. Fu, D.Y. Li, Adv. Eng. Mater. 15, 476 (2013) DOI URL
[20]	L. Zhou, G. Liu, X.L. Ma, K. Lu, Acta Mater. 56, 78 (2008) DOI URL
[21]	H. Mughrabi, Int. J. Fatigue 28, 1501 (2006) DOI URL
[22]	K. Shiozawa, M. Murai, Y. Shimatani, T. Yoshimoto, Int. J. Fatigue 32, 541 (2010)
[23]	Z.Y. Feng, X.J. Di, S.P. Wu, D.P. Wang, X.Q. Liu, Acta Metall. Sin. (Engl. Lett.) 31, 541 (2018)
[24]	L. Li, Z. Wan, Z. Wang, C. Ji, Acta Metall. Sin. (Engl. Lett.) 22, 202 (2009)
[25]	M.K. Khan, M.E. Fitzpatrick, Q.Y. Wang, Y.S. Pyoun, A. Amanov, Fatigue Fract. Eng. Mater. Struct. 41, 844 (2018)