2025 Volume 66 Issue 1 Pages 93-98
Aluminum casting alloys are widely used for various machine parts for the purpose of weight reduction and energy saving. Because of the strong demands for high-stiffness Al alloy to improve their operating accuracy in the fields of precision machinery and robots, we have developed Al-12.5∼14%Si-5∼6%Ni-14∼15%Cu-0.5%Mg alloys with a stiffness of 100 GPa. The solidification sequence of this alloy was investigated to clarify the structural constituents that contribute to its higher stiffness. A series of quenched Al-14%Si-5.5%Ni-15%Cu-0.5%Mg samples were analyzed by optical microscope, EPMA and X-ray diffraction. The results revealed that the alloy solidifies in the order of primary Si, primary-like Ni2Al3, Al(α) + Si eutectic, Al(α) + Ni2Al3 eutectic, Al(α) + CuAl2 eutectic and Al(α) + Al4Cu2Mg7Si8 eutectic. Just after the crystallization of primary-like Ni2Al3, Al(α) hollow and α-dendrites developed around primary Si and Ni2Al3, since these primaries hardly nucleated the above eutectics. The thermodynamic calculation software used provides information on the solidification temperatures and volume fraction for primary Si, Ni2Al3, and other eutectic structures. However, it is unable to predict the appearance of Al(α) hollow and α-dendrites because these are non-equilibrium phenomena. In addition, some discrepancies were observed especially in the final stage of solidification. The evaluation performed by the thermodynamic calculation software using the Scheil’s equation provides details on the final solidification reactions similar to experiment findings.
This Paper was Originally Published in Japanese in J. JFS 95 (2023) 419–425. Some figure captions were modified.
