Förner A, Vollhüter J, Krapf A, Jamjoom AFA, Hausmann D, Wahlmann B, Fu Z, Körner C, Neumeier S, Göken M (2023)
Publication Type: Journal article
Publication year: 2023
By increasing the density of interfaces in NiAl–CrMo in situ composites, the mechanical properties can be significantly improved compared to conventionally cast material. The refined microstructure is achieved by manufacturing through electron beam powder bed fusion (PBF-EB). By varying the process parameters, an equiaxed or columnar cell morphology can be obtained, exhibiting a plate-like or an interconnected network of the (Cr,Mo) reinforcement phase which is embedded in a NiAl matrix. The microstructure of the different cell morphologies is investigated in detail using scanning electron microscope, transmission electron microscopy, and atom probe tomography. For both morphologies, the mechanical properties at elevated temperatures are analyzed by compression and creep experiments parallel and perpendicular to the building direction. In comparison to cast NiAl and NiAl–(Cr, Mo), the yield strength of the PBF-EB fabricated specimens is significantly improved at temperatures up to 1,027 °C. While the columnar morphology exhibits the best improved mechanical properties at high temperatures, the equiaxial morphology shows nearly ideal isotropic mechanical behavior, which is a substantial advantage over directionally solidified material.
APA:
Förner, A., Vollhüter, J., Krapf, A., Jamjoom, A.F.A., Hausmann, D., Wahlmann, B.,... Göken, M. (2023). Using Selective Electron Beam Melting to Enhance the High-Temperature Strength and Creep Resistance of NiAl–28Cr–6Mo In Situ Composites. Advanced Engineering Materials. https://doi.org/10.1002/adem.202300407
MLA:
Förner, Andreas, et al. "Using Selective Electron Beam Melting to Enhance the High-Temperature Strength and Creep Resistance of NiAl–28Cr–6Mo In Situ Composites." Advanced Engineering Materials (2023).
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