基于Bethe小孔耦合理论和镜像原理的双腔体电磁泄漏的解析模型

doi:10.19595/j.cnki.1000-6753.tces.170311

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摘要针对复杂金属屏蔽体一般是由多个空间区域组成的特征,推导一种开有孔阵双金属腔体电磁泄露的解析模型。该模型将电偶极子天线作为激励源放置在一个腔体中,依据Bethe小孔耦合理论和镜像原理将相邻腔体中电磁场分布用等效偶极子表示,最后计算出耦合电磁场通过腔体中的孔阵泄露到腔体外部的辐射场。该解析模型利用屏蔽效能作为参考衡量电磁泄露问题,通过将该模型的计算结果与全波仿真软件CST结果对比,证实所建解析模型的有效性。同时利用该模型分析激励源位置、开孔位置及不同开孔形状对屏蔽效能的影响,从而分析屏蔽体外部泄露场的大小。该模型的建立为多腔体构成的复杂金属屏蔽体的电磁泄漏问题提供了一种可靠有效的参考。

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关键词 ：双金属腔体, 电磁泄露, Bethe小孔耦合理论, 镜像原理, 屏蔽效能

Abstract：An efficient and accurate analytical model has been developed for the electromagnetic leakage from two multiple apertured cascaded metallic rectangular enclosures connected by a metallic plate excited by an electric dipole located in the enclosure. The slot coupling of electromagnetic interference are represented by the equivalent electric and magnetic dipoles through the Bethe’s small aperture coupling theory, so the leakage fields through the multiple apertures are obtained by using the mirror procedure. Comparison with the full wave simulation software CST has verified the model over a wide frequency band. The model then is employed to analyze the influences of the excitation source location, aperture location, and the apertures in different shapes on the shielding effectiveness in the high frequency domain. This analytical model is helpful for evaluating the electromagnetic leakage from complex shielding enclosures.

Key words： Double cascaded metallic enclosures electromagnetic leakage Bethe's small aperture coupling theory mirror procedure shielding effectiveness

收稿日期: 2017-03-22 出版日期: 2018-05-08

PACS:

TM15

基金资助:国家自然科学基金（61372050）和中央高校基本科研业务费专项基金（2016MS06）资助项目

通讯作者: 范杰清男,1979年生,讲师,研究方向为电工理论与新技术、电力系统电磁兼容。E-mail：fanjieqing@ncepu.edu.cn

作者简介: 公延飞男,1987年生,博士研究生,研究方向为电工理论与新技术、电力系统电磁兼容。E-mail：yuxin880323@126.com

引用本文:

公延飞, 郝建红, 蒋璐行, 范杰清. 基于Bethe小孔耦合理论和镜像原理的双腔体电磁泄漏的解析模型[J]. 电工技术学报, 2018, 33(9): 2139-2147. Gong Yanfei, Hao Jianhong, Jiang Luhang, Fan Jieqing. An Analytical Model for Electromagnetic Leakage from Double Cascaded Enclosures Based on Bethe’s Small Aperture Coupling Theory and Mirror Procedure. Transactions of China Electrotechnical Society, 2018, 33(9): 2139-2147.

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