Controlling melt flow by nanoparticles to eliminate surface wave induced surface fluctuation

Minglei Qu, Qilin Guo, Luis I. Escano, Jiandong Yuan, S. Mohammad H. Hojjatzadeh, Samuel J. Clark, Kamel Fezzaa, Tao Sun, Lianyi Chen

Research output: Contribution to journalArticlepeer-review

17 Scopus citations

Abstract

The high surface roughness is one of the major challenges encountered in laser metal additive manufacturing (AM) processes, which is closely related to the melt flow behavior. However, how to control the melt flow in laser metal AM processes to improve surface finish is not clear. Here we reveal the effects of nanoparticles on melt flow behavior at every location of melt pool during laser metal AM process for the first time using Al6061 + TiC nanoparticles system and achieve significant improvement of surface finish by using TiC nanoparticles to control the melt flow and damp the surface wave. Based on the in-situ x-ray imaging observation, the surface wave is fully damped after adding TiC nanoparticles, compared with only 56% damping without nanoparticles during LPBF of Al6061. Our in-depth in-situ x-ray imaging analysis and viscosity measurement enable us to identify that nanoparticle-induced increase of viscosity causes the fully damping of the surface wave by (1) increasing the internal fluid friction for more efficient wave amplitude reduction, (2) controlling the melt flow to increase the surface wave number, (3) controlling the melt flow to increase the wave damping time. Furthermore, we also quantified the relative contributions of increasing fluid friction, increasing wave number and increasing damping time to wave damping, which account for 61%, 25% and 14%, respectively. Our research provides the mechanisms and potential method to address the surface finish challenge in laser metal AM processes.

Original languageEnglish
Article number103081
JournalAdditive Manufacturing
Volume59
DOIs
StatePublished - Nov 2022
Externally publishedYes

Funding

This work is supported by US National Science Foundation and University of Wisconsin-Madison Startup Fund . This research used resources of the Advanced Photon Source, a U.S. Department of Energy (DOE) Office of Science User Facility operated for the DOE Office of Science by Argonne National Laboratory under Contract No. DE- AC02-06CH11357 .

FundersFunder number
National Science Foundation
U.S. Department of Energy
Office of Science
Argonne National LaboratoryDE- AC02-06CH11357
University of Wisconsin-Madison

    Keywords

    • Additive manufacturing
    • Laser powder bed fusion
    • Melt flow
    • Nanocomposites
    • Surface roughness
    • Synchrotron x-ray imaging

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