基于SF6分解組分的負極性直流局部放電故障診斷
楊旭1,2,3,黃勤清1,2,張曉星3,文豪1,2,聶德鑫1,2,周文1,2,江翼1,2
(1 南瑞集團(國網(wǎng)電力科學研究院)有限公司,江蘇 南京 211006;2 國網(wǎng)電力科學研究院武漢南瑞有限責任公司,湖北 武漢 430074;
3 武漢大學 電氣與自動化學院,湖北 武漢 430072)
摘 要:為了利用SF6局部放電(PD)分解特性開展直流氣體絕緣設備(GIE)故障診斷研究,以直流GIE中最為常見的4 種絕緣缺陷為例,研究了缺陷從起始放電發(fā)展至臨近擊穿整個過程的PD特性,選擇q v、n v 和Δt v作為表征PD狀態(tài)的特征量,并將PD嚴重程度劃分為3 個等級;在每種缺陷的3 個PD等級下開展了大量SF6分解實驗,獲取了SF6分解特性。實驗結(jié)果表明,SF6分解生成了CF4、CO2、SO2F2、SOF2 和SO2 5 種穩(wěn)定組分,其中SOF2是最主要的分解產(chǎn)物,且含硫組分的生成量高于含碳組分的生成量;構(gòu)建了由21 個濃度比值組成的特征集合,運用最大相關最小冗余準則進行特征量選擇,并基于BP神經(jīng)網(wǎng)絡和支持向量機進行了故障診斷,準確率超過88%。
關鍵詞:局部放電;SF6 分解特性;最大相關最小冗余;故障診斷
中圖分類號:TM21 文獻標識碼:A 文章編號:1007-3175(2020)09-0001-07
Type Identification of Negative DC Partial Discharge Based on SF6 Decomposed Components
YANG Xu1, 2, 3, HUANG Qin-qing1, 2, ZHANG Xiao-xing3, WEN Hao1, 2, NIE De-xin1, 2, ZHOU Wen1, 2, JIANG Yi1, 2
(1 Nanjing NARI Group Corp(State Grid Electric Power Research Institute), Nanjing 211 006, China;
2 Wuhan NARI Co., Ltd, State Grid Electric Power Research Institute, Wuhan 430074,China;
3 School of Electrical Engineering and Automation, Wuhan University, Wuhan 430072,China)
Abstract: In order to use SF6 decomposition characteristics to identify faults of DC gas-insulated equipment (GIE) under partial discharge (PD), this paper studied the PD characteristics of the whole process from the initial discharge to near breakdown of the four most common insulation defects in DC-GIE. qv, nv, and Δtv are selected as the feature quantities for characterizing the PD state, and the PD severity is divided into three levels. Then, a large number of SF6 decomposition experiments were carried out under the three PD level of each defect, and the decomposition characteristics of SF6 were obtained. The experimental results show that SF6 decomposition produces include five stable components of CF4, CO2, SO2F2, SOF2 and SO2, among which SOF2 is the most important decomposition product, and the formation amount of sulfur components are higher than that of carbonaceous components. Finally, a feature set consisting of 21 concentration ratios is constructed, and the maximum relevance minimum redundancy criterion is used for feature quantity selection. BP neural network and support vector were used for fault identification, and the accuracy rate was higher than 88%.
Key words: partial discharge; SF6 decomposition characteristics; maximum relevance minimum redundancy; fault identification
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