Phase-field simulation of lack-of-fusion defect and grain growth during laser powder bed fusion of Inconel 718

Miaomiao Chen; Renhai Shi; Zhuangzhuang Liu; Yinghui Li; Qiang Du; Yuhong Zhao; Jianxin Xie

doi:10.1007/s12613-023-2664-z

International Journal of Minerals, Metallurgy, and Materials ›› 2023, Vol. 30 ›› Issue (11) : 2224 -2235. DOI: 10.1007/s12613-023-2664-z

Article

Phase-field simulation of lack-of-fusion defect and grain growth during laser powder bed fusion of Inconel 718

Miaomiao Chen ¹
, Renhai Shi ¹^,²^,³^,^b
, Zhuangzhuang Liu ¹^,²^,³^,^c
, Yinghui Li ¹
, Qiang Du ⁴
, Yuhong Zhao ¹^,⁵
, Jianxin Xie ¹^,²^,³^,^g

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Abstract

The anisotropy of the structure and properties caused by the strong epitaxial growth of grains during laser powder bed fusion (L-PBF) significantly affects the mechanical performance of Inconel 718 alloy components such as turbine disks. The defects (lack-of-fusion, LoF) in components processed via L-PBF are detrimental to the strength of the alloy. The purpose of this study is to investigate the effect of laser scanning parameters on the epitaxial grain growth and LoF formation in order to obtain the parameter space in which the microstructure is refined and LoF defect is suppressed. The temperature field of the molten pool and the epitaxial grain growth are simulated using a multiscale model combining the finite element method with the phase-field method. The LoF model is proposed to predict the formation of LoF defects resulting from insufficient melting during L-PBF. Defect mitigation and grain-structure control during L-PBF can be realized simultaneously in the model. The simulation shows the input laser energy density for the as-deposited structure with fine grains and without LoF defects varied from 55.0–62.5 J·mm⁻³ when the interlayer rotation angle was 0°–90°. The optimized process parameters (laser power of 280 W, scanning speed of 1160 mm·s⁻¹, and rotation angle of 67°) were computationally screened. In these conditions, the average grain size was 7.0 µm, and the ultimate tensile strength and yield strength at room temperature were (1111 ± 3) MPa and (820 ± 7) MPa, respectively, which is 8.8% and 10.5% higher than those of reported. The results indicating the proposed multiscale computational approach for predicting grain growth and LoF defects could allow simultaneous grain-structure control and defect mitigation during L-PBF.

Keywords

Inconel 718 alloy / laser powder bed fusion / scanning parameter optimization / lack-of-fusion phase-field method / finite element method

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Miaomiao Chen, Renhai Shi, Zhuangzhuang Liu, Yinghui Li, Qiang Du, Yuhong Zhao, Jianxin Xie. Phase-field simulation of lack-of-fusion defect and grain growth during laser powder bed fusion of Inconel 718. International Journal of Minerals, Metallurgy, and Materials, 2023, 30(11): 2224-2235 DOI:10.1007/s12613-023-2664-z

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References

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[1]	Sangid MD, Book TA, Naragani D, et al. Role of heat treatment and build orientation in the microstructure sensitive deformation characteristics of IN718 produced via SLM additive manufacturing. Addit. Manuf., 2018, 22, 479.

[2]	S.C. Luo, W.P. Huang, H.H. Yang, J.J. Yang, Z.M. Wang, and X.Y. Zeng, Microstructural evolution and corrosion behaviors of Inconel 718 alloy produced by selective laser melting following different heat treatments, Addit. Manuf., 30(2019), art. No. 100875.

[3]	Deng HZ, Wang L, Liu Y, Song X, Meng FQ, Huang S. Evolution behavior of γ″ phase of IN718 superalloy in temperature/stress coupled field. Int. J. Miner., Metall. Mater., 2021, 28(12): 1949.

[4]	E. Hosseini and V.A. Popovich, A review of mechanical properties of additively manufactured Inconel 718, Addit. Manuf., 30(2019), art. No. 100877.

[5]	Chen HY, Gu DD, Ge Q, et al. Role of laser scan strategies in defect control, microstructural evolution and mechanical properties of steel matrix composites prepared by laser additive manufacturing. Int. J. Miner., Metall. Mater., 2021, 28(3): 462.

[6]	Li N, Huang S, Zhang GD, Qin RY, et al. Progress in additive manufacturing on new materials: A review. J. Mater. Sci. Technol., 2019, 35(2): 242.

[7]	Gruber K, Stopyra W, Kobiela K, Madejski B, Malicki M, Kurzynowski T. Mechanical properties of Inconel 718 additively manufactured by laser powder bed fusion after industrial high-temperature heat treatment. J. Manuf. Process., 2022, 73, 642.

[8]	Zhang M, Zhang B, Wen Y, Qu X. Research progress on selective laser melting processing for nickel-based superalloy. Int. J. Miner., Metall. Mater., 2022, 29(3): 369.

[9]	Lu FY, Wan HY, Ren X, Huang LM, Liu HL, Yi X. Mechanical and microstructural characterization of additive manufactured Inconel 718 alloy by selective laser melting and laser metal deposition. J. Iron Steel Res. Int., 2022, 29(8): 1322.

