流-电耦合场中金属颗粒群的荷电计算及影响因素研究

doi:10.19595/j.cnki.1000-6753.tces.231050

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (13667 KB) HTML
输出: BibTeX | EndNote (RIS)

摘要绝缘油中金属颗粒的荷电量分布是研究颗粒运动特性以及绝缘油中局部放电与击穿行为的关键。该文搭建了油道模拟观测系统,采用动力学分析的方法,构建了液固耦合系统中金属颗粒的运动模型,并在此基础上提出通过粒子图像测速（PIV）来计算颗粒荷电量;分析了不同油流速度、电压等级以及电压类型对颗粒荷电量的分布影响以及作用机理。结果表明,基于PIV计算出的油中颗粒的荷电量与传统模型的计算结果数量级相近,绝缘油中金属颗粒荷电量占比分布曲线接近高斯分布,这是由于颗粒与颗粒之间碰撞也会发生电荷转移或中和。在直流电压下流速增加会阻碍颗粒之间的电荷传递,增加颗粒与极板碰撞概率,导致颗粒荷电量减小。电压等级增加则会使颗粒群的流线由平缓变为振荡,颗粒荷电量普遍增加。相比于直流电压,在交流电压下,荷电量大的颗粒占比较多。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	张宁
	王鹏
	刘智捷
	刘恭智
	贺博

关键词 ：粒子图像测速, 金属颗粒, 绝缘油, 液固耦合, 荷电分布

Abstract：In the life cycle of power equipment, the insulating oil is easy to mix with various solid impurity particles such as metal and fiber, which will cause electric field distortion and insulation balance failure of equipment. Therefore, considering that compared with non-metallic particles, metal particles have a greater impact on partial discharge and arc breakdown of oil, this paper proposes a method to derive the charge of particles by analyzing the force model of metal particles on the basis of discrete particle model, and reveals the influence of electric field intensity, voltage type and flow velocity on the charge distribution of metal particles.
Firstly, the internal oil channel environment of power transformer was simulated and the experimental observation platform for particles in oil was built. Secondly, the force model of metal particles in the fluid electric coupling system was established combined with fluid dynamics. The formula for calculating the charge of metal particles under experimental conditions was derived through the formula. Thirdly, the particle image velocimetry (PIV) system was used to capture the cloud picture of particle swarm velocity and streamline, and the velocity and acceleration of metal particles were calculated through the streamline of particles and the finite difference method, so as to calculate the charge of particles, which was close to the charge of particles calculated by the traditional model. Finally, by changing the applied voltage, oil flow rate and voltage type, the charge value and distribution of metal particles in the oil flow were calculated and counted.
The experimental results show that when the flow rate of insulating oil is 0.15 m/s, the maximum charge of particles is 0.17 pC, and the proportion of particles with the absolute value of charge greater than 0.01 pC is 36%, while when the flow rate is 0.3 m/s, the maximum charge of particles is -0.13 pC, and the proportion of particles with the absolute value of charge greater than 0.01 pC is 29%, which may be due to the increase of horizontal drag force on particles when the flow rate of oil increases. The time of particles flowing through the electric field region is shortened. When the voltage is -10 kV, the maximum charge of particles is 0.05 pC, and the proportion of particles whose absolute value of charge is greater than 0.01 pC is 12%. When the voltage is -20 kV, the maximum charge of particles is 0.09 pC, and the proportion of particles whose absolute value of charge is greater than 0.01pC is 25%. When the voltage is -30 kV, the maximum charge of particles is 0.17 pC, and the proportion of particles whose absolute value of charge is greater than 0.01 pC is 36%. The acceptable explanation is that the increase of electric field intensity leads to the increase of collision probability between particles and electrodes. When the applied voltage is AC, the proportion of particles with the absolute value of charge greater than 0.01 pC is about 10%, and the maximum charge of particles is 0.03 pC.
Through the above analysis, it can be concluded that: (1) The maximum charge of particles is in the same order of magnitude as the traditional model, but the distribution curve of the charge proportion of particles is close to the Gaussian distribution. (2) With the increase of insulating oil flow rate, the movement time of particles in the electric field between electrodes is reduced, resulting in the reduction of the probability of particles colliding with electrodes in the same time interval, and the proportion of particles not colliding with electrodes is increased. (3) The velocity component of particles in the vertical direction increases, the collision between particles and electrodes becomes frequent, and the charge of particles generally increases. (4) When the applied voltage is AC, the particles with large charge account for less.

