Add to ORKGA numerical model to study the growth of dendrites in a pure metal solidification process with an imposed rotational flow field is presented. The micro-scale features of the solidification are modeled by the well-known enthalpy technique. The effect of flow changing the position of the dendrite is captured by the Volume of Fluid (VOF) method. An imposed rigid-body rotational flow is found to gradually transform the dendrite into a globular microstructure. A parametric study is carried out for various angular velocities and the time for merger of dendrite arms is compared with the order estimate obtained from scaling
Bulk and interdendritic flow during solidification alters the microstructure development, potentiall...
In this study, two semi-analytical models of microsegregation were developed to predict the concentr...
AbstractWe propose a scheme for simulation of the solute-driven dendritic solidification which accou...
A numerical model to study the growth of dendrites in a pure metal solidification process with an im...
A coupled methodology for simulating the simultaneous growth and motion of equiaxed dendrites in sol...
A numerical micro-scale model is developed to study the behavior of dendrite growth in presence of m...
We study the growth of a single dendrite from a small initial seed in an undercooled melt in the pre...
We have developed a three-dimensional, adaptive, parallel finite element code to examine solidificat...
Dendrite growth and morphology evolution during solidification have been studied using a phase field...
An anisotropic phase-field model is used to simulate numerically dendritic solidification for a pure...
The presence of bulk and interdendritic flow during solidification can alter the microstructure, pot...
Directional solidification experiments were performed with AlSi6Cu4 and AlSi9Cu4 alloys. The solidif...
Mechanical property of cast metals is strongly dependent on solidification structure, in particular ...
The effects of a constant uniform magnetic field on dendritic solidification were investigated using...
The microstructure of directionally solidified AlSi7Mg0.6 alloys (A357) mainly consists of primary p...
Bulk and interdendritic flow during solidification alters the microstructure development, potentiall...
In this study, two semi-analytical models of microsegregation were developed to predict the concentr...
AbstractWe propose a scheme for simulation of the solute-driven dendritic solidification which accou...
A numerical model to study the growth of dendrites in a pure metal solidification process with an im...
A coupled methodology for simulating the simultaneous growth and motion of equiaxed dendrites in sol...
A numerical micro-scale model is developed to study the behavior of dendrite growth in presence of m...
We study the growth of a single dendrite from a small initial seed in an undercooled melt in the pre...
We have developed a three-dimensional, adaptive, parallel finite element code to examine solidificat...
Dendrite growth and morphology evolution during solidification have been studied using a phase field...
An anisotropic phase-field model is used to simulate numerically dendritic solidification for a pure...
The presence of bulk and interdendritic flow during solidification can alter the microstructure, pot...
Directional solidification experiments were performed with AlSi6Cu4 and AlSi9Cu4 alloys. The solidif...
Mechanical property of cast metals is strongly dependent on solidification structure, in particular ...
The effects of a constant uniform magnetic field on dendritic solidification were investigated using...
The microstructure of directionally solidified AlSi7Mg0.6 alloys (A357) mainly consists of primary p...
Bulk and interdendritic flow during solidification alters the microstructure development, potentiall...
In this study, two semi-analytical models of microsegregation were developed to predict the concentr...
AbstractWe propose a scheme for simulation of the solute-driven dendritic solidification which accou...