Effects of Substrate Crystallographic Orientations on Microstructure in Laser Surface-Melted Single-Crystal Superalloy: Theoretical Analysis

doi:10.1007/s40195-016-0442-x

Abstract

Abstract:

A geometric analysis technique for crystal growth and microstructure development in single-crystal welds had been previously developed. And the effect of welding conditions on the tendency of stray grains formation during solidification was researched. In the present work, these analytical methods were further extended. Combined with an original vectorization method, a 3D Rosenthal solution was used to determine thermal conditions of the welds. Afterward, the dendrite growth orientation, the dendrite growth velocity and the thermal gradient along dendrite direction were calculated and lively plotted. Finally, the tendency of stray grains formation in the solidification front was forecasted and its distribution was presented with a 3D plot. The results indicate that substrate orientation has some impacts on the crystal growth pattern, dendrite growth velocity, distribution of thermal gradient and stray grain. Based on the research methods proposed in this work, any substrate crystallographic orientation can be studied, and predicted stray grains distribution can be visualized.

Key words: Single crystal, Laser surface remelting, Weld repair, Modeling, Stray grains distribution, List of symbols

Guo-Wei Wang,Jing-Jing Liang,Yi-Zhou Zhou,Tao Jin,Xiao-Feng Sun,Zhuang-Qi Hu. Effects of Substrate Crystallographic Orientations on Microstructure in Laser Surface-Melted Single-Crystal Superalloy: Theoretical Analysis[J]. Acta Metallurgica Sinica (English Letters), 2016, 29(8): 763-773.

Figures/Tables 10

Fig. 1 Schematic diagram of weld pool; heat source is located at x = y=z = 0

Fig. 2 Weld pool shape and thermal conditions for P = 100 W, Vb = 0.01 m/s, T0 = 300 K: a weld pool shape; b thermal gradient on solidification front Gsl; c growth velocity of solid-liquid interface Vsl/Vb

Fig. 3 Calculated dendrite growth direction for various orientations: a [100]/(001); b [210]/(001); c [110]/(001); d [100]/(011); e\([0\bar{1}1]\)/(011); f\([11\bar{1}]\)/(112)

Fig. 4 Calculated component of thermal gradient along dendrite growth direction Gd for various orientations: a [100]/(001); b [210]/(001); c [110]/(001); d [100]/(011); e\([0\bar{1}1]\)/(011); f\([11\bar{1}]\)/(112)

Fig. 5 Calculated dendrite growth velocity along preferred orientation Vd for various orientations: a [100]/(001); b [210]/(001); c [110]/(001); d [100]/(011); e\([0\bar{1}1]\)/(011); f\([11\bar{1}]\)/(112)

Fig. 6 Calculated areal fraction of stray grains Φ for various orientations; the area without SG is colored with sky blue: a [100]/(001); b [210]/(001); c [110]/(001); d [100]/(011); e\([0\bar{1}1]\)/(011); f\([11\bar{1}]\)/(112)

References

[1]	Z.D. Fan, D. Wang, L.H. Lou, Acta Metall. Sin(Engl. Lett.) 28, 152(2015)
[2]	Z.X. Shi, S.Z. Liu, J.R. Li, Acta Metall. Sin. (Engl. Lett.) 28, 1278(2015)
[3]	M. Gaumann, S. Henry, F. Cleton, J.D. Wagniere, W. Kurz, A 271, 232 (1999)
[4]	J.D. Hunt, Mater. Sci. Eng. 65, 75(1984)
[5]	M. Gaumann, R. Trivedi, W. Kurz, A 226, 763 (1997)
[6]	M. Rappaz, S.A. David, J.M. Vitek, L.A. Boatner, Metall. Trans. A 20, 1125 (1989)
[7]	S.A. David, J.M. Vitek, M. Rappaz, L.A. Boatner, Metall. Trans. A 21, 1753 (1990)
[8]	M. Rappaz, S.A. David, J.M. Vitek, L.A. Boatner, Metall. Trans. A 21, 1767 (1990)
[9]	W.P. Liu, J.N. Acta Mater. 52, 4833(2004)
[10]	W.P. Liu, J.N. Acta Mater. 53, 1545(2005)
[11]	J.M. Vitek, Acta Mater. 53, 53(2005)
[12]	T.D. Anderson, J.N. Acta Mater. 58, 1441(2010)
[13]	L. Wang, N. Wang, W.J. Yao, Y.P. Zheng, Acta Mater. 88, 283(2015)
[14]	J.W. Park, S.S. Babu, J.M. Vitek, E.A. Kenik, S.A. David, J. Appl. Phys. 94, 4203(2003)
[15]	J.W. Park, J.M. Vitek, S.S. Babu, S.A. David, Sci. Technol. Weld. 9, 472(2004)
[16]	M. Gaumann, C. Bezencon, P. Canalis, W. Kurz, Acta Mater. 49, 1051(2001)
[17]	D. Rosenthal, Trans. ASME 48, 849 (1946)
[18]	J.F. Ready, D.F. Farson, LIA Handbook of Laser Materials Processing (Springer, Berlin, 2001), pp. 307-424
[19]	W.M. Steen, J. Mazumder, Laser Materials Processing, 4th edn. (Springer, London, 2010), pp. 199-294
[20]	S. Katayama, Handbook of Laser Welding Technologies (Woodhead Publishing Limited, Cambridge, 2013), pp. 139-162
[21]	G.G. Gladush, I. Smurov, Physics of Laser Materials Processing (Springer, Berlin, 2011), pp. 9-19
[22]	H.E. Cline, T.R. Anthony, J. Appl. Phys. 48, 3895(1977)
[23]	M. Davis, P. Kapadia, J. Dowden, W.M. Steen, C.H.G. J. Phys. D 19, 1981 (1986)
[24]	D. Rosenthal, Weld. J. 20, 220(1941)
[25]	E. Kannatey-Asibu, Principles of Laser Materials Processing (Hoboken, 2009), pp. 228-280
[26]	J.M. Dowden, Boca Raton, 2001)
[27]	C. Bezencon, A. Schnell, W. Kurz, Scr. Mater. 49, 705(2003)
[28]	Y.Z. Zhou, A. Volek, N.R. Green, Acta Mater. 56, 2631(2008)
[29]	Y.Z. Zhou, Scr. Mater. 65, 281(2011)