Microstructures and Mechanical Properties of the TiC/CM247LC Nickel-Based Composite Fabricated by Selective Laser Melting: Effect of Heat Treatment

doi:10.1007/s40195-023-01613-9

Abstract

Abstract:

In this study, TiC/CM247LC nickel-based composite was successfully prepared by selective laser melting, then was heat treated at a solid solution temperature of 1260 °C and different aging temperature of 840 °C, 870 °C, 900 °C and 930 °C respectively. Effects of aging temperatures on the microstructures and mechanical properties were systematically studied. The results show that the microstructures of all the heat treated samples are composed of γ matrix, carbides and γ′ phase. The γ grains remain a columnar shape after treatments, but the size of γ′ phase grows up gradually with the increasing aging temperature. The composite treated at an aging temperature of 870 °C exhibits the best mechanical properties with the tensile strength of 1073 MPa, yield strength of 1004 MPa and elongation of 7.57%. The plastic deformation and strengthening mechanisms of heat treated composite were systematically investigated.

Key words: Selective laser melting, Heat treatment, Nickel-based composite, Microstructures, Mechanical properties

Yuting Lv, Yaojie Liu, Zhe Zhang, Qiang Zhang, Hongyao Yu, Rui Wang, Guangbao Sun, Guijiang Wei. Microstructures and Mechanical Properties of the TiC/CM247LC Nickel-Based Composite Fabricated by Selective Laser Melting: Effect of Heat Treatment[J]. Acta Metallurgica Sinica (English Letters), 2023, 36(12): 1936-1946.

Figures/Tables 8

Fig. 1 Preparation of TiC/CM247LC mixed powder by ball milling process: a schematic diagram of CM247LC powder, and the inset showing the morphologies of CM247LC powder, b schematic diagram of Nano-TiC particles, and the inset showing the morphologies of Nano-TiC particles powder, c schematic diagram of the ball milling process, d TiC/CM247LC mixed powder, e a partial enlargement image of the blue square area in (d)

Fig. 2 a Schematic diagram of the scanning strategy, b rectangular specimens fabricated by SLM, c dimension of the tensile specimen

Fig. 3 SEM images of heat treated TiC/CM247LC composites and corresponding γ′ phase particle size distribution: a HT840, b HT870, c HT900, d HT930, e, f, g, h local enlarged image of Fig. 3(a, b, c, d), respectively, i, j, k, l γ′ phase particle size distribution of heat treated composite

Fig. 4 IPF, grain size distribution and pole figure of the composites with different aging treatments: a-d IPF of HT840, HT870, HT900 and HT930, e-h grain size distribution of HT840, HT870, HT900 and HT930, i-l pole figure of HT840, HT870, HT900 and HT930

Fig. 5 Room temperature mechanical properties of the composites with different aging treatments: a stress-strain curves, b UTS, YS, and elongation

Fig. 6 TEM images showing the microstructures of the stretched HT870 sample: a bright field image of the matrix microstructures, and the inset shows the SAED of the red circle area, b bright field image for the precipitated phase, and the inset showing the SAED of the particle phase, c EDS mapping

Fig. 7 TEM images of the HT870 sample near the tensile fracture: a parallel dislocations, b, c stacking fault located inside γ′ phase, d stacking fault through γ and γ′ phases

Fig. 8 Dislocation pairs present in the stretched HT870 sample

References 47.

