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Influence of test methods on dc flashover performance of ice-covered composite insulators and statistical analysis | IEEE Journals & Magazine | IEEE Xplore
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Journals & Magazines >IEEE Transactions on Dielectr... >Volume: 19 Issue: 6

Influence of test methods on dc flashover performance of ice-covered composite insulators and statistical analysis

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Xingliang Jiang; Maoqiang Bi; Jianlin Hu; Zhijing Zhang; Yunfeng Xia
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Abstract:

Operational statistics and studies have revealed that, the reduction of insulation strength of transmission line insulators caused by icing is one of the critical reasons...Show More

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Abstract:

Operational statistics and studies have revealed that, the reduction of insulation strength of transmission line insulators caused by icing is one of the critical reasons of the power grid faults. This paper compares of various test methods for evaluating the flashover characteristic of ice-covered composite insulators. Two types of composite insulators, i.e. FXBW-±800/530 short sample and FXBW-110/100 are investigated. The influences of various test methods on flashover performance of ice-covered insulators are studied in an artificial climate chamber. The test results revealed the influences are significant. The average flashover voltage (Uav) using even raising method is highest, followed by the 50% withstand voltage (U50%) which is corresponding to up and down method, the lowest flashover voltage (Uf.min) using Ucurve method is the third, and the maximum withstand voltage (Uws) using the maximum withstand voltage method is the lowest. Through the statistical analysis, the U50% can be estimated by Uav and σav though the estimated value Ue (Ue=(Uav-k1σav)/( 1+k2δe)). The estimated errors (Ee) are less than 1.80% in this paper. Therefore, there is an intrinsic relationship among the test results obtained by using various test methods. This simplifies selection of the appropriate test method according to the testing specific circumstances.
Published in: IEEE Transactions on Dielectrics and Electrical Insulation ( Volume: 19, Issue: 6, December 2012)
Page(s): 2019 - 2028
Date of Publication: 04 January 2013

ISSN Information:

DOI: 10.1109/TDEI.2012.6396961
References is not available for this document.
Contents

I. Introduction

One of the challenging problems associated with ice and snow accretion on power lines is the loss in electrical performance of insulators. A drastic decrease in electrical insulation, under certain conditions, can lead to flashover and consequent power outages [1]–[4]. Flashover phenomena on icecovered insulators have been reported from many cold climate regions, such as countries in North America [1], [4]–[7], Europe [8], [9] and Asia [10], [11].

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