Asymptotic Decay of the Quasi-static Near-field Electromagnetic Field Components of the DD Wireless Power Transfer Coupler

2022 IEEE Green Technologies Conference (GreenTech) Pub Date : 2022-03-30 DOI:10.1109/GreenTech52845.2022.9772033

J. Mclean

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Abstract

The extraneous electromagnetic field of the double-D (DD) coupler is analyzed in detail to determine the asymptotic decay rate with distance of the near field components; that is, the magnetic and electric field components in the quasi-static far field. In this region the source-observation distance is many times the maximum source dimension, but still well within the reactive near field. It is shown that, because of the operating frequency of 85 kHz, when current electromagnetic compatibility standards are considered, it is this quasi-static far field that is of most interest. In spite of the appearance of the DD coupler, the near magnetic field is shown to decay asymptotically with radial distance as does that of a horizontal magnetic dipole, −60 dB/decade. This result is somewhat counter-intuitive as the DD coupler clearly physically resembles a higher-order multipole source. The results here contradict other published work which predict a greater decay rate with distance. A full multipole model of the DD coupler is presented and discussion of the relationship between this multipole model and a spherical wavefunction expansion is given. For the DD design given in the current SAE J2954 TIR, it is shown that, primarily due to the presence of the inhomogeneous ferrite core, a pronounced net horizontal dipole moment exists. However, the inhomogeneous ferrite core is a central part of the DD coupler design and without it the electrical performance, e.g., efficiency and tolerance to offset and alignment, are diminished. It can be deduced that in order for the extraneous fields to behave as a $\text{TE}_{12}-z$ multipole with the attendant quasi-static far field decay rate, careful attention would have to be devoted to maintaining the symmetry and this would likely degrade performance parameters such as efficiency. Without such a modification, the DD coupler produces a near extraneous magnetic field that decays at −60 dB/decade.

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DD无线电力传输耦合器准静态近场电磁场分量的渐近衰减

详细分析了双d (DD)耦合器的外加电磁场，确定了近场分量随距离的渐近衰减率;即准静态远场中的磁场分量和电场分量。在这个区域，源-观测距离是最大源维数的许多倍，但仍在反应近场范围内。结果表明，由于工作频率为85 kHz，当考虑当前的电磁兼容标准时，这种准静态远场是最令人感兴趣的。尽管出现了DD耦合器，但近磁场与水平磁偶极子一样，随径向距离渐近衰减，为- 60 dB/ 10年。这个结果有点违反直觉，因为DD耦合器在物理上明显类似于一个高阶多极源。这里的结果与其他已发表的预测随着距离的增加衰减率更大的工作相矛盾。提出了DD耦合器的全多极模型，并讨论了该多极模型与球面波函数展开的关系。对于当前SAE J2954 TIR中给出的DD设计，结果表明，主要由于不均匀铁氧体核心的存在，存在明显的净水平偶极矩。然而，不均匀铁氧体磁心是DD耦合器设计的核心部分，如果没有它，电气性能，例如效率和对偏置和对准的容错性都会降低。可以推断，为了使外来场表现为具有准静态远场衰减率的$\text{TE}_{12}-z$多极，必须仔细注意保持对称性，这可能会降低诸如效率之类的性能参数。如果没有这样的修改，DD耦合器产生一个几乎无关的磁场，衰减在−60 dB/ 10年。

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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2022 IEEE Green Technologies Conference (GreenTech)

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