The influence of fabrication parameters on the electrochemical performance of multifunctional structural supercapacitors

Q1 Materials Science Multifunctional Materials Pub Date : 1900-01-01 DOI:10.1088/2399-7532/ac1ea6
Guocheng Qi, S. Nguyen, D. B. Anthony, A. Kucernak, M. Shaffer, E. Greenhalgh
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引用次数: 13

Abstract

Multifunctional structural supercapacitors based on carbon fibre electrodes (CF) and structural electrolytes (SEs) can realise multifunctionality by simultaneously bearing load and providing electrochemical energy storage. Structural supercapacitor constituents (i.e. electrodes and electrolytes) have undergone significant development to enhance their electrochemical and mechanical properties. However, the fabrication of fully functional devices presents a number of practical challenges to achieve optimal multifunctional properties, particularly those associated with assembly and lamination. This work investigated the effect of separator selection and processing parameters on the electrochemical performance of structural supercapacitors, as well as evaluating the repeatability of the SE filming process. Two layers of glass fibre fabrics were the most effective separator for preventing short-circuiting of the structural supercapacitors. The weight fraction of the SE matrix had a significant effect on the capacitance, energy and power of the structural supercapacitors. By addressing such fabrication challenges, high performance structural supercapacitors can be manufactured with greater reproducibility and at larger scales such that they are suitable for integration in industrial applications.
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制备参数对多功能结构超级电容器电化学性能的影响
基于碳纤维电极(CF)和结构电解质(SEs)的多功能结构超级电容器可以同时承受载荷和提供电化学储能,从而实现多功能。结构超级电容器组件(即电极和电解质)已经经历了重大的发展,以提高其电化学和机械性能。然而,全功能器件的制造在实现最佳多功能特性方面提出了许多实际挑战,特别是与组装和层压相关的挑战。研究了隔膜选择和工艺参数对结构超级电容器电化学性能的影响,并评价了SE膜工艺的可重复性。双层玻璃纤维织物是防止结构超级电容器短路的最有效的隔膜。SE矩阵的质量分数对结构超级电容器的电容、能量和功率有显著影响。通过解决这些制造挑战,高性能结构超级电容器可以以更高的可重复性和更大的规模制造,从而适合集成在工业应用中。
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来源期刊
Multifunctional Materials
Multifunctional Materials Materials Science-Materials Science (miscellaneous)
CiteScore
12.80
自引率
0.00%
发文量
9
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