Variations among lithium iron cells could lead to earlier cell overcharging or overdischarging in a lithium iron battery module in a high number of cells in serials. Overcharging or overdischarging will inevitably shorten the life cycle of any cell. Cell balance is the main approach to counteract cell inconsistencies. This paper investigated some of the suitable cell balance circuits. Evaluation of the performance and suitability of the selected circuits are thoroughly conducted. To improve some of the shortcomings of the selected balance circuits, we propose a new active and global type balance circuit. This new active balance circuit is basically based on DMOS switching components and specially designed control logics. The single cell with the lowest voltage is compensated by the whole module in series via an isolated buck converter, which converts the module voltage into a suitably low voltage to move electrons from the module to a single cell in a global fashion. Due to the high conversion efficiency of the DC-DC converter and high allowable conduction currents of the switching component DMOSs, the new cell balance circuit show high balance efficiency and high balance current at the same time. The new cell balance system therefore outperforms the passive dissipation balance system. This study conducts experiments on various battery modules with serial numbers from 4 to 24. Performance of the current DMOS based cell balance system is evaluated in details in the current paper.