Artificial Intelligence for Electrochemical Prediction and Optimization of Direct Carbon Fuel Cells Fueled with Biochar

Adam Cherni, K. Halouani
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Abstract

At present, direct carbon fuel cells constitute an emerging energy technology that electrochemically converts solid carbon to electricity with high efficiency. The recent trend of DCFCs fueled with biochar from biomass carbonization as green fuel has reinforced the environmental benefits of DCFCs as a clean and sustainable technology. However, there remain new challenges related to some complex unknown kinetic parameters, X=(αa,αc,σg,i0,a,i0,c,ilO2,ilCO2,c,ilCO2,a,ilCO), of the electrochemical conversion of biochar in DCFCs and there is a need for intelligent techniques for prediction and optimization, refering to the available experimental data. The differential evolution (DE) algorithm, which ranked as one of the top performers in optimization competitions with competitive accuracy and convergence speed, was used here for providing the optimized values of these parameters by minimizing the root mean squared errors (RMSE). The proposed technique was then applied to DCFCs fueled by activated pure carbon (APC) using CO2 and CO/CO2 electrochemical models with RMSE around 10−2 and 10−3, respectively. Then, the CO/CO2 model was applied to a DCFC fueled with almond shell biochar (ASB), which displayed a slight increase in RMSE (of the order of 10−2) due to the complex porous structure of ASB and the content of additional chemical elements that affect the electrochemistry of the DCFC and are not considered in the model.
用人工智能预测和优化以生物炭为燃料的直接碳燃料电池的电化学过程
目前,直接碳燃料电池是一种新兴能源技术,它通过电化学方法将固体碳高效转化为电能。最近,以生物质碳化产生的生物炭作为绿色燃料的直接碳燃料电池的发展趋势加强了直接碳燃料电池作为清洁和可持续技术的环境效益。然而,DCFCs 中生物炭电化学转化过程中一些复杂的未知动力学参数 X=(αa,αc,σg,i0,a,i0,c,ilO2,ilCO2,c,ilCO2,a,ilCO)仍然存在新的挑战,需要根据现有实验数据,采用智能技术进行预测和优化。微分进化(DE)算法在优化竞赛中名列前茅,具有极高的准确性和收敛速度,本文采用该算法通过最小化均方根误差(RMSE)来提供这些参数的优化值。然后,利用二氧化碳和一氧化碳/二氧化碳电化学模型,将所提出的技术应用于以活性纯碳(APC)为燃料的直流FC,其 RMSE 分别约为 10-2 和 10-3。然后,将 CO/CO2 模型应用于以杏仁壳生物炭(ASB)为燃料的直流FC,由于 ASB 复杂的多孔结构以及模型中未考虑的影响直流FC 电化学的其他化学元素的含量,RMSE 略有增加(10-2 左右)。
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
6.30
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