[1] [1] BUCHANAN C, GARDNER L. Metal 3D printing in construction: A review of methods, research, applications, opportunities and challenges[J]. Engineering Structures, 2019, 180: 332-348.

[4] [4] RAFI H K, KARTHIK N V, GONG H J, et al. Microstructures and mechanical properties of Ti6Al4V parts fabricated by selective laser melting and electron beam melting[J]. Journal of Materials Engineering and Performance, 2013, 22(12): 3872-3883.

[5] [5] REN X P, LI H Q, GUO H, et al. A comparative study on mechanical properties of Ti-6Al-4V alloy processed by additive manufacturing vs. traditional processing[J]. Materials Science and Engineering: A, 2021, 817: 141384.

[6] [6] AZARMI F, SEVOSTIANOV I. Evaluation of the residual stresses in metallic materials produced by additive manufacturing technology: Effect of microstructure[J]. Current Opinion in Chemical Engineering, 2020, 28: 21-27.

[7] [7] CARPENTER K, TABEI A. On residual stress development, prevention, and compensation in metal additive manufacturing[J]. Materials, 2020, 13(2): 255.

[9] [9] LIU S Y, SHIN Y C. Additive manufacturing of Ti6Al4V alloy: A review[J]. Materials & Design, 2019, 164: 107552.

[10] [10] XIAO Z X, CHEN C P, ZHU H H, et al. Study of residual stress in selective laser melting of Ti6Al4V[J]. Materials & Design, 2020, 193: 108846.

[11] [11] LI C, LIU Z Y, FANG X Y, et al. Residual stress in metal additive manufacturing[J]. Procedia CIRP, 2018, 71: 348-353.

[12] [12] CHEN W, VOISIN T, ZHANG Y, et al. Microscale residual stresses in additively manufactured stainless steel[J]. Nature Communications, 2019, 10(1): 4338.

[13] [13] STRANTZA M, VRANCKEN B, PRIME M B, et al. Directional and oscillating residual stress on the mesoscale in additively manufactured Ti-6Al-4V[J]. Acta Materialia, 2019, 168: 299-308.

[14] [14] LINDROOS M, PINOMAA T, ANTIKAINEN A, et al. Micromechanical modeling approach to single track deformation, phase transformation and residual stress evolution during selective laser melting using crystal plasticity[J]. Additive Manufacturing, 2021, 38: 101819.

[15] [15] LIANG X, CHENG L, CHEN Q, et al. A modified method for estimating inherent strains from detailed process simulation for fast residual distortion prediction of single-walled structures fabricated by directed energy deposition[J]. Additive Manufacturing, 2018, 23: 471-486.

[16] [16] SONG X, FEIH S, ZHAI W, et al. Advances in additive manufacturing process simulation: Residual stresses and distortion predictions in complex metallic components[J]. Materials & Design, 2020, 193: 108779.

[17] [17] MATTHEWS C, LABOURE V, DEHART M, et al. Coupled multiphysics simulations of heat pipe microreactors using DireWolf[J]. Nuclear Technology, 2021, 207(7): 1142-1162.

[18] [18] GRILLI N, HU D, YUSHU D, et al. Crystal plasticity model of residual stress in additive manufacturing using the element elimination and reactivation method[J]. Computational Mechanics, 2021, 69: 825-845.

[19] [19] HU D J, GRILLI N, WANG L, et al. Microscale residual stresses in additively manufactured stainless steel: Computational simulation[J]. Journal of Mechanics Physics of Solids, 2022, 161: 104822.

[21] [21] ZINOVIEVA O, ZINOVIEV A, PLOSHIKHIN V. Three-dimensional modeling of the microstructure evolution during metal additive manufacturing[J]. Computational Materials Science, 2018, 141: 207-220.

[27] [27] YIN L W, UMEZAWA O. Crystal plasticity analysis of temperature-sensitive dwell fatigue in Ti-6Al-4V titanium alloy for an aero-engine fan disc[J]. International Journal of Fatigue, 2022, 156: 106688.

[28] [28] DAYMOND M R, BOUCHARD P J. Elastoplastic deformation of 316 stainless steel under tensile loading at elevated temperatures[J]. Metallurgical and Materials Transactions A, 2006, 37(6): 1863-1873.

[29] [29] KALIDINDI S R, ANAND L. An approximate procedure for predicting the evolution of crystallographic texture in bulk deformation processing of fcc metals[J]. International Journal of Mechanical Sciences, 1992, 34(4): 309-329.

[30] [30] ADDESSIO F L, LUSCHER D J, CAWKWELL M J, et al. A single-crystal model for the high-strain rate deformation of cyclotrimethylene trinitramine including phase transformations and plastic slip[J]. Journal of Applied Physics, 2017, 121(18): 185902.

[31] [31] JIANG W C, ZHANG Y C, WOO W. Using heat sink technology to decrease residual stress in 316L stainless steel welding joint: Finite element simulation[J]. International Journal of Pressure Vessels and Piping, 2012, 92: 56-62.

[32] [32] VUJOSEVIC L, LUBARDA V A. Finite-strain thermoelasticity based on multiplicative decomposition of deformation gradient[J]. Theoretical and Applied Mechanics, 2002(28/29): 379-399.

[33] [33] GRILLI N, KOSLOWSKI M. The effect of crystal orientation on shock loading of single crystal energetic materials[J]. Computational Materials Science, 2018, 155: 235-245.