现代电子技术
現代電子技術
현대전자기술
MODERN ELECTRONICS TECHNIQUE
2013年
18期
20-22
,共3页
组合电器%SF6分解物%故障诊断%绝缘设备
組閤電器%SF6分解物%故障診斷%絕緣設備
조합전기%SF6분해물%고장진단%절연설비
composite apparatus%SF6 decomposition product%fault diagnosis%insulated equipment
六氟化硫(SF6)气体在电弧、电火花和电晕放电的作用下会发生分解,产生二氧化碳(CO2)、四氟化碳(CF4)等分解产物。SF6气体组分分析(可在设备带电状态下进行)是诊断SF6气体绝缘设备内部运行情况的一个强有力的手段,据此可判断设备是否故障,并确定故障的具体部位,近年来已有不少成功案例。探讨了GIS 中典型放电性故障特征及相应的SF6气体分解产物和分解机理,给出了不同放电类型故障相关试验结果,并对最常见的电晕放电故障给出了放电量与分解产物的关系。在此基础上,归纳了不同放电故障下主要气体分解产物的反应方程,并应用于一起GIS故障分析,为GIS 潜伏性故障及其故障类型判断累积经验。
六氟化硫(SF6)氣體在電弧、電火花和電暈放電的作用下會髮生分解,產生二氧化碳(CO2)、四氟化碳(CF4)等分解產物。SF6氣體組分分析(可在設備帶電狀態下進行)是診斷SF6氣體絕緣設備內部運行情況的一箇彊有力的手段,據此可判斷設備是否故障,併確定故障的具體部位,近年來已有不少成功案例。探討瞭GIS 中典型放電性故障特徵及相應的SF6氣體分解產物和分解機理,給齣瞭不同放電類型故障相關試驗結果,併對最常見的電暈放電故障給齣瞭放電量與分解產物的關繫。在此基礎上,歸納瞭不同放電故障下主要氣體分解產物的反應方程,併應用于一起GIS故障分析,為GIS 潛伏性故障及其故障類型判斷纍積經驗。
륙불화류(SF6)기체재전호、전화화화전훈방전적작용하회발생분해,산생이양화탄(CO2)、사불화탄(CF4)등분해산물。SF6기체조분분석(가재설비대전상태하진행)시진단SF6기체절연설비내부운행정황적일개강유력적수단,거차가판단설비시부고장,병학정고장적구체부위,근년래이유불소성공안례。탐토료GIS 중전형방전성고장특정급상응적SF6기체분해산물화분해궤리,급출료불동방전류형고장상관시험결과,병대최상견적전훈방전고장급출료방전량여분해산물적관계。재차기출상,귀납료불동방전고장하주요기체분해산물적반응방정,병응용우일기GIS고장분석,위GIS 잠복성고장급기고장류형판단루적경험。
SF6 gas decomposition may occur in the role of electric arc,sparks and corona discharge,and produce carbon dioxide(CO2),four carbon fluoride(CF4)and other decomposition products. SF6 gas component analysis,which can be done in a electrification state)is a powerful method to diagnose the internal operation status of SF6 gas insulated equipment. It can deter-mine whether the equipment fault has existed or not,and make sure the fault position. In recent years,there have been a lot of successful cases. The typical discharge fault characteristics in gas insulated swtchgear(GIS),and the corresponding SF6 gas de-composition products and decomposition mechanism are dicussed. The relevant test results of different kinds of discharge failures are given. The relationship between the common corona discharge faults and decomposition products is pointed out. On this ba-sis,the reaction equation of main gas decomposition products generating under different discharge faults are summed up. It was applied to a GIS failure analysis. The experience were accumulated for GIS potential faults and fault type judgement.
