[1] Zhu J H, Zhang W H, Xia L. Topology optimization in aircraft and aerospace structures design[J]. Archives of Computational Methods in Engineering, 23, 595-622(2016).

[2] Zhu J H, Zhou H, Wang C et al. Status and future of topology optimization for additive manufacturing[J]. Aeronautical Manufacturing Technology, 63, 24-38(2020).

[3] Quan D L, Shi G H, Guan C Q et al. Applications and challenges of structural optimization in high-speed aerocraft[J]. Mechanics in Engineering, 41, 373-381, 415(2019).

[4] Wang X M. New concept structure design and engineering application of aircraft[J]. Aeronautical Science & Technology, 31, 1-7(2020).

[5] White D A, Voronin A. A computational study of symmetry and well-posedness of structural topology optimization[J]. Structural and Multidisciplinary Optimization, 59, 759-766(2019).

[6] Shi G H, Guan C Q, Quan D L et al. An aerospace bracket designed by thermo-elastic topology optimization and manufactured by additive manufacturing[J]. Chinese Journal of Aeronautics, 33, 1252-1259(2020).

[7] Jankovics D, Barari A. Customization of automotive structural components using additive manufacturing and topology optimization[J]. IFAC-PapersOnLine, 52, 212-217(2019).

[8] Zhu J H, Zhou H, Wang C et al. A review of topology optimization for additive manufacturing: status and challenges[J]. Chinese Journal of Aeronautics, 34, 91-110(2021).

[9] Taylor B, Zeinalov J, Kim I Y. Topology optimization of large scale turbine engine bracket assembly with additive manufacturing considerations[M]. Schumacher A, Vietor T, Fiebig S, et al. World congress of structural and multidisciplinary optimization, 1211-1223(2018).

[10] DebRoy T, Wei H L, Zuback J S et al. Additive manufacturing of metallic components-process, structure and properties[J]. Progress in Materials Science, 92, 112-224(2018).

[11] Ligon S C, Liska R, Stampfl J et al. Polymers for 3D printing and customized additive manufacturing[J]. Chemical Reviews, 117, 10212-10290(2017).

[12] Liu S T, Li Q H, Liu J H et al. A realization method for transforming a topology optimization design into additive manufacturing structures[J]. Engineering, 4, 277-285(2018).

[13] Liu J K. Piecewise length scale control for topology optimization with an irregular design domain[J]. Computer Methods in Applied Mechanics and Engineering, 351, 744-765(2019).

[14] Mirzendehdel A M, Rankouhi B, Suresh K. Strength-based topology optimization for anisotropic parts[J]. Additive Manufacturing, 19, 104-113(2018).

[15] Li Q H. Topology optimization methods for additive manufacturing structures with connectivity constraint and structural feature constraints[D](2017).

[16] Bendsøe M P, Kikuchi N. Generating optimal topologies in structural design using a homogenization method[J]. Computer Methods in Applied Mechanics and Engineering, 71, 197-224(1988).

[17] Mlejnek H P. Some aspects of the genesis of structures[J]. Structural Optimization, 5, 64-69(1992).

[18] Xie Y M, Steven G P. A simple evolutionary procedure for structural optimization[J]. Computers & Structures, 49, 885-896(1993).

[19] Jin S M. Evolutionary structural optimization design with maximum structural scale constraint[D](2020).

[20] Lin Z J. Solid isotropic material with penalization and level set method in structural topology optimization design[D](2010).

[21] Guo X, Zhou J H, Zhang W S et al. Self-supporting structure design in additive manufacturing through explicit topology optimization[J]. Computer Methods in Applied Mechanics and Engineering, 323, 27-63(2017).

[22] Zhang W H, Zhou L. Topology optimization of self-supporting structures with polygon features for additive manufacturing[J]. Computer Methods in Applied Mechanics and Engineering, 334, 56-78(2018).

[23] Chen Y P, He Z Y. Summary of research methods for removing numerical instability in structural topology optimization[J]. Technology and Market, 22, 40-42(2015).

[24] Kim T S, Kim Y Y. Mac-based mode-tracking in structural topology optimization[J]. Computers & Structures, 74, 375-383(2000).

[25] Chang J K, Duan B Y. An improved variable density method and application for topology optimization of continuum structures[J]. Chinese Journal of Computational Mechanics, 26, 188-192(2009).

