Clean hydrogen is vital for achieving net-zero emissions and reducing carbon output in society. Anion exchange membrane water electrolysis is gaining momentum in the growing electrolyzer market as a means of producing climate-neutral hydrogen when paired with renewable energy sources. Anion exchange membrane water electrolyzers do not rely on precious metals for electrocatalysts and do not require harsh caustic conditions, making them a safe, scalable, efficient, and potentially affordable method for splitting water. This investigation uses a zero-dimensional numerical model to assess the operation of a market-ready anion exchange membrane water electrolyzer and its capacity to generate clean hydrogen and recover waste heat. A commercial electrolyzer rack with four nominal 2.4 kW el electrolyzer modules is used to collect experimental data and examine multiple process parameters during dynamic operation from start to steady-state conditions. These include stack temperature, pressure, hydrogen production rate, cell voltage, and current density. The observed average electrolysis efficiencies at the stack and system levels, based on the lower heating value of hydrogen, reach 68.4% and 61.5%, respectively. The recoverability of the generated waste heat at the stack level is approximately 79.4% at 46 °C, providing approximately 340 W th of heating power and about 111 W th of exergy heating rate per module. The developed model accurately reproduces the dynamic behavior of electrolyzers, showing strong correlations with experimental data, achieving R 2 values of 0.95 or higher across various time-dependent process parameters, and providing new insights into process simulation for system integration, design, and scaling. • Anion Exchange Membrane Water Electrolyzer: Modeling and Process Simulation • Assessment of experimental data of multiple time-dependent process parameters • Evaluation of electrical efficiencies at the system and stack levels • Quantification of recoverable waste heat generation for system integration • Energy balances, energy flow, and exergy rate analysis of usable waste heat
Wienken et al. (Fri,) studied this question.