دانلود مقاله ISI انگلیسی شماره 55121
ترجمه فارسی عنوان مقاله

استراتژی های طراحی تئوریک سلول سوختی غشای دو قطبی با افزایش رفتار خود رطوبت سازی

عنوان انگلیسی
Theoretical design strategies of bipolar membrane fuel cell with enhanced self-humidification behavior
کد مقاله سال انتشار تعداد صفحات مقاله انگلیسی
55121 2016 10 صفحه PDF
منبع

Publisher : Elsevier - Science Direct (الزویر - ساینس دایرکت)

Journal : Journal of Power Sources, Volume 307, 1 March 2016, Pages 358–367

ترجمه کلمات کلیدی
پیل سوختی غشای دوقطبی ؛ خود رطوبت سازی؛ مدیریت آب؛ غشاء الکترولیت پلیمری؛ غشاء تبادل آنیون ؛ مدل ریاضی
کلمات کلیدی انگلیسی
Bipolar membrane fuel cell; Self-humidification; Water management; Polymer electrolyte membrane; Anion exchange membrane; Mathematical model
پیش نمایش مقاله
پیش نمایش مقاله  استراتژی های طراحی تئوریک سلول سوختی غشای دو قطبی با افزایش رفتار خود رطوبت سازی

چکیده انگلیسی

The bipolar membrane fuel cells (BPMFCs), which have a unique acid-alkaline jointed membrane electrode assembly (MEA) structure, have demonstrated their great potential for self-humidification during operation. Although the self-humidification ability of such bipolar membranes (BPMs) has recently been validated by a one-dimensional BPM model, the transport mechanism and the formation of self-humidification in the MEAs are not well understood. In the present study, a two-dimensional cross-channel MEA model is developed to elucidate the mechanisms and enhancement of water transport on self-humidification with comprehensive consideration of the three electrochemical reaction zones. The water–formation interface model has been successfully investigated by theoretical and experimental interface reaction kinetics, streamlines of water flux present the formation process and mechanism of self-humidification. A critical current (voltage) value, beyond which self-humidification is initiated, is identified. It is also found that such critical current (voltage) can be adjusted by changing the membrane thickness and the water uptake property of the ionomer. It is concluded that fabricating BPMs with proper membrane thickness and water uptake property are effective strategies to enhance the water management and cell performance in BPMFCs.