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http://dx.doi.org/10.5229/JKES.2007.10.4.306

Effect of Clamping Pressure on Surface Properties of Gas Diffusion Layer in PEFCs  

Ahn, Eun-Jin (Fuel Cell Research Center, KIER)
Park, Gu-Gon (Fuel Cell Research Center, KIER)
Yoon, Young-Gi (Fuel Cell Research Center, KIER)
Park, Jin-Soo (Fuel Cell Research Center, KIER)
Lee, Won-Yong (Fuel Cell Research Center, KIER)
Kim, Chang-Soo (Fuel Cell Research Center, KIER)
Publication Information
Journal of the Korean Electrochemical Society / v.10, no.4, 2007 , pp. 306-310 More about this Journal
Abstract
Characteristics of GDL (Gas Diffusion Layer) mainly determine the gas diffusion and water removal in a cell, thereby changing the performance and affecting durability of PEFC. To optimize the water management and understand the two phase flow in a GDL, it is important to study the behaviors of GDL micro structure under the real operating condition. In the clamped condition of cell, the GDL beneath the rib is more compressed than beneath the channel. Many researches on physical, electrochemical, mechanical behaviors of gas diffusion layer has been conducted. However, changes in surface properties under clamped condition have rarely studied. In present study, the morphology of broken connections of carbon fibers and detachment of PTFE coatings on the fibers were shown from the microscopic observations. In addition, changes in wetting properties of GDL by compression were investigated by using XPS and liquid uptake methods. The hydrophobic characteristics of GDL surface beneath the rib of the flow field plate are changed due to the deformation of micro structure.
Keywords
Compression; Wetting property; Gas diffusion layer; Polymer electrolyte fuel cell;
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