Design of 325 MHz RF grid-controlled high voltage thermionic cathode electron gun

Q4 Engineering 强激光与粒子束 Pub Date : 2021-05-02 DOI:10.11884/HPLPB202133.200310
Xia Qianxu, Zhao Quantang, Zong Yang, Cao Shuchun, Li Zhongping, Shen Xiaokang, Zhan Zimin
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Abstract

The electron gun with high repetition rate and high average current has a very wide range of applications. This paper presents the design of a microwave grid-controlled high-voltage thermionic electron gun working in CW mode with a bunch repetition rate of 325 MHz and elaborates the experimental principles of this kind of electron guns. Firstly, simulation software EGUN, POISSON (Poisson Superfish) and GPT (General Particle Tracer) are used to accomplish the structure design of a300kV high-voltage DC electron gun and beam dynamics verification.Secondly, to feed the microwave into the gap between the cathode and the grid of the electron gunefficiently, design of a power supply with a scheme of impedance matching from the radio frequency power source to the cathode is completed.Accordingly, a 325 MHz dual-mode coaxial power supply device is designed, and its feasibility is verified and analyzed..
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325 MHz射频栅控高压热离子阴极电子枪的设计
具有高重复率和高平均电流的电子枪具有非常广泛的应用。本文介绍了一种工作在连续波模式、束重复频率为325MHz的微波栅控高压热离子电子枪的设计,并阐述了这种电子枪的实验原理。首先,利用仿真软件EGUN、POISSON(POISSON Superfish)和GPT(General Particle Tracer)完成了一款300kV高压直流电子枪的结构设计和电子束动力学验证。其次,为了有效地将微波馈入电子枪阴极和栅极之间的间隙,完成了射频电源到阴极阻抗匹配方案的电源设计。为此,设计了一种325MHz双模同轴电源装置,并对其可行性进行了验证和分析。。
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来源期刊
强激光与粒子束
强激光与粒子束 Engineering-Electrical and Electronic Engineering
CiteScore
0.90
自引率
0.00%
发文量
11289
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