Microstructural Evolution and Toughness in the HAZ of Submerged Arc Welded Low Welding Crack Susceptibility Steel

doi:10.1007/s40195-012-0103-7

Abstract

Abstract:

Microstructural characteristics of different sub-regions of heat affected zone (HAZ) of low welding crack susceptibility steel weldment were investigated by using optical microscopy and scanning electron microscopy equipped with electron backscattered diffraction system. And the focus was put on the correlation between microstructural characteristics and HAZ toughness of the weldment. The results reveal that the toughness of fusion line zone (FLZ) specimens is much lower than that of fine grained HAZ (FGHAZ) specimens. The coarse inclusions in the weld metal and the large martensite–austenite constituents in the coarse grained HAZ (CGHAZ) have an obvious negative effect on the crack initiation energy of FLZ. Meanwhile, the coarse granular bainite with large effective grain decreases the crack propagation energy seriously. By contrast, fine crystallographic grains in the FGHAZ play a key role in increasing toughness, especially in improving crack propagation energy.

Key words: Steel, Heat affected zone (HAZ), Submerged arc welding, Effective grain size, Toughness, Microstructure

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Chunlin QIU, Liangyun LAN, Dewen ZHAO, Xiuhua GAO and Linxiu DU. Microstructural Evolution and Toughness in the HAZ of Submerged Arc Welded Low Welding Crack Susceptibility Steel[J]. Acta Metallurgica Sinica (English Letters), 2013, 26(1): 49-55.

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URL: https://www.amse.org.cn/EN/10.1007/s40195-012-0103-7

https://www.amse.org.cn/EN/Y2013/V26/I1/49

References

[1] B. de Meester, ISIJ Int. 37 (1997) 537.

[2] F.Matsuda,K.Ikeuchi,J.Liaoand H.Tanabe,Trans. JWRI 23 (1994) 49.

[3] L.D. Yao, X.T. Zhao and S.X. Zhao, U. S. Patent 0032062A1Feb 11(2010).

[4] M. Shome, Mater. Sci. Eng. A 445–446 (2007) 454.

[5] N.J.Smith,J.T.Mcgrath,J.A.Gianetto andR.F.Orr, Weld Res. 68 (1989) 112.

[6] F. Matsuda, K.Ikeuchi,H.Okada,I.Hrivnak and H.

S. Park, Trans. JWRI 23 (1994) 231.

[7] S. Talas, Mater. Des. 31 (2010) 2649.

[8] R. Petrov, O.G. Leon, J.J.L. Mulders, A.C.C. Reis,

J. H. Bae, L. Kestens and Y. Houbaert, Mater. Sci. Forum 550 (2007) 625.

[9]A.F.Gourgues,H.M. Flower andT.C.Lindley,Mater. Sci. Technol. 16 (2000) 26.

[10] M. Diaz-Fuentes,A.Iza-Mendiaand I.Gutierrez,Met. Mater. Trans. A 34 (2003) 2505.

[11] A.M. Guo, R.D.K. Misra, J.B. Liu, L.Chen, X.L. He and S.J. Jansto, Mater. Sci. Eng. A 527 (2010) 6440.

[12] J.M. Roudriquez-Ibabe, Mater. Sci. Forum 284–286 (1998) 51.

[13] ISO 9016, Destructive Tests on Welds in Metallic Materials-impactTests-testSpecimen Location,Notch Orientationand Examination,IDT(2001).

[14] C.L. Davis and J.E. King, Metall. Mater. Trans. A 25 (1994) 563.

[15] L.Y. Lan, C.L. Qiu, D.W. Zhao, X.H. Gao, and L.X. Du, Mater. Sci. Eng. A 529 (2011) 192.

[16] Y. Ohmori, H. Ohtani and T. Kunitake, Met. Sci. 8 (1974) 357.

[17] A. Lambert-Perlade, A.F. Gourgues, J. Besson, T. Sturel and A. Pineau, Metall. Mater. Trans. A 35 (2004) 1039.

[18] W. Wang,W.Yan,L.Zhu, P.Hu, Y.Y. Shanand K. Yang, Mater. Des. 30 (2009) 3436.

[19] Y.M. Huang, Y.M. Wu and C.X. Pan, Mater. Sci. Technol. 6 (2010) 750.

[20] V.M. Goritskii and D.P. Khromov, Strength Mater. 16 (1984) 867.

[21] P. Yan, O.E. Gungor, P. Thibaux and H.K.D.H. Bhadeshia, Sci. Technol. Weld. Join. 15 (2010) 137.

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