An important issue in solar cell technol. is the storage of generated elec. energy for later use. In this respect supercapacitors, as compared to batteries and electrolysis cells, offer the advantage of long-term stability and relatively low energy loss in the charge-discharge cycle. In this study, ruthenium oxide has been selected as charge storage material for coupled (integrated) dye-sensitized solar cell and supercapacitor system hereinafter called as three electrode configuration. Org. D35 dye was used to sensitize TiO2 photoanode and a conducting polymer, poly-(3-hexylthiophene-2,5-diyl) served as hole conductor. The photovoltaic part was sepd. from charge storage material by utilizing a thin layer of vapor evapd. silver. The specific capacitance, power d., coulombic and energy conversion efficiency of the hybrid cell was analyzed. The system was compared to that of our previous reports, i.e. two electrode configuration built of N719 dye modified TiO2 and poly (3,4-ethylenodioxythiophene)/carbon nanotubes composite as charge storage material.