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Comparison of hydrogen storage technologies for solar-powered stand-alone power supplies: A photovoltaic system sizing approach

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Authors

Richards, Brendon
Conibeer, Gavin

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Pergamon-Elsevier Ltd

Abstract

This paper compares the performance of three different solar based technologies for a stand-alone power supply (SAPS) using different methods to address the seasonal variability of solar insolation-(i) photovoltaic (PV) panels with battery storage; (ii) PV panels with electrolyser and hydrogen (H2) storage; and (iii) photoelectrolytic (PE) dissociation of water for H2 generation and storage. The system size is determined at three different Australian locations with greatly varying latitudes-Darwin (12{ring operator} S), Melbourne (38{ring operator} S) and Macquarie Island (55{ring operator} S). While the PV/electrolyser system requires fewer PV panels compared to the PV/battery scenario due to the seasonal storage ability of H2, the final number of PV modules is only marginally less at the highest latitude due to the lower energy recovery efficiency of H2 compared to batteries. For the PE technology, an upper limit on the cost of such a system is obtained if it is to be competitive with the existing PV/battery technology.

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Source

International Journal of Hydrogen Energy

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Restricted until

2037-12-31