特高压交流GIS/GIL拔孔型陷阱优化设计与协同布置方法  被引量：5

作　　者：耿秋钰 胡智莹 李庆民 庄添鑫 刘焱 Geng Qiuyu;Hu Zhiying;Li Qingmin;Zhuang Tianxin;Liu Yan(State Key Laboratory of Alternate Electrical Power System with Renewable Energy Sources North China Electric Power University ,Beijing 102206 China;Jiangsu Electric Power Research Institute,Nanjing 210036 China;China Electric Power Research Institute, Beijing 100192 China)

机构地区：[1]新能源电力系统全国重点实验室(华北电力大学),北京102206 [2]江苏电力科学研究院,南京210036 [3]中国电力科学研究院有限公司,北京100192

出　　处：《电工技术学报》2023年第23期6539-6552,共14页Transactions of China Electrotechnical Society

基　　金：国家电网有限公司科技项目资助(5500-202155109A-0-0-00)。

摘　　要：交流气体绝缘组合电器(GIS)和气体绝缘输电管道(GIL)内的运动金属微粒是诱发设备绝缘故障的重要因素,且特高压下的运动金属微粒引发设备绝缘故障的概率更大,而微粒陷阱可抑制金属微粒的运动,但实际工程中的微粒陷阱仍缺乏主动捕获微粒的能力。该文首先基于GIS/GIL内金属微粒动力学模型,分析了拔孔型陷阱的微粒主动捕获机制,进而根据金属微粒荷电运动与碰撞动力学特性,建立了拔孔型陷阱捕获概率计算模型,考虑陷阱的捕获能力对拔孔型陷阱的结构参数进行优化设计。具体结果表明,针对苏通工程中的特高压交流GIL,当陷阱直径为60cm、深度为30cm时,拔孔型陷阱抑制微粒效果达到最佳。进一步考虑微粒碰撞反射角的随机性,将拔孔型陷阱附近捕获率大于90%的区域定义为有效捕获范围,优化的拔孔型陷阱的有效捕获范围为32cm。最后,通过分析栅格型陷阱与拔孔型陷阱轴向电场分布,表明栅格型陷阱能够增强拔孔型陷阱的有效捕获范围,并以提高绝缘子附近的微粒抑制效果为目标,提出了绝缘子附近栅格型与拔孔型陷阱的协同布置方法。AC gas insulated switchgear and transmission lines faces critical insulation failure challenges caused by metal particles inside,and the probability of insulation failure caused by metal particles under UHV increases.However,the particle traps in practical engineering,the key devices available to inhibit the movement of particles,lack the ability to proactively capture particles.Firstly,this paper analyzes the mechanism of active particle capture by convex-shaped trap based on the dynamic model of metal particles in GIS/GIL.By analyzing the force of particles and the axial electric field distribution of the convex-shaped trap,this paper considers that the axial electric field distribution near the convex-shaped traps is an important factor leading to the active trapping of metal particles.The external voltage is applied to the starting voltage.Considering the applied voltage is AC voltage,the initial time should be set.Due to the electrostatic induction,the metal particles are negatively charged,and the metal particles on both sides of the trap move towards the trap direction.At the same time,the maximum moving height of the trapped particles under AC voltage is 2~8 cm,so the particles in the trap cannot escape from the trap.Based on the force analysis of particles,it can not only analyze the active capture mechanism of the convex-shaped trap,but also provide a theoretical basis for the subsequent establishment of the capture range calculation model of the convex-shaped trap.On this basis,this paper realizes the performance test and optimization design of the convex-shaped trap.According to the charged motion and collision dynamics characteristics of metal particles,the model for calculating the capture probability of the convex-shaped trap is established,and the structural parameters of the convex-shaped trap should be optimized considering the capture ability of trap.The results illustrate when the diameter of trap is 60 cm and the depth of trap is 30 cm in the UHV GIS/GIL of Sutong GIL Comprehensive Pipe Corri

关 键 词：特高压 GIS/GIL 拔孔型陷阱 栅格型陷阱 优化设计 协同布置方法 

分 类 号：TM85[电气工程—高电压与绝缘技术]