Phase-Field Modeling of Wetting and Balling Dynamics in Powder Bed Fusion Process

TL;DR

This paper develops a phase-field model to study wetting and balling dynamics in powder bed fusion additive manufacturing, revealing how wetting, solidification, and flow instabilities influence surface quality.

Contribution

It introduces a simplified 2D theoretical model to analyze fluid flow, heat transfer, and phase transitions during laser-based powder bed fusion, highlighting key factors affecting balling.

Findings

Wetting and rapid solidification counteract balling effects.

Rayleigh-Plateau instability influences bead formation under certain conditions.

Model provides insights into optimizing process parameters for better surface quality.

Abstract

In a powder bed fusion additive manufacturing (AM) process, the balling effect has a significant impact on the surface quality of the printing parts. Surface wetting helps the bonding between powder and substrate and the inter-particle fusion, whereas the balling effect forms large spheroidal beads around the laser beam and causes voids, discontinuities, and poor surface roughness during the printing process. To better understand the transient dynamics, a theoretical model with a simplified 2D configuration is developed to investigate the underlying fluid flow and heat transfer, phase transition, and interfacial instability along with the laser heating. We demonstrate that the degree of wetting and fast solidification counter-balance the balling effect, and the Rayleigh-Plateau flow instability plays an important role for cases with relatively low substrate wettability and high scanning rate.