This paper investigates the tensile behaviour of Laser powder bed fusion (LPBF) processed Ti6Al4 V samples under three build orientations. The effect of microstructural changes from the post-heat treatments (PHTs – 850 °C, 950 °C 1050 °C) was assessed. The microstructural characterization was performed using optical microscopy, X-ray diffraction, and SEM techniques. The tensile tests were performed using a uniaxial universal testing machine (UTM). The fractal dimension analysis was performed on the fractured surfaces using ImageJ software integrated with an open-source MultiFrac plug-in. The PHT at a higher temperature (i.e., 1050 °C) induces a higher amount of β phase than the other PHTs. The PHT performed at 1050 °C exhibited α-Widmanstatten microstructure consisting of elongated β and a small amount of α. The PHT induces an isotropic behaviour in the LPBF-processed samples. However, the ductility of specimens subjected to PHT at 1050 °C showed ∼ 67%, 40%, and 177% improvement under horizontal (0°), inclined (45°), and vertical (90°) orientations than as-printed samples. Further fractal dimension analysis corroborates well with the ductility values of PHT samples. Therefore, the combination of fractography analysis and fractal dimension approach can be a promising methodology towards fractured surface characterization of additively manufactured metal parts.
KumarLJKrishnadas NairCG. Current trends of additive manufacturing in the aerospace industry. In: WimpennyDIPandeyPMKumarLJ (eds) Advances in 3D printing & additive manufacturing technologies. Singapore: Springer, 2017, pp.39–54.
2.
DassAMoridiA. State of the art in directed energy deposition: from additive manufacturing to materials design. Coatings2019; 9: 418.
3.
DebRoyTWeiHLZubackJS, et al.Additive manufacturing of metallic components – process, structure and properties. Prog Mater Sci2018; 92: 112–224.
4.
DudaTRaghavanLV. 3D metal printing technology. IFAC-PapersOnLine2016; 49: 103–110.
5.
VoraHDSanyalS. A comprehensive review: metrology in additive manufacturing and 3D printing technology. Prog Addit Manuf2020; 5: 319–353.
6.
CaoSZouYLimCVS, et al.Review of laser powder bed fusion (LPBF) fabricated Ti6Al4V: process, post-process treatment, microstructure, and property. Light: Adv Manuf2021; 2: 313–332.
7.
LiuSShinYC. Additive manufacturing of Ti6Al4 V alloy: a review. Mater Des2019; 164: 107552.
8.
BarrosRSilvaFJGGouveiaRM, et al.Laser powder bed fusion of Inconel 718: residual stress analysis before and after heat treatment. Metals2019; 9: 1290.
9.
HeYMaYZhangW, et al.Anisotropic tensile and fatigue properties of laser powder bed fusion Ti6Al4 V under high temperature. Eng Fract Mech2022; 276: 108948.
10.
CarrollBEPalmerTABeeseAM. Anisotropic tensile behavior of Ti–6Al–4 V components fabricated with directed energy deposition additive manufacturing. Acta Mater2015; 87: 309–320.
11.
KokYTanXPWangP, et al.Anisotropy and heterogeneity of microstructure and mechanical properties in metal additive manufacturing: a critical review. Mater Des2018; 139: 565–586.
12.
WuM-WNiKYenH-W, et al.Revealing the intensified preferred orientation and factors dominating the anisotropic mechanical properties of laser powder bed fusion Ti-6Al-4 V alloy after heat treatment. J Alloys Compd2023; 949: 169494.
13.
JiaoZHXuRDYuHC, et al.Evaluation on tensile and fatigue crack growth performances of Ti6Al4 V alloy produced by selective laser melting. Procedia Struct Integr2017; 7: 124–132.
14.
SimonelliMTseYYTuckC. Effect of the build orientation on the mechanical properties and fracture modes of SLM Ti–6Al–4 V. Mater Sci Eng A2014; 616: 1–11.
15.
Tarik HasibMOstergaardHELiX, et al.Fatigue crack growth behavior of laser powder bed fusion additive manufactured Ti6Al4V: roles of post heat treatment and build orientation. Int J Fatigue2021; 142: 105955.
