中国电机工程学报
中國電機工程學報
중국전궤공정학보
Proceedings of the CSEE
2015年
11期
2887-2895,后插29
,共10页
应展烽%冯凯%杜志佳%柳亚芳%吴军基
應展烽%馮凱%杜誌佳%柳亞芳%吳軍基
응전봉%풍개%두지가%류아방%오군기
高压架空导线%热路模型%轴向温度分布%参数辨识
高壓架空導線%熱路模型%軸嚮溫度分佈%參數辨識
고압가공도선%열로모형%축향온도분포%삼수변식
high voltage overhead conductor%thermal circuit model%axial temperature distribution%grey box identification
不同电流时的高压架空导线轴向温度分布对输电系统安全运行具有重要意义.根据热平衡原理,提出了基于状态方程形式的轴向热路模型.为验证模型精度,设计了导线温度测量实验平台,利用接续管使实验导线轴向产生温度分布,在自然对流条件下对不同电流时的 LGJ—400 导线和LJG—240导线轴向温度进行了实测.利用线性回归方法,对模型中导热热阻和对流热阻进行了灰箱辨识.热阻辨识结果表明在环境条件相对稳定时,随着导线电流及平均实验数据所用时间窗长度的增加,导线导热热阻呈增大趋势,对流热阻呈减小趋势.通过求解轴向热路模型时域响应,得到了导线温度分布计算值.与实验结果对比表明,热路模型计算结果平均误差在3%以内,精度高于IEEE标准模型,能够用于计算自然对流下LGJ—400导线和LJG—240导线的轴向温度分布.
不同電流時的高壓架空導線軸嚮溫度分佈對輸電繫統安全運行具有重要意義.根據熱平衡原理,提齣瞭基于狀態方程形式的軸嚮熱路模型.為驗證模型精度,設計瞭導線溫度測量實驗平檯,利用接續管使實驗導線軸嚮產生溫度分佈,在自然對流條件下對不同電流時的 LGJ—400 導線和LJG—240導線軸嚮溫度進行瞭實測.利用線性迴歸方法,對模型中導熱熱阻和對流熱阻進行瞭灰箱辨識.熱阻辨識結果錶明在環境條件相對穩定時,隨著導線電流及平均實驗數據所用時間窗長度的增加,導線導熱熱阻呈增大趨勢,對流熱阻呈減小趨勢.通過求解軸嚮熱路模型時域響應,得到瞭導線溫度分佈計算值.與實驗結果對比錶明,熱路模型計算結果平均誤差在3%以內,精度高于IEEE標準模型,能夠用于計算自然對流下LGJ—400導線和LJG—240導線的軸嚮溫度分佈.
불동전류시적고압가공도선축향온도분포대수전계통안전운행구유중요의의.근거열평형원리,제출료기우상태방정형식적축향열로모형.위험증모형정도,설계료도선온도측량실험평태,이용접속관사실험도선축향산생온도분포,재자연대류조건하대불동전류시적 LGJ—400 도선화LJG—240도선축향온도진행료실측.이용선성회귀방법,대모형중도열열조화대류열조진행료회상변식.열조변식결과표명재배경조건상대은정시,수착도선전류급평균실험수거소용시간창장도적증가,도선도열열조정증대추세,대류열조정감소추세.통과구해축향열로모형시역향응,득도료도선온도분포계산치.여실험결과대비표명,열로모형계산결과평균오차재3%이내,정도고우IEEE표준모형,능구용우계산자연대류하LGJ—400도선화LJG—240도선적축향온도분포.
High voltage overhead conductor axial temperature distribution with various current is significant for the safe operation of electricity transmission system. An axial thermal circuit model in the form of state equation was proposed based on thermal equilibrium principle. The overhead conductor temperature measurement experiment platform which fitted with a connecting tube to generate axial temperature distribution was set up for verification of model accuracy. The LGJ—400 and LGJ—240 overhead conductor axial temperature with various current were measured under the condition of natural convection. The thermal conduction resistance and thermal convection resistance in the thermal circuit model were identified by grey box identification based on linear regression. The identification result of thermal resistance show that with the increasing current level and length of time window for experimental result average calculating operation, the thermal conduction resistance trends to be larger and the thermal convection resistance moves toward smaller under relatively stable environmental condition. The calculation results of overhead conductor axial temperature distribution with various current were obtained by solving time response of proposed model. Comparison of calculation results and experimental results shows that the average calculation error of proposed model is less than 3%. The accuracy of proposed model is better than IEEE standard model, and it can be used to calculate LGJ—400 and LGJ—240 overhead conductor axial temperature distribution with various current under the condition of natural convection.