People | Locations | Statistics |
---|---|---|
Ferrari, A. |
| |
Schimpf, Christian |
| |
Dunser, M. |
| |
Thomas, Eric |
| |
Gecse, Zoltan |
| |
Tsrunchev, Peter |
| |
Della Ricca, Giuseppe |
| |
Cios, Grzegorz |
| |
Hohlmann, Marcus |
| |
Dudarev, A. |
| |
Mascagna, V. |
| |
Santimaria, Marco |
| |
Poudyal, Nabin |
| |
Piozzi, Antonella |
| |
Mørtsell, Eva Anne |
| |
Jin, S. |
| |
Noel, Cédric |
| |
Fino, Paolo |
| |
Mailley, Pascal |
| |
Meyer, Ernst |
| |
Zhang, Qi |
| |
Pfattner, Raphael | Brussels |
|
Kooi, Bart J. |
| |
Babuji, Adara |
| |
Pauporte, Thierry |
|
Clemens, H.
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (9/9 displayed)
- 2021On the Formation Mechanism of Banded Microstructures in Electron Beam Melted Ti–48Al–2Cr–2Nb and the Design of Heat Treatments as Remedial Actioncitations
- 2021Designing advanced intermetallic titanium aluminide alloys for additive manufacturingcitations
- 2018Non-equilibrium solid solution of molybdenum and sodium: Atomic scale experimental and first principles studiescitations
- 2013An in-situ high-energy X-ray diffraction study on the hot-deformation behavior of a β-phase containing TiAl alloy
- 2012In Situ Study of Gamma-TiAl Lamellae Formation in Supersaturated alpha(2)-Ti 3 Al Grains
- 2012In-situ synchrotron study of B19 phase formation in an intermetallic $%5Cgamma$-TiAl alloycitations
- 2011Deformation mechanisms in micron-sized PST TiAl compression samples: Experiment and modelcitations
- 2010Can local hot spots induce α 2 /γ lamellae during incomplete massive transformation of γ-TiAl alloys?citations
- 2006Characterization of the behavior under impact loading of a maraging steel strengthened by nano-precipitates
Places of action
article
On the Formation Mechanism of Banded Microstructures in Electron Beam Melted Ti–48Al–2Cr–2Nb and the Design of Heat Treatments as Remedial Action
Abstract
The formation mechanism of banded microstructures of an electron beam melted engineering intermetallic Ti–48Al–2Cr–2Nb alloy, the solidification behavior, and the heat treatment response are investigated via a process parameter study. Scanning electron microscopy, hardness testing, X-ray diffraction, electron probe microanalysis, thermomechanical analysis, electron backscatter diffraction, heat treatments, as well as thermodynamic equilibrium calculation, and numerical simulation were performed. All specimens show near-γ microstructures with low amounts of α2 and traces of βo. Fabrication with an increased energy input leads to an increased Al loss due to evaporation, a lower α-transus temperature, and to a higher hardness. Banded microstructures form due to abnormal grain growth toward the bottom of original melt pools, whereas α2 in Al-depleted zones enables a Zener pinning of the γ-grain boundaries, leading to fine-grained areas. Via numerical simulation, it is shown that increasing the energy input leads to larger maximum temperatures and melt pool sizes, longer times in the liquid state, and more remelting events. Solidification happens via the α-phase and increasing the energy input leads to an alignment of (111)γ in building direction. Furthermore, banded microstructures respond heterogeneously to heat treatments. Heat treatment is introduced based on homogenization via phase transformation to obtain isotropic microstructures.