用于自供电可穿戴传感器的集成柔性能量采集器和超级电容器

A. Vyas, Q. Li, R. V. D. Eeckhoudt, G. Geréb, A. Smith, C. Rusu, P. Lundgren, P. Enoksson
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引用次数: 1

摘要

我们展示了柔性能量收集器和可折叠超级电容器的第一个结果,用于为可穿戴和柔性传感器供电。这种柔性能量收集器是用38 μ m的压电聚偏氟乙烯(PVDF)夹在碳电极之间制成的。设计和过程都在简单和成本效益方面表现出色。该柔性收割机在50 Hz谐振频率下的输出功率为2.6 μ W - cm-3, 3dB带宽约为11 Hz,高于先前报道的器件,与相同尺寸的商用PZT收割机薄膜相似。以石墨/垂直排列碳纳米管(VACNTs)材料为电极制备了柔性储能超级电容器(GP-SC)。原型GP-SCs的面电容约为1.2 mF cm-2。最后,对今后的工作提出了综合方案。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Towards Integrated Flexible Energy Harvester and Supercapacitor for Self-powered Wearable Sensors
We present the first results of a flexible energy harvester and a foldable supercapacitor to power wearable and flexible sensors. The flexible energy harvester is fabricated by using $38 \mu m$ piezoelectric polyvinylidene difluoride (PVDF) sandwiched between carbon-electrodes. Both the design and process excel in simplicity and cost-effectiveness. The flexible harvester demonstrates a power output of $2.6 \mu W$ cm-3 at a resonant frequency of 50 Hz with a 3dB bandwidth of about 11 Hz, which is higher than devices previously reported and similar to a commercial PZT harvester film of same size. A flexible energy storage supercapacitor (GP-SC) was fabricated using a graphite/VACNTs (vertically aligned carbon nanotubes) material as electrodes. A prototype GP-SCs has an areal capacitance of about 1.2 mF cm-2. Finally, an integrated scheme is proposed for future work.
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