1.	R. Wang, G.L. Zhu, Q.B. Tan, W.Z. Zhou, C. Yang, D.H. Wang, A.P. Dong, D. Shu, L. Zhang, B.D. Sun, J. Alloys Compd. 853, 157226 (2021) DOI URL
2.	J.P. Kruth, M.C. Leu, T. Nakagawa, Ann. CRIP. 47, 525 (1998)
3.	Q.Q. Han, H. Gu, S. Soe, R. Setchi, F. Lacan, J. Hill, Mater. Des. 160, 1080 (2018) DOI URL
4.	Q.Q. Han, Y.Q. Geng, R. Setchi, F. Lacan, D.D. Gu, S.L. Evans, Compos. B Eng. 127, 26 (2017) DOI URL
5.	Y.T. Lv, J.W. Guo, Q. Zhang, G.J. Wei, H. Yu, Mater. Lett. 325, 132616 (2022) DOI URL
6.	Y.T. Lv, J.W. Guo, W.M. Huang, Y.J. Liu, W.T. Liu, Anti-Corros. Methods Mater. 69, 660 (2022) DOI URL
7.	S. Griffiths, H.G. Tabasi, T. Ivas, X. Maeder, A.D. Luca, K. Zweiacker, R. Wróbel, J. Jhabvala, R.E. Logé, C. Leinenbach, Addit. Manuf. 36, 101443 (2020)
8.	E. Bassini, A. Sivo, P.A. Martelli, E. Rajczak, G. Marchese, F. Calignano, S. Biamino, D. Ugues, J. Alloys Compd. 905, 164213 (2022) DOI URL
9.	X.Q. Wang, L.N. Carter, B. Pang, M.M. Attallah, M.H. Loretto, Acta Mater. 128, 87 (2017) DOI URL
10.	T.M. Pollock, A.S. Argon, Acta Metall. Mater. 40, 1 (1992) DOI URL
11.	M.P. Jackson, R.C. Reed, Mater. Sci. Eng. A 259, 85 (1999) DOI URL
12.	C.M.F. Rae, R.C. Reed, Acta Mater. 55, 1067 (2007) DOI URL
13.	N. Kalenticsa, N. Sohrabi, H.G. Tabasi, S. Griffiths, J. Jhabvala, C. Leinenbach, A. Burn, R.E. Logé, Addit. Manuf. 30, 100881 (2019)
14.	M.D. Hayat, H. Singh, Z. He, P. Cao, Compos. Part A 121, 418 (2019)
15.	K. Morsi, J. Mater. Sci. 54, 6753 (2019) DOI
16.	S.Z. Yang, Q.Q. Han, Y.Y. Yin, Z.H. Zhang, L.Q. Wang, Z.X. Zhu, H.L. Liu, T. Ma, Z.J. Gao, Opt. Laser Technol. 155, 108441 (2022) DOI URL
17.	Q.Q. Han, Y.C. Gu, R. Setchi, F. Lacan, R. Johnston, S.L. Evans, S.F. Yang, Addit. Manuf. 30, 100919 (2019)
18.	H.M. Zhang, D.D. Gu, C.L. Ma, M. Guo, J.K. Yang, R. Wang, Mater. Sci. Eng. A 765, 138294 (2019) DOI URL
19.	Z. Zhang, R. Wang, Y.T. Lv, W.T. Liu, Y.J. Liu, Mater. Sci. Eng. A 851, 143588 (2022) DOI URL
20.	Y.T. Lv, Z. Zhang, Q. Zhang, R. Wang, G.B. Sun, X.Z. Chen, H.Y. Yu, Z.N. Bi, J.L. Xie, G.J. Wei, Mater. Sci. Eng. A 858, 144119 (2022) DOI URL
21.	V.D. Divya, R. Munoz-Moreno, O.M.D.M. Messe, J.S. Barnard, S. Baker, T. Illston, H.J. Stone, Mater Charact 114,62 (2016) DOI URL
22.	S. Griffiths, H.G. Tabasi, A.D. Luca, J. Pado, S.S. Joglekar, J. Jhabvala, R.E. Loge, C. Leinenbach, Mater Charact 171,110815 (2021) DOI URL
23.	Y.B. Wu, C.B. Yang, W.X. Hou, Y. Rong, C. Li, Y.J. Lu, L.L. Li, Heat Treat. Met. 46, 13 (2021)
