The primary purpose of this study is to analyze the quantity, distribution, morphology, location, and chemical composition of δ-ferrite and Sigma phase formed in the S309 austenitic stainless steel cast billet. The correlation between the microstructural data and the subsequent 2/6-hour homogenization heat treatment will be examined. The key factors affecting the achievement of δ-ferrite morphology blunt/spheroidized or reducing δ-ferrite amount in the homogenization heat treatment will be clarified. Additionally, the mechanism of Sigma precipitation will be explored for optimizing process parameters in order to manufacture high-alloy austenite stainless wire in Walsin Company. Three types of samples were performed on the S309 stainless steel cast billet, including no heat treatment, 2 and 6 hours heat treatment at 1240℃, and three specimens were taken from three locations of the cast billet, i.e., near surface, 1/2 radius, and center for the purpose of comparison, including morphology, volume fraction, hardness, the quantitative concentrations of elements distributed in different phases, and mechanisms of microstructural evolution after high-temperature homogenization treatment. The rationality of different phases was verified using the Schaeffler diagram. The experimental results showed that the Sigma is a hard and brittle phase that can cause cracking during subsequent wire drawing processes. The structure of the Sigma phase was confused with δ-ferrite in EBSD analyses, and their chemical compositions were similar. They were only significant different in hardness. Moreover, the cooling rate of the center and outside of the cast billet were quite different. The microstructure at the radius R was much uniform and fine expecting with a better performance in subsequent wire drawing. The experimental results showed that δ-ferrite is often accompanied by the generation of Sigma. According to the isothermal sections using Thermo-Calc simulation demonstrates the original forging temperature of 1240℃with a two-phase region (BCC+FCC). Still, when the temperature decreased to 1090℃, an FCC single-phase region was achieved providing a better approach for future process improvement.