基于ESLE采样和径向基函数响应面法的变压器静电环结构优化设计

doi:10.19595/j.cnki.1000-6753.tces.221608

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摘要变压器的运行安全稳定与其内部绝缘结构密切相关,为了提高变压器的绝缘性能,本文以提高最小绝缘裕度为优化目标,通过径向基函数响应面模型优化变压器主绝缘结构。为提高响应面模型预测优化的准确性,选用采样更均匀的ESLE (改进的连续局部枚举)方法进行试验设计,优化后的变压器最小绝缘裕度比优化前提高了12.56%。将优化结果分别从采样、模型和优化方法三个角度进行了对比,与LHS（拉丁超立方采样）采样下的径向基函数响应面模型对比,ESLE方法的引入使得优化精度提高了218倍;与ESLE采样下的二次多项式响应面模型对比,径向基函数响应面模型的引入降低了模型预测误差并使优化精度提高了78倍;和遗传算法对比,在相同的优化精度下,优化效率是遗传算法的10倍。上述结果表明本文所提模型具有很高的预测精度和优化能力,同时相比于遗传算法优化,在保证优化质量的同时,显著地提高了优化效率。本文所提出的方法为变压器主绝缘结构优化问题提供了较好的解决方案。

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关键词 ：响应面方法, 改进的连续局部枚举ESLE, 径向基函数, 绝缘裕度, 变压器, 结构优化

Abstract：The transformer main insulation structure needs be reasonably designed to ensure its safe and reliable operation. The RSM (response surface method) is an efficient tool to the optimization problem of transformer main insulation structure. In the field of traditional transformer structure optimization, the RSM is widely used due to its superior optimization accuracy and efficiency in comparison to the empirical formula method and the global optimization algorithm. This paper proposes combining the ESLE (Enhanced Successful Local Enumeration) method with upgraded sampling uniformity and the RBF(radial basis function)-RSM with superior nonlinear fitting capability to solve the main insulation structure optimization problem, whose optimization objective is to improve the minimum insulation margin, so as to obtain a more effective design scheme for the transformer main insulation structure.
Firstly, a 500kV transformer is modeled using the APDL( ANSYS Parametric Design Language) . Secondly, it is necessary to identify optimization variables, which are selected from the electrostatic ring structure. Subsequently, the training set and test set data are obtained using the ESLE sampling method. Then, the RBF-RSM is derived using the training set data. Finally, the resulting RSM is optimized by an intelligent algorithm, which can figure out the variables’ values with the minimum insulation margin. Due to the parametric modeling, the training set and test set objective function results are obtained via Matlab and ANSYS calls, which significantly reduces the human workload and enhances the engineering applicability of the above process.
The results of the optimization based on ESLE and RBF-RSM are compared with the pre-optimized results, and the minimum insulation margin is improved by 12.56%, which indicates that the proposed method has practical utility. In order to verify the advantages of the proposed approach, firstly, from the sampling method, the ESLE method is compared to the LHS sampling method in RBF-RSM optimization, and the usage of the ESLE method with superior uniform sampling improves the optimization accuracy by 218 times. Secondly, from the response surface model, the optimization results of quadratic polynomial RSM and RBF-RSM are compared in ESLE sampling. The RBF-RSM enhances the optimization accuracy by a factor of 78 in addition to lowering the model's prediction error. Finally, the optimization results and those of the GA (genetic algorithm) are compared. The RSM yields an optimization result of 1.8525, the GA yields a result of 1.8514 and the values of the optimization variables in both schemes are consistent. Therefore, the accuracy of the RSM's optimization findings is validated. In addition, the RSM takes only 19.3 hours, whereas the GA requires 194 hours. It is evident that the RSM has significantly increased optimization efficiency while ensuing precision.
Through the above comparative analysis, the following conclusions can be drawn: 1) Compared with LHS sampling, the prediction error and optimization error of the model under ESLE sampling are less than those under LHS sampling, which verifies the feasibility of ESLE sampling method applied to the optimization of transformer main insulation structure. 2) Compared to the quadratic polynomial RSM, the predictive ability and optimization accuracy of the model proposed have been enhanced, indicating that the RBF-RSM has a proper fitting effect and calculation accuracy, and is more suitable for engineering applications. 3) Compared to GA, the precision of the optimization results of both methods is comparable, however, the efficiency of the method proposed is 10 times that of GA, which can effectively solve the optimization problem of the main insulation structure of transformers.

Key words： Response surface method (RSM) enhanced successful local enumeration (ESLE) radial basis function (RBF) insulation margin transformer structural optimization

收稿日期: 2022-08-22

PACS:

TM403.3

基金资助:国家重点研发计划（2021YFB2401703）和中央高校基本科研业务费专项资金（2022MS073）资助项目

通讯作者: 刘刚男,1985年生,副教授,硕士生导师,主要从事电气设备多物理场建模及仿真、电力系统时域仿真和电磁场理论及其应用方面的研究工作。E-mail：liugang_em@163.com

作者简介: 高成龙男,1999年生,硕士研究生,主要从事电磁场理论及其应用优化方面的研究工作。E-mail：cg_01041024@163.com

引用本文:

刘刚, 高成龙, 胡万君, 朱章宸, 刘云鹏. 基于ESLE采样和径向基函数响应面法的变压器静电环结构优化设计[J]. 电工技术学报, 0, (): 78-78. Liu Gang, Gao Chenglong, Hu Wanjun, Zhu Zhangchen, Liu Yunpeng. Optimized Design of Transformer Electrostatic Ring Based on Radial Basis Function Response Surface Method With Enhanced Successful Local Enumeration Sampling. Transactions of China Electrotechnical Society, 0, (): 78-78.

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