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A single-mold Gasar technique was developed to produce lotus-type porous micro-channel copper with uniform porous structure. In this paper the effect of withdrawal rate on the solid/liquid interface morphology and the corresponding porous structure was systematically investigated, especially the pore morphology, pore growth direction, porosity, and pore diameter of porous copper ingots. In addition, a temperature fi eld simulation was carried out based on Pro Cast software to investigate the shape and movement velocity of the solidifying solid/liquid interface. The experimental results show that the solidifi cation interface changes from convex to planar, then to concave shape with an increase in withdrawal rate. The average porosities of copper ingots are constant and independent of the withdrawal rate. The average pore diameter decreases with an increase in withdrawal rate.
A single-mold Gasar technique was developed to produce lotus-type porous micro-channel copper with uniform porous structure. In this paper, morphology, pore growth of porous copper ingots. In addition, a temperature fi eld simulation was carried out based on Pro Cast software to investigate the shape and movement velocity of the solidifying solid / liquid interface. show that the solidifi cation interface changes from convex to planar, then to concave shape with an increase in withdrawal rate. The average porosities of copper ingots are constant and independent of the withdrawal rate.