高电压技术
高電壓技術
고전압기술
HIGH VOLTAGE ENGINEERING
2012年
11期
3067-3073
,共7页
程子霞%薛文彬%周远翔%刘睿%岳振国%金金元
程子霞%薛文彬%週遠翔%劉睿%嶽振國%金金元
정자하%설문빈%주원상%류예%악진국%금금원
电缆载流量%有限元法(FEM)%涡流损耗%电气化铁路%单相电缆%接地方式
電纜載流量%有限元法(FEM)%渦流損耗%電氣化鐵路%單相電纜%接地方式
전람재류량%유한원법(FEM)%와류손모%전기화철로%단상전람%접지방식
cable ampacity%finite element modeling(FEM)method%eddy-current loss%electrified railway%singlephase cable%bonded mode
电气化铁路单相供电电缆是电气化铁路运行的关键组成部分,为获得铁路专用27.5kV单相单芯交联聚乙烯电缆的载流量,通过仿真计算的方法进行了研究。首先对电缆的运行情况进行分析,用有限元法对比计算了单相供电与三相供电条件下电缆金属护套涡流与环流损耗。在对电缆的环流损耗与涡流损耗计算的过程中,通过对计算单元自由度的修改与温度场的耦合,为电气化铁路单相供电电缆载流量计算建立更为精确的计算模型。在该模型的基础上,根据铁路电缆实际敷设环境,分析了不同接地方式、线芯间距、回路数量、媒质热阻、环境温度下电缆载流量的变化。结果表明:双端接地方式下铁路单相供电电缆金属护套层环流损耗较三相供电提高约75%,单端接地方式下相位影响不明显;电缆温升受相邻电缆间距、周围媒质热阻及温度影响较大;回路数增多,受临近电缆的影响,中间电缆的温升将导致电缆整体载流量下降。
電氣化鐵路單相供電電纜是電氣化鐵路運行的關鍵組成部分,為穫得鐵路專用27.5kV單相單芯交聯聚乙烯電纜的載流量,通過倣真計算的方法進行瞭研究。首先對電纜的運行情況進行分析,用有限元法對比計算瞭單相供電與三相供電條件下電纜金屬護套渦流與環流損耗。在對電纜的環流損耗與渦流損耗計算的過程中,通過對計算單元自由度的脩改與溫度場的耦閤,為電氣化鐵路單相供電電纜載流量計算建立更為精確的計算模型。在該模型的基礎上,根據鐵路電纜實際敷設環境,分析瞭不同接地方式、線芯間距、迴路數量、媒質熱阻、環境溫度下電纜載流量的變化。結果錶明:雙耑接地方式下鐵路單相供電電纜金屬護套層環流損耗較三相供電提高約75%,單耑接地方式下相位影響不明顯;電纜溫升受相鄰電纜間距、週圍媒質熱阻及溫度影響較大;迴路數增多,受臨近電纜的影響,中間電纜的溫升將導緻電纜整體載流量下降。
전기화철로단상공전전람시전기화철로운행적관건조성부분,위획득철로전용27.5kV단상단심교련취을희전람적재류량,통과방진계산적방법진행료연구。수선대전람적운행정황진행분석,용유한원법대비계산료단상공전여삼상공전조건하전람금속호투와류여배류손모。재대전람적배류손모여와류손모계산적과정중,통과대계산단원자유도적수개여온도장적우합,위전기화철로단상공전전람재류량계산건립경위정학적계산모형。재해모형적기출상,근거철로전람실제부설배경,분석료불동접지방식、선심간거、회로수량、매질열조、배경온도하전람재류량적변화。결과표명:쌍단접지방식하철로단상공전전람금속호투층배류손모교삼상공전제고약75%,단단접지방식하상위영향불명현;전람온승수상린전람간거、주위매질열조급온도영향교대;회로수증다,수림근전람적영향,중간전람적온승장도치전람정체재류량하강。
We numerically researched the ampacity of 27.5kV single-phase single-core power cables that were used in traction substation.The operating condition was analyzed based on calculations of the circulation loss and eddy current loss of the cable under single-phase and three-phase conditions respectively by using the finite element modeling(FEM)method.A more accurate ampacity calculating model of the cable for cases with single-phase power supply was established by modifying the degree of freedom of the calculating unit and by coupling the thermal analysis of calculation the temperature distribution.On the basis of the model,according to the actual environment of railway cable,changes in the cable ampacity were analyzed in different grounding connections,cable distances,loop numbers,thermal resistances of surrounding media and environment temperatures.Several conclusions can be drawn as follows:for a cable with sheath layers grounded in two terminals,its circulation loss in single-phase mode is 75% more than that in three-phase mode,while the phase condition has little effect on cables with sheath layers grounded in one terminal;the distances between cables,the thermal resistance of surrounding media,and the environment temperature affect the cable temperature seriously;with the increase of cable loops,the temperature of the cables in the middle of the cable loops rises obviously which will result in an overall ampacity decrease of the cable group.
