Aluminium anodes have been widely used to protect marine equipments and offshore structures. Both open circuit potential and galvanic current efficiency are the main requirements for this anode material. In this study, the orthogonal array L18 of Taguchi method was employed to study the effects of alloy elements on both of these characteristics of aluminium anodes, especially galvanic current efficiency. Additionally the differences in both characteristics of those anodes casted by metal and sand molds into different section sizes also have been investigated. The results indicate that the Taguchi method can effectively search the better alloy design for the anodes, and the galvanic current efficiency can be improved by addition of indium or decrease of iron content. The surface of the anode with high galvanic current efficiency is bright and smooth after test because of the occurrence of uniform corrosion. On the other hand, because more iron-containing precipitates developed along the grain boundaries resulting from the high content of iron on deficit of indium and magnesium the surface of the anode with low galvanic current efficiency is dark and rough. In addition, a decrease of solidifcation rate by increasing cast size or using sand mold makes the casted structure change from a coexistance of columnar and equiaxed into equiaxed. This slow solidification rate results in microsegregation of zinc and magnesium in cellular solidification which induces decrease of initial corrosion potential, uniform corrosion and increase of galvanic current efficincy. A high grade aluminium anode with over 96% galvanic current efficiency and -1100mV open circuit potential has been developed by the alloy design and control of solidification condition.