摘要
为了实现重频脉冲功率源小型化,研制了基于快Marx发生器的紧凑型重频低阻抗脉冲功率源。采用大功率重频高压电源对Marx发生器充电,通过对充电电源和脉冲触发源的同步控制,实现对Marx发生器重频充电;Marx发生器中采用薄膜脉冲电容器、小型化气体开关、电感隔离以及SF6气体绝缘等设计,以8级紧凑Marx发生器进行验证性研究,在16Ω阻抗负载上实现了重复频率10 Hz、脉宽150ns、峰值电压大于400kV连续多脉冲输出;在此基础上,设计了18级紧凑型Marx发生器,在约18Ω阻抗负载上输出功率达到33GW,峰值功率密度大于150GW/m^3,实现重复频率5 Hz、脉宽约160ns、峰值电压大于600kV的连续多脉冲输出。为了降低Marx发生器的输出阻抗,采用4台电容器并联作为Marx发生器的一级储能模块,研制了同轴紧凑Marx脉冲功率源,有效减小放电回路电感,实现12Ω低阻抗负载近似匹配输出,前沿减小至50ns以下,脉宽约130ns。
A series of compact repetitive pulsed power systems on the basis of fast Marx generator were developed in Institute of Fluid Physics,China Academy of Engineering Physics.They are mainly composed of a fast Marx generator and a repetitive high voltage charging device.There are polypropylene film capacitors with plastic shell,miniaturized gas switches,isolated inductors and SF6 gas insulation in these fast Marx generators.An 8-stage Marx generator was designed and tested.It can output repetitively 5 pulses with peak power of beyond 10 GW,rising-time of 50 ns,pulse width of 150 ns at frequency of 10 Hz.An 18-stage Marx generator has the same structure as the 8-stage Marx generator.It can generate a single pulse with peak power of more than 33 GW and pulse duration of about 160 ns on a resistor load of 18Ω.Its peak power density is up to 150 GW/m^3.But its output pulse has an obvious reverse pulse in the falling time,which is not helpful to drive a diode load.So,a 16-stage coaxial Marx generator was designed,there are four capacitors in parallel in one stage.The coaxial Marx generator has a low inductance and a low output impedance.It can generate a pulse with peak power of 28 GW and pulse duration of 130 ns without reverse pulse on an 12Ωload.This work is useful for the development of high power compact pulsed power.There are also some work to do in order to enhance the working life and repetitive operation stability of high power compact Marx generator.
作者
伍友成
杨宇
何泱
戴文峰
郝世荣
谢卫平
冯传均
曹龙博
Wu Youcheng;Yang Yu;He Yang;Dai Wenfeng;Hao Shirong;Xie Weiping;Feng Chuanjun;Cao Longbo(Key Laboratory of Pulsed Power, Institute of Fluid Physics, CAEP, P. O. Box 919-108, Mianyang 621900, China)
出处
《强激光与粒子束》
EI
CAS
CSCD
北大核心
2018年第7期141-146,共6页
High Power Laser and Particle Beams
基金
国家高技术发展计划项目