Key words： Particle image velocimetry metal particles insulating oil liquid solid coupling charge distribution

收稿日期: 2023-07-05

PACS:

TM855

基金资助:国家自然科学基金资助项目（51977170）

通讯作者: 贺博男,1976年生,教授,博士生导师,研究方向为高电压与绝缘技术领域的基础理论、电力设备绝缘性能分析与绝缘结构优化设计、复合电介质形态结构与性能关系等。E-mail：hebo@mail.xjtu.edu.cn

作者简介: 张宁男,2000年生,硕士研究生,研究方向为绝缘介质特性以及电力设备绝缘结构仿真。E-mail：zi1213123321456@stu.xjtu.edu.cn

引用本文:

张宁, 王鹏, 刘智捷, 刘恭智, 贺博. 流-电耦合场中金属颗粒群的荷电计算及影响因素研究[J]. 电工技术学报, 2024, 39(17): 5534-5544. Zhang Ning, Wang Peng, Liu Zhijie, Liu Gongzhi, He Bo. Study on the Charge Calculation and Influencing Factors of Metal Particle Groups in Fluid-Electric Coupling Field. Transactions of China Electrotechnical Society, 2024, 39(17): 5534-5544.

链接本文:

https://dgjsxb.ces-transaction.com/CN/10.19595/j.cnki.1000-6753.tces.231050 https://dgjsxb.ces-transaction.com/CN/Y2024/V39/I17/5534

