Accurate temperature correction of dissipation factor data for oil-impregnated paper insulation bushings: Field experience

D. Robalino
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引用次数: 12

Abstract

Typically, dissipation factor (DF) or power factor (PF) test is carried out in the field following well known procedures. It is not necessary to emphasize the importance of dielectric test for power system operators. Accurate recording of insulation temperature values during the test is critical but not always feasible in the field. DF measured values are later normalized to a 20°C base for future comparison and trending. Nevertheless, as stated in several international publications, accuracy of temperature correction is still under investigation because temperature correction factors (TCF) from reference tables do not consider the percentage moisture concentration of the insulation system. The existing Temperature Correction Tables correspond to a variety of insulation materials and construction of different high voltage electrical equipment and components. Therefore, the application of state-of-the-art technologies to determine “specific” temperature correction factors for DF, is essential to provide reliable interpretation of results and proper equipment condition assessment. Frequency Domain Spectroscopy (FDS) in conjunction with DF Analysis are a powerful tool to determine the percentage moisture concentration in solid insulation capable to estimate Individual Temperature Compensation (ITC) of DF measured data of power transformers. Throughout this document, field experience is summarized when a three-winding transformer is removed from service and put to a series of testing procedures including DF, FDS and tip-up test on the high voltage bushings. Results of the analysis, experimental data and conclusions made based on the obtained results are presented herein.
油浸纸绝缘套管耗散系数数据的精确温度校正:现场经验
通常,耗散系数(DF)或功率因数(PF)测试是按照众所周知的程序在现场进行的。对于电力系统操作人员来说,介电试验的重要性无需再强调。在测试过程中准确记录绝缘温度值是至关重要的,但在现场并不总是可行的。DF测量值稍后归一化为20°C基准,以便将来比较和趋势。然而,正如一些国际出版物所述,温度校正的准确性仍在研究中,因为参考表中的温度校正因子(TCF)没有考虑绝缘系统的水分浓度百分比。现有的温度校正表对应于不同高压电气设备和元件的各种绝缘材料和结构。因此,应用最先进的技术来确定DF的“特定”温度校正因子,对于提供可靠的结果解释和适当的设备状态评估至关重要。频域光谱(FDS)与DF分析相结合,是确定固体绝缘中水分浓度百分比的有力工具,能够估计电力变压器DF测量数据的单独温度补偿(ITC)。在整个文档中,总结了三绕组变压器停止使用并进行一系列测试程序(包括DF, FDS和高压套管的倾斜试验)时的现场经验。本文给出了分析结果、实验数据和根据所得结果得出的结论。
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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