Modeling of interdendritic strain and macrosegregation for dendritic solidification processes: Part I. Theory and experiments

Abstract

In the first part of this two-part article, mathematical models have been developed to characterize temperature, interdendritic stain, and segregation distributions during dendritic solidification. This aims to predict the effect of interdendric strain associated with sudden changes in the cooling conditions on the macrosegregation distributions, i.e., the combined effect of interdendric strain and macrosegregation on the dendritic structure. These theoretical models were verified on a laboratory scale. Four laboratory ingots of 0.53 and 0.9 wt pct C steels were cast horizontally and unidirectionally in a static mold under cooling conditions designed to approximate those in the continuous-casting process. Thermocouples recorded temperatures in the ingot at different locations from copper chill. The ingots were examined for macro-microstructure, and the extent of carbon macrosegregation was determined by wet chemical analysis. The experimental results indicate that static mold with sudden changes in the cooling conditions on the copper chill provides an approximately similar structure and macrosegregation profiles to those in a continuous-casting process. It is concluded that these cooling conditions have a significant effect on the fluctuated macrosegregation phenomenon. The sudden drop in the heat flux on the chill causes a positive segregation, whereas a sudden increase in heat flux results in a negative segregation. Also, the metallographic examination shows that there is high inelastic deformation of the dendrites due to the sudden drop in heat flux on the chill.