Annual performance of a thermochemical solar syngas production plant based on non-stoichiometric CeO2

Annual performance of a thermochemical solar syngas production plant based on non-stoichiometric CeO2

We present, for the first time, a dynamic model of a 1-MWth thermochemical syngas production plant based on non-stoichiometric CeO2. This work aims to provide a simulation tool to assess plant performance under realistic solar conditions. We propose a route to produce a continuous syngas flow rate w...

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Bibliographic Details
Published in:International journal of hydrogen energy Vol. 44; no. 3; pp. 1409 - 1424
Main Authors: de la Calle, Alberto, Bayon, Alicia
Format: Journal Article
Language:English
Published: Elsevier Ltd 15-01-2019
Subjects:
Carbon dioxide
Concentrating solar power
Hydrogen
Modelica
Solar fuels
Thermochemical
Thermochemical
Solar fuels
Modelica
Hydrogen
Concentrating solar power
Carbon dioxide
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Summary:We present, for the first time, a dynamic model of a 1-MWth thermochemical syngas production plant based on non-stoichiometric CeO2. This work aims to provide a simulation tool to assess plant performance under realistic solar conditions. We propose a route to produce a continuous syngas flow rate without requiring syngas storage, an optimisation method to achieve maximum solar-to-fuel efficiency, and a control strategy to maintain plant operation at optimal conditions. An extensive evaluation of the effect of dynamic and off-design performance on plant operation is also discussed for both discontinuous and continuous production of syngas. When a heat-recovery strategy is implemented, a maximum efficiency of 9.24–9.03% in Geraldton (WA) can be obtained, respectively. The thermochemical syngas production plant was also evaluated at another nine locations in Australia. The maximum solar-to-fuel efficiency of 9.68% was obtained in Alice Springs (NT), while in Melbourne (VIC) was 6.14%. These results demonstrate that previous steady-state calculations overestimated the values of the solar-to-fuel efficiency. This is due to an inability to accommodate the effect of essential variables such as: plant size and location, variation of the direct normal irradiance, heliostat field operation, and thermal inertia in solids, gases, reactors and storage tanks. Ultimately, this work demonstrates the need for the development of dynamic and off-design models to evaluate more accurately the potential of solar-driven fuel-production processes. •Dynamic and off-design models of a 1-MWth thermochemical syngas production are presented for the first time.•A route to produce a continuous syngas flow rate without requiring syngas storage is developed.•An optimisation method to maximize the effciency and a control strategy to maintain plant under optimal conditions.•The maximum solar-to-fuel efficiency of 9.68% was obtained in Alice Springs.•The results demonstrate that previous steady-state calculations overestimated the values of the solar-to-fuel efficiency.
ISSN:0360-3199
1879-3487
DOI:10.1016/j.ijhydene.2018.11.076