Reduction of radiated emission from resonance coil in GaN wireless power transmission circuit by using Nd–Fe–N magnetic material

The Japan Society of Applied Physics Pub Date : 2019-07-10 DOI:10.1063/1.5131141

T. Ide, N. Imaoka, Mikio Oomori, K. Ozaki, M. Shimizu, N. Takada

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引用次数: 1

Abstract

In this study, the Nd–Fe–N materials are employed as an electromagnetic shield, for the first time, for the resonance coil in the 13.56-MHz-GaN wireless power transmission circuit. The Nd–Fe–N materials are introduced into the air-core resonance coil as the cap of the edges or the core. By using Nd–Fe–N, the radiated emission from the resonance coil is reduced because the electromagnetic field distribution is shrunk due to the effect of not the imaginary part but the real part of the permeability. When the spectrum of the magnetic field of the resonance coil is measured at the frequency from 30 MHz to 800 MHz, the intensity of the higher harmonics radiated emission is restricted by Nd–Fe–N in all of the frequency ranges. In particular, the Nd–Fe–N capped air-core coil shows the superior characteristics in both the shielding effect and the power loss. In addition, by numerical calculation, it is found that the effect of the electromagnetic shield will be enhanced by increasing the real part of the permeability by optimizing the Nd–Fe–N material fabrication.In this study, the Nd–Fe–N materials are employed as an electromagnetic shield, for the first time, for the resonance coil in the 13.56-MHz-GaN wireless power transmission circuit. The Nd–Fe–N materials are introduced into the air-core resonance coil as the cap of the edges or the core. By using Nd–Fe–N, the radiated emission from the resonance coil is reduced because the electromagnetic field distribution is shrunk due to the effect of not the imaginary part but the real part of the permeability. When the spectrum of the magnetic field of the resonance coil is measured at the frequency from 30 MHz to 800 MHz, the intensity of the higher harmonics radiated emission is restricted by Nd–Fe–N in all of the frequency ranges. In particular, the Nd–Fe–N capped air-core coil shows the superior characteristics in both the shielding effect and the power loss. In addition, by numerical calculation, it is found that the effect of the electromagnetic shield will be enhanced by increasing the real part of the permeabi...

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利用Nd-Fe-N磁性材料降低氮化镓无线输电电路谐振线圈的辐射发射

本研究首次将Nd-Fe-N材料作为电磁屏蔽材料应用于13.56 mhz - gan无线电力传输电路的谐振线圈。将Nd-Fe-N材料引入空芯谐振线圈中，作为边缘或磁芯的封盖。Nd-Fe-N的使用减少了谐振线圈的辐射发射，这是由于磁导率的虚部而非实部的影响使电磁场分布缩小。在30 ~ 800 MHz的频率范围内测量谐振线圈的磁场频谱，在所有频率范围内，高次谐波辐射发射的强度都受到Nd-Fe-N的限制。其中，Nd-Fe-N包封空芯线圈在屏蔽效果和功率损耗方面均表现出优越的特性。此外，通过数值计算发现，通过优化Nd-Fe-N材料的制作工艺，可以提高磁导率的实部，从而增强电磁屏蔽的效果。本研究首次将Nd-Fe-N材料作为电磁屏蔽材料应用于13.56 mhz - gan无线电力传输电路的谐振线圈。将Nd-Fe-N材料引入空芯谐振线圈中，作为边缘或磁芯的封盖。Nd-Fe-N的使用减少了谐振线圈的辐射发射，这是由于磁导率的虚部而非实部的影响使电磁场分布缩小。在30 ~ 800 MHz的频率范围内测量谐振线圈的磁场频谱，在所有频率范围内，高次谐波辐射发射的强度都受到Nd-Fe-N的限制。其中，Nd-Fe-N包封空芯线圈在屏蔽效果和功率损耗方面均表现出优越的特性。另外，通过数值计算发现，增大磁导率的实部可以增强电磁屏蔽的效果。

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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The Japan Society of Applied Physics

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