无线电工程
無線電工程
무선전공정
RADIO ENGINEERING OF CHINA
2014年
12期
55-58
,共4页
高空核爆电磁脉冲%时域有限差分方法%贯通导线%耦合
高空覈爆電磁脈遲%時域有限差分方法%貫通導線%耦閤
고공핵폭전자맥충%시역유한차분방법%관통도선%우합
high-altitude electromagnetic pulse%finite difference time domain method%penetrated wire%coupling
电磁脉冲( EMP )对电子设备构成严重威胁,研究电子设备HEMP效应是电磁兼容与电子设备安全领域的迫切需求。多层金属腔体是电子设备较为常见的一种结构形式,以一种带贯通导线的双层金属腔体为研究对象,基于时域有限差分方法( FDTD)建立计算模型,分析计算了贯通导线在高空核爆电磁脉冲( HEMP )入射波作用下对腔体内电路的耦合效应。仿真结果表明,贯通导线能将入射脉冲能量耦合进腔体内部,使内电路负载产生感应电流,当入射电场与贯通导线平面相互平行时影响较大,但相互垂直时仍会耦合一部分能量。所得结论可为多层腔体的电磁防护设计提供依据。
電磁脈遲( EMP )對電子設備構成嚴重威脅,研究電子設備HEMP效應是電磁兼容與電子設備安全領域的迫切需求。多層金屬腔體是電子設備較為常見的一種結構形式,以一種帶貫通導線的雙層金屬腔體為研究對象,基于時域有限差分方法( FDTD)建立計算模型,分析計算瞭貫通導線在高空覈爆電磁脈遲( HEMP )入射波作用下對腔體內電路的耦閤效應。倣真結果錶明,貫通導線能將入射脈遲能量耦閤進腔體內部,使內電路負載產生感應電流,噹入射電場與貫通導線平麵相互平行時影響較大,但相互垂直時仍會耦閤一部分能量。所得結論可為多層腔體的電磁防護設計提供依據。
전자맥충( EMP )대전자설비구성엄중위협,연구전자설비HEMP효응시전자겸용여전자설비안전영역적박절수구。다층금속강체시전자설비교위상견적일충결구형식,이일충대관통도선적쌍층금속강체위연구대상,기우시역유한차분방법( FDTD)건립계산모형,분석계산료관통도선재고공핵폭전자맥충( HEMP )입사파작용하대강체내전로적우합효응。방진결과표명,관통도선능장입사맥충능량우합진강체내부,사내전로부재산생감응전류,당입사전장여관통도선평면상호평행시영향교대,단상호수직시잉회우합일부분능량。소득결론가위다층강체적전자방호설계제공의거。
Electromagnetic pulses ( EMP ) have a serious threat on electronic equipment, so the study of HEMP effects is an urgent task in the fields of electromagnetic compatibility and electronic equipment safety. Multi?layer metal cavities are common struc?tures of electronic equipment, so the paper focuses on a kind of double wall cavities with penetrated wire. Based on the finite difference time domain method ( FDTD) , it analyses and calculates the internal circuit coupling effects of the penetrated wire in a structure of double wall cavities under the high-altitude electromagnetic pulse ( HEMP ) plane wave. The results show that the penetrated wires couple the incident pulse energy into the internal cavity, so load current is induced in the internal circuit; there is a greater impact when the incident electric field is parallel to the plane of the penetrated wires, but when they are perpendicular to each other, part of the energy is still coupled. The conclusions provide a reference for the electromagnetic protective design of multi-layer cavities.