Development process of micropores partial discharge of silicon rubber in prefabricated cable joint
Author:
Chang Wenzhi1, Du Fei1, Bi Jiangang1, Shao Jin2, Peng Jiang2, Liu Jiping3, Wang Haoming3
Affiliation:
1. China Electric Power Research Institute , Beijing 100192 China 2. State Grid Corporation of China, Beijing 100031 , 3. State Grid Tianjin Electric Power Research Institute , Tianjin , 300384 China
Abstract
Abstract
To clarify the relationship between microporous defects and the development of partial discharge(PD) in silicone rubber, meanwhile evaluate insulation state of the prefabricated power cable joints quantitatively, the microporous defect is made based on real power cable joint, and PD signals are measured by step test method with the development of the defect. The discharge number, total energy and average energy of PD is gained to calculate the curves changed over time, based on which the breakdown process is divided into 4 stages, then phased spectra and grayscale maps are calculated for reflection of PD repetition rate and average energy in phase domain. Phase width, skewness of spectrum and coefficient of variation of parameter are employed to indicate the spectra statistical shape feature in each stage. The study indicates that the shape features of spectra are changed during the development of defect, the 3 features parameters are monotonously changed, and the changing rate is significantly higher at the end of the breakdown process. Evaluation method for micropores PD of silicon rubber is proposed based on the analysis of the parameters and the trend of PDs development.
Publisher
Walter de Gruyter GmbH
Reference14 articles.
1. [1] G. Katsuta, A.Toya, K. Muraoka et al, “Development of a Method Partial Discharge Detection in Extra-High Voltage Cross-Linked Polyethylene Insulated Cable Lines”, IEEE Transactions on Power Delivery, 1992, vol. 7, no. 3, pp. 1068–1079. 2. [2] R. Liao, T. Zhou and L. Liu et al, “Experimental Research on Electrical Treeing and Partial Discharge Characteristics of Cross-linked Polyethylene Power Cables”, Proceedings of the CSEE, 2011, vol. 31 no. 28, pp. 136–143. 3. [3] X. Chen, Y. Xu, M. Wang et al, “Propagation and Partial Discharge Characteristics of Electrical Trees in 110 kV XLPE Cable Insulation at High Temperature”, High Voltage Engineering, 2012, vol. 38, no. 3, pp. 645–654. 4. [4] T. Heizmann, T. Aschwanden, H. Hahn et al, “On-Site Partial Discharge Measurements on Premolded Cross-Bonding Joints of 170 kV XLPE and EPR cables”, Power Delivery, 1998, vol. 13, no. 2, pp. 330–335. 5. [5] K. Fukunaga, M. Tan and H. Takehana, “New Partial Discharge Detection Method for Live UHV/EHV Cable Joints”, IEEE Transactions on Electrical Insulation, 1992, vol. 27, no. 3, pp. 669–674.
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