Prediction of Melt Pool Dimension and Residual Stress Evolution with Thermodynamically-Consistent Phase Field and Consolidation Models during Re-Melting Process of SLM

Re-melting process has been utilized to mitigate the residual stress levelin the selective laser melting (SLM) process in recent years. However, the complex consolidation mechanism of powder and the different material behavior afterthe first laser melting hinder the direct implementation of the re-melting process.In this work, the effects of re-melting on the temperature and residual stress evolution in the SLM process are investigated using a thermo-mechanically coupledfinite element model. The degree of consolidation is incorporated in the energybalance equation based on the thermodynamically-consistent phase-fieldapproach. The drastic change of material properties due to the variation of temperature and material state is also considered. Using the proposed simulation framework, the single-track scanning is simulated first to predict the melt pooldimension and validate the proposed model with the existing experimental data.The obtained thermal histories reveal that the highest cooling rate is observedat the end of the local solidification time which acts as an important indicatorfor the alleviation of temperature gradient. Then, the scanning of a whole singlelayer that consists of multiple tracks is simulated to observe the stress evolutionwith several re-melting processes. After the full melting of powder material in thefirst scanning process, the increase of residual stress level is observed with one remelting cycle. Moreover, the predicted stress level with the re-melting processshows the variation trend attributable to the accumulated heat in the tracks. Thenumerical issues and the detailed implementation process are also introducedin this paper.