Integrated all-silicon thin-film power electronics on flexible sheets for ubiquitous wireless charging stations based on solar-energy harvesting

2012 Symposium on VLSI Circuits (VLSIC) Pub Date : 2012-06-13 DOI:10.1109/VLSIC.2012.6243858

Liechao Huang, W. Rieutort-Louis, Yingzhe Hu, J. Sanz-Robinson, S. Wagner, J. Sturm, N. Verma

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引用次数: 15

Abstract

With the explosion in the number of battery-powered portable devices, ubiquitous powering stations that exploit energy harvesting can provide an extremely compelling means of charging. We present a system on a flexible sheet that, for the first time, integrates the power electronics using the same thin-film amorphous-silicon (a-Si) technology as that used for established flexible photovoltaics. This demonstrates a key step towards future large-area flexible sheets which could cover everyday objects, to convert them into wireless charging stations. In this work, we combine the thin-film circuits with flexible solar cells to provide embedded power inversion, harvester control, and power amplification. This converts DC outputs from the solar modules to AC power for wireless device charging through patterned capacitive antennas. With 0.5-2nF transfer antennas and solar modules of 100cm2, the system provides 47-120μW of power at 11-22% overall power-transfer efficiency under indoor lighting.

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基于太阳能收集的无所不在的无线充电站的柔性片上集成全硅薄膜电力电子器件

随着电池供电的便携式设备数量的激增，利用能量收集的无处不在的发电站可以提供一种极具吸引力的充电方式。我们提出了一个柔性片上的系统，该系统首次使用与已建立的柔性光伏电池相同的非晶硅薄膜(a- si)技术集成了电力电子器件。这是迈向未来的关键一步，它可以覆盖日常物品，并将其转化为无线充电站。在这项工作中，我们将薄膜电路与柔性太阳能电池结合起来，提供嵌入式功率反转，收割机控制和功率放大。这将太阳能模块的直流输出转换为交流电源，通过图案电容天线为无线设备充电。系统采用0.5-2nF传输天线和100cm2的太阳能模块，在室内照明条件下可提供47-120μW的功率，总功率传输效率为11% -22%。

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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2012 Symposium on VLSI Circuits (VLSIC)

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