24.	P. Kanagarajah, F. Brenne, T. Niendorf, H.J. Maier, Mater. Sci. Eng. A 588, 188 (2013) DOI URL
25.	M.R. Jahangiri, H. Arabi, S.M.A. Boutorabi, Trans. Nonferrous Metal. Soc. China 24,1717 (2014) DOI URL
26.	J.S. Huo, J.T. Gou, L.Z. Zhou, X.Z. Qin, G.S. Li, J. Mater. Eng. Perform. 16, 55 (2007) DOI URL
27.	P. Zhang, Y. Yuan, B. Li, G. Yang, X. Song, Phil. Mag. Letts. 96, 238 (2016) DOI URL
28.	S. Sinharoy, P. Virro-Nic, W.W. Milligan, Metall. Mater. Trans. A 31, 2021 (2001)
29.	Y. Yuan, Y.F. Gu, T. Osada, Z.H. Zhong, T. Yokokawa, H. Harada, Scr. Mater. 67, 137 (2012) DOI URL
30.	C.X. Dang, P. Zhang, J. Li, Z.H. Gao, B. Li, X.F. Gong, X.L. Song, Mater. Charact. 170, 110648 (2020) DOI URL
31.	B. Decamps, A.J. Morton, M. Condat, Philoso. Mag. 64, 641 (1991)
32.	P. Caron, T. Khan, P. Veyssière, Philoso. Mag. 57, 859 (1988)
33.	P. Zhang, Y. Yuan, S.C. Shen, B. Li, R.H. Zhu, G.X. Yang, X.L. Song, J. Alloys Compd. 694, 502 (2017) DOI URL
34.	G.B. Viswanathan, P.M. Sarosi, M.F. Henry, D.D. Whitis, W.W. Milligan, M.J. Mills, Acta Mater. 53, 3041 (2005) DOI URL
35.	Z.H. Zhang, Q.Q. Han, Z.Y. Liu, J. Gao, L.Q. Wang, H.L. Liu, R. Wang, T. Ma, Z.J. Gao, Mater. Sci. Eng. A 861, 144379 (2022) DOI URL
36.	A. Takahashi, M. Kawanabe, N.M. Ghoniem, Philos. Mag. 90, 27 (2010)
37.	P. Pandey, S. Kashyap, D. Palanisamy, A. Sharma, K. Chattopadhyay, Acta Mater. 177, 82 (2019) DOI URL
38.	Q. Wang, Z. Li, S.J. Pang, X.N. Li, C. Dong, P.K. Liaw, Entropy 20,878 (2018) DOI URL
39.	W.Q. Hu, Z.Y. Huang, Q. Yu, Y.B. Wang, Y.D. Jiao, Y. Zhou, H.X. Zhai, Met. Mater. Int. 27, 3003 (2021) DOI
40.	V. Gerold, H. Haberkorn, Phys. Status Solidi 16, 675 (1966)
41.	S.S. Xu, Y. Zhao, D. Chen, L.W. Sun, L. Chen, X. Tong, C.T. Liu, Z.W. Zhang, Int. J. Plast. 113, 99 (2019) DOI URL
42.	R. Yang, L.J. Yang, T.M. Wang, Q.H. Wang, Mater. Sci. Eng. A 870, 144880 (2023) DOI URL
43.	H. Monajati, M. Jahazi, R. Bahrami, S. Yue, Mater. Sci. Eng. A 373, 286 (2004) DOI URL
44.	D. Hausmann, C. Solis, L.P. Freund, N. Volz, A. Heinemann, M. Goken, R. Gilles, S. Neumeier, Metals 10,321 (2020) DOI URL
45.	Y.Z. Ji, Y.C. Lou, M. Qu, J.D. Rowatt, F. Zhang, T.W. Simpson, L.Q. Chen, Metall. Mater. Trans. A 47, 3235 (2016) DOI URL
46.	R.E. Stoltz, A.G. Pineau, Mater. Sci. Eng. 34, 275 (1978) DOI URL
47.	M.A. Charpagne, P. Vennegues, T. Billot, J.M. Franchet, N. Bozzolo, J. Microsc. 263, 106 (2016) DOI URL

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