[10]	Zinoviev A, Zinovieva O, Ploshikhin V, Romanova V, Balokhonov R. Evolution of grain structure during laser additive manufacturing. Simulation by a cellular automata method. Mater. Des., 2016, 106, 321.

[11]	S.Y. Liu, H.Q. Li, C.X. Qin, R. Zong, and X.Y. Fang, The effect of energy density on texture and mechanical anisotropy in selective laser melted Inconel 718, Mater. Des., 191(2020), art. No. 108642.

[12]	J.Y. Shao, G. Yu, X.L. He, S.X. Li, R. Chen, and Y. Zhao, Grain size evolution under different cooling rate in laser additive manufacturing of superalloy, Opt. Laser Technol., 119(2019), art. No. 105662.

[13]	Wan HY, Zhou ZJ, Li CP, Chen GF, Zhang GP. Effect of scanning strategy on grain structure and crystallographic texture of Inconel 718 processed by selective laser melting. J. Mater. Sci. Technol., 2018, 34(10): 1799.

[14]	O. Gokcekaya, T. Ishimoto, S. Hibino, J. Yasutomi, T. Narushima, and T. Nakano, Unique crystallographic texture formation in Inconel 718 by laser powder bed fusion and its effect on mechanical anisotropy, Acta Mater., 212(2021), art. No. 116876.

[15]	B. Stegman, A.Y. Shang, L. Hoppenrath, et al., Volumetric energy density impact on mechanical properties of additively manufactured 718 Ni alloy, Mater. Sci. Eng. A, 854(2022), art. No. 143699.

[16]	Wang YC, Shi J, Liu Y. Competitive grain growth and dendrite morphology evolution in selective laser melting of Inconel 718 superalloy. J. Cryst. Growth, 2019, 521, 15.

[17]	Acharya R, Sharon JA, Staroselsky A. Prediction of microstructure in laser powder bed fusion process. Acta Mater., 2017, 124, 360.

[18]	M. Yang, L. Wang, and W.T. Yan, Phase-field modeling of grain evolution in additive manufacturing with addition of reinforcing particles, Addit. Manuf., 47(2021), art. No. 102286.

[19]	W.J. Xiao, S.M. Li, C.S. Wang, et al., Multi-scale simulation of dendrite growth for direct energy deposition of nickel-based superalloys, Mater. Des., 164(2019), art. No. 107553.

[20]	Kumara C, Segerstark A, Hanning FB, et al. Microstructure modelling of laser metal powder directed energy deposition of alloy 718. Addit. Manuf., 2019, 25, 357.

[21]	C. Kumara, A.R. Balachandramurthi, S. Goel, F.B. Hanning, and J. Moverare, Toward a better understanding of phase transformations in additive manufacturing of Alloy 718, Materialia, 13(2020), art. No. 100862.

[22]	Cheloni JPM, Fonseca EB, Gabriel AHG, Lopes SN. The transient temperature field and microstructural evolution of additively manufactured AISI H13 steel supported by finite element analysis. J. Mater. Res. Technol., 2022, 19, 4583.

[23]	Goldak J, Chakravarti A, Bibby M. A new finite element model for welding heat sources. Metall. Trans. B, 1984, 15(2): 299.

[24]	Cheng YH. Numerical Simulation and Experimental Research of Selective Laser Melting on Nickel Based Alloy Powder GH4169, 2016, Taiyuan, North University of China.

[25]	Steinbach I, Pezzolla F, Nestler B, et al. A phase field concept for multiphase systems. Phys. D, 1996, 94(3): 135.

[26]	J. Eiken, B. Böttger, and I. Steinbach, Multiphase-field approach for multicomponent alloys with extrapolation scheme for numerical application, Phys. Rev. E, 73(2006), No. 6Pt2, art. No. 066122.

[27]	I. Steinbach, Phase-field models in materials science, Modell. Simul. Mater. Sci. Eng., 17(2009), No. 7, art. No. 073001.

[28]	Peng Q. Study on Microstructure and Properties of Nickel-based Superalloy by Selective Laser Melting, 2020, Beijing, University of Science and Technology Beijing.

[29]	Zheng M, Wei L, Chen J, et al. On the role of energy input in the surface morphology and microstructure during selective laser melting of Inconel 718 alloy. J. Mater. Res. Technol., 2021, 11, 392.

[30]	M. Balbaa, S. Mekhiel, M. Elbestawi, and J. McIsaac, On selective laser melting of Inconel 718: Densification, surface roughness, and residual stresses, Mater. Des., 193(2020), art. No. 108818.

[31]	Wang WQ, Wang SY, Zhang XG, Chen F, Xu YX, Tian YT. Process parameter optimization for selective laser melting of Inconel 718 superalloy and the effects of subsequent heat treatment on the microstructural evolution and mechanical properties. J. Manuf. Process., 2021, 64, 530.

[32]	Wang HY, Wang L, Cui R, Wang BB, Luo LS, Su YQ. Differences in microstructure and nano-hardness of selective laser melted Inconel 718 single tracks under various melting modes of molten pool. J. Mater. Res. Technol., 2020, 9(5): 10401.