Browsing by Subject "laser melting powder bed fusion"
Now showing 1 - 2 of 2
- Results Per Page
- Sort Options
Item Laser Powder Bed Fusion Fabricated and Characterization of Crack-Free Aluminum Alloy 6061 Using In-Process Powder Bed Induction Heating(University of Texas at Austin, 2017) Uddin, Syed Zia; Espalin, David; Mireles, Jorge; Morton, Philip; Terrazas, Cesar; Collins, Shane; Murr, Lawrence E.; Wicker, RyanA parameter development study for pre-alloyed aluminum alloy 6061 (AA6061) was carried out using an open-architecture powder bed laser melting (LM) technology with capabilities of induction heating for raising the powder bed temperature. Cube specimens (10 mm on each side) were used for parameter development with variation in laser power and scanning speed, whereas layer thickness, hatch spacing and powder bed temperature were empirically determined. While higher relative densities were achieved when using induction heating (as compared to specimens fabricated without induction heating), the key difference in the experiments was the ability to fabricate specimens without cracks when using induction heating. That is, crack-free AA6061 parts were fabricated with the highest relative density measured of 98.7%. Micrographs of specimens fabricated with the induction heating demonstrated the lack of melt pool and melt track features, which are normally only achieved with post-processing heat treatments. This research was important in its approach of using high temperature heating of the powder bed prior to laser scanning to produce crack-free AA6061 parts. Further investigations are ongoing to explore and optimize this fabrication process.Item Material Characterization for Lightweight Thin Wall Structures Using Laser Powder Bed Fusion Additive Manufacturing(2018) Dobson, Sean; Wu, Yan; Yang, LiIn this study the geometry-process-material characteristics of the Ti6Al4V thin wall features fabricated by the EOS M270 laser melting powder bed fusion (LM-PBF) additive manufacturing (AM) was investigated. Samples with varying wall thickness, orientation, scanning speeds and laser power were fabricated and analyzed. The dimensional accuracies, microstructural characteristics and mechanical properties of the samples were evaluated experimentally. The results clearly indicated the significant coupling effects between the geometry design of these thin wall features and their material properties, which is critical to the design and manufacturing of many AM lightweight structures. By identifying significant design and process parameters for the thin wall structures, this study will enable further investigations of the integrated design theories for the AM lightweight structures.