Modelling the fluid mechanics in single-flow batteries with an adjacent channel for improved reactant transport

IF 2.8 Q2 MECHANICS
S. Kuperman, R. Ronen, Yoav Matia, Anna Zigelman, M. Suss, A. Gat
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引用次数: 0

Abstract

Abstract Redox flow batteries (RFBs) are an emerging electrochemical technology envisioned towards storage of renewable energy. A promising sub-class of RFBs utilizes single-flow membraneless architectures in an effort to minimize system cost and complexity. To support multiple functions, including reactant separation and fast reactant transport to electrode surfaces, electrolyte flow must be carefully designed and optimized. In this work, we propose adding a secondary channel adjacent to a permeable battery electrode, solving for the flow field and analysing the effects on the reactant concentration boundary layer at the electrode. We find that an adjacent channel with gradually changing thickness leads to a desired nearly uniform flow through the electrode to the adjacent channel. Consequently, the thickness of the concentration boundary layer is significantly reduced, increasing reactant transport to the electrode surface to 140% of the rate of a battery with a constant width adjacent channel, and 350% of the rate with no adjacent channel. Overall, this theory provides insight into the important role of flow physics for this promising sub-class of flow batteries, and can pave the way to improved energy efficiency of such flow batteries.
模拟具有相邻通道的单流电池的流体力学,以改善反应物的传输
氧化还原液流电池(rfb)是一种新兴的电化学技术,用于可再生能源的存储。rfb的一个很有前途的子类利用单流无膜架构,以尽量减少系统成本和复杂性。为了支持多种功能,包括反应物分离和快速反应物传输到电极表面,必须仔细设计和优化电解质流动。在这项工作中,我们建议在渗透率电池电极附近增加一个二次通道,求解流场并分析对电极上反应物浓度边界层的影响。我们发现,一个相邻通道的厚度逐渐变化导致一个理想的几乎均匀的流动通过电极到相邻通道。因此,浓度边界层的厚度显著减小,将反应物传输到电极表面的速率提高到具有等宽相邻通道的电池的140%,没有相邻通道的电池的350%。总的来说,这一理论为流体电池这一有前途的子类提供了流动物理的重要作用,并为提高此类流体电池的能量效率铺平了道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
2.40
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0.00%
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