Effects of processing parameters on a β-solidifying TiAl alloy fabricated by laser-based additive manufacturing

Danni Huang; Yangping Dong; Hancong Chen; Yinghao Zhou; Ming-Xing Zhang; Ming Yan

doi:10.20517/microstructures.2022.17

Microstructures ›› 2022, Vol. 2 ›› Issue (4) :2022019 DOI: 10.20517/microstructures.2022.17

Research Article

Effects of processing parameters on a β-solidifying TiAl alloy fabricated by laser-based additive manufacturing

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Abstract

β-solidifying TiAl alloys are considered as promising candidate materials for high-temperature structural applications. Laser-based additive manufacturing (LAM) enables the fabrication of components with geometrical complexity in near-net shape, leading to time and feedstock savings. In this study, a gas-atomized Ti-44Al-4Nb-1Mo-1Cr powder is used as a feedstock material for LAM. However, the LAM of TiAl alloys remains a challenge due to serious cracking during the printing process. To minimize the cracking, the optimization of the LAM processing parameters is essential. Hence, the effects of the LAM processing parameters on the cracking susceptibility and microstructure are studied here. Our experimental results show that the cracking susceptibility can be mitigated by increasing the laser power. Accordingly, the microstructure transforms from the dominating α₂ grains to a near-lamellar microstructure with an increment in laser power, leading to a reduction in microhardness, even though it is still higher than that of its as-cast counterparts. It is concluded that changes in the laser power can directly tailor the microstructure, phase composition and microhardness of LAM-fabricated TiAl alloys.

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β-solidifying TiAl alloy / laser-based additive manufacturing / phase / microstructural evolution / microhardness

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Danni Huang, Yangping Dong, Hancong Chen, Yinghao Zhou, Ming-Xing Zhang, Ming Yan. Effects of processing parameters on a β-solidifying TiAl alloy fabricated by laser-based additive manufacturing. Microstructures, 2022, 2(4): 2022019 DOI:10.20517/microstructures.2022.17

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Perrut M,Thomas M.High temperature materials for aerospace applications: Ni-based superalloys and γ-TiAl alloys.Comptes Rendus Physique2018;19:657-71

[2]	Dimiduk DM.Gamma titanium aluminide alloys-an assessment within the competition of aerospace structural materials.Mater Sci Eng1999;263:281-8

[3]	Wu X.Review of alloy and process development of TiAl alloys.Intermetallics2006;14:1114-22

[4]	Niu HZ,Xiao SL.Microstructure evolution and mechanical properties of a novel beta γ-TiAl alloy.Intermetallics2012;31:225-31

[5]	Clemens H.Design, processing, microstructure, properties, and applications of advanced intermetallic TiAl alloys.Adv Eng Mater2013;15:191-215

[6]	Kartavykh A,Piskun N,Gorshenkov M.A promising microstructure/deformability adjustment of β-stabilized γ-TiAl intermetallics.Mater Lett2016;162:180-4

[7]	Clemens H,Kremmer S,Otto A.Design of novel β-solidifying TiAl alloys with adjustable β/B2-phase fraction and excellent hot-workability.Adv Eng Mater2008;10:707-13

[8]	Mayer S,Fischer FD.Intermetallic β-solidifying γ-TiAl based alloys - from fundamental research to application: intermetallic β-solidifying γ-TiAl based alloys.Adv Eng Mater2017;19:1600735

[9]	Kothari K,Wereley NM.Advances in gamma titanium aluminides and their manufacturing techniques.Prog Aerosp Sci2012;55:1-16

[10]	Thomas M,Popoff F.Cast and PM processing development in gamma aluminides.Intermetallics2005;13:944-51

[11]	Sahasrabudhe H,Bandyopadhyay A.Laser-based additive manufacturing processes.Adva Laser Mater Proc2018;507-39

[12]	Li S,Jiang Z.Controlling the columnar-to-equiaxed transition during directed energy deposition of inconel 625.Addit Manufact2022;57:102958

[13]	Narayana P,Kim S.High strength and ductility of electron beam melted β stabilized γ-TiAl alloy at 800 °C.Mater Sci Eng2019;756:41-5

[14]	Wartbichler R,Mayer S.Electron beam melting of a β-solidifying intermetallic titanium aluminide alloy.Adv Eng Mater2019;21:1900800

[15]	Baudana G,Klöden B.Electron beam melting of Ti-48Al-2Nb-0.7Cr-0.3Si: feasibility investigation.Intermetallics2016;73:43-9

[16]	Lin B,Yang Y,Li Z.Anisotropy of microstructure and tensile properties of Ti-48Al-2Cr-2Nb fabricated by electron beam melting.J Alloys Compd2020;830:154684

[17]	Schwerdtfeger J.Selective electron beam melting of Ti-48Al-2Nb-2Cr: microstructure and aluminium loss.Intermetallics2014;49:29-35

[18]	Bhavar PKV,Khot S,Singh R.A review on powder bed fusion technology of metal additive manufacturing, In 4th international conference and exhibition on additive manufacturing technologies-AM-2014, 1-2 Septeber 2014, Banglore, India.

