Early Investigations on Electrolyte Mixing Issues in Large Flow Battery Tanks

IF 4.6 4区化学 Q2 ELECTROCHEMISTRY

Batteries Pub Date : 2024-04-17 DOI:10.3390/batteries10040133

Andrea Trovò, Pablo A. Prieto-Díaz, Nicolò Zatta, Francesco Picano, Massimo Guarnieri

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Abstract

Most investigations on flow batteries (FBs) make the assumption of perfectly mixed electrolytes inside the tanks without estimating their likelihood, while specific analyses are missing in the literature. This paper presents a pioneering investigation of the electrolyte flow dynamics inside FB tanks. This study considers the Open Circuit Voltage (OCV) measured at the stack of a 9 kW/27 kWh Vanadium FB with 500 L tanks. Order-of-magnitude estimates of the measured dynamics suggest that differences in densities and viscosities of the active species drive gradients of concentrations with different patterns in the positive and negative tanks and in charge and discharge, affected by current and flow rate, which result in significant deviation from homogeneity, affecting the State of Charge (SoC) of the electrolytes flowed into the stack and thus the FB performance. In particular, stratifications of the inlet electrolytes may appear which are responsible for delays in reaching the outlets, with initial plateau and following step (s) in the SoC at the stack. These events can have a major impact in the performance of industrial FBs with large tanks and suggest that specific tank designs may improve the overall dynamics, calling for further analysis.

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关于大型液流电池槽中电解液混合问题的早期研究

大多数有关液流电池（FB）的研究都假定电池槽内的电解质完全混合，而没有估计其可能性，同时文献中也缺乏具体的分析。本文开创性地研究了液流电池槽内电解质的流动动态。该研究考虑了在带有 500 L 储液罐的 9 kW/27 kWh 钒电池堆上测得的开路电压 (OCV)。对所测动态的数量级估算表明，活性物质密度和粘度的差异导致正负槽以及充放电过程中的浓度梯度形态各异，并受到电流和流速的影响，从而导致严重偏离均匀性，影响流入堆栈的电解质的电荷状态（SoC），进而影响 FB 的性能。特别是，入口电解质可能会出现分层，导致电解质延迟到达出口，电堆的电荷状态（SoC）也会出现最初的高点和随后的阶跃。这些事件会对带有大型槽的工业炉灶的性能产生重大影响，并表明特定的槽设计可能会改善整体动态，因此需要进一步分析。

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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来源期刊

Batteries Energy-Energy Engineering and Power Technology

CiteScore

4.00

自引率

15.00%

发文量

217

审稿时长

7 weeks