Abstract
In the last decade, additive manufacturing technologies like laser powder bed fusion (LPBF) have emerged strongly. However, the process characteristics involving layer-wise build-up of the part and the occurring high, directional thermal gradient result in significant changes of the microstructure and the related properties compared to traditionally fabricated materials. This study presents the influence of the build direction (BD) on the microstructure and resulting properties of a novel austenitic Fe-30Mn-1C-0.02S alloy processed via LPBF. The fabricated samples display a {011} texture in BD which was detected by electron backscatter diffraction. Furthermore, isolated binding defects could be observed between the layers. Quasi-static tensile and compression tests displayed that the yield, ultimate tensile as well as the compressive yield strength are significantly higher for samples which were built with their longitudinal axis perpendicular to BD compared to their parallel counterparts. This was predominantly ascribed to the less severe effects of the sharp-edged binding defects loaded perpendicular to BD. Additionally, a change of the Young’s modulus in dependence of BD could be demonstrated, which is explained by the respective texture. Potentiodynamic polarization tests conducted in a simulated body fluid revealed only slight differences of the corrosion properties in dependence of the build design.
Highlights
Additive manufacturing (AM) opens up new possibilities to fabricate load-adapted implants with a high freedom of design out of metallic biomaterials
This study presents the influence of the build direction (BD) on the microstructure and resulting properties of a novel austenitic Fe-30Mn-1C-0.02S alloy processed via laser powder bed fusion (LPBF)
The microstructure of the LPBF-processed FeMnCS alloy exclusively consists of face centered cubic austenite phase, in which the elements are homogenously distributed
Summary
Additive manufacturing (AM) opens up new possibilities to fabricate load-adapted implants with a high freedom of design out of metallic biomaterials. This is possible due to the layer-wise manufacturing, which enables function integration [1,2,3,4]. Specific non-equilibrium microstructural effects can be realized, e.g., grain refinement, extended solid solubility promoting the reduction of phase segregation size and the fraction or even full suppression of secondary phase precipitation. Such effects can be very beneficial for the resulting mechanical and chemical properties. Together with the specific defects of the layer-by-layer manufacturing such as inclusions, porosity and residual stresses, this may result in multi-scale microstructural anisotropy characteristics
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