Acta Metallurgica Sinica (English Letters) ›› 2014, Vol. 27 ›› Issue (4): 663-669.DOI: 10.1007/s40195-014-0090-y
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Xin Zhang, Xiaohong Shi(), Jie Wang, Hejun Li, Kezhi Li, Yancai Ren
Received:
2013-07-29
Revised:
2013-12-30
Online:
2014-08-25
Published:
2014-10-16
Xin Zhang, Xiaohong Shi, Jie Wang, Hejun Li, Kezhi Li, Yancai Ren. Effect of Bonding Temperature on the Microstructures and Strengths of C/C Composite/GH3044 Alloy Joints by Partial Transient Liquid-Phase (PTLP) Bonding with Multiple Interlayers[J]. Acta Metallurgica Sinica (English Letters), 2014, 27(4): 663-669.
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Cr | W | Mo | Al | Ti | Fe | N | Si | Trace | Ni |
---|---|---|---|---|---|---|---|---|---|
23.5–26.5 | 13.0–16.0 | ≤1.5 | ≤0.50 | 0.30–0.70 | ≤4.0 | ≤0.50 | ≤0.80 | ≤0.04 | Bal. |
Table 1 Chemical composition of Ni-based superalloy GH3044 (in wt%)
Cr | W | Mo | Al | Ti | Fe | N | Si | Trace | Ni |
---|---|---|---|---|---|---|---|---|---|
23.5–26.5 | 13.0–16.0 | ≤1.5 | ≤0.50 | 0.30–0.70 | ≤4.0 | ≤0.50 | ≤0.80 | ≤0.04 | Bal. |
Fig. 3 a SEM image of the C/C composite/GH3044 joint obtained at 1,010 °C, the arrows represented for lamination defects; b magnifying image of the zone A marked in Fig. 3a
Fig. 4 a SEM image of the C/C composite/GH3044 joint obtained at 1,030 °C (inset of image is the line-scanning EDS analysis for the cross section of the joint); b, c magnifying of the zone A marked in Fig. 4a
Zone | Composition (at%) | Possible phase | |||
---|---|---|---|---|---|
C | Ti | Ni | Cu | ||
A | 36.76 | 48.90 | 14.34 | – | TiC, NiTi |
B | 26.76 | 38.90 | 34.34 | – | TiC, NiTi |
C | 32.07 | 21.91 | 32.01 | 14.01 | TiNi, Ni–Cu |
D | 31.47 | 18.90 | 49.63 | – | Ni3Ti |
E | 37.57 | 0.75 | 18.53 | 43.15 | Ni–Cu |
Table 2 The EDS analysis results of the zones as marked in Fig. 4c
Zone | Composition (at%) | Possible phase | |||
---|---|---|---|---|---|
C | Ti | Ni | Cu | ||
A | 36.76 | 48.90 | 14.34 | – | TiC, NiTi |
B | 26.76 | 38.90 | 34.34 | – | TiC, NiTi |
C | 32.07 | 21.91 | 32.01 | 14.01 | TiNi, Ni–Cu |
D | 31.47 | 18.90 | 49.63 | – | Ni3Ti |
E | 37.57 | 0.75 | 18.53 | 43.15 | Ni–Cu |
Zone | Composition (at%) | Possible phase | |||
---|---|---|---|---|---|
C | Ti | Ni | Cu | ||
A1 | 38.45 | 58.34 | – | 3.22 | TiC |
B1 | 30.19 | 35.73 | 29.02 | 5.06 | TiC, NiTi, |
C1 | 35.37 | 25.18 | 29.83 | 9.61 | NiTi, Ni–Cu |
D1 | 27.32 | 28.77 | 33.62 | 10.28 | NiTi, Ni–Cu |
E1 | 22.79 | 8.02 | 41.50 | 27.69 | Ni–Cu |
Table 3 The EDS analysis results in the zones as marked in Fig. 5c
