High Temperature Stress Rupture Anisotropy of a Ni-Based Single Crystal Superalloy

doi:10.1016/j.jmst.2016.08.018

Abstract

Abstract:

High temperature stress rupture anisotropies of a second generation Ni-base single crystal (SC) superalloy specimens with [001], [011] and [111] orientations under 900 °C/445 MPa and 1100 °C/100 MPa have been investigated in the present study, with attentions to the evolution of γ/γ′ microstructure observed by scanning electron microscopy and the dislocation configuration characterized by transmission electron microscopy in each oriented specimen. At 1100 °C/100 MPa as well as 900 °C/445 MPa, the single crystal superalloy exhibits obvious stress rupture anisotropic behavior. The [001] oriented specimen has the longest rupture lifetime at 900 °C/445 MPa, and the [111] oriented sample shows the best rupture strength at 1100 °C/100 MPa. While the [011] oriented specimen presents the worst rupture lifetime at each testing condition, its stress rupture property at 1100 °C/100 MPa is clearly improved, compared with 900 °C/445 MPa. The evident stress rupture anisotropy at 900 °C/445 MPa is mainly attributed to the distinctive movement way of dislocations in each oriented sample. Whereas, at 1100 °C/100 MPa, together with the individual dislocation configuration, the evolution of γ/γ′ microstructure in each orientation also plays a key role in the apparent stress rupture anisotropy.

Key words: Ni-based single crystal superalloy, Stress rupture property, Anisotropy, Microstructure characterization, Deformation mechanism

Wang Guanglei,Liu Jinlai,Liu Jide,Jin Tao,Sun Xiaofeng,Sun Xudong,Hu Zhuangqi. High Temperature Stress Rupture Anisotropy of a Ni-Based Single Crystal Superalloy[J]. J. Mater. Sci. Technol., 2016, 32(10): 1003-1007.

Figures/Tables 5

Table 1 Stress rupture properties of the SC superalloy specimens with three orientations: t characterizes the rupture lifetime and δδ marks the rupture elongation

Table 1 Stress rupture properties of the SC superalloy specimens with three orientations: t characterizes the rupture lifetime and δδ marks the rupture elongation">

SC superalloy	[001]		[011]		[111]
SC superalloy	t (h)	δ (%)	t (h)	δ (%)	t (h)	δ (%)
900 °C/445 MPa	234.5	24.8	34.8	5.8	127.1	39.1
1100 °C/100 MPa	395.7	10.2	116.3	17.3	522.6	3.7

Fig. 1. SEM micrographs on (a) (100) plane of the [001] oriented specimen, (b) (100) plane of the [011] oriented specimen and (c) () plane of the [111] oriented specimen (c) after rupture at 900 °C/445 MPa. Stress parallel to vertical direction.

Fig. 2. Two-beam TEM bright field images on cross section of the (a) [001] oriented specimen, (b) [011] oriented specimen and [111] oriented specimen (c) after 2 h deformation and (d) after rupture at 900 °C/445 MPa.

Fig. 3. SEM micrographs on (a) (100) plane of the [001] oriented specimen, (b) () plane of the [011] oriented specimen and (c) () plane of the [111] oriented specimen after rupture at 1100 °C/100 MPa. Stress parallel to the vertical direction.

Fig. 4. Two-beam TEM bright field images on (a) (001) plane and (b) (100) plane of the [001] oriented specimen, (c) (011) plane of the [011] oriented specimen, and (d) (111) plane of the [111] oriented specimen after rupture at 1100 °C/100 MPa.

