What question did this study set out to answer?

The research aims to develop a novel mechanical stirring method for improving A356 semi-solid slurry fabrication.

June 1, 2026

Multiphysics simulation and process optimisation for A356 semi-solid slurry fabrication using mechanical stirring with integrated internally cooled cylinders

Puntos clave

The research aims to develop a novel mechanical stirring method for improving A356 semi-solid slurry fabrication.
Established a thermal-flow-phase change multiphysics model
Investigated the effects of stirring rate and cooling block to melt mass ratio
Determined optimal parameters for uniform temperature and solid phase distribution
Optimal parameters found at 10% cooling block to melt mass ratio and 2000 r/min
Achieved uniform temperature and solid phase fraction distribution
Confirmed findings through metallographic characterization and quantitative temperature validation

Resumen

A novel mechanical stirring method integrating homogeneous A356 internally cooled blocks is developed for A356 semi-solid slurry fabrication. A thermal-flow-phase change multiphysics model is established to investigate the effects of stirring rate and cooling block to melt mass ratio on the evolution of multiphysics fields. The optimal parameters (10% cooling block to melt mass ratio, 2000 r/min) yield the most uniform temperature and solid phase fraction distribution, which is confirmed by both metallographic characterisation and quantitative temperature validation.

Multiphysics simulation and process optimisation for A356 semi-solid slurry fabrication using mechanical stirring with integrated internally cooled cylinders

Puntos clave

Resumen

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