文化大學機構典藏 CCUR:Item 987654321/41855
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    Please use this identifier to cite or link to this item: https://irlib.pccu.edu.tw/handle/987654321/41855


    Title: Experimental characterization of high-temperature proton exchange membrane fuel cells under CO- and methane-containing hydrogen-rich gases
    Authors: Chen, CY (Chen, Chen-Yu)
    Huang, KP (Huang, Keng-Pin)
    Contributors: 機械工程系暨機械工程學系數位機電研究所
    Keywords: POLYMER ELECTROLYTE MEMBRANE
    PT-RU ANODE
    OPERATING TEMPERATURE
    CARBON-MONOXIDE
    TRANSIENT-BEHAVIOR
    IMPEDANCE SPECTRA
    DILUTED HYDROGEN
    PEMFC STACK
    POLYBENZIMIDAZOLES
    PERFORMANCE
    Date: 2018-08
    Issue Date: 2019-01-17 11:50:08 (UTC+8)
    Abstract: The objective of this work is to study a high-temperature proton exchange membrane fuel cell using CO- and methane-containing hydrogen-rich gases because of the advantages of high operating temperature and the growing feasibility of using natural gases or methane as the sources of hydrogen-rich reformate gases. According to the experimental results, it is suggested that the fuel cell be operated at 180 A degrees C under reformate gases with high CO concentrations to avoid not only a significant decrease in performance, but also severe potential oscillations. In addition, the anode oxidation reaction is more sensitive to the temperature than the cathode reduction reaction under CO-containing H-2. On the other hand, the effects of methane in the reformate gas on the fuel cell can be ignored because the existence of methane causes neither a decrease in the cell performance nor an increase in the anodic charge transfer resistance. Thus, the CO concentration and operating temperature are still the two dominant parameters with regard to the cell performance under CO- and methane-containing hydrogen-rich gases.

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