Reliability-Based Design Optimization of Additive Manufacturing for Lithium Battery Silicon Anode

Zheng Liu, Hao Wu, Pingfeng Wang, Yumeng Li
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Abstract

With the blooming of the electric vehicle market and the advancement in the lithium-ion battery industry, silicon anode has shown great potential for the next-generation battery. Using the state-of-the-art additive manufacturing technique (three-dimensional holographic lithography), researchers have demonstrated that silicon anode can be fabricated as a three-dimensional bicontinuous porous microstructure. However, the volume fluctuation of the silicon anode caused by lithiation during the discharging process causes continuous capacity decay and poor cycling life. Besides, uncertainties are inherent in the manufacturing and usage processes, making it crucial to systematically consider them in the silicon anode design to improve its performance and reliability. To fill the gap between current silicon anode research and future industrial need, this study established a digital twin to investigate the optimal design for silicon anode under the uncertainties of additive manufacturing and battery usage. This study started with developing multiphysics finite element models of the silicon anode lithiation process to investigate the volume fluctuation of silicon. Then, surrogate models were built based on the results from the finite element models to reduce computational cost. The reliability-based design optimization was employed to find the best design point for the silicon anode, in which an outer optimization loop maximized the objective function and an inner loop dedicated to reliability analysis. Finally, the Pareto optimal front of the silicon anode designs was obtained and validated, which shows over 10% improvements in the silicon anode's total capacity and rate capability.
基于可靠性的锂电池硅负极增材制造设计优化
随着电动汽车市场的蓬勃发展和锂离子电池行业的进步,硅负极在下一代电池中显示出巨大的潜力。研究人员利用最先进的增材制造技术(三维全息光刻技术)证明,硅负极可以制造成三维双连续多孔微结构。然而,硅阳极在放电过程中由于锂化引起的体积波动会导致容量持续衰减,循环寿命变短。此外,硅阳极在制造和使用过程中存在不确定性,因此在硅阳极设计中系统地考虑这些不确定性对提高其性能和可靠性至关重要。为了填补当前硅负极研究与未来工业需求之间的空白,本研究建立了一个数字孪生模型,以研究在增材制造和电池使用的不确定性条件下硅负极的优化设计。本研究首先开发了硅负极光化过程的多物理场有限元模型,以研究硅的体积波动。然后,根据有限元模型的结果建立代用模型,以降低计算成本。采用基于可靠性的设计优化来寻找硅阳极的最佳设计点,其中外优化环最大化目标函数,内优化环专门用于可靠性分析。最后,获得了硅阳极设计的帕累托最优前沿并进行了验证,结果表明硅阳极的总容量和速率能力提高了 10%以上。
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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