The primary purposes of this research are two folds: (1) To investigate the effect of Ni on the mechanical properties (tensile strength, yield strength, elongation, hardness, and low-temperature impact value) and microstructures (nodularity, nodule counts and percent pearlite) of heavy-section ductile iron. Based on the experimental results, multiple regression analyses were performed to correlate the mechanical properties with chemical composition and microstructure. (2) To establish the optimal conditions for the production of ductile cast iron inserts for the storage of the spent nuclear fuels through alloy design and manufacturing process control. Furthermore, in this study, the microstructure that occurred in the castings were analyzed and schemes were proposed to eliminate those abnormities, aiming to conform with the specification of EN-GJS-400-15U (T.S.>370MPa, Y.S.>240MPa and El.>7%) for the ductile cast iron inserts. The results of the first part indicate that the addition of Ni to the ductile cast irons can enhance the mechanical properties, i.e., as tensile strength, yield strength, microhardnesses of both ferrite and pearlite phases. However, the effect is affected by other factors, such as the Si and Mn contents, the pearlite (or ferrite) percentage, and the nodule count. The multiple regression analyses were performed to correlate the impact value at various temperatures with the selected metallurgical parameters (percent Ni, percent pearlite, and nodule counts). The results show that the impact value increase with increasing Ni content, and decreasing the percent pearlite and nodule counts. Regarding the trial tests of the reduced-length small scale ductile cast iron inserts, the results of the first attempt fail to conform with the specification due to the presence of chunky graphite in the microstructure, which causes a significant drop in tensile properties. The presence of chunky graphite can be attributed to the excessive amount of Cerium (Ce), especially in heavy section castings. To counteract the adverse effect of Ce, an appropriate amount of antimony (Sb) was added in the second trial. The results of the second trial of the reduced-length small scale ductile cast iron insert can meet the requirement of the specification. Finally, the reduced-length ductile cast iron insert was poured based upon the optimal casting conditions obtained from the first two trials for the reduced-length small scale ductile cast iron inserts. Again, the results fulfill the specification. In addition, the quality indices of all the specimens obtained from the three ductile cast iron inserts, together with the standard grades ductile cast iron, were calculated and compared. The comparisons in quality index can serve as basis for the evaluation of casting performance.