Abstract:
Water electrolysis has been used to produce green hydrogen, for which identifying optimum operation parameters is crucial to
improve its energy efficiency and energy consumption. This paper used a commercial proton exchange membrane (PEM) water
electrolyser stack (180 W) to demonstrate the correlation between operating current change, temperature, and water flow rate and
their impact on the thermal and electrical performance of the stack. It was found that the current control regime and temperature
control can offset the voltage ageing in a long-term operating electrolyser with no negative impact on the H2 production rate. For a
controlled decreasing current path, in the medium range of operating current, the stack’s energy efficiency was improved by 5%,
and 3.7% specific energy consumption can be saved comparing to the standard operation (57.8 kWh·kg−1
H2). The results provide
insights into the potential optimisation in operation conditions to further increase cell energy efficiency and reduce energy
consumption. This new finding sheds light on developing an energy- and cost-saving operating method for long-term green
hydrogen production via water electrolysis.
