Resin wafer electrodeionization is different from the other water purification technologies in that its brackish water desalination requires no harmful chemicals use. In addition, it is capable of purifying and producing metal ion containing wastewater. Despite these merits, two drawbacks of the general electrodeionization technology affect its wide application in the field: the high energy consumption and heterogeneization. In this study, the performance efficacy of resin wafer electrodeionization used nickel ion-containing synthetic wastewater under different applied voltages and feed flow rates, and evaluated the energy efficiency, removal ratio, productivity, and recovery ratio. The results showed the nickel ion concentration is 2g/L, the removal ratio can reach 94% or more, and under the operating conditions, the inflow flow rate of 90mL/min and the application voltage of 9V, the concentration after treatment is 0.4 mg/l lower than the regulatory standard. The nickel ion concentration is 3 g/L, and the removal ratio of 70% or more and the productivity of 6 (g/m2/hour) or more are obtained, and the results are found that optimization operating conditions of the high removal ratio and low energy consumption by Design Expert software. In the study of the reaction kinetics of the electrodeionization technology, it was found that the removal rate partially conformed to the first-order reaction kinetics model. Finally, Umberto 5.5. life cycle software was used for preliminary evaluation. The resin wafer electrodeionization technology has lower environmental impact results. Therefore, the advantages of this technology are demonstrated in this present study: (1) this technology with ion exchange resins can be being electrically re-generable in situ; (2) reducing sludge formation; (3) its waiving the use of harmful chemicals; (4) allowing purification and concentration, which is beneficial to recycling. In conclusion, all these merits confirm the strengths of this technology in meeting the needs of contemporary life and its promising role in the field.