16.
SunWMaYHuangW, et al.Effects of build direction on tensile and fatigue performance of selective laser melting Ti6Al4 V titanium alloy. Int J Fatigue2020; 130: 105260.
17.
WangPNaiMLSTanX, et al.Anisotropic mechanical properties in a big-sized Ti6Al4 V plate fabricated by electron beam melting. In: TMS 2016 145th annual meeting & exhibition. Cham: Springer International Publishing, 2016, pp.5–12.
18.
LiuJZhangKGaoX, et al.Effects of the morphology of grain boundary α-phase on the anisotropic deformation behaviors of additive manufactured Ti–6Al–4 V. Mater Des2022; 223: 111150.
19.
QiuCAdkinsNJEAttallahMM. Microstructure and tensile properties of selectively laser-melted and of HIPed laser-melted Ti–6Al–4 V. Mater Sci Eng A2013; 578: 230–239.
20.
AlcistoJEnriquezAGarciaH, et al.Tensile properties and microstructures of laser-formed Ti6Al4 V. J Mater Eng Perform2011; 20: 203–212.
21.
VilaroTColinCBartoutJD. As-fabricated and heat-treated microstructures of the Ti6Al4 V alloy processed by selective laser melting. Metall Mater Trans A2011; 42: 3190–3199.
22.
ZhangX-YFangGLeeflangS, et al.Effect of subtransus heat treatment on the microstructure and mechanical properties of additively manufactured Ti6Al4 V alloy. J Alloys Compd2018; 735: 1562–1575.
23.
ChenBWuZYanT, et al.Experimental study on mechanical properties of laser powder bed fused Ti6Al4 V alloy under post-heat treatment. Eng Fract Mech2022; 261: 108264.
24.
RonnebergTDaviesCMHooperPA. Revealing relationships between porosity, microstructure and mechanical properties of laser powder bed fusion 316L stainless steel through heat treatment. Mater Des2020; 189: 108481.
25.
FerreriNCGhorbanpourSBhowmikS, et al.Effects of build orientation and heat treatment on the evolution of microstructure and mechanical properties of alloy Mar-M-509 fabricated via laser powder bed fusion. Int J Plast2019; 121: 116–133.
26.
MarcheseGPariziaSRashidiM, et al.The role of texturing and microstructure evolution on the tensile behavior of heat-treated Inconel 625 produced via laser powder bed fusion. Mater Sci Eng A2020; 769: 138500.
27.
CarlucciGPatriarcaLDemirAG, et al.Building orientation and heat treatments effect on the pseudoelastic properties of NiTi produced by LPBF. Shap Mem Superelasticity2022; 8: 235–247.
28.
MandelbrotBBPassojaDEPaullayAJ. Fractal character of fracture surfaces of metals. Nature1984; 308: 721–722.
29.
NayakSRMishraJPalaiG. Analysing roughness of surface through fractal dimension: a review. Image Vis Comput2019; 89: 21–34.
30.
WuJJinXMiS, et al.An effective method to compute the box-counting dimension based on the mathematical definition and intervals. Results Eng2020; 6: 100106.
31.
HildersOARamosMPeñaND, et al.Fractal geometry of fracture surfaces of a duplex stainless steel. J Mater Sci2006; 41: 5739–5742.
AhmedTRackHJ. Phase transformations during cooling in α+β titanium alloys. Mater Sci Eng A1998; 243: 206–211.
34.
LütjeringG. Influence of processing on microstructure and mechanical properties of (α+β) titanium alloys. Mater Sci Eng A1998; 243: 32–45.
35.
TorreIGHeckRJTarquisAM. MULTIFRAC: an ImageJ plugin for multiscale characterization of 2D and 3D stack images. SoftwareX2020; 12: 100574.
36.
PathaniaASubramaniyanAKNageshaBK. Influence of post-heat treatments on microstructural and mechanical properties of LPBF-processed Ti6Al4 V alloy. Prog Addit ManufEpub ahead of print 14 May 2022; 7: 1323–1343
37.