[26] Hsu M H, Hsu Y L. Interpreting three-dimensional structural topology optimization results[J]. Computers & Structures, 83, 327-337(2005).

[27] Li X, Wang H. A new variable density method with gray-scale filter function for topology optimization of continuum structures[J]. Journal of Fudan University (Natural Science), 51, 400-405, 414(2012).

[28] Zhou M, ShyyY K, Thomas H L. Checkerboard and minimum member size control in topology optimization[J]. Structural and Multidisciplinary Optimization, 21, 152-158(2001).

[29] Díaz A, Sigmund O. Checkerboard patterns in layout optimization[J]. Structural Optimization, 10, 40-45(1995).

[30] Yuan Z, Wu C C. Topology optimization for periodic linear elastic microstructures of composite materials[J]. Acta Mechanica Solida Sinica, 24, 40-45(2003).

[31] Zhang W H, Duysinx P. Dual approach using a variant perimeter constraint and efficient sub-iteration scheme for topology optimization[J]. Computers & Structures, 81, 2173-2181(2003).

[32] Yang X Y, Xie Y M, Liu J S et al. Perimeter control in the bidirectional evolutionary optimization method[J]. Structural and Multidisciplinary Optimization, 24, 430-440(2002).

[33] Bendsøe M P, Sigmund O[M]. Topology optimization: theory, methods, and applications(2003).

[34] Sigmund O, Petersson J. Numerical instabilities in topology optimization: a survey on procedures dealing with checkerboards, mesh-dependencies and local minima[J]. Structural Optimization, 16, 68-75(1998).

[35] Borrvall T, Petersson J. Topology optimization using regularized intermediate density control[J]. Computer Methods in Applied Mechanics and Engineering, 190, 4911-4928(2001).

[36] Fujii D, Kikuchi N. Improvement of numerical instabilities in topology optimization using the SLP method[J]. Structural and Multidisciplinary Optimization, 19, 113-121(2000).

[37] Zuo K T, Wang S T, Chen L P et al. Research on algorithms to eliminate numerical instabilities in topology optimization[J]. Mechanical Science and Technology, 24, 86-89, 93(2005).

[38] Li Q, Steven G P, Xie Y M. A simple checkerboard suppression algorithm for evolutionary structural optimization[J]. Structural and Multidisciplinary Optimization, 22, 230-239(2001).

[39] Luo Z. Research on topology optimization design of continuum structure based on variable density method[D](2005).

[40] Sethian J A, Wiegmann A. Structural boundary design via level set and immersed interface methods[J]. Journal of Computational Physics, 163, 489-528(2000).

[41] Guo X, Zhang W S, Zhong W L. Doing topology optimization explicitly and geometrically: a new moving morphable components based framework[J]. Journal of Applied Mechanics, 81, 081009(2014).

[42] Zhang W S, Yuan J, Zhang J et al. A new topology optimization approach based on Moving Morphable Components (MMC) and the ersatz material model[J]. Structural and Multidisciplinary Optimization, 53, 1243-1260(2016).

[43] Zhang W H, Zhou Y, Jiu L P et al. Feature-driven method for structural topology optimization[J]. Scientia Sinica: Technologica, 49, 1177-1185(2019).

[44] Yaji K, Otomori M, Yamada T et al. Shape and topology optimization based on the convected level set method[J]. Structural and Multidisciplinary Optimization, 54, 659-672(2016).

[45] Burger M, Hackl B, Ring W. Incorporating topological derivatives into level set methods[J]. Journal of Computational Physics, 194, 344-362(2004).

[46] Allaire G, Gournay F, Jouve F et al. Structural optimization using topological and shape sensitivity via a level set method[J]. Control and Cybernetics, 34, 59-80(2005).

[47] Allaire G, Jouve F. A level-set method for vibration and multiple loads structural optimization[J]. Computer Methods in Applied Mechanics and Engineering, 194, 3269-3290(2005).

[48] Yamada T, Izui K, Nishiwaki S et al. A topology optimization method based on the level set method incorporating a fictitious interface energy[J]. Computer Methods in Applied Mechanics and Engineering, 199, 2876-2891(2010).

[49] Otomori M, Yamada T, Izui K et al. Matlab code for a level set-based topology optimization method using a reaction diffusion equation[J]. Structural and Multidisciplinary Optimization, 51, 1159-1172(2015).

