Investigation of the effect of ion transition type on performance in solid oxide fuel cells fueled hydrogen and coal gas

Investigation of the effect of ion transition type on performance in solid oxide fuel cells fueled hydrogen and coal gas

Renewable energy will be a panacea for environmental difficulties due to the extensive usage of carbon-rich fuels as a main source of energy. As a result, hydrogen-fueled solid oxide fuel cell is a revolutionary clean technology that has a great contribution in solving the current energy and environ...

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Bibliographic Details
Published in:International journal of hydrogen energy Vol. 47; no. 5; pp. 3409 - 3415
Main Authors: Kumuk, Berre, Asmare Alemu, Molla, Ilbas, Mustafa
Format: Journal Article
Language:English
Published: Elsevier Ltd 15-01-2022
Subjects:
Numerical analysis
Oxygen-conducting
Proton-conducting
Solid oxide fuel cell
Oxygen-conducting
SOFC, Solid oxide fuel cell
Numerical analysis
ES-P-SOFC, Electrolyte Supported-Planar-Solid oxide fuel cell
AS-SOFC, Anode supported solid oxide fuel cell
SOFC–O, Oxygen conducting solid oxide fuel cell
Proton-conducting
Solid oxide fuel cell
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Summary:Renewable energy will be a panacea for environmental difficulties due to the extensive usage of carbon-rich fuels as a main source of energy. As a result, hydrogen-fueled solid oxide fuel cell is a revolutionary clean technology that has a great contribution in solving the current energy and environmental-related challenges. Thus, a 3D model of hydrogen and coal gases fueled solid oxide fuel cell (H2–SOFC) using different electrolytes has been developed and simulated using COMSOL commercial software to explore the performance of electrolyte supported SOFC. The performance of the developed model has been studied and characterized using different differential equations. Accordingly, it has been found that the performance of hydrogen-fueled oxide ion conducting electrolytes (SOFC–O) is lower than that of protonic conducting one (SOFC–H) at 800 °C. Furthermore, a numerical simulation has been conducted to investigate the result of temperature changes on SOFC performance at 400 °C, 600 °C, and 800 °C for proton-conducting SOFC and 800 °C and 1000 °C for oxygen-conducting SOFC. It has been demonstrated that SOFC–O shows a better performance at high temperatures compared with SOFC–H while SOFC–H can be an agreeable selection at medium temperatures. Therefore, this study reveals that the temperature augments the performance of both electrolytes, yet at higher working temperatures SOFC–H becomes more advantageous than SOFC–O to use hydrogen and coal gas as a primary fuel. Besides, the effect of channel height was also analyzed numerically and the finding disclosed that decreasing the channel height emerges in a curtly current path. Thus, it can be reasoned out that the performance of SOFC decreases when the channel height is increased. •The performance of a 3D model of ES-P-SOFC has been investigated.•SOFC–H and SOFC–O are running with hydrogen feed are better than water gas.•Both electrolytes types have better performance when the temperature is increased.•The working temperature and channel height have a strong impact on cell performance.
ISSN:0360-3199
1879-3487
DOI:10.1016/j.ijhydene.2021.10.212