PedersonRBabushkinOSkystedtF, et al.Use of high temperature X-ray diffractometry to study phase transitions and thermal expansion properties in Ti6Al4 V. Mater Sci Technol2003; 19: 1533–1538.
38.
KatzarovIMalinovSShaW. Finite element modeling of the morphology of b to a phase transformation in Ti6Al4 V alloy. Metall Mater Trans A2002; 33: 1027–1040.
39.
YanXYinSChenC, et al.Effect of heat treatment on the phase transformation and mechanical properties of Ti6Al4 V fabricated by selective laser melting. J Alloys Compd2018; 764: 1056–1071.
40.
HeBWuWZhangL, et al.Microstructural characteristic and mechanical property of Ti6Al4 V alloy fabricated by selective laser melting. Vacuum2018; 150: 79–83.
41.
Galindo-FernándezMAMumtazKRivera-Díaz-del-CastilloPEJ, et al.A microstructure sensitive model for deformation of Ti6Al4 V describing Cast-and-Wrought and Additive Manufacturing morphologies. Mater Des2018; 160: 350–362.
42.
LiKMLiuYJLiuXC, et al.Simultaneous strength-ductility enhancement in as-cast Ti6Al4 V alloy by trace Ce. Mater Des2022; 215: 110491.
43.
SimonelliMTseYYTuckC. The formation of α + β microstructure in as-fabricated selective laser melting of Ti–6Al–4 V. J Mater Res2014; 29: 2028–2035.
44.
XuXNashP. Sintering mechanisms of Armstrong prealloyed Ti–6Al–4 V powders. Mater Sci Eng A2014; 607: 409–416.
45.
ChenCGuDDaiD, et al.Laser additive manufacturing of layered TiB2/Ti6Al4 V multi-material parts: understanding thermal behavior evolution. Opt Laser Technol2019; 119: 105666.
46.
EdwardsPRamuluM. Fatigue performance evaluation of selective laser melted Ti–6Al–4 V. Mater Sci Eng A2014; 598: 327–337.
47.
Dareh BaghiANafisiSHashemiR, et al.Experimental realisation of build orientation effects on the mechanical properties of truly as-built Ti6Al4 V SLM parts. J Manuf Process2021; 64: 140–152.
48.
AgiusDKourousisKIWallbrinkC, et al.Cyclic plasticity and microstructure of as-built SLM Ti6Al4V: the effect of build orientation. Mater Sci Eng A2017; 701: 85–100.
49.
RafiHKStarrTLStuckerBE. A comparison of the tensile, fatigue, and fracture behavior of Ti–6Al–4 V and 15-5 PH stainless steel parts made by selective laser melting. Int J Adv Manuf Technol2013; 69: 1299–1309.
50.
MertensAReginsterSPaydasH, et al.Mechanical properties of alloy Ti–6Al–4 V and of stainless steel 316L processed by selective laser melting: influence of out-of-equilibrium microstructures. Powder Metall2014; 57: 184–189.
51.
MurrLEQuinonesSAGaytanSM, et al.Microstructure and mechanical behavior of Ti–6Al–4 V produced by rapid-layer manufacturing, for biomedical applications. J Mech Behav Biomed Mater2009; 2: 20–32.
52.
LeudersSThöneMRiemerA, et al.On the mechanical behaviour of titanium alloy TiAl6V4 manufactured by selective laser melting: fatigue resistance and crack growth performance. Int J Fatigue2013; 48: 300–307.
53.
XuWBrandtMSunS, et al.Additive manufacturing of strong and ductile Ti–6Al–4 V by selective laser melting via in situ martensite decomposition. Acta Mater2015; 85: 74–84.
54.
VranckenBThijsLKruthJ-P, et al.Heat treatment of Ti6Al4 V produced by selective laser melting: microstructure and mechanical properties. J Alloys Compd2012; 541: 177–185.
55.
DasJLinkeB. Evaluation and systematic selection of significant multi-scale surface roughness parameters (SRPs) as process monitoring index. J Mater Process Technol2017; 244: 157–165.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
