高电压技术
高電壓技術
고전압기술
HIGH VOLTAGE ENGINEERING
2012年
9期
2366-2372
,共7页
吴锴%朱庆东%王浩森%吕泽鹏%王霞
吳鍇%硃慶東%王浩森%呂澤鵬%王霞
오개%주경동%왕호삼%려택붕%왕하
双层油纸绝缘%空间电荷%油纸界面%温度梯度%电场畸变%油纸电导%电极注入
雙層油紙絕緣%空間電荷%油紙界麵%溫度梯度%電場畸變%油紙電導%電極註入
쌍층유지절연%공간전하%유지계면%온도제도%전장기변%유지전도%전겁주입
double-layer oil impregnated paper%space charge%oiled paper interface%temperature gradient%electricfield distortion%oiled paper conductivity%electrode injection
换流变压器为直流高压输电系统中的重要设备,但因其运行工况的特殊性,其内部油纸等绝缘材料往往承受较大的内外温度差异作用。针对换流变压器中双层油纸绝缘系统存在的内外温度不同的温度梯度效应对油纸绝缘中空间电荷分布的影响,利用电声脉冲法测量了不同温度梯度下(Δθ=0、20、40°C),电压分别为-3.4、-10.2、-20.4kV(即平均电场强度分别为10、30、60MV/m)时双层油纸中空间电荷在20min内随时间变化规律及电场分布。实验结果表明:在低场强下,上下电极均有明显的同极性电荷注入;温度梯度使低温侧出现异极性电荷,并且随着温度梯度的增大、电压的升高,低温侧异极性电荷越来越多,从而使低温侧的场强畸变越来越大;加压后,2层油纸界面处开始积累与上电极相同极性的电荷,并且界面处电荷量随温度梯度及电压的增大而增大,但电荷密度出现饱和现象。经分析可知,油纸界面起到阻挡正负电荷通过的作用,而温度对电极注入特性及试样电导特性的影响为温度梯度影响空间电荷分布的主要原因。
換流變壓器為直流高壓輸電繫統中的重要設備,但因其運行工況的特殊性,其內部油紙等絕緣材料往往承受較大的內外溫度差異作用。針對換流變壓器中雙層油紙絕緣繫統存在的內外溫度不同的溫度梯度效應對油紙絕緣中空間電荷分佈的影響,利用電聲脈遲法測量瞭不同溫度梯度下(Δθ=0、20、40°C),電壓分彆為-3.4、-10.2、-20.4kV(即平均電場彊度分彆為10、30、60MV/m)時雙層油紙中空間電荷在20min內隨時間變化規律及電場分佈。實驗結果錶明:在低場彊下,上下電極均有明顯的同極性電荷註入;溫度梯度使低溫側齣現異極性電荷,併且隨著溫度梯度的增大、電壓的升高,低溫側異極性電荷越來越多,從而使低溫側的場彊畸變越來越大;加壓後,2層油紙界麵處開始積纍與上電極相同極性的電荷,併且界麵處電荷量隨溫度梯度及電壓的增大而增大,但電荷密度齣現飽和現象。經分析可知,油紙界麵起到阻擋正負電荷通過的作用,而溫度對電極註入特性及試樣電導特性的影響為溫度梯度影響空間電荷分佈的主要原因。
환류변압기위직류고압수전계통중적중요설비,단인기운행공황적특수성,기내부유지등절연재료왕왕승수교대적내외온도차이작용。침대환류변압기중쌍층유지절연계통존재적내외온도불동적온도제도효응대유지절연중공간전하분포적영향,이용전성맥충법측량료불동온도제도하(Δθ=0、20、40°C),전압분별위-3.4、-10.2、-20.4kV(즉평균전장강도분별위10、30、60MV/m)시쌍층유지중공간전하재20min내수시간변화규률급전장분포。실험결과표명:재저장강하,상하전겁균유명현적동겁성전하주입;온도제도사저온측출현이겁성전하,병차수착온도제도적증대、전압적승고,저온측이겁성전하월래월다,종이사저온측적장강기변월래월대;가압후,2층유지계면처개시적루여상전겁상동겁성적전하,병차계면처전하량수온도제도급전압적증대이증대,단전하밀도출현포화현상。경분석가지,유지계면기도조당정부전하통과적작용,이온도대전겁주입특성급시양전도특성적영향위온도제도영향공간전하분포적주요원인。
Temperature gradient existing in the oil impregnated paper insulation such as converting transformer or DC bushing affects the space charge distribution. The space charge profiles and field distributions in double layers of oil impregnated paper within 20 minutes were measured by the pulse electro-acoustic method under different temperature differences(Δθ=0、20、40°C), and DC voltage of - 3. 4, - 10. 2, - 20. 4 kV (DC electric field intensity of 10, 30, 60 MV/m), respectively. The test results show that homocharge exists in both electrodes when the electric field intensity was low, and the heterocharge appears in the low temperature side due to the temperature difference. Moreover, the more remarkable the temperature difference and electric filed intensity were, the more the heterocharge at the low temperature side is, resulting in a greater field distortion. The homocharge of the upelectrode starts to accumulate in the space between two layers of oil impregnated paper. The higher the temperature and electric field intensity were, the more the space charge were while the density of the charge is saturated. The result suggests that the oil paper interface plays the role in preventing the charge from passing by, and the temperature is the main factor which affects the space charge distribution and the electricity conduction of the sample.
