Thermal behavior of coated powder during directed energy deposition (DED)

Sen Jiang, Baolong Zheng, David Svetlizky, Lorenzo Valdevit, Noam Eliaz, Enrique J. Lavernia, Julie M. Schoenung*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

Abstract

In powder-based additive manufacturing (AM), the quality of the feedstock material is critical for obtaining enhanced mechanical properties. Recently, the application of coated powders during directed energy deposition (DED) has been prompted by the goal of fabricating composite and functional materials in-situ. The complex temperature and momentum fields established during DED render direct experimental characterization of coated powder behavior challenging. To address this challenge, this study reports on the thermal behavior of coated powders during interactions with the molten pool by constructing three-dimensional heat transfer and phase distribution models using the finite elements method (FEM). Transient temperature and phase distributions were calculated for coated and uncoated stainless steel 316L and ZnAl powders under various particle size, coating thickness, molten pool temperature, and coating material conditions. Particle residence time values were extracted from the calculations, defined as time spent by the particle before a phase change. The results show large variations in particle residence time (85 μs to 2670 μs for stainless steel 316L particles, and 48 μs to infinity for ZnAl particles) as a function of the variables considered, especially the thermal diffusivity of the coating materials, thereby highlighting the potential value of coatings as an additional design parameter in DED. Significant increases in particle residence time for both stainless steel 316L and ZnAl particles were found when contact angle increases from 0° (submergence regime) to 180° (floating regime).

Original languageEnglish
Article number102235
JournalMaterialia
Volume38
DOIs
StatePublished - Dec 2024

Keywords

  • Coated powder
  • Directed energy deposition
  • Heat transfer and phase distribution modeling
  • Particle residence time

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