This thesis focuses on material and component development and system expansion of a lead acid redox flow battery, a promising large scale energy storage device. We aim to reduce the cost of this energy storage device, so as to facilitate its commercialization. Through integration of power grid and the developed energy storage device, we expect to achieve better load leveling and efficient energy utilization. In this research we concentrated on materials development, electrochemical analyses, additives study, and system expansion for a lead acid redox flow battery. With this research effort, the electrodes are found to be able to endure higher current density and cyclability of the battery is extended. Better battery performance is achieved by using graphite electrode as the positive electrode, nickel plate as the negative electrode, hexadecyl trimethyl ammonium hydroxide as the leveling agent to prevent the growing of lead dendrite, and sodium fluoride as the surface smoother to restrain oxygen evolution. In order to further reduce formation of oxygen on the positive electrode, a layer of β-PbO2 is pre-deposited on the positive electrode before cycling. We found this pretreatment extends the cycle life of the battery to 140 times and maintains the energy efficiency at above 50%, which is much better than a reference system with commercialized composite carbon electrode utilized in fuel cell systems.