Zone | Composition (at%) | Possible phase | |||
---|---|---|---|---|---|
C | Ti | Ni | Cu | ||
A1 | 38.45 | 58.34 | – | 3.22 | TiC |
B1 | 30.19 | 35.73 | 29.02 | 5.06 | TiC, NiTi, |
C1 | 35.37 | 25.18 | 29.83 | 9.61 | NiTi, Ni–Cu |
D1 | 27.32 | 28.77 | 33.62 | 10.28 | NiTi, Ni–Cu |
E1 | 22.79 | 8.02 | 41.50 | 27.69 | Ni–Cu |
Fig. 7 Fracture surface morphologies of the joints on the GH3044 side at different bonding temperatures: a 1010 °C, b 1030 °C, c 1050 °C; d the magnification SEM image of fracture surface on the C/C composite side obtained at 1,070 °C (inset is the image of fracture surface on the C/C composite side)
Point | C | O | Ti | Cr | Ni | Cu |
---|---|---|---|---|---|---|
Piont F | 15.7 | 3.55 | 2.65 | 78.62 | – | – |
Piont G | 4.60 | – | 1.76 | 2.93 | 63.22 | 27.49 |
Table 4 The EDS analysis results of point F and point G as marked in Fig. 7 (in wt%)
Point | C | O | Ti | Cr | Ni | Cu |
---|---|---|---|---|---|---|
Piont F | 15.7 | 3.55 | 2.65 | 78.62 | – | – |
Piont G | 4.60 | – | 1.76 | 2.93 | 63.22 | 27.49 |
[1] | J.M. Zhang, M. Xie, X.C. Song, J. Mater. Rev. 5, 12(2010) |
[2] | B.Y. Chen, J. Aviat. Eng. Maint. 12, 12(1995) |
[3] | G. Wang, B.G. Zhang, J.S. He, Y.B. Ma, J. Weld. Join. 1, 20(2008). (in Chinese) |
[4] | H.J. Li, New Carbon Mater. 16, 79(2001) |
[5] | H.J. Li, R.Y. Luo, Z. Yang, J. Mater. Eng. 8, 8(1997). (in Chinese) |
[6] | C.J. Li, B.X. Ma, Z.H. Jin, Mater. Sci. Eng. 18, 135(2000) |
[7] | L.J. Guo, C. Guo, H.J. Li, K.Z. Li, J. Rare Met. Mater. Eng. 40, 111(2011) |
[8] | M. Singh, Scr. Mater. 37, 1151(1997)10.1016/S1359-6462(97)00233-9 |
[9] | G.I. Howling, E. Ingham, H. Sakoda, T.D. Stewart, J. Fisher, A. Antonarulrajah, S. Appleyard, B. Rand, J. Mater. Sci. 15, 91(2004) |
[10] | F.T. Lan, K.Z. Li, H.J. Li, L.J. Guo, W.F. Cao, J. Mater. Rev. 23(4), 9(2006) |
[11] | Y.X. Shen, Z.L. Li, C.Y. Hao, J.S. Zhang, J. Eur. Ceram. Soc. 32, 1769(2012)10.1016/j.jeurceramsoc.2011.12.016 |
[12] | F. GaleW, Y. Guan, J. Mater. Sci. 32, 357(1997)10.1023/A%3A1018597115287 |
[13] | X.Q. Ji, X.J. Li, T.Y. Ma, Y. Zhang, J. Chin. Ceram. Soc. 3, 305(2002) |
[14] | C.G. Zhang, G.J. Qiao, Z.H. Jin, J. Eur. Ceram. Soc. 22, 2181(2002)10.1016/S0955-2219(02)00011-0 |
[15] | S.M. Zhang, K.Z. Li, J. Wang, X.R. Song, L.J. Guo, J. Solid Rocket Technol. 35, 414(2012) |
[16] | Y.H. Zhang, F.S. Wang, A.M. Zhang, Cast. Forg. Weld. 39(9), 163(2010). (in Chinese) |
[17] | J.T. Xiong, J.N. Li, F.S. Zhang, W.D. Wang, J. Inorg. Mater. 21, 1391(2006) |
[18] | Y.H. Zhang, J.Q. Liu, X.X. Duan, Electr. Weld. Mach. 37, 15(2007) |
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