[1] 刘道生, 周春华, 丁金, 等. 变压器纳米改性油纸复合绝缘研究综述[J]. 电工技术学报, 2023, 38(9): 2464-2479, 2490.
Liu Daosheng, Zhou Chunhua, Ding Jin, et al.Research overview of oil-paper composite insulation modified by nano particles for transformer[J]. Transactions of China Electrotechnical Society, 2023, 38(9): 2464-2479, 2490.
[2] 张宁, 刘士利, 郝建, 等. 变压器油中气泡杂质相局部放电特性研究综述[J]. 电工技术学报, 2023, 38(10): 2757-2776.
Zhang Ning, Liu Shili, Hao Jian, et al.Review on partial discharge characteristics of bubble impurity phase in transformer oil[J]. Transactions of China Electrotechnical Society, 2023, 38(10): 2757-2776.
[3] 谢小荣, 贺静波, 毛航银, 等. “双高”电力系统稳定性的新问题及分类探讨[J]. 中国电机工程学报, 2021, 41(2): 461-475.
Xie Xiaorong, He Jingbo, Mao Hangyin, et al.New issues and classification of power system stability with high shares of renewables and power electronics[J]. Proceedings of the CSEE, 2021, 41(2): 461-475.
[4] 王有元, 吴俊锋, 徐海鹰. 电力设备局部放电超高频信号检测用新型微带天线[J]. 电工技术学报, 2016, 31(10): 136-144.
Wang Youyuan, Wu Junfeng, Xu Haiying.A new microstrip antenna used for detecting the ultra-high frequency signal caused by the partial discharge in power equipments[J]. Transactions of China Electrotechnical Society, 2016, 31(10): 136-144.
[5] 张国治, 闫伟阳, 王堃, 等. 流动绝缘油中纤维杂质颗粒运动特性仿真研究[J]. 电工技术学报, 2023, 38(9): 2500-2509.
Zhang Guozhi, Yan Weiyang, Wang Kun, et al.Simulation research on movement characteristics of fiber impurity particles in flowing insulating oil[J]. Transactions of China Electrotechnical Society, 2023, 38(9): 2500-2509.
[6] 骆欣瑜. 换流变压器油道中带电自由金属微粒运动规律和局部放电特性研究[D]. 重庆: 重庆大学, 2020.
Luo Xinyu.Transformers particles in the oil channel of converter characteristics of free charged metallic investigations on motion behaviors and PD[D]. Chongqing: Chongqing University, 2020.
[7] 黄宇辰, 房俊龙, 闫伟阳. 不同电压类型下油流中纤维杂质颗粒运动特性仿真研究[J]. 高电压技术, 2022, 48(12): 4817-4828.
Huang Yuchen, Fang Junlong, Yan Weiyang.Simulation research on the motion characteristics of fiber impurity particles in oil flow under different voltage types[J]. High Voltage Engineering, 2022, 48(12): 4817-4828.
[8] 孙继星, 陈维江, 李志兵, 等. 直流电场下运动金属微粒的带电估算与碰撞分析[J]. 高电压技术, 2018, 44(3): 779-786.
Sun Jixing, Chen Weijiang, Li Zhibing, et al.Charge estimation and impact analysis of moving metal particle under DC electric field[J]. High Voltage Engineering, 2018, 44(3): 779-786.
[9] 董曼玲, 寇晓适, 姚德贵, 等. 交直流复合电压下变压器油中金属微粒聚集特性和局部放电特性研究[J]. 绝缘材料, 2022, 55(10): 74-79.
Dong Manling, Kou Xiaoshi, Yao Degui, et al.Aggregation behaviors and partial discharge characteristics of metal particles in transformer oil under AC/DC composite voltage[J]. Insulating Materials, 2022, 55(10): 74-79.
[10] 骆仲泱, 江建平, 赵磊, 等. 不同电场中细颗粒物的荷电特性研究[J]. 中国电机工程学报, 2014, 34(23): 3959-3969.
Luo Zhongyang, Jiang Jianping, Zhao Lei, et al.Research on the charging of fine particulate in different electric fields[J]. Proceedings of the CSEE, 2014, 34(23): 3959-3969.
[11] 但敏, 郝建, 廖瑞金, 等. 直流电压下矿物油和天然酯中纤维颗粒运动及成桥特性的差异[J]. 电网技术, 2018, 42(2): 665-672.
Dan Min, Hao Jian, Liao Ruijin, et al.Different motion and bridging characteristics of fiber particles in mineral oil and natural ester under DC voltage[J]. Power System Technology, 2018, 42(2): 665-672.
[12] Khayari A, Perez A T.Charge acquired by a spherical ball bouncing on an electrode: comparison between theory and experiment[J]. IEEE Transactions on Dielectrics and Electrical Insulation, 2002, 9(4): 589-595.
[13] Sarathi R, Archana M.Investigation of partial discharge activity by a conducting particle in transformer oil under harmonic AC voltages adopting UHF technique[J]. IEEE Transactions on Dielectrics and Electrical Insulation, 2012, 19(5): 1514-1520.
[14] Wei Chao, Wang Shengquan, Lu Yuncai, et al.Influence of metallic particles on the breakdown voltage of insulating oil at AC and DC voltage[C]//2016 IEEE Electrical Insulation Conference (EIC), Montreal, QC, Canada, 2016: 280-283.
[15] 尹克宁. 变压器设计原理[M]. 北京: 中国电力出版社, 2003.
[16] 于萍. 工程流体力学[M]. 2版. 北京: 科学出版社, 2015.
[17] Gouesbet G, Berlemont A.Eulerian and Lagrangian approaches for predicting the behaviour of discrete particles in turbulent flows[J]. Progress in Energy and Combustion Science, 1999, 25(2): 133-159.
[18] 麻守孝, 唐炬, 张明君, 等. 牵引变压器中运动金属颗粒群的分布状态及影响因素仿真研究[J]. 高电压技术, 2015, 41(11): 3628-3634.
Ma Shouxiao, Tang Ju, Zhang Mingjun, et al.Simulation study on distribution and influence factors of metal particles in traction transformer[J]. High Voltage Engineering, 2015, 41(11): 3628-3634.
[19] 贺博, 王鹏, 吴锴, 等. 多物理场中染污绝缘油内杂质相动力学行为研究综述[J]. 电工技术学报, 2022, 37(1): 266-282.
He Bo, Wang Peng, Wu Kai, et al.Reviews on impurity phase dynamics in contaminated insulating oil under multi-physical field conditions[J]. Transactions of China Electrotechnical Society, 2022, 37(1): 266-282.
[20] 刘刚, 王晓晗, 马永强, 等. 基于控制体—迎风有限元法的变压器绕组二维流体场—温度场耦合计算方法研究[J]. 高压电器, 2021, 57(6): 1-9.
Liu Gang, Wang Xiaohan, Ma Yongqiang, et al.Study on coupled calculation method of two dimensional fluid and temperature field of transformer winding based on control volume-upstream FEM[J]. High Voltage Apparatus, 2021, 57(6): 1-9.
[21] 李维仲, 姜远新. 小木球在固液两相流中上升规律研究及Magnus力测量[J]. 大连理工大学学报, 2011, 51(5): 653-657.
Li Weizhong, Jiang Yuanxin.Research on rising motion rule of wooden ball in solid-liquid two-phase flow and its Magnus force measurement[J]. Journal of Dalian University of Technology, 2011, 51(5): 653-657.
[22] 张国强, 吴家鸣. 流体力学[M]. 北京: 机械工业出版社, 2006.
[23] 刘大有. 二相流体动力学[M]. 北京: 高等教育出版社, 1993.
[24] Bermúdez A, Rodríguez R.Finite element computation of the vibration modes of a fluid—solid system[J]. Computer Methods in Applied Mechanics and Engineering, 1994, 119(3/4): 355-370.
[25] Wang L K, Pereira N C, Hung Y T.Air Pollution Control Engineering[M]. New Jersey: Humana Press, 2004.
[26] 程林, 李兴兴, 唐炬, 等. 不同温度下含金属微粒的流动液体绝缘介质放电形成过程与机理分析[J]. 高电压技术, 2018, 44(9): 2917-2925.
Cheng Lin, Li Xingxing, Tang Ju, et al.Discharge process and its mechanism analysis in flowing liquid dielectric containing metal particles at different temperatures[J]. High Voltage Engineering, 2018, 44(9): 2917-2925.
[27] Cheng L, Soo S L.Charging of dust particles by impact[J]. Journal of Applied Physics, 1970, 41(2): 585-591.
[28] 申南轩, 苏子寒, 张远航, 等. 湿度对悬浮液滴荷电特性及离子流场特性的影响[J]. 电工技术学报, 2022, 37(13): 3422-3430, 3452.
Shen Nanxuan, Su Zihan, Zhang Yuanhang, et al.Influence of humidity on the charge characteristics of suspension droplets and the characteristics of ion flow field[J]. Transactions of China Electrotechnical Society, 2022, 37(13): 3422-3430, 3452.