Study on Microstructure and Properties of Overlap Region of GH3536 Alloy Processed by Multi-Laser Powder Bed Fusion

Yin Xie; Qing Teng; Muyu Shen; Jikang Li; Rui Ma; Jie Bai; Qingsong Wei

doi:10.3788/CJL220975

[1] Hebert R J. Viewpoint: metallurgical aspects of powder bed metal additive manufacturing[J]. Journal of Materials Science, 51, 1165-1175(2016).

[2] 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).

[3] Yang Y Q, Wang D, Wu W H. Research progress of direct manufacturing of metal parts by selective laser melting[J]. Chinese Journal of Lasers, 38, 0601007(2011).

[4] 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).

[5] Zhang D Y, Wang R Z, Zhao J Z et al. Latest advance of laser direct manufacturing of metallic parts[J]. Chinese Journal of Lasers, 37, 18-25(2010).

[6] Khorasani A, Gibson I, Veetil J K et al. A review of technological improvements in laser-based powder bed fusion of metal printers[J]. The International Journal of Advanced Manufacturing Technology, 108, 191-209(2020).

[7] Yap C Y, Chua C K, Dong Z L et al. Review of selective laser melting: materials and applications[J]. Applied Physics Reviews, 2, 041101(2015).

[8] Wei C, Zhang Z Z, Cheng D X et al. An overview of laser-based multiple metallic material additive manufacturing: from macro-to micro-scales[J]. International Journal of Extreme Manufacturing, 3, 47-70(2021).

[9] Fayazfar H, Salarian M, Rogalsky A et al. A critical review of powder-based additive manufacturing of ferrous alloys: process parameters, microstructure and mechanical properties[J]. Materials & Design, 144, 98-128(2018).

[10] She B Z. Fundamental study on multi-beam selective laser melting of TA15 alloy[D], 4-9(2019).

[11] Li S H, Yang J J, Wang Z M. Multi-laser powder bed fusion of Ti-6.5Al-2Zr-Mo-V alloy powder: defect formation mechanism and microstructural evolution[J]. Powder Technology, 384, 100-111(2021).

[12] Yin J, Wang D Z, Wei H L et al. Dual-beam laser-matter interaction at overlap region during multi-laser powder bed fusion manufacturing[J]. Additive Manufacturing, 46, 102178(2021).

[13] Wiesnera A, Schwarzea D. Multi-laser selective laser melting[C], 1-3(2014).

[14] Taheri A M, Dehghani R, Karamooz-Ravari M R et al. Spatter formation in selective laser melting process using multi-laser technology[J]. Materials & Design, 131, 460-469(2017).

[15] Zhang C C, Zhu H H, Hu Z H et al. A comparative study on single-laser and multi-laser selective laser melting AlSi10Mg: defects, microstructure and mechanical properties[J]. Materials Science and Engineering: A, 746, 416-423(2019).

[16] Wei K W, Li F Z, Huang G et al. Multi-laser powder bed fusion of Ti-6Al-4V alloy: defect, microstructure, and mechanical property of overlap region[J]. Materials Science and Engineering: A, 802, 140644(2021).

[17] Xie Y, Teng Q, Sun S S et al. Effect of hot isostatic pressing temperature on microcrack, microstructure and mechanical properties of GH3536 nickel-based superalloy fabricated by selective laser melting[J]. Journal of Mechanical Engineering, 58, 1-9(2022).

[18] Zheng Y L, He Y L, Chen X H et al. Elevated-temperature tensile properties and fracture behavior of GH3536 alloy formed via selective laser melting[J]. Chinese Journal of Lasers, 47, 0802008(2020).

[19] Xiao L R, Tan W, Liu L M et al. Low cycle fatigue behavior of GH3536 alloy formed via laser additive manufacturing[J]. Chinese Journal of Lasers, 48, 2202009(2021).

[20] Sun S S, Teng Q, Xie Y et al. Two-step heat treatment for laser powder bed fusion of a nickel-based superalloy with simultaneously enhanced tensile strength and ductility[J]. Additive Manufacturing, 46, 102168(2021).

[21] Wei K W, Lü M, Zeng X Y et al. Effect of laser remelting on deposition quality, residual stress, microstructure, and mechanical property of selective laser melting processed Ti-5Al-2.5Sn alloy[J]. Materials Characterization, 150, 67-77(2019).

