Component Analysis of Oxygen Transport Resistance Increased due to Water Accumulated in a PEFC

Iizuka, Yutaka; Tabe, Yutaka; Kitami, Yuki; Uemura, Suguru

doi:10.1149/1945-7111/aca6ab


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Component Analysis of Oxygen Transport Resistance Increased due to Water Accumulated in a PEFC

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Title:	Component Analysis of Oxygen Transport Resistance Increased due to Water Accumulated in a PEFC
Authors:	Iizuka, Yutaka Browse this author
	Tabe, Yutaka Browse this author →KAKEN DB
	Kitami, Yuki Browse this author
	Uemura, Suguru Browse this author
Issue Date:	22-Dec-2022
Publisher:	The Electrochemical Society (ECS)
Journal Title:	Journal of the electrochemical society
Volume:	169
Issue:	12
Start Page:	124510
Publisher DOI:	10.1149/1945-7111/aca6ab
Abstract:	To increase the power output of polymer electrolyte fuel cells, care in the water management is important. This study extends the limiting current analysis to evaluate the effects of condensed water in the oxygen transport resistance. The resistance increase by water accumulation is separated into pressure-dependent and -independent components by introducing two indices determining the condensed water effects. The components approximately correspond to the transport resistances outside and inside of the catalyst layer (CL) respectively. The results show that both of the components increase from the low index region at 35 degrees C. At 80 degrees C, the increase in the pressure-dependent resistance is suppressed, while the pressure-independent resistance increases gradually as the current density increases. This gradual increase is confirmed in a cell with 1.0 mm wide channels, and the increase is suppressed with 0.3 mm wide channels. The observation of water distributions by a freezing method and cryo-SEM shows that there is ice at the interface between the micro-porous layer and CL only with the wider channel at 80 degrees C. These suggest that poorer contact of the interface under the wider channel allows condensed water to accumulate and expand at the interface, disturbing the oxygen transport to the CL.
Type:	article
URI:	http://hdl.handle.net/2115/87915
Appears in Collections:	工学院・工学研究院 (Graduate School of Engineering / Faculty of Engineering) > 雑誌発表論文等 (Peer-reviewed Journal Articles, etc)

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