高电压技术
高電壓技術
고전압기술
HIGH VOLTAGE ENGINEERING
2012年
5期
1163-1171
,共9页
周远翔%沙彦超%聂德鑫%伍志荣%邓建刚%卢理成
週遠翔%沙彥超%聶德鑫%伍誌榮%鄧建剛%盧理成
주원상%사언초%섭덕흠%오지영%산건강%로리성
变压器油%交直流复合电压%不同电压比例%局部放电%放电速率%表面形貌特征%放电波形%电场仿真
變壓器油%交直流複閤電壓%不同電壓比例%跼部放電%放電速率%錶麵形貌特徵%放電波形%電場倣真
변압기유%교직류복합전압%불동전압비례%국부방전%방전속솔%표면형모특정%방전파형%전장방진
transformer oil%combined AC-DC voltage%composite voltage in different ratios%partial discharge%streamer propagation velocities%surface topography%discharge wave shape%electric field simulation
换流变阀侧绕组同时承受交流、直流、交直流叠加、极性反转等多种特殊电压形式,其许用场强却未得到同等关注。因此,采用针-板、板-板典型电极模型和脉冲电流法及宽频带电流传感器检测法,研究了变压器油在交流、直流、交直流复合电压条件下的局部放电起始过程;总结了该起始电压随电压类型变化的规律曲线,为换流变许用场强的提出奠定了基础。试验结果表明:针-板电极模型下局放起始电压基本只与交流、直流、复合电压的幅值有关,而与电压类型、复合电压分量所占比例无明显关系;板-板电极模型中,复合电压下交流局部放电起始电压受直流分量的影响很小。通过高速摄像仪记录复合电压下局部放电引发击穿的全过程并估算出了放电增长速率约为1.8km/s;利用扫描电镜观测放电通道表面形貌特征,进而采用表面能谱分析法检测其主要元素含量由高至低依次为C、O、Cu、Si。最后通过复合电压下油中局部放电产生随机分布气泡的仿真模型算出,气泡使局部放电场强严重畸变,不均匀系数f达1.6。
換流變閥側繞組同時承受交流、直流、交直流疊加、極性反轉等多種特殊電壓形式,其許用場彊卻未得到同等關註。因此,採用針-闆、闆-闆典型電極模型和脈遲電流法及寬頻帶電流傳感器檢測法,研究瞭變壓器油在交流、直流、交直流複閤電壓條件下的跼部放電起始過程;總結瞭該起始電壓隨電壓類型變化的規律麯線,為換流變許用場彊的提齣奠定瞭基礎。試驗結果錶明:針-闆電極模型下跼放起始電壓基本隻與交流、直流、複閤電壓的幅值有關,而與電壓類型、複閤電壓分量所佔比例無明顯關繫;闆-闆電極模型中,複閤電壓下交流跼部放電起始電壓受直流分量的影響很小。通過高速攝像儀記錄複閤電壓下跼部放電引髮擊穿的全過程併估算齣瞭放電增長速率約為1.8km/s;利用掃描電鏡觀測放電通道錶麵形貌特徵,進而採用錶麵能譜分析法檢測其主要元素含量由高至低依次為C、O、Cu、Si。最後通過複閤電壓下油中跼部放電產生隨機分佈氣泡的倣真模型算齣,氣泡使跼部放電場彊嚴重畸變,不均勻繫數f達1.6。
환류변벌측요조동시승수교류、직류、교직류첩가、겁성반전등다충특수전압형식,기허용장강각미득도동등관주。인차,채용침-판、판-판전형전겁모형화맥충전류법급관빈대전류전감기검측법,연구료변압기유재교류、직류、교직류복합전압조건하적국부방전기시과정;총결료해기시전압수전압류형변화적규률곡선,위환류변허용장강적제출전정료기출。시험결과표명:침-판전겁모형하국방기시전압기본지여교류、직류、복합전압적폭치유관,이여전압류형、복합전압분량소점비례무명현관계;판-판전겁모형중,복합전압하교류국부방전기시전압수직류분량적영향흔소。통과고속섭상의기록복합전압하국부방전인발격천적전과정병고산출료방전증장속솔약위1.8km/s;이용소묘전경관측방전통도표면형모특정,진이채용표면능보분석법검측기주요원소함량유고지저의차위C、O、Cu、Si。최후통과복합전압하유중국부방전산생수궤분포기포적방진모형산출,기포사국부방전장강엄중기변,불균균계수f체1.6。
As a critical parameter for the main insulation design of power transformer, available electric field strength is the important index of the technology and management level. The valve winding of converter transformer withstands several types of voltage, including AC, DC, combined AC-DC voltages. However, the analogous problem for converter transformer has not received enought attention. Therefore, based on broadband sensors and pulse electric methods, the initiating process of partial discharge of transformer oil under combined AC-DC voltage was studied by using needle-plate and plane-plane electrodes. Partial discharge inception voltages ~PDIV) of two electrodes under the different voltages were summarized. The results show that PDIV is not related to voltage types under needle-plate electrodes but only to voltage amplitude. The results also show that AC PDIV has little relation with DC pre-stressed voltage. The process of the dielectric breakdown caused by partial discharge was recorded with an initial velocity of about 1.8 km/s. The surface topography of plasma channel was observed by scanning electron microscope (SEM). And the amounts of chemical elements C, O, Cu and Si are in sequence from high to low by energy dispersive spectrum (EDS). At last, an ANSYS structural model of single bubble in oil was established. The simulation results show that electric fields are more easily distorted by bubbles, and non-uniformity coefficient f is about 1.6.