[50] Qu D Y, Zhang H B, Xu J A et al. Theoretical research of structure topology optimization based on the level set method[J]. Chinese Journal of Applied Mechanics, 36, 895-900, 1000(2019).

[51] Allaire G, Jouve F, Toader A M. Structural optimization using sensitivity analysis and a level-set method[J]. Journal of Computational Physics, 194, 363-393(2004).

[52] Dijk N P, Langelaar M, Keulen F. Explicit level-set-based topology optimization using an exact Heaviside function and consistent sensitivity analysis[J]. International Journal for Numerical Methods in Engineering, 91, 67-97(2012).

[53] Li H, Grandhi R V, Kobayashi M. Level-set based cellular division method for structural shape and topology optimization[C], 1837(2018).

[54] Luo Z, Tong L Y, Kang Z. A level set method for structural shape and topology optimization using radial basis functions[J]. Computers & Structures, 87, 425-434(2009).

[55] Guirguis D, Aly M F. A derivative-free level-set method for topology optimization[J]. Finite Elements in Analysis and Design, 120, 41-56(2016).

[56] Dunning P D, Kim H A. Introducing the sequential linear programming level-set method for topology optimization[J]. Structural and Multidisciplinary Optimization, 51, 631-643(2015).

[57] Challis V J. A discrete level-set topology optimization code written in Matlab[J]. Structural and Multidisciplinary Optimization, 41, 453-464(2010).

[58] Allaire G, Dapogny C, Delgado G et al. Multi-phase structural optimizationviaa level set method[J]. ESAIM: Control, Optimisation and Calculus of Variations, 20, 576-611(2014).

[59] Wei P, Wang M Y, Xing X H. A study on X-FEM in continuum structural optimization using a level set model[J]. Computer-Aided Design, 42, 708-719(2010).

[60] Kreissl S, Maute K. Levelset based fluid topology optimization using the extended finite element method[J]. Structural and Multidisciplinary Optimization, 46, 311-326(2012).

[61] Parvizian J, Düster A, Rank E. Topology optimization using the finite cell method[J]. Optimization and Engineering, 13, 57-78(2012).

[62] Zhang W H, Zhao L Y, Gao T et al. Topology optimization with closed B-splines and Boolean operations[J]. Computer Methods in Applied Mechanics and Engineering, 315, 652-670(2017).

[63] Groen J P, Langelaar M, Sigmund O et al. Higher-order multi-resolution topology optimization using the finite cell method[J]. International Journal for Numerical Methods in Engineering, 110, 903-920(2017).

[64] Hassani B, Khanzadi M, Tavakkoli S M. An isogeometrical approach to structural topology optimization by optimality criteria[J]. Structural and Multidisciplinary Optimization, 45, 223-233(2012).

[65] Yamasaki S, Nishiwaki S, Yamada T et al. A structural optimization method based on the level set method using a new geometry-based re-initialization scheme[J]. International Journal for Numerical Methods in Engineering, 83, 1580-1624(2010).

[66] Yamasaki S, Nomura T, Kawamoto A et al. A level set-based topology optimization method targeting metallic waveguide design problems[J]. International Journal for Numerical Methods in Engineering, 87, 844-868(2011).

[67] Zhou J H. Research on explicit topology optimization considering structural manufacturability[D](2018).

[68] Li P, Du Y B, Peng J C et al. Effect of component number on topology structure optimization in moving morphable component method[J]. Manufacturing Technology & Machine Tool, 84-88(2020).

[69] Yu C T. Topology optimization method of MMC based on smoothing technology[D](2021).

[70] Xie X D. Research on moving morphable components topology optimization method and application based on isogeometric analysis[D](2021).

[71] Xue R Y, Du Z L, Guo X. Topology optimization of hyperelastic structures via Moving Morphable Void (MMV) approach[J]. Chinese Journal of Computational Mechanics, 36, 441-447(2019).

[72] Zhou Y. Feature-driven structural topology optimization theory and method[D](2018).

[73] Wu B, Wang X M, Xuan M H et al. Structural innovation of new fighter based on additive manufacturing[J]. Journal of Aeronautical Materials, 41, 1-12(2021).

[74] Gu D D, Zhang H M, Chen H Y et al. Laser additive manufacturing of high-performance metallic aerospace components[J]. Chinese Journal of Lasers, 47, 0500002(2020).

