Investigating Energization Transients and the Potentiality of Partial Discharge Inception and Damage in Nanofilled Polypropylene Insulation for DC Cables and Capacitors

2019 IEEE 4th International Conference on Condition Assessment Techniques in Electrical Systems (CATCON) Pub Date : 2019-11-01 DOI:10.1109/CATCON47128.2019.42

P. Seri, R. Ghosh, H. Naderiallaf, G. Montanari

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引用次数: 1

Abstract

New nanostructured insulating materials are investigated, within the European project GRIDABLE, to be used for DC cable and capacitors. Besides electrical, thermal and mechanical properties, and life behavior, work is being done to evaluate their capability to endure highly stressing conditions as those cause by the inception of partial discharges, PD. This paper, in particular, analyzes what happens during energization of a DC cable or capacitors, when voltage goes from zero to the nominal value in a few seconds, while the internal electrical field takes longer time to reach the DC steady state configuration. During an energization transient, indeed, electrical field in insulation, and insulation defects (as cavities), is driven by permittivity, not conductivity as in steady state. Hence, PD might occur with high repetition rate, which would not occur, or at much lower repetition rate, in steady state. The way to evaluate the time constant of the transient, that is, through charging current measurement, is described and successfully fitted to the results of PD measurements performed on two types of polypropylene, PP: neat and nanostructured, and a crosslinked polyethylene, XLPE, having significantly different electrical characteristics.

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研究直流电缆和电容器用纳米填充聚丙烯绝缘的通电瞬态和局部放电开始和损坏的可能性

在欧洲GRIDABLE项目中，研究了用于直流电缆和电容器的新型纳米结构绝缘材料。除了电学、热学和机械性能以及使用寿命外，研究人员还对其承受部分放电(PD)引起的高应力条件的能力进行了评估。本文特别分析了当电压在几秒钟内从零到标称值，而内部电场需要更长的时间才能达到直流稳态配置时，直流电缆或电容器通电时会发生什么。实际上，在通电瞬态过程中，绝缘中的电场和绝缘缺陷(如空腔)是由介电常数驱动的，而不是由稳态中的电导率驱动的。因此，PD可能在高重复率下发生，而在稳定状态下不会发生，或者在低得多的重复率下不会发生。描述了通过充电电流测量来评估瞬态时间常数的方法，并成功地拟合了两种类型的聚丙烯的PD测量结果，PP:整齐和纳米结构，以及交联聚乙烯，XLPE，具有显著不同的电特性。

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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2019 IEEE 4th International Conference on Condition Assessment Techniques in Electrical Systems (CATCON)

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