While casting the A390 hypereutectic aluminum alloy, primary Si particles tend to float to the upper part of the casting due to the difference in specific weight between the primary Si particles and the aluminum bulk liquid, the so-called gravity segregation. As a result, the mechanical properties in different parts of the casting vary. Utilizing the above-mentioned phenomenon of the primary silicon gravity segregation, the present study further enhanced this segregation nature by employing centrifuging casting process to achieve better wear resistance in specific areas of the castings. A centrifuging casting apparatus was constructed which allows the casting to be solidified under the centrifugal force. Under the centrifuging casting condition, the primary silicon particles which have low specific gravity and high hardness tend to move toward the rotational axis and aggregate at the inner portion of the castings. By analyzing the microstructures of different parts of the casting under different pouring temperatures (780, 820℃) and rotational speeds (400 rpm, 450 rpm, …, 650 rpm), we concluded that the degree of primary silicon segregation toward the inner portion of the casting increases with increasing both pouring temperature and rotational speed, and reaches a plateau at 500 rpm. Therefore, a pouring temperature of 820℃and a rotational speed of 500rpm were chosen in this study. In addition, P refinement (for primary Si) and Sr modification (for eutectic Si) were performed to examine the effects of either P refinement or Sr modification on the microstructures of the centrifuging castings at 500 rpm. The microstructure of the A390 alloy without any treatments exhibits somewhat large primary Si particles with an average size of some 98μm, and acicular type eutectic Si of class 1. When the alloy was refined with 0.02%P, the size of the primary Si was substantially reduced to about 61μm, while the eutectic Si remained more or less unchanged. On the other hand, when the alloy was modified by 0.02%Sr, the eutectic Si was improved to class 4-5, while the primary Si was coarsened significantly to about 208μm. Furthermore, the effects of the microstructure features on the wear resistance property of A390 alloy was studied, and regression analyses were performed by correlating the four main dependent variables, namely, the area ratio of the primary Si (X, %), the average primary Si size (Y,μm), degree of eutectic Si modification (Z, class), and hardness (H, HRC) with the wear rate (W, mm3/m). The obtained regression equation is: W = 0.249367 – 0.00225X + 0.000393Y – 0.02212Z – 0.00382H. The regressing equation indicates that the wear rate can be reduced by increasing area ratio of the primary Si, decreasing primary Si size, increasing degree (class) of eutectic Si modification, and enhancing harness.