Numerical modeling and analysis of the effect of pressure on the performance of an alkaline water electrolysis system

Hydrogen is considered a promising green energy carrier due to its long storage period and zero harmful emissions. The green hydrogen produced by water electrolysis using renewable energy is indispensable for expanding the renewable energy grid and establishing a clean energy society. As renewable power sources are widely deployed, hydrogen can be utilized to connect the energy demand section with the energy supply section. To transport hydrogen to demand sites, one of the most common commercial methods is hydrogen compression. Notably, high-pressure water electrolysis does not need to additionally compress hydrogen, which can significantly diminish the cost of hydrogen production. In this study, to evaluate the effect of the operating pressure on the performance of an alkaline water electrolysis (AWE) system, a numerical model of the AWE system was developed using Aspen Plus (R). The AWE system is comprised of the AWE stack, water pumps, heat exchangers, separator, condenser, and electric heat pump (EHP) system. The AWE stack model is validated by comparing the current-voltage polarization curve with experimental data. Simulation results show that an appropriate pressure makes the system more efficient due to decreasing the power consumption of the balance of plant (BOP). Furthermore, high-pressure water electrolysis has a large advantage for obtaining high-purity hydrogen (over 99.9%) without using a water adsorption device.

Automated summary

Hydrogen is seen as a promising green energy carrier due to its long storage period and zero harmful emissions, and green hydrogen produced by water electrolysis using renewable energy is essential for expanding the renewable energy grid and establishing a clean energy society. Operating pressure plays a significant role in the performance of the alkaline water electrolysis system, with simulation results showing that high-pressure water electrolysis is advantageous for obtaining high-purity hydrogen efficiently.