[22] Mumtaz K, Hopkinson N. Selective laser melting of Inconel 625 using pulse shaping[J]. Rapid Prototyping Journal, 16, 248-257(2010).

[23] Song J F, Song Y N, Wang W W et al. Prediction and control on the surface roughness of metal powder using selective laser melting[J]. Chinese Journal of Lasers, 49, 0202008(2022).

[24] Spierings A B, Schneider M, Eggenberger R. Comparison of density measurement techniques for additive manufactured metallic parts[J]. Rapid Prototyping Journal, 17, 380-386(2011).

[25] Zafer Y E, Goel S, Ganvir A et al. Encapsulation of electron beam melting produced alloy 718 to reduce surface connected defects by hot isostatic pressing[J]. Materials, 13, 1226(2020).

[26] Goel S, Ahlfors M, Bahbou F et al. Effect of different post-treatments on the microstructure of EBM-built alloy 718[J]. Journal of Materials Engineering and Performance, 28, 673-680(2019).

[27] Guo S D, Lu L, Wu W H et al. Study on laser remelting process of Inconel718 nickel alloy by selective laser melting[J]. Journal of Shanghai Polytechnic University, 39, 51-59(2022).

[28] Yao C W, Pang X T, Gong Q F et al. Effect of laser remelting on the microstructure and mechanical properties of AerMet100 steel fabricated by laser cladding[J]. Materials Science and Engineering: A, 840, 142951(2022).

[29] Xu J J, Lin X, Zhao Y F et al. HAZ liquation cracking mechanism of IN-738LC superalloy prepared by laser solid forming[J]. Metallurgical and Materials Transactions A, 49, 5118-5136(2018).

[30] Kontis P, Chauvet E, Peng Z R et al. Atomic-scale grain boundary engineering to overcome hot-cracking in additively-manufactured superalloys[J]. Acta Materialia, 177, 209-221(2019).

[31] Sun S S, Teng Q, Cheng T et al. Influence of heat treatment on microstructure evolution of GH3536 superalloy fabricated by selective laser melting[J]. Journal of Mechanical Engineering, 56, 208-218(2020).

[32] Cheng T, Zhang Z Y, Liu Y B et al. Effects of online static magnetic field on anisotropy of microstructure and mechanical properties of GH3536 fabricated by selective laser melting[J]. Chinese Journal of Lasers, 49, 0802015(2022).

[33] Chen H, Cheng T, Li Z W et al. Is high-speed powder spreading really unfavourable for the part quality of laser powder bed fusion additive manufacturing?[J]. Acta Materialia, 231, 117901(2022).

[34] Wang B H, Cheng L, Li D C. Microstructure evolution and nanocrystal formation of TC4 by laser shock peening[J]. Chinese Journal of Lasers, 49, 0802019(2022).

[35] Roberts I A, Wang C J, Esterlein R et al. A three-dimensional finite element analysis of the temperature field during laser melting of metal powders in additive layer manufacturing[J]. International Journal of Machine Tools and Manufacture, 49, 916-923(2009).

[36] Shakerin S, Hadadzadeh A, Amirkhiz B S et al. Additive manufacturing of maraging steel-H13 bimetals using laser powder bed fusion technique[J]. Additive Manufacturing, 29, 100797(2019).

[37] Fitzpatrick M E, Fry A T, Holdway P et al. Determination of residual stresses by X-ray diffraction[EB/OL]. https:∥ eprintspublications.npl.co.uk/2391/1/mgpg52.pdf

[38] Zhang Q X. Research on microstructure and properties of Hastelloy X prepared by selective laser melting[D], 23-28(2021).

[39] Fan P, Pan J T, Ge Y M et al. Finite element analysis of residual stress in TC4/TC11 titanium alloy gradient material produced by laser additive manufacturing[J]. Chinese Journal of Lasers, 48, 1802012(2021).

[40] Ni X Q, Kong D C, Zhang L et al. Effect of process parameters on the mechanical properties of hastelloy X alloy fabricated by selective laser melting[J]. Journal of Materials Engineering and Performance, 28, 5533-5540(2019).