干式空心电抗器五环简化缩比模型最优结构对比分析

doi:10.19595/j.cnki.1000-6753.tces.212145

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摘要在干式空心电抗器的空间磁场预测方面,三环简化缩比模型是一种实用的方法,针对其预测精度不高的问题,该文提出了干式空心电抗器的五环简化缩比模型。首先推导原模型和两种简化缩比模型空间磁场分布的计算公式,然后拟合原模型高径比H/D和简化模型参数的函数表达式,最后搭建磁场测量平台对仿真结果进行验证。研究结果表明：线圈匝数不变只调整位置时,五环简化模型由于两两线圈间漏磁更小,其对应的方均根误差（RMSE）和绝对百分比误差（MAPE）分别比三环简化模型降低了18 %和17 %,决定系数（R²）提高了4 %;线圈的匝数和位置均可调整时,五环简化模型不但可以减小漏磁,还可以同时减小4个监测方向上的误差,其对应的RMSE和MAPE相比三环简化模型分别降低了40 %和21 %,具有较高的等效精度;试验表明,五环简化模型最优结构对应的RMSE和MAPE分别比三环简化模型降低了21 %和22 %。建立某空心电抗器的三环和五环简化缩比模型,并进行了现场试验,结果表明,五环简化缩比模型在准确等效电抗器空间磁场分布的同时,RMSE和MAPE分别比三环简化模型降低了38.7 %和4.9 %,证明了五环简化缩比模型具有更高的准确性。

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	代岭均
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关键词 ：干式空心电抗器, 空间磁场分布, 五环简化模型, 三环简化模型, 最优结构

Abstract：The large dry hollow reactor has been widely used in HV and UHV power systems due to its high linearity, low loss, stable parameters, and low resistance. However, with the increase of the voltage level and size of the hollow reactor, the magnetic field will be generated in the surrounding space. It is necessary to establish a scale-down model for predicting the magnetic field distribution of the large hollow reactor in the design stage to provide the theoretical and technical basis for designing and manufacturing of the large hollow reactor. The three-ring simplified model can effectively predict the spatial magnetic field distribution of the hollow reactor, but the accuracy is limited. Therefore, a five-ring simplified scaled model of the dry hollow reactor is proposed, in which the number of turns and position of the coil can be adjusted.
According to the structural parameters of the model, the formulas for calculating the spatial magnetic field distribution of the original model and two simplified scaled models are derived. Under the premise of constant coil turns, the influence of coil position on spatial magnetic field distribution is studied, and the function expression of the position parameters of the five rings and the height-to-diameter ratio H/D of the original model is fitted. Comparing the magnetic induction intensity in four specific directions between the original model and the optimal five-ring simplified model, the five-ring simplified model can well simulate the magnetic induction intensity of the original model without considering the effect of equivalent errors in the near-field region. The root means square error (RMSE) and absolute percentage error (MAPE) of the five-ring simplified scaled model were reduced by 18 % and 17 %, respectively, and the coefficient of determination (R²) was increased by 4 % compared with the three-ring simplified model. When the number of turns and the position of the coil can be adjusted, the optimal position and the number of turns of the five rings are determined based on the least square method and the minimum sum of the square losses in each direction. The function expression of the structure parameters of the simplified model of the optimal five rings and the height-to-diameter ratio H/D of the original model is fitted. The five-ring simplified model can not only reduce the magnetic flux leakage, but also reduce the error in the four monitoring directions at the same time. Compared with the three-ring simplified model, the corresponding RMSE and MAPE are reduced by 40 % and 21 %, respectively, and have higher equivalent accuracy.
It is found that the RMSE and MAPE corresponding to the optimal structural parameters of the five-ring simplified scaling model are reduced by 21 % and 22 %, respectively, compared with the three-ring simplified scaling model. Therefore, it is proved that the five-ring simplified model has higher prediction accuracy than the three-ring simplified model in magnetic field prediction. The field test measurements are carried out in the converter station. Compared with the measurement data of two simplified scale models, it is also proved that the simplified scale model of five rings has a better equivalent effect of space magnetic field.

Key words： Dry-type air-core reactor (DAR) spatial magnetic field distribution (SMFD) five-loop simplified scaling model three-loop simplified scaling model optimal structure

收稿日期: 2021-12-30

PACS:

TM47

基金资助:国家自然科学基金项目（51977122）、新能源电力系统国家重点实验室开放课题项目（LAPS22003）和南方电网科技项目（CGYKJXM20200228）资助

通讯作者: 邹亮男,1983年生,教授,博士生导师,研究方向为高电压与绝缘技术、应用电磁学等。E-mail: zouliang@sdu.edu.cn

作者简介: 代岭均女,1999年生,硕士研究生,研究方向为高电压与绝缘技术。E-mail: 202114542@mail.sdu.edu.cn

引用本文:

代岭均, 邹亮, 孙玉鑫, 刘青松, 张黎. 干式空心电抗器五环简化缩比模型最优结构对比分析[J]. 电工技术学报, 2023, 38(4): 1088-1103. Dai Lingjun, Zou Liang, Sun Yuxin, Liu Qingsong, Zhang Li. Investigation of Comparison on Optimal Structure of Five-Loop Simplified Scaling Model for Dry-Type Air-Core Reactors. Transactions of China Electrotechnical Society, 2023, 38(4): 1088-1103.

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