Comparison of Microstructure and Mechanical Properties of Scalmalloy (R) Produced by Selective Laser Melting and Laser Metal Deposition

The second-generation aluminum-magnesium-scandium (Al-Mg-Sc) alloy, which is often referred to as Scalmalloy (R), has been developed as a high-strength aluminum alloy for selective laser melting (SLM). The high-cooling rates of melt pools during SLM establishes the thermodynamic conditions for a fine-grained crack-free aluminum structure saturated with fine precipitates of the ceramic phase Al-3-Sc. The precipitation allows tensile and fatigue strength of Scalmalloy (R) to exceed those of AlSi10Mg by similar to 70%. Knowledge about properties of other additive manufacturing processes with slower cooling rates is currently not available. In this study, two batches of Scalmalloy (R) processed by SLM and laser metal deposition (LMD) are compared regarding microstructure-induced properties. Microstructural strengthening mechanisms behind enhanced strength and ductility are investigated by scanning electron microscopy (SEM). Fatigue damage mechanisms in low-cycle (LCF) to high-cycle fatigue (HCF) are a subject of study in a combined strategy of experimental and statistical modeling for calculation of Woehler curves in the respective regimes. Modeling efforts are supported by non-destructive defect characterization in an X-ray computed tomography (mu-CT) platform. The investigations show that Scalmalloy (R) specimens produced by LMD are prone to extensive porosity, contrary to SLM specimens, which is translated to similar to 30% lower fatigue strength.