[1] [1] NICKEL A H, BARNETT D M, PRINZ F B. Thermal stresses and deposition patterns in layered manufacturing［J］. Materials Science and Engineering: A, 2001, 317(1-2): 59-64.

[2] [2] GAO M, WANG Z M, LI X Y, et al. The effect of deposition patterns on the deformation of substrates during direct laser fabrication［J］. Journal of Engineering Materials and Technology, 2013, 135(3): 034502.

[3] [3] DENLINGER E R, IRWIN J, MICHALERIS P. Thermomechanical modeling of additive manufacturing large parts［J］. Journal of Manufacturing Science and Engineering, 2014, 136(6): 061007.

[4] [4] KOLOSSOV S, BOILLAT E, GLARDON R, et al. 3D FE simulation for temperature evolution in the selective laser sintering process［J］. International Journal of Machine Tools and Manufacture, 2004, 44(2-3): 117-123.

[5] [5] JAMSHIDINIA M, KONG F R, KOVACEVIC R. Numerical modeling of heat distribution in the electron beam melting of Ti-6Al-4V［J］. Journal of Manufacturing Science and Engineering, 2013, 135(6): 061010.

[6] [6] CHIUMENTI M, CERVERA M, SALMI A, et al. Finite element modeling of multi-pass welding and shaped metal deposition processes［J］. Computer Methods in Applied Mechanics and Engineering, 2010, 199(37-40): 2343-2359.

[7] [7] LUNDBCK A, LINDGREN L E. Modelling of metal deposition［J］. Finite Elements in Analysis and Design, 2011, 47(10): 1169-1177.

[8] [8] UEDA Y, FUKUDA K, NAKACHO K, et al. A new measuring method of residual stresses with the aid of finite element method and reliability of estimated values［J］. Journal of the Society of Naval Architects of Japan, 1975, 1975(138): 499-507.

[9] [9] DENG D A, MURAKAWA H, LIANG W. Numerical simulation of welding distortion in large structures［J］. Computer Methods in Applied Mechanics and Engineering, 2007, 196(45-48): 4613-4627.

[10] [10] LIANG X, DONG W, HINNEBUSCH S, et al. Inherent strain homogenization for fast residual deformation simulation of thin-walled lattice support structures built by laser powder bed fusion additive manufacturing［J］. Additive Manufacturing, 2020, 32: 101091.

[11] [11] LIANG X, CHEN Q, CHENG L, et al. Modified inherent strain method for efficient prediction of residual deformation in direct metal laser sintered components［J］. Computational Mechanics, 2019, 64(6): 1719-1733.

[12] [12] CHEN Q, LIANG X, HAYDUKE D, et al. An inherent strain based multiscale modeling framework for simulating part-scale residual deformation for direct metal laser sintering［J］. Additive Manufacturing, 2019, 28: 406-418.

[13] [13] 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.

[14] [14] WILLIAMS R J, DAVIES C M, HOOPER P A. A pragmatic part scale model for residual stress and distortion prediction in powder bed fusion［J］. Additive Manufacturing, 2018, 22: 416-425.

[16] [16] LINDGREN L E, LUNDBCK A. Approaches in computational welding mechanics applied to additive manufacturing: Review and outlook［J］. Comptes Rendus Mécanique, 2018, 346(11): 1033-1042.

[17] [17] ZHANG L, REUTZEL E W, MICHALERIS P. Finite element modeling discretization requirements for the laser forming process［J］. International Journal of Mechanical Sciences, 2004, 46(4): 623-637.