[19]	Sharman A,Ridgway K.Characterisation of titanium aluminide components manufactured by laser metal deposition.Intermetallics2018;93:89-92

[20]	Yan Z,Tang Z.Review on thermal analysis in laser-based additive manufacturing.Opt Laser Technol2018;106:427-41

[21]	Zheng B,Smugeresky J,Lavernia E.Thermal behavior and microstructural evolution during laser deposition with laser-engineered net shaping: part I. numerical calculations.Metall Mat Trans A2008;39:2228-36

[22]	Srivastava D,Loretto MH.The effect of process parameters and heat treatment on the microstructure of direct laser fabricated TiAl alloy samples.Intermetallics2001;9:1003-13

[23]	Balla VK,Mohammad A.Additive manufacturing of γ-TiAl: processing, microstructure, and properties: additive manufacturing of γ-TiAl: processing.Adv Eng Mater2016;18:1208-15

[24]	Li W,Zhou Y.Effect of laser scanning speed on a Ti-45Al-2Cr-5Nb alloy processed by selective laser melting: microstructure, phase and mechanical properties.J Alloys Compd2016;688:626-36

[25]	Löber L,Kühn U,Eckert J.Selective laser melting of a beta-solidifying TNM-B1 titanium aluminide alloy.J Mater Proc Technol2014;214:1852-60

[26]	Biamino S,Ackelid U.Electron beam melting of Ti-48Al-2Cr-2Nb alloy: microstructure and mechanical properties investigation.Intermetallics2011;19:776-81

[27]	Huang SH,Mokasdar A.Additive manufacturing and its societal impact: a literature review.Int J Adv Manuf Technol2013;67:1191-203

[28]	Zhou Y,Wang D.Selective laser melting enabled additive manufacturing of Ti-22Al-25Nb intermetallic: excellent combination of strength and ductility, and unique microstructural features associated.Acta Mater2019;173:117-29

[29]	Brion DA,Pattinson SW.Automated recognition and correction of warp deformation in extrusion additive manufacturing.Addit Manuf2022;56:102838

[30]	Abdulrahman KO,Mahamood RM.Characteristics of laser metal deposited titanium aluminide.Mater Res Express2019;6:046504

[31]	Liu W.Fabrication of carbide-particle-reinforced titanium aluminide-matrix composites by laser-engineered net shaping.Metall Mater Trans A2004;35:1133-40

[32]	Li W,Wen S,Yan C.Crystal orientation, crystallographic texture and phase evolution in the Ti-45Al-2Cr-5Nb alloy processed by selective laser melting.Maters Charact2016;113:125-33

[33]	Xu H,Xing W,Ma Y.Solidification pathway and phase transformation behavior in a beta-solidified gamma-TiAl based alloy.J Mater Sci Technol2019;35:2652-7

[34]	Schwaighofer E,Mayer S.Microstructural design and mechanical properties of a cast and heat-treated intermetallic multi-phase γ-TiAl based alloy.Intermetallics2014;44:128-40

[35]	Ramanujan R.Phase transformations in γ based titanium aluminides.Int Mater Rev2000;45:217-40

[36]	Yang G,Liu Y.Effect of pre-deformation in the β phase field on the microstructure and texture of the α phase in a boron-added β-solidifying TiAl alloy.J Alloys Compd2018;742:304-11

[37]	Hu D,Wu X.On the massive phase transformation regime in TiAl alloys: the alloying effect on massive/lamellar competition.Intermetallics2007;15:327-32

[38]	Sankaran A,Humbert M.Variant selection during nucleation and growth of γ-massive phase in TiAl-based intermetallic alloys.Acta Materialia2009;57:1230-42

[39]	Sun YQ.Surface relief and the displacive transformation to the lamellar microstructure in TiAl.Philosopy Magaz Lett1998;78:297-305

[40]	Chaturvedi M,Richards N.Development of crack-free welds in a TiAl-based alloy.J Mater Proc Technol2001;118:74-8

[41]	Srivastava D,Loretto M.The optimisation of processing parameters and characterisation of microstructure of direct laser fabricated TiAl alloy components.Mater Design2000;21:425-33

[42]	Denquin A.Phase transformation mechanisms involved in two-phase TiAl-based alloys-I. lambellar structure formation.Acta Materialia1996;44:343-52

[43]	Kastenhuber M,Clemens H.Enhancement of creep properties and microstructural stability of intermetallic β-solidifying γ-TiAl based alloys.Intermetallics2015;63:19-26

[44]	Bernal D,Hurtado I.Evolution of lamellar microstructures in a cast TNM alloy modified with boron through single-step heat treatments.Intermetallics2020;124:106842

[45]	Song B,Zhang B,Coddet C.Effects of processing parameters on microstructure and mechanical property of selective laser melted Ti6Al4V.Mater Design2012;35:120-5

[46]	Berteaux O,Thomas M.An experimental assessment of the effects of heat treatment on the microstructure of Ti-47Al-2Cr-2Nb powder compacts.Metall Mat Trans A2008;39:2281-96

[47]	Li M,Yang Y.TiAl/RGO (reduced graphene oxide) bulk composites with refined microstructure and enhanced nanohardness fabricated by selective laser melting (SLM).Mater Charact2018;143:197-205

[48]	Taha AS.Application of the hall-petch relation to microhardness measurements on Al, Cu, Al-MD 105, and Al-Cu alloys.Physica Status Solidi1990;119:455-62