Microstructure evolution and mechanical behavior of Ni-based single crystal superalloy joint brazed with mixed powder at elevated temperature

doi:10.1016/j.jmst.2017.01.027

Abstract

Abstract:

Brazing of a Ni-based single crystal superalloy has been investigated with the additive Ni-based superalloy and filler Ni-Cr-W-B alloy at 1260 °C, and attentions were paid to the microstructure evolution during brazing and the stress-rupture behavior at 980 °C of such brazed joints after homogenization. Microstructure in the brazed joint generally includes brazing alloy zone (BAZ), isothermally solidified zone (ISZ) and diffusion affected zone (DAZ). Microstructure evolution during this brazing process is discussed at the heating stage, the holding stage and the cooling stage respectively, according to the diffusion path of B atoms. Initially well-distributed γ/γ′ microstructure in the homogenized bonded zone after heat treatment and substantial γ′ rafts enhance the post-brazed joint to obtain a stress-rupture lifetime of more than 120 h at 980 °C/250 MPa. On the other hand, the decreased stress-rupture behavior of post-brazed joint, compared with parenting material, is ascribed to the presence of inside brazing porosity and stray grain boundary, which not only reduces the effective loading-carrying area but also offers preferential sites for creep vacancy aggregation to further soften stray grain boundary. And finally an early fracture of these post-brazed joints through the intergranular microholes aggregation and growth mode under this testing condition was observed.

Key words: Ni-based single crystal superalloy, Mixed powder brazing, Microstructure evolution, Fracture behavior, Brazing porosity

Wang Guanglei, Sun Yuan, Wang Xinguang, Liu Jide, Liu Jinlai, Li Jinguo, Yu Jinjiang, Zhou Yizhou, Jin Tao, Sun Xudong, Sun Xiaofeng. Microstructure evolution and mechanical behavior of Ni-based single crystal superalloy joint brazed with mixed powder at elevated temperature[J]. J. Mater. Sci. Technol., 2017, 33(10): 1219-1226.

Figures/Tables 10

Table 1 Chemical composition of SC superalloy, additive alloy and Ni-Cr-W-B alloy (wt%).

Materials	Ni	Cr	W	Mo	Co	Al	Ti	Re	Ta	B	C
SC superalloy	Bal.	2-5	7-9	1-3	8-10	5-7	0-1	2-4	6-9	-	0.01-0.1
Additive alloy	Bal.	8-10	6-8	0-1	3-7	5-7	1-3	-	2-4	-	-
Ni-Cr-W-B alloy	Bal.	12-15	3-5	-	-	-	-	-		1-3	-

Fig. 1. Schematic diagram of bonding assembly.

Fig. 2. SEM micrographs in the joint brazed at 1260 °C/15 min.

Fig. 3. SEM micrographs in joints brazed at 1260 °C for (a) 0 min, (b) 60 min, and (c) 180 min: brazing porosity was denoted by single arrow and casting porosity was shown by double arrows.

Fig. 4. SEM micrographs in the post-heated joint.

Fig. 5. Elements map distribution of the bonded pair after homogenization.

Fig. 6. Mechanical properties of brazed joints and the base metal after homogenization: (a, b) tensile testing, (c, d) stress-rupture testing.

Fig. 7. SEM micrographs of (a, b) tensile and (c, d) stress-rupture fracture surfaces of joints.

Fig. 8. SEM micrograph in the longitudinal section of post-brazed joints after stress-rupture testing.

Fig. 9. Schematic illustration of diffusion of vacancy and B atoms within stray grains.

