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Laser powder bed fusion: Defect type influences critical porosity re-growth during reheating after hot isostatic pressing

Jakob Schröder, Tobias Fritsch, Bruno Ferrari, Mika León Altmann, Giovanni Bruno, Anastasiya Toenjes

2025Journal of Materials Processing Technology13 citationsDOIOpen Access PDF

Abstract

Despite the remarkable product design flexibility offered by additive manufacturing (AM) techniques, such as laser powder bed fusion, AM processes are susceptible to the formation of defects. In this context, the control of process parameters and the application of post-processing treatments, such as hot isostatic pressing (HIP), are of paramount importance to achieve the desired mechanical properties. The present study investigates the effectiveness of HIP as a function of process parameters in laser powder bed fused Ti-6V-4Al (PBF-LB/Ti64) using X-ray computed tomography. The process parameters are modified to obtain reference samples with low porosity, lack of fusion defects, or keyhole porosity. In all instances, subsurface keyhole porosity was observed in the as-built parts. Moreover, it was found that the efficacy of pore closure is dependent on the specific defect type. In the case of low porosity and keyhole pores, HIP resulted in effective closure. Conversely, larger lack of fusion defects were not closed due to their interconnectivity and the entrapment of argon gas. Subsequent heat treatments above the β-transus temperature allowed the investigation of the impact of defect type on porosity re-growth. For the first time, we reveal that lack of fusion defects are affected by considerable pore re-growth during post-HIP heat treatments of PBF-LB/Ti64. Such phenomenon is driven by the increasing internal pore pressure and local creep deformation at high temperatures. In contrast, re-growth is limited in samples with low porosity or keyhole pores. • Defect control in laser powder bed fused Ti-6V-4Al by process parameter variation. • Densification during hot isostatic pressing depends on defect type. • Verification by correlating metallography and X-ray computed tomography. • Unraveling pore regrowth during reheating up to 1050 °C after hot isostatic pressing

Topics & Concepts

Hot isostatic pressingMaterials sciencePorosityFusionMetallurgyPressingComposite materialMicrostructureLinguisticsPhilosophyAdditive Manufacturing Materials and ProcessesAdditive Manufacturing and 3D Printing TechnologiesHigh Entropy Alloys Studies