Hydrogen production with a novel coaxial cylindrical electrolyser: A CFD study

Q1 Chemical Engineering International Journal of Thermofluids Pub Date : 2024-09-03 DOI:10.1016/j.ijft.2024.100850

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Abstract

This study introduces a unique coaxial cylindrical electrode design for Alkaline Water Electrolysers (AWEs) that is analyzed to show possible enhancements over the traditional stacked plate design. It investigates the performance of the proposed coaxial AWE for enhanced hydrogen production. Through comprehensive computational simulations, key performance indicators, such as current density and hydrogen volume fraction, are analyzed across various operating parameters. The results of this study indicate that the production rate of hydrogen achieves its highest level at a volume percentage of 3.4 %. This rate is significantly influenced by the concentration of the electrolyte, the distance between the cathode and anode rings, and, to a lesser degree, the porosity of the separator. Consequently, the optimized conditions demonstrate a promising increase in current densities, reaching 1000 mA/cm² at an operating voltage of 2 V, showcasing the potential for developing more efficient and cost-effective AWE systems. This study further contributes valuable insights into the design and operational improvements needed for the advancement of large-scale hydrogen production technologies.

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利用新型同轴圆柱形电解槽制氢：CFD 研究

本研究为碱性水电解槽 (AWE) 引入了一种独特的同轴圆柱形电极设计，通过分析表明该设计与传统的叠板式设计相比可能具有的优势。本研究调查了拟议的同轴 AWE 在提高氢气生产方面的性能。通过全面的计算模拟，分析了各种运行参数下的关键性能指标，如电流密度和氢气体积分数。研究结果表明，氢气的生产率在体积百分比为 3.4% 时达到最高水平。电解液的浓度、阴极环和阳极环之间的距离以及分离器的孔隙率对这一生产率有很大影响，但影响程度较小。因此，优化后的条件有望提高电流密度，在 2 V 工作电压下达到 1000 mA/cm2，展示了开发更高效、更具成本效益的 AWE 系统的潜力。这项研究还为大规模制氢技术所需的设计和操作改进提供了宝贵的见解。

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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