Wireless Power Transmission into a Space Enclosed by Metal Walls Using Magnetic Resonance Coupling

M. Yamakawa, Y. Mizuno, Jun Ishida, K. Komurasaki, H. Koizumi
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引用次数: 34

Abstract

In this paper, a wireless power transmission system using magnetic resonance coupling was proposed and demonstrated for supplying power at high efficiency to electrical devices in a space enclosed by metal walls. This is applicable to power supply to electrical sensors or devices working in the area surrounded by metal walls. Proposed magnetic resonance coupling system is driven at a resonance frequency of 50 Hz, which is selected to avoid eddy current loss on the surrounding metals. Firstly, resonator designs and its performance limitation were described. Secondly, the equivalent circuits and theoretical transmission efficiency were presented. Finally, power transmission was experimentally demonstrated and transmission efficiency was measured in some conceivable situations. As a result, electric power of 3 W was supplied to LEDs over a stainless steel wall. When the stainless steel wall thickness was 10 mm, transmission efficiency of approximately 40% was achieved over the transmission distance of 12 cm. Moreover, in the demonstration of transmission through a metal pipe, 1.2 W of power was transmitted to LEDs in a 10 mm thick metal pipe.
利用磁共振耦合将无线电力传输到金属墙封闭的空间
本文提出并演示了一种利用磁共振耦合的无线电力传输系统,该系统可以在金属墙封闭的空间内为电气设备高效供电。适用于在金属墙周围区域工作的电子传感器或设备的供电。所提出的磁共振耦合系统的驱动频率为50 Hz,选择该频率是为了避免对周围金属的涡流损耗。首先,介绍了谐振器的设计及其性能限制。其次,给出了等效电路和理论传输效率。最后,对功率传输进行了实验验证,并在一些可能的情况下测量了传输效率。因此,通过不锈钢墙为led提供了3w的电力。当不锈钢壁厚为10 mm时,在12 cm的传输距离内,传输效率约为40%。此外,在通过金属管传输的演示中,在10毫米厚的金属管中向led传输了1.2 W的功率。
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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