色散对PD脉冲在屏蔽电缆中传播的影响

2008 Annual Report Conference on Electrical Insulation and Dielectric Phenomena Pub Date : 2008-10-01 DOI:10.1109/CEIDP.2008.4772878

E. Shu, S. Boggs

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引用次数: 15

摘要

高频衰减和频散影响屏蔽电力电缆局部放电的检测和定位。通过测量和计算，我们很好地理解了高频衰减的影响，这是色散不能说的。根据测量到的材料特性，计算出了同轴神经分布电缆中电磁传播速度随频率的变化规律，并由此推导出了色散。计算得到的色散与文献中的测量结果一致。研究了色散对PD脉冲传播的影响，包括色散与高频衰减之间的耦合，两者都是相同材料参数的函数。分析表明，色散导致高斯PD脉冲(在源处)演变成上升快于下降的不对称形状。数值计算了有色散和无色散时脉冲峰值到达时间的差值，并建立了预测该差值的简单分析基础。

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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Effect of Dispersion on PD Pulse Propagation in Shielded Power Cable

High frequency attenuation and dispersion affect partial discharge detection and location in shielded power cables. The effect of high frequency attenuation is well understood through both measurement and computation, which cannot be said of dispersion. The electromagnetic propagation velocity as a function of frequency in concentric neural distribution cable has been computed from measured material properties, from which the dispersion deduced. The computed dispersion is in reasonable agreement measurements in the literature. The effect of dispersion on PD pulse propagation has been evaluated, including coupling between dispersion and high frequency attenuation, which are both functions of the same material parameters. The analysis indicates that dispersion causes a Gaussian PD pulse (at the source) to evolve into an asymmetric shape with faster rise than fall. The difference in pulse peak time of arrival with and without dispersion has been computed numerically, and a simple analytical basis for predicting this offset has been developed.

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2008 Annual Report Conference on Electrical Insulation and Dielectric Phenomena

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