Dynamic hydrogen production from PV & wind direct electricity supply – Modeling and techno-economic assessment

Renewable hydrogen from water electrolysis could contribute to the defossilization of various energy intensive sectors but continues to suffer from unfavorable economics. Attention is being paid to the direct supply of renewable electricity to electrolyzers; in particular from photovoltaic (PV) and...

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Bibliographic Details
Published in:International journal of hydrogen energy 2020-11, Vol.45 (55), p.29938-29952
Main Authors: Schnuelle, Christian, Wassermann, Timo, Fuhrlaender, David, Zondervan, Edwin
Format: Article
Language:English
Subjects:
Direct electricity supply
Energy storage
Hydrogen
Modeling and simulation
Water electrolysis
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Summary:Renewable hydrogen from water electrolysis could contribute to the defossilization of various energy intensive sectors but continues to suffer from unfavorable economics. Attention is being paid to the direct supply of renewable electricity to electrolyzers; in particular from photovoltaic (PV) and wind units, whose fixed remuneration period has expired. However, detailed analysis of such operating strategies via modeling and simulation of the dynamic behavior of alkaline electrolysis (AEL) and polymer electrolyte membrane electrolysis (PEMEL) is lacking. In this work, an electrolyzer model is developed for both AEL and PEMEL and analyzed for PV and wind power input data sets from the region of northwest Germany. It is shown that key performance indicators (KPI) such as hydrogen production efficiency, electricity utilization rate, product output and net production costs are highly reliant on the shape of transient power input signals as well as the electrolyzers ability to cope with them. PEMEL technology generally has higher electricity utilization rates than AEL, while AEL still achieves relatively large hydrogen production quantities due to its higher efficiency. Thus, the better operational flexibility of PEMEL cannot generally be considered advantageous in terms of hydrogen production quantities – the same applies for economics. The most competitive hydrogen production costs were 4.33 € per kg for the AEL technology with direct electricity supply from old wind farms, which no longer receive fixed remuneration. •Modeling and simulation of dynamic electrolyzer operation over a period of one year.•KPI's are reliant on transient power profile and electrolyzer operating flexibility.•Cheapest hydrogen production costs are 4.33 €/kg for AEL with onshore wind.
ISSN:0360-3199
1879-3487
DOI:10.1016/j.ijhydene.2020.08.044