[75] Kuo Y L, Kamigaichi A, Kakehi K. Characterization of Ni-based superalloy built by selective laser melting and electron beam melting[J]. Metallurgical and Materials Transactions A, 49, 3831-3837(2018).

[76] Sing S L, Wiria F E, Yeong W Y. Selective laser melting of titanium alloy with 50wt% tantalum: effect of laser process parameters on part quality[J]. International Journal of Refractory Metals and Hard Materials, 77, 120-127(2018).

[77] Jia H L, Sun H, Wang H Z et al. Scanning strategy in selective laser melting (SLM): a review[J]. The International Journal of Advanced Manufacturing Technology, 113, 2413-2435(2021).

[78] Cooke S, Ahmadi K, Willerth S et al. Metal additive manufacturing: technology, metallurgy and modelling[J]. Journal of Manufacturing Processes, 57, 978-1003(2020).

[79] Murr L E. Open-cellular metal implant design and fabrication for biomechanical compatibility with bone using electron beam melting[J]. Journal of the Mechanical Behavior of Biomedical Materials, 76, 164-177(2017).

[80] Wang H M. Materials’ fundamental issues of laser additive manufacturing for high-performance large metallic components[J]. Acta Aeronautica et Astronautica Sinica, 35, 2690-2698(2014).

[81] Yang J X, Ke H, Cui Z et al. Research and application progress of laser metal deposition[J]. Aeronautical Manufacturing Technology, 63, 14-22(2020).

[82] Qin L Y, Xie Y K, Yang G et al. Detection and control of morphology deviation in laser deposition manufacturing[J]. Chinese Journal of Lasers, 48, 1002113(2021).

[83] Lin X, Huang W D. High performance metal additive manufacturing technology applied in aviation field[J]. Materials China, 34, 684-688, 658(2015).

[84] Wang F D, Williams S, Colegrove P et al. Microstructure and mechanical properties of wire and arc additive manufactured Ti-6Al-4V[J]. Metallurgical and Materials Transactions A, 44, 968-977(2013).

[85] Lian Y P, Wang P D, Gao J et al. Fundamental mechanics problems in metal additive manufacturing: a state-of-art review[J]. Advances in Mechanics, 51, 648-701(2021).

[86] Lei L M, Hou H P, He Y L et al. Application and challenges of metal additive manufacturing in civil aviation[J]. Aeronautical Manufacturing Technology, 62, 22-30(2019).

[87] Gong S L, Suo H B, Li H X. Development and application of metal additive manufacturing technology[J]. Aeronautical Manufacturing Technology, 56, 66-71(2013).

[88] Xu S J, Quan C Y, Yang K et al. Application and prospect of metal additive manufacturing technology in aviation field[J]. Powder Metallurgy Industry, 32, 9-17(2022).

[89] Chen D J, Wang P, Pan R et al. Characteristics of metal specimens formed by selective laser melting: a state-of-the-art review[J]. Journal of Materials Engineering and Performance, 30, 7073-7100(2021).

[90] Sun H K, Chu X, Luo C et al. Selective laser melting for joining dissimilar materials: investigations of interfacial characteristics and in situ alloying[J]. Metallurgical and Materials Transactions A, 52, 1540-1550(2021).

[91] Murr L E, Gaytan S M, Ramirez D A et al. Metal fabrication by additive manufacturing using laser and electron beam melting technologies[J]. Journal of Materials Science & Technology, 28, 1-14(2012).

[92] Guo C, Zhang P P, Lin F. Research advances of electron beam selective melting additive manufacturing technology[J]. Industrial Technology Innovation, 4, 6-14(2017).

[93] Gong X B, Anderson T, Chou K. Review on powder-based electron beam additive manufacturing technology[C], 507-515(2013).

[94] Le F B, Ye H, Liu Y. Research and application of metal additive manufacturing[J]. Jiangxi Science, 38, 157-161, 262(2020).

[95] Palčič I, Balažic M, Milfelner M et al. Potential of laser engineered net shaping (LENS) technology[J]. Materials and Manufacturing Processes, 24, 750-753(2009).

[96] Chen H, Ye L, Han Y et al. Additive manufacturing of W–Fe composites using laser metal deposition: microstructure, phase transformation, and mechanical properties[J]. Materials Science and Engineering: A, 811, 141036(2021).

[97] Izadi M, Farzaneh A, Mohammed M et al. A review of laser engineered net shaping (LENS) build and process parameters of metallic parts[J]. Rapid Prototyping Journal, 26, 1059-1078(2020).