References

[1]	T.M. Pollock, A.S. Argon. Acta Metall. Mater, 40 (1992), pp. 1-30
[2]	M.P. Jackson, R.C. Reed. Mater. Sci. Eng. A, 259 (1999), pp. 85-97
[3]	R.C. Reed. Superalloys: Foundations and Applications Cambridge University Press, New York(2006), pp. 1-32
[4]	Z. Zhu, H. Basoalto, N. Warnken, R.C. Reed. Acta Mater, 60 (2012), pp. 4888-4900
[5]	V. Sass, U. Glatzel, M. Feller-Kniepmeier. Acta Mater, 44 (1996), pp. 1967-1977
[6]	V. Sass, M. Feller-Kniepmeier. Mater. Sci. Eng. A, 245 (1998), pp. 19-28
[7]	G.M. Han, J.J. Yu, Y.L. Sun, X.F. Sun, Z.Q. Hu. Mater. Sci. Eng. A, 527 (2010), pp. 5383-5390
[8]	J.L. Liu, T. Jin, X.F. Sun, J.H. Zhang, H.R. Guan, Z.Q. Hu. Mater. Sci. Eng. A, 479 (2008), pp. 277-284
[9]	H.C. Yu, Y. Su, N. Tian, S.G. Tian, Y. Li, X.F. Yu, L.L. Yu. Mater. Sci. Eng. A, 565 (2013), pp. 292-300
[10]	G. Malzer, R.W. Hayes, T. Mack, G. Eggeler. Metall. Mater. Trans. A, 38 (2007), pp. 314-327
[11]	L.A. Jacome, P. Nortershauser, J.K. Heyer, A. Lahni, J. Frenzel, A. Dlouhy, C. Somsen, G. Eggeler. Acta Mater, 61 (2013), pp. 2926-2943
[12]	L.A. Jacome, P. Nortershauser, C. Somsen, A. Dlouhy, G. Eggeler. Acta Mater, 69 (2014), pp. 246-264
[13]	A. Fredholm, J.L. Strudel. R.H. Bricknell, W.B. Kent, M. Gell, C.S. Kortovich, J.F. Radavich (Eds.), Superalloy 1984, TMS, Warrendale (1984), pp. 211-220
[14]	A. Fredholm, J.L. Strudel. J.B. Mariott, H. Herz, J. Nihoul, J. Ward (Eds.), High Temperature Alloys, their Exploitable Potential, Proceeding of the Petten, 1985, Elsevier Applied Science, London (1987), pp. 9-18
[15]	A. Epishin, T. Link, U. Bruchener, P.D. Portella. Acta Mater, 49 (2001), pp. 4017-4023
[16]	T.M. Pollock, A.S. Argon. Acta Metall. Mater, 42 (1994), pp. 1859-1874
[17]	M. Fahrmann, E. Fahrmann, O. Paris, P. Fratzl, T.M. Pollock. R.D. Kissinger, D.J. Deye, D.L. Anton, A.D. Cetel, M.V. Nathal, T.M. Pollock, D.A. Woodford (Eds.), Superalloy 1996, TMS, Warrendale (1996), pp. 191-200
[18]	S. Tian, S. Zhang, C. Li, H. Yu, Y. Su, X. Yu, L. Yu. Metall. Mater. Trans. A, 43 (2012), pp. 3880-3889
[19]	A. Gaubert, M. Jouiad, J. Cormier, Y.L. Bouar, J. Ghighi. Acta Mater, 84 (2015), pp. 237-255
[20]	G.L. Wang. Stress rupture properties of a Ni-base single crystal superalloy, (Master thesis); Northeastern University (2013)
[21]	T. Kuttner, M. Feller-Kniepmeier. Mater. Sci. Eng. A Struct. Mater, 188 (1994), pp. 147-152
[22]	V. Sass, U. Glatzel, M. Feller-Kniepmeier. R.D. Kissinger, D.J. Deye, D.L. Anton, A.D. Cetel, M.V. Nathal, T.M. Pollock, D.A. Woodford (Eds.), Superalloy 1996, TMS, Warrendale (1996), pp. 283-290
[23]	M. Feller-Kniepmeier, T. Kuttner. Acta Metall. Mater, 42 (1994), pp. 3167-3174
[24]	G.L. Drew, R.C. Reed, K. Kakehi, C.M.F. Rae. K.A. Green, T.M. Pollock, H. Harada, T.E. Howson, R.C. Reed, J.J. Schirra, S. Walston (Eds.), Superalloys 2004, TMS, Warrendale (2004), pp. 127-136
[25]	J.X. Zhang, T. Murakumo, H. Harada, Y. Koizumi. Scr. Mater, 48 (2003), pp. 287-293
[26]	A. Epishin, T. Link. Philos. Mag, 84(2004), pp. 1979-2000