Radiation-induced electrical insulator breakdown

Conference on Electrical Insulation and Dielectric Phenomena, Pub Date : 1989-10-29 DOI:10.1109/CEIDP.1989.69548

A. Frederickson, P. McGrath, P. Leung

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引用次数: 4

Abstract

A mechanism is determined for the induction of electrical breakdown in thick solid insulating material exposed to high-energy particles or photons. The authors have found a mechanism where common radiation levels, greater than on the order of 100 rad/h, will induce breakdown in insulators under typical high levels of applied electric field stress. In the experiments reported here, an attempt was made to determine if beam-induced discharges could couple with an applied (battery or power supply) electric stress and result in full insulator failure. Without applied voltages, the discharges were transient and the insulators recovered their properties within microseconds, even though the beam continued after the discharge. A model explaining the experimental results is developed. It is seen that peculiar combinations of geometry and radiation are required in order to produce radiation-initiated breakdown. The radiation must induce high fields over a small volume of the insulator so that the normal bias levels can invert the space-charge-induced fields through the rest of the dielectric. Also, before it quenches, the streamer must propagate fully through the insulator. These conditions can be used to encourage the occurrence of the breakdown, or one can choose geometries to avoid the problem.<>

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辐射引起的电绝缘体击穿

在暴露于高能粒子或光子的厚固体绝缘材料中，确定了电击穿的感应机制。作者发现了一种机制，在典型的高水平外加电场应力下，大于100拉德/小时数量级的普通辐射水平会导致绝缘体击穿。在这里报告的实验中，试图确定光束感应放电是否可以与应用(电池或电源)电应力耦合并导致完全绝缘体失效。在没有施加电压的情况下，放电是短暂的，绝缘体在微秒内恢复了它们的特性，即使放电后光束继续存在。建立了一个解释实验结果的模型。可以看出，为了产生辐射引发的击穿，需要几何形状和辐射的特殊组合。辐射必须在一小块绝缘体上产生高场，这样正常的偏置电平才能使空间电荷感应的场在其余的绝缘体上反转。此外，在它熄灭之前，流光必须完全通过绝缘体传播。这些条件可以用来促进击穿的发生，或者可以选择几何形状来避免这个问题。

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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Conference on Electrical Insulation and Dielectric Phenomena,

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