[98] Wirth F, Arpagaus S, Wegener K. Analysis of melt pool dynamics in laser cladding and direct metal deposition by automated high-speed camera image evaluation[J]. Additive Manufacturing, 21, 369-382(2018).

[99] Zhang L H, Qian B, Zhang C R et al. Summary of development trend of metal additive manufacturing technology[J]. Materials Science and Technology, 30, 42-52(2022).

[100] Liang J J, Yang Y H, Jin T et al. Research status of 3D printing technology for metals in space[J]. Manned Spaceflight, 23, 663-669(2017).

[101] He J B, Xu Y, Zhou J P et al. Research progress of additive manufacturing technology for metal[J]. Machine Tool & Hydraulics, 48, 171-175(2020).

[102] Liu S T, Li Q H, Chen W J et al. An identification method for enclosed voids restriction in manufacturability design for additive manufacturing structures[J]. Frontiers of Mechanical Engineering, 10, 126-137(2015).

[103] Wang X M, Su Y D, Wu B. Application of additive manufacturing technology on aircraft structure development[J]. Aeronautical Manufacturing Technology, 57, 16-20(2014).

[104] Wang X M, Cui C, Su Y D et al. Aircraft structures technology based on power beam additive manufacturing[J]. Aeronautical Manufacturing Technology, 60, 16-21(2017).

[105] Guest J K, Prévost J H, Belytschko T. Achieving minimum length scale in topology optimization using nodal design variables and projection functions[J]. International Journal for Numerical Methods in Engineering, 61, 238-254(2004).

[106] Sigmund O. Morphology-based black and white filters for topology optimization[J]. Structural and Multidisciplinary Optimization, 33, 401-424(2007).

[107] Wang F W, Lazarov B S, Sigmund O. On projection methods, convergence and robust formulations in topology optimization[J]. Structural and Multidisciplinary Optimization, 43, 767-784(2011).

[108] Zhou M D, Lazarov B S, Wang F W et al. Minimum length scale in topology optimization by geometric constraints[J]. Computer Methods in Applied Mechanics and Engineering, 293, 266-282(2015).

[109] Yang K K, Fernandez E, Niu C et al. Note on spatial gradient operators and gradient-based minimum length constraints in SIMP topology optimization[J]. Structural and Multidisciplinary Optimization, 60, 393-400(2019).

[110] Rong X P, Rong J H, Zhao S N et al. New method for controlling minimum length scales of real and void phase materials in topology optimization[J]. Acta Mechanica Sinica, 36, 805-826(2020).

[111] Chen S K, Wang M Y, Liu A Q. Shape feature control in structural topology optimization[J]. Computer-Aided Design, 40, 951-962(2008).

[112] Luo J Z, Luo Z, Chen S K et al. A new level set method for systematic design of hinge-free compliant mechanisms[J]. Computer Methods in Applied Mechanics and Engineering, 198, 318-331(2008).

[113] Dunning P D. Minimum length-scale constraints for parameterized implicit function based topology optimization[J]. Structural and Multidisciplinary Optimization, 58, 155-169(2018).

[114] Zhang W S, Li D, Zhang J et al. Minimum length scale control in structural topology optimization based on the Moving Morphable Components (MMC) approach[J]. Computer Methods in Applied Mechanics and Engineering, 311, 327-355(2016).

[115] Liu J K, Yu H C, Ma Y S. Minimum void length scale control in level set topology optimization subject to machining radii[J]. Computer-Aided Design, 81, 70-80(2016).

[116] Guest J K. Topology optimization with multiple phase projection[J]. Computer Methods in Applied Mechanics and Engineering, 199, 123-135(2009).

[117] Zhang W S, Zhong W L, Guo X. An explicit length scale control approach in SIMP-based topology optimization[J]. Computer Methods in Applied Mechanics and Engineering, 282, 71-86(2014).

[118] Guo X, Zhang W S, Zhong W L. Explicit feature control in structural topology optimization via level set method[J]. Computer Methods in Applied Mechanics and Engineering, 272, 354-378(2014).

[119] Xia Q, Shi T L. Constraints of distance from boundary to skeleton: for the control of length scale in level set based structural topology optimization[J]. Computer Methods in Applied Mechanics and Engineering, 295, 525-542(2015).

