[1] Baumers M, Tuck C, Wildman R, et al. Shape complexity and process energy consumption in electron beam melting: a case of something for nothing in additive manufacturing?[J]. Journal of Industrial Ecology, 2017, 21(S1): S157-S167.

[2] HopkinsonN, HagueR, DickensP. Rapid manufacturing: an industrial revolution for the digital age[M]. Chichester: John Wiley & Sons, 2006: 228- 229.

[3] YadroitsavaI, GrewarS, HattinghD, et al. Residual stress in SLM Ti6Al4V alloy specimens[J]. Materials Science Forum, 2015, 828/829: 305- 310.

[4] CasavolaC, S L, Campanelli C. Pappalettere C. Experimental analysis of residual stresses in the selective laser melting process[C]. Proceedings of the XIth International Congress and Exposition, 2008: 18270126.

[5] Parry L, Ashcroft I A, Wildman R D. Understanding the effect of laser scan strategy on residual stress in selective laser melting through thermo-mechanical simulation[J]. Additive Manufacturing, 2016, 12: 1-15.

[6] Verhaeghe F, Craeghs T, Heulens J, et al. A pragmatic model for selective laser melting with evaporation[J]. Acta Materialia, 2009, 57(20): 6006-6012.

[7] Khairallah S A, Anderson A. Mesoscopic simulation model of selective laser melting of stainless steel powder[J]. Journal of Materials Processing Technology, 2014, 214(11): 2627-2636.

[8] 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.

[9] Kruth J P, Deckers J, Yasa E, et al. Assessing and comparing influencing factors of residual stresses in selective laser melting using a novel analysis method[J]. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 2012, 226(6): 980-991.

[10] Kruth JP, BadrossamayM, YasaE, et al. Part and material properties in selective laser melting of metals[C]. International Symposium on Electromachining, 2010, 16: 3- 14.

[11] Zaeh M F, Branner G. Investigations on residual stresses and deformations in selective laser melting[J]. Production Engineering, 2010, 4(1): 35-45.

[12] van Belle L, Vansteenkiste G, Boyer J C. Investigation of residual stresses induced during the selective laser melting process[J]. Key Engineering Materials, 2013: 1828-1834.

[13] Roberts IA. Investigation of residual stresses in the laser melting of metal powders in additive layer manufacturing[D]. Wolverhampton: University of Wolverhampton, 2012: 246.

[14] Lu Y J, Wu S Q, Gan Y L, et al. Study on the microstructure, mechanical property and residual stress of SLM Inconel-718 alloy manufactured by differing island scanning strategy[J]. Optics & Laser Technology, 2015, 75: 197-206.

[15] Dunbar A J, Denlinger E R, Heigel J, et al. Development of experimental method for in situ distortion and temperature measurements during the laser powder bed fusion additive manufacturing process[J]. Additive Manufacturing, 2016, 12: 25-30.

[16] Cheng B, Shrestha S, Chou K. Stress and deformation evaluations of scanning strategy effect in selective lasermelting[J]. Additive Manufacturing, 2016, 12: 240-251.

[17] Gusarov A V, Pavlov M, Smurov I. Residual stresses at laser surface remelting and additive manufacturing[J]. Physics Procedia, 2011, 12: 248-254.

[18] 朱刚, 张晖, 张旺峰, 等. 高强度钛合金管材残余应力测试及对比分析[J]. 稀有金属材料与工程, 2014, 43(10): 2492-2496.

    Zhu G, Zhang H, Zhang W F, et al. Test and analysis of the residual stress in Ti-3Al-2.5V tubes with different processes[J]. Rare Metal Materials and Engineering, 2014, 43(10): 2492-2496.

[19] 杨健, 陈静, 杨海欧, 等. 激光快速成形过程中残余应力分布的实验研究[J]. 稀有金属材料与工程, 2004, 33(12): 1304-1307.

    Yang J, Chen J, Yang H O, et al. Experimental study on residual stress distribution of laser rapid forming process[J]. Rare Metal Materials and Engineering, 2004, 33(12): 1304-1307.

[20] Liu Y, Yang Y Q, Wang D. A study on the residual stress during selective laser melting (SLM) of metallic powder[J]. The International Journal of Advanced Manufacturing Technology, 2016, 87: 647-656.

[21] Yadroitsev I, Yadroitsava I. Evaluation of residual stress in stainless steel 316L and Ti6Al4V samples produced by selective laser melting[J]. Virtual and Physical Prototyping, 2015, 10(2): 67-76.

[22] 蔡春波, 李美艳, 韩彬, 等. 不同预热温度下宽带激光熔覆铁基涂层数值模拟[J]. 应用激光, 2017, 37(1): 66-71.

    Cai C B, Li M Y, Han B, et al. Numerical simulation iron-based cladding coating with wide-band laser at different preheating temperatures[J]. Applied Laser, 2017, 37(1): 66-71.

[23] 罗开玉, 周阳, 鲁金忠, 等. 激光冲击强化对316L不锈钢熔覆层微观结构和性能的影响[J]. 中国激光, 2017, 44(4): 0402005.

    Luo K Y, Zhou Y, Lu J Z, et al. Influence of laser shock peening on microstructure and property of cladding layer of 316L stainless steel[J]. Chinese Journal of Lasers, 2017, 44(4): 0402005.

[24] 杨健, 黄卫东, 陈静, 等. 激光快速成形金属零件的残余应力[J]. 应用激光, 2004, 24(1): 5-8.

    Yang J, Huang W D, Chen J, et al. Residual stress on laser rapid forming metal part[J]. Applied Laser, 2004, 24(1): 5-8.

[25] Mercelis P, Kruth J P. Residual stresses in selective laser sintering and selective laser melting[J]. Rapid Prototyping Journal, 2006, 12(5): 254-265.