The Effects of Electromagnetic Stirring on Microstructure and Properties of γ-TiAl Based Alloys Fabricated by Selective Laser Melting Technique
References:
[1] D. Srivastava, Microstructural characterization of the γ-TiAl alloy
samples fabricated by direct laser fabrication rapid prototype technique.
Bulletin of Materials Science, 2002, p. 619-633.
[2] D. Srivastava,I. Chang, and M. Loretto The effect of process parameters
and heat treatment on the microstructure of direct laser fabricated TiAl
alloy samples. Intermetallics, 2001, p. 1003-1013.
[3] D. Srivastava, et al. The influence of thermal processing route on the
microstructure of some TiAl-based alloys. Intermetallics, 1999, p.
1107-1112.
[4] H.P. Qu, et al. The effects of heat treatment on the microstructure and
mechanical property of laser melting deposition γ-TiAl intermetallic
alloys. Materials and Design, 2010, p. 2201-2210.
[5] A. Menand, H. Zapolsky-Tatarenko,and A. Nrac-Partaix. Atom-probe
investigations of TiAl alloys. Materials Science and Engineering A,
1998, p. 55-64.
[6] S.Z. Zhang, et al. Microstructure and tensile properties of hot fogred high
Nb containing TiAl based alloy with initial near lamellar microstructure.
Materials Science and Engineering A, 2015, p. 16-21.
[7] C. Kenel, et al. MSelective laser melting of an oxide dispersion
strengthened (ODS) γ-TiAl alloy towards production of complex
structures. Materials and Design, 2017.
[8] X.P. Li, J.V. Humbeeck, and J.P. Kruth. Selective laser melting of
weak-textured commercially pure titanium with high strength and
ductility: A study from laser power perspective. Materials and Design,
2017, p. 352-358.
[9] W. Li, et al. SEffect of laser scanning speed on a Ti-45Al-2Cr-5Nb
alloy processed by selective laser melting: Microstructure, phase and
mechanical properties. Journal of Alloys and Compounds, 2016, p.
626-636.
[10] G. Yang, et al. Microstructures of as-Fabricated and Post Heat
Treated Ti-47Al-2Nb-2Cr Alloy Produced by Selective Electron Beam
Melting(SEBM). Rare Metal Materials and Engineering, 2016.
[11] M. Thomas, et al. The prospects for additive manufacturing of bulk TiAl
alloy. High Temperature Technology, 2016, p. 571-577.
[12] J. Gussone, et al. Microstructure of γ-titanium aluminide processed by
selective laser melting at elevated temperatures. Intermetallics, 2015, p.
133-140.
[13] L. Lober, et al. Selective laser melting of a beta-solidifying TNM-B1
titanium aluminide alloy. Journal of Materials Processing Technology,
2014, p. 1852-1860.
[14] Y.Z. Zhao, et al. Microstructural evolution of hot-forged high Nb
containing TiAl alloy during high temperature tension. Materials Science
and Engineering ,2016,p.116-121.
[15] E.T. Zhao, et al. Microstructural control and mechanical properties of
a β-solidified γ-TiAl alloy Ti-46Al-2Nb-1.5V-1Mo-Y. Materials Science
and sengineering:A, 2017, p. 1-6.
[16] H. Jabbar, et al. Microstructures and deformation mechanisms of a G4
TiAl alloy produced by spark plasma sintering. Acta Materialia, 2011,
p. 7574-7585.
[17] F. Appel, J.D.H. Paul, and M. Oehring. Gamma Titanium Aluminide
Alloys (Science and Technology) Applications, Component Assessment,
and Outlook. Wiley-VCH Verlag GmbH and Co. KGaA, 2010.
[18] M.F. Zaeh, and G. Branner. Investigations on residual stresses and
deformations in selective laser melting. Production Engineering.2010,
P. 35-45.
[19] B. Vrancken, et al. Residual stress via the contour method in
compact tension specimens produced via selective laser melting. Scripta
Materialia. 87, p. 29-32.
[20] B. L. Van Belle, G. Vansteenkiste, and J.C. Boyer. Investigation of
residual stresses induced during the selective laser melting process.
Trans Tech Publ. 2013.
[21] P. Mercelis and J.P. Kruth. Residual stresses in selective laser sintering
and selective laser melting. Rapid prototyping journal. 2006, P. 254-265.
[22] J. H Matthew,et al. Effect of electromagnetic stirring on grain refinement
of Al-(4.5%)Cu alloy. Thesis submitted to the University of Alabama.
2013.