References

[1]	R.C. Reed, Superalloy: Fundamentals and Applications, Cambridge University Press, Cambridge, 2006, pp. 1-32.
[2]	X.B. Meng, J.G. Li, Z.Q. Chen, Y.H. Wang, S.Z. Zhu, X.F. Bai, F. Wang, J. Zhang, T. Jin, X.F. Sun, Z.Q. Hu, Metall. Mater. Trans. A 44 (2013) 1955-1965.
[3]	N.D. Souza, M. Newell, K. Devendra, P.A. Jennings, M.G. Ardakani, B.A. Shollock, Mater. Sci. Eng. A 413 (2005) 567-570.
[4]	A.F. Giamei, B.H. Kear, Metall. Trans. 1(1970) 2185-2192.
[5]	M.A. Burke, P.D. Freyer, M.A. Hebbar, B.B. Seth, G.W. Swartzbeck, T.W. Zagar, Turbine blades made from multiple single crystal superalloy segments, US,Patent, No. 6331217, 2001.
[6]	J.H.G.Mattheij, Mater. Sci. Techol. 1(1985) 608-612.
[7]	J.M. Vitek, Acta Mater. 53(2005) 53-67.
[8]	K. Nishimoto, K. Saida, D. Kim, Y. Nakao, ISIJ Int. 35 (10) (1995) 1298-1306.
[9]	W. Li, T. Jin, X.F. Sun, Y. Guo, H.R. Guan, Z.Q. Hu, Scr. Mater. 48(2003)1283-1288.
[10]	N.C. Sheng, J.D. Liu, T. Jin, X.F. Sun, Z.Q. Hu, Metall. Mater. Trans. A 44 (2013) 1793-1804.
[11]	W.F. Gale, D.A. Butts, Sci. Technol. Weld. Join. 9(2004) 283-300.
[12]	G.O.Cook III, C.D. Sorensen, J. Mater. Sci. 46(2011) 5305-5323.
[13]	S.J. Ferrigno, M. Somerville, R. Young, Alloy powder mixture for treating alloys, U.S., Patent No. 4830934, 1989.
[14]	W.D. Demo, S.J. Ferrigno, Adv. Mater. Process. 141(1992) 43-45.
[15]	E. Lugscheider, T. Schittny, E. Halmoy, J. Weld.Res.Suppl..68(1989) 9s-13s.
[16]	D. McGuire, X. Huang, D. Nagy, Eng. Gas. Turb. Powder 132 (2010), Paper No.062101.
[17]	Y. Sun, J.D. Liu, X.Y. Hou, G.L. Wang, J.X. Yang, T. Jin, Y.Z. Zhou, Acta Metall. Sin.52(2016) 875-882 (in Chinese).
[18]	Y.H. Yu, M.O. Lai, J. Mater.Sci..30(1995) 2101-2107.
[19]	B. Frische, A. Satir-Kolorz, Weld. World 44 (2000) 10-14.
[20]	C.Y. Su, C.P. Chou, W.J. Chang, M.H. Liu, J. Mater.Eng.Perform..9(2000)663-668.
[21]	Y.H. Kim, I.H. Kim, C.S. Kim, Key Eng. Mater. 297(2005) 2876-2882.
[22]	D.Q. Shi, C.L. Dong, X.G. Yang, L. Zhang, J.B. Hou, Y. Liu, Mater. Sci. Eng. A 545 (2012) 162-167.
[23]	L.O. Osoba, O.A. Ojo, Metall. Mater. Trans. A 44A (2013) 4020-4024.
[24]	J. Cao, Y.F. Wang, X.G. Song, C. Li, J.C. Feng, Mater. Sci. Eng. A 590 (2014) 1-6.
[25]	A. Ekrami, S. Moeinifar, A.H. Kokabi, Mater. Sci. Eng. A 456 (2007) 93-98.
[26]	M. Pouranvari, A. Ekrami, A.H. Kokabi, Mater. Sci. Eng. A 490 (2008) 229-234.
[27]	Y.H. Kim, K.T. Kim, I.H. Kim, Key Eng. Mater. 306(2006) 935-940.
[28]	R. Wustman, L. Hampson, M. Suneson, High strength diffusion brazing repairs of gas turbine component, ASME International Gas Turbine and Aeroengine Congress and Exhibition (2016), Paper No.96-G T-427.
[29]	D.U. Kim, K. Nishimoto, Mater. Sci. Technol. 19(2003) 456-460.
[30]	J.D. Liu, T. Jin, N.R. Zhao, Z.H. Wang, X.F. Sun, H.R. Guan, Z.Q. Hu, J. AlloysCompd..457(2008) 185-190.
[31]	J.D. Liu, T. Jin, N.R. Zhao, Z.H. Wang, X.F. Sun, H.R. Guan, Z.Q. Hu, Mater. Charact. 59(2008) 68-73.
[32]	L. Chai, J.H. Huang, J.B. Hou, B. Lang, L. Wang, J. Mater. Eng. Perform. 24 (6)(2015) 2287-2293.
[33]	N.C. Sheng, J.D. Liu, T. Jin, X.F. Sun, Z.Q. Hu, J. Mater.Sci.Technol..31(2015)129-134.
[34]	A. Sobolev, A. Fedorov, Neorg. Mater. 3(1967) 723-726.
[35]	B.Y. Huang, Powder Metallurgy Science, Metallurgical Industry Press, Beijing,1997.
[36]	M. Pouranvari, A. Ekrami, A.H. Kokabi, J. AlloysCompd..469(2009) 270-275.
[37]	J.D. Liu, T. Jin, Z.H. Wang, X.F. Sun, H.R. Guan, Z.Q. Hu, Mater. Sci.Forum 546-549(2007) 1245-1248.
[38]	O.A. Idowu, N.L. Richards, M.C. Chaturvedi, Mater. Sci. Eng. A 397 (2005)98-112.
[39]	N.P. Wikstrom, O.A. Ojo, M.C. Chaturvedi, Mater. Sci. Eng. A 417 (2006)299-306.
[40]	A. Ghoneim, O.A. Ojo, Philos. Mag. 91(2011) 3649-3666.
[41]	N.C. Sheng, J.D. Liu, T. Jin, X.F. Sun, Z.Q. Hu, Metall. Mater. Trans. A 44 (2013)1793-1804.
[42]	R.B. Scarlin, Scr. Metall. 10(1976) 711-715.
[43]	X. Cai, Foundation of Materials Science and Engineering, Shanghai Jiao Tong University Press, Shanghai, 2010, pp. 140-171.
[44]	A.D. Smigelskas, E.O. Kiekendall, AIME Trans. 171(1947) 130-142.
[45]	T.M. Pollock, A.S. Argon, Acta Metall. Mater. 40(1992) 1-30.
[46]	M.P. Jackson, R.C. Reed, Mater. Sci. Eng. A 259 (1999) 85-97.
[47]	Z. Zhu, H. Basoalto, N. Warnken, R.C. Reed, Acta Mater. 60(2012) 4888-4900.
[48]	A. Epishin, T. Link, Philos. Mag. 84(2004) 1979-2000.
[49]	J.L. Liu, J.J. Yu, T. Jin, X.F. Sun, H.R. Guan, Z.Q. Hu, Trans. Nonferrous Met. Soc.China 21 (2011) 1518-1523.
[50]	T.M. Pollock, A.S. Argon, Acta Metall. Mater. 42(1994) 1859-1874.
[51]	M. Thuvander, H.O. Andrén, Mater. Charact. 44 (1) (2000) 87-100.
[52]	L. Xiao, D.L. Chen, M.C. Chaturvedi, Mater. Sci. Eng. A 428 (2006) 1-11.