Assessment of Thermal Aging and Moisture Content in Medium Voltage XLPE Cable From Polarization Current Measurements

被引：1

作者：

Jamshed, Aadil ^{[1
]}

Haque, Nasirul ^{[1
]}

机构：

[1] Natl Inst Technol Calicut, Dept Elect Engn, Kozhikode 673601, Kerala, India

来源：

IEEE TRANSACTIONS ON DIELECTRICS AND ELECTRICAL INSULATION | 2024年 / 31卷 / 06期

关键词：

Aging; analysis of variance (ANOVA); cross-linked polyethylene (XLPE); machine learning (ML); moisture; polarization current; OIL-PAPER INSULATION; TRANSFORMER INSULATION; SERVICE; FIELD;

D O I：

10.1109/TDEI.2024.3352534

中图分类号：

TM [电工技术]; TN [电子技术、通信技术];

学科分类号：

0808 ; 0809 ;

摘要：

In this work, a methodology is presented to assess the thermal aging condition and moisture content of cross-linked polyethylene (XLPE) cable insulation from a single polarization current measurement. For this purpose, polarization current measurements are performed on several specimens of 11 kV XLPE having varied degrees of moisture content and thermal aging. The moisture content is introduced in the aged and unaged specimens through very small artificial holes of 0.5 mm diameter. From the polarization current measurements, various features are extracted using a five-parameter power law-based dielectric response modeling and a modified version of isothermal relaxation current analysis. Following this, an efficient feature selection algorithm analysis of variance (ANOVA) is used to select the best features prior to classification based on thermal aging using three well-known machine learning (ML) classifiers, namely, cubic support vector machine (SVM), extreme gradient boost (XGBoost), and random forest algorithm (RFA). All samples, irrespective of the moisture content, are classified into five classes with an accuracy of 99.5%, 97.5%, and 98%, respectively. After that, a moisture-sensitive parameter is identified that is capable of predicting the moisture content quantitatively in each of the aging classes with satisfactory performance.

引用

页码：3252 / 3260

页数：9

共 33 条

[1] Yu J., Chen X., Meng F., Paramane A., Hou S., Numerical analysis of thermo-electric field for AC XLPE cables with different service times in DC operation based on conduction current measurement, IEEE Trans. Dielectr. Electr. Insul., 27, 3, pp. 900-908, (2020)
[2] Knenicky M., Prochazka R., Hlavacek J., Partial discharge patterns during accelerated aging of medium voltage cable system, Proc. IEEE Int. Conf. High Voltage Eng. Appl. (ICHVE), pp. 1-4, (2018)
[3] Ghaderi A., Mingotti A., Lama F., Peretto L., Tinarelli R., Effects of temperature on MV cable joints tan delta measurements, IEEE Trans. Instrum. Meas., 68, 10, pp. 3892-3898, (2019)
[4] Meng F.-B., Et al., Effect of thermal ageing on physico-chemical and electrical properties of EHVDC XLPE cable insulation, IEEE Trans. Dielectr. Electr. Insul., 28, 3, pp. 1012-1019, (2021)
[5] Liang B., Et al., Influence of thermal aging on dielectric properties of high voltage cable insulation layer, Coatings, 13, 3, (2023)
[6] Guo L., Et al., Fault diagnosis based on multiscale texture features of cable terminal on EMU of high-speed railway, IEEE Trans. Instrum. Meas., 70, pp. 1-12, (2021)
[7] Steennis E.F., Kreuger F.H., Water treeing in polyethylene cables, IEEE Trans. Electr. Insul., 25, 5, pp. 989-1028, (1990)
[8] Ross R., Inception and propagation mechanisms of water treeing, IEEE Trans. Dielectr. Electr. Insul., 5, 5, pp. 660-680, (1998)
[9] Garton A., Bamji S., Bulinski A., Densley J., Oxidation and water tree formation in service-aged XLPE cable insulation, IEEE Trans. Electr. Insul., EI-22, 4, pp. 405-412, (1987)
[10] Werelius P., Tharning P., Eriksson R., Holmgren B., Gafvert U., Dielectric spectroscopy for diagnosis of water tree deterioration in XLPE cables, IEEE Trans. Dielectr. Electr. Insul., 8, 1, pp. 27-42, (2001)

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