INCREASING OF ELECTRICAL AND RADIOELECTRONIC EQUIPMENT’S IMMUNITY AGAINST HIGH VOLTAGE SHORT-DURATION PULSE DISTURBANCES IN THE MAINS

Q3 Energy

Technical Electrodynamics Pub Date : 2022-08-18 DOI:10.15407/techned2022.05.034

V. Pavlovskyi, V. Gurin, O. Yurchenko

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引用次数: 1

Abstract

A problem of electrical and radioelectronic equipment’s high energy pulse disturbance immunity is considered in the paper, in particular against microsecond high voltage disturbances (MHVD) in the power mains. It is showed causes of MHVD with amplitude up to 4 kV and even higher. A review of various protection methods against MHVD is carried out and it is shown that the use of a two-terminal network (TTN) with a significantly nonlinear current-voltage characteristic: varistors, suppressors and gas arrestors is the most effective. The report analyzes the operation principle of these two-poles and shows that the typical inclusion of such a device directly at the equipment’s input is not effective enough for cases where the high-frequency impedance of the mains is low. An L-circuit for connecting the TTN together with an LR link is proposed, and results of computer simulation with the aid of PSPICE showed that such a scheme reduces the MHVD amplitude on the network input of the equipment by 1.5 times comparing with the typical inclusion of such a device even under a low impedance of the mains Adding the low-pass filter to the L-circuit allows to reduce the MHVD amplitude by 40 and more times comparing with the typical inclusion of the TTN. References 8, figures 6.

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提高电气和无线电电子设备对市电高压短时间脉冲干扰的抗扰性

本文研究了电气和无线电电子设备对高能脉冲干扰的抗扰性问题，特别是对电源中微秒高压干扰的抗扰性问题。它显示了振幅高达4kv甚至更高的MHVD的原因。对各种防止MHVD的保护方法进行了回顾，并表明使用具有显著非线性电流电压特性的双端网络(TTN):压敏电阻，抑制器和气体避雷器是最有效的。该报告分析了这些两极的工作原理，并表明在设备的输入端直接包含这样一个典型的装置对于市电高频阻抗较低的情况是不够有效的。的电路连接TTN一起提出了一个LR的链接,和计算机模拟的结果与PSPICE软件显示这样一个计划的援助减少了MHVD振幅在网络上输入设备的1.5倍与典型的包含这样的装置即使在电源的低阻抗增加的低通滤波器电路允许MHVD振幅降低40和多次与TTN的典型夹杂物进行比较。参考文献8，图6。

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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