Lithium ion cells, including lithium iron phosphate (LFP) cells, possess high energy density and high power density. However due to discrepancies in cell internal resistance and aging process, cell voltage and capacity imbalance are common among cells in series connection or battery module. Lithium ion batteries therefore require an effective battery management system to avoid overcharged or over discharge states resulted from cell imbalance via active protection. Nevertheless, electronic protection strategy reduces effective ranges and might acerbate cell imbalance degree. This study manages cell imbalance problem in both charging and discharging stages respectively based on the same globally active balance module. A two-staged charging and balancing scheme compensates cell inconsistency in the charging stage and evenly charges each cell to a full state without the shortcomings of existing balance methods. A selective balance method in discharging state counterbalances cell imbalance via an external power source injecting balance current to weakest cell in the series. Balance measures in both charging and discharging stages adopted by the current study are aimed at extending ranges for the vehicles served by proposed balance module. The proposed globally active balance module is integrated with a 48 V module BMS and range extension effects are evaluated by experiments with lab instruments and field tests on a 96V prototype tricycle. Test results show the proposed balance method employed both in charging and discharging stages has the advantage of promoting range extension.