[120] Wang Y Q, Zhang L, Wang M Y. Length scale control for structural optimization by level sets[J]. Computer Methods in Applied Mechanics and Engineering, 305, 891-909(2016).

[121] Bai W, Li Q H, Chen W J et al. A novel projection based method for imposing maximum length scale in topology optimization[J]. Engineering Mechanics, 34, 18-26(2017).

[122] Niu B, Wadbro E. On equal-width length-scale control in topology optimization[J]. Structural and Multidisciplinary Optimization, 59, 1321-1334(2019).

[123] Leary M, Merli L, Torti F et al. Optimal topology for additive manufacture: a method for enabling additive manufacture of support-free optimal structures[J]. Materials & Design, 63, 678-690(2014).

[124] Brackett D, Ashcroft I, Hague R. Topology optimization for additive manufacturing[C], 348-362(2011).

[125] Langelaar M. Topology optimization of 3D self-supporting structures for additive manufacturing[J]. Additive Manufacturing, 12, 60-70(2016).

[126] Qian X P. Undercut and overhang angle control in topology optimization: a density gradient based integral approach[J]. International Journal for Numerical Methods in Engineering, 111, 247-272(2017).

[127] Gaynor A T, Guest J K. Topology optimization considering overhang constraints: eliminating sacrificial support material in additive manufacturing through design[J]. Structural and Multidisciplinary Optimization, 54, 1157-1172(2016).

[128] Luo Y F, Sigmund O, Li Q H et al. Additive manufacturing oriented topology optimization of structures with self-supported enclosed voids[J]. Computer Methods in Applied Mechanics and Engineering, 372, 113385(2020).

[129] Wang Y G, Gao J C, Kang Z. Level set-based topology optimization with overhang constraint: towards support-free additive manufacturing[J]. Computer Methods in Applied Mechanics and Engineering, 339, 591-614(2018).

[130] Liu J K, Yu H C. Self-support topology optimization with horizontal overhangs for additive manufacturing[J]. Journal of Manufacturing Science and Engineering, 142, 091003(2020).

[131] Xiong Y L, Yao S, Zhao Z L et al. A new approach to eliminating enclosed voids in topology optimization for additive manufacturing[J]. Additive Manufacturing, 32, 101006(2020).

[132] Zhou L, Zhang W H. Topology optimization method with elimination of enclosed voids[J]. Structural and Multidisciplinary Optimization, 60, 117-136(2019).

[133] Wang C, Xu B, Duan Z Y et al. Additive manufacturing-oriented stress minimization topology optimization with connectivity[J]. Chinese Journal of Theoretical and Applied Mechanics, 53, 1070-1080(2021).

[134] Gaynor A T, Johnson T E. Eliminating occluded voids in additive manufacturing design via a projection-based topology optimization scheme[J]. Additive Manufacturing, 33, 101149(2020).

[135] Liu J K, Yu H C. Concurrent deposition path planning and structural topology optimization for additive manufacturing[J]. Rapid Prototyping Journal, 23, 930-942(2017).

[136] Liu J K, To A C. Deposition path planning-integrated structural topology optimization for 3D additive manufacturing subject to self-support constraint[J]. Computer-Aided Design, 91, 27-45(2017).

[137] Dapogny C, Estevez R, Faure A et al. Shape and topology optimization considering anisotropic features induced by additive manufacturing processes[J]. Computer Methods in Applied Mechanics and Engineering, 344, 626-665(2019).

[138] Li H, Gao L, Li H et al. Spatial-varying multi-phase infill design using density-based topology optimization[J]. Computer Methods in Applied Mechanics and Engineering, 372, 113354(2020).

[139] Wang T C, Liu L, Li Z Z et al. Structural topology optimization with connectivity constraints based on anisotropic Helmholtz equation[J]. Journal of Mechanical Engineering, 58, 240-250(2022).

[140] 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, 28, 406-418(2019).

[141] Zhang Z D, Ibhadode O, Ali U et al. Topology optimization parallel-computing framework based on the inherent strain method for support structure design in laser powder-bed fusion additive manufacturing[J]. International Journal of Mechanics and Materials in Design, 16, 897-923(2020).

[142] Takezawa A, To A C, Chen Q et al. Sensitivity analysis and lattice density optimization for sequential inherent strain method used in additive manufacturing process[J]. Computer Methods in Applied Mechanics and Engineering, 370, 113231(2020).