Sea Water Activated Magnesium-Air Reserve Batteries: Calculation of Specific Energy and Energy Density for Various Cell Geometries

DRC Sustainable Future: Journal of Environment, Agriculture, and Energy Pub Date : 2019-12-27 DOI:10.37281/drcsf/1.1.1

D. Lowy, B. Mátyás

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引用次数: 5

Abstract

We address sustainable energy issues via scrutinizing magnesium-air reserve batteries. Such energy storage systems can hold their energy indefinitely, releasing it on demand, in emergency situations. Main advantage of water-activated batteries is that their electrolyte is supplied by the environment, where they get deployed, hence, only light weight electrodes and battery frames should be transported, rather than the significantly heavier aqueous electrolyte. Recent literature in the field is reviewed. One merit of this account is that recently, battery storage has become an effective way to increase share of renewables in photovoltaic energy systems utilized in farming. While the specific energy of reserve batteries can be determined unequivocally, their energy density calculation needs a clear definition of the considered battery volume. Therefore, this paper proposes a new modality of evaluating specific energy and energy density of seawater-activated metal-air reserve batteries for prismatic and cylindrical geometries, respectively.

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海水活化镁-空气储备电池:计算比能量和能量密度为各种电池的几何形状

我们通过仔细研究镁空气储备电池来解决可持续能源问题。这种储能系统可以无限期地储存能量，在紧急情况下根据需要释放能量。水活性电池的主要优点是其电解质由环境提供，因此，只需要运输重量较轻的电极和电池框架，而不需要运输重量较大的水电解质。本文回顾了该领域的最新文献。这种说法的一个优点是，最近，电池存储已成为增加可再生能源在农业光伏能源系统中所占份额的有效方法。虽然备用电池的比能量可以明确确定，但其能量密度计算需要明确定义所考虑的电池体积。因此，本文提出了一种评估海水活化金属-空气储备电池的比能量和能量密度的新方法。

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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DRC Sustainable Future: Journal of Environment, Agriculture, and Energy

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