基于鲸鱼优化算法超参数优化的径向基函数响应面模型的油浸式变压器绕组挡板结构优化

doi:10.19595/j.cnki.1000-6753.tces.231064

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (5204 KB) HTML
输出: BibTeX | EndNote (RIS)

摘要热点温度过高会严重影响变压器运行稳定性,为提高变压器运行的稳定性,该文以降低变压器绕组热点温度为优化目标,采用径向基函数（RBF）响应面模型优化变压器绕组挡板尺寸,改善油流分布以实现更好的散热。为提高RBF响应面模型的拟合精度,该文采用鲸鱼优化算法（WOA）对径向基函数的超参数值进行优化,并与传统网格搜索（GS）寻优方法和定参RBF模型进行对比。对比结果表明对于超参数优化问题,在拟合精度占优的前提下,WOA优化效率是GS寻优方法的3.13倍。在此基础上,该文基于WOA-RBF响应面模型对绕组挡板结构尺寸进行优化,优化后的热点温度相较于初始结构的热点温度降低了3.81℃,相对于全场域的最大温升降低了13.42%,并有效地降低了绕组整体温升。同时将所提算法与遗传算法（GA）优化结果进行对比,在保证精度的同时,WOA-RBF响应面模型优化效率是GA的13.41倍。根据上述结果分析可知,所提算法具有很好的优化性能,同时相比于遗传算法,可以在保证优化精度的同时,显著地提高优化效率。

	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
	刘刚
	高成龙
	胡万君
	刘云鹏
	李琳

关键词 ：响应面方法, 径向基函数, 热点温度, 鲸鱼优化算法, 油浸式变压器, 挡板结构优化

Abstract：High hot spot temperature (HST) can seriously affect the stability of transformer operation. The structure of the transformer winding block washers plays a key role in the distribution of oil flow between windings, indirectly affecting the heat dissipation capacity of the windings. In order to improve the stability of transformer operation, this article takes reducing the winding HST as the optimization objective, and uses radial basis function (RBF) response surface model (RSM) to optimize the size of winding block washers, improve oil flow distribution, and achieve better heat dissipation. To the problem of empirical selection of hyper-parameters in the construction of traditional RBF RSM, this paper introduces the whale optimization algorithm (WOA) to determine the optimal hyper-parameters of the RBF RSM. The WOA-RBF RSM is proposed to optimize the size of winding block washers to improve the fitting accuracy and optimization ability of the RSM.
Firstly, use the Workbench platform to parameterize the block washers' size with a two-dimensional eight-zone winding with non-split turn model based on an actual large oil immersed transformer. Secondly, the optimization variable was determined to be the lengths of 7 block washers. The range of changes in block washers' length was determined, aiming to avoid oil flow dead zones. Use Latin hypercube sampling (LHS) to obtain the data set, and obtain the corresponding HST response values of the relevant data set through mutual calls between Matlab and Workbench, forming the final sample set. Thirdly, based on the existing sample set, a RBF RSM was established using the newrb function provided by Matlab. Combining WOA and cross validation ideas, hyper-parameters were optimized for the two hyper-parameters in the newrb function: spread (expansion speed) and MN (maximum number of neurons). Finally, the final RBF RSM was constructed based on the optimal hyper-parameters, and intelligent algorithms were used to obtain the optimal block washers' size scheme and the corresponding minimum HST.
The effectiveness of the non-split turn model used was verified by comparing the flow and temperature results of the split and the non-split turn model. The optimized results based on the WOA-RBF RSM were compared with those before optimization. The HST decreased by 3.81℃ and the maximum temperature rise decreased by 13.42%. Moreover, the optimized block washers' size not only reduced the HST, but also effectively ameliorated the phenomenon of excessive local temperature rise in winding various zones. To verify the accuracy of the optimization results by WOA-RBF, the results were compared with the optimization results of the genetic algorithm (GA). The optimal solution trends of the two methods were consistent, and the optimal HST value difference was only 0.05℃. The block washers' sizes obtained by the two methods were the two optimal credible solutions of the multi-solution problem. The reliability of the optimization results obtained by WOA-RBF was verified. Meanwhile, the efficiency of WOA-RBF is 13.41 times that of GA, indicating that the WOA-RBF method is an accurate and efficient method to solve the optimization problem of winding block washers' size. Simultaneously, this article also compared the WOA with grid search (GS) optimization method and fixed hyper-parameter method from the perspective of hyper-parameter optimization. The average root mean square error (RMSE) and average optimization error of GS-RBF and fixed parameter RBF are 1.12 times, 4.52 times and 1.67 times, 2.56 times higher than those of WOA-RBF, respectively. In the case of superior fitting and optimization accuracy, the optimization efficiency of WOA was 3.13 times than that of GS method, which verified the feasibility of applying WOA to hyper-parameter optimization design.

Key words： Response surface method (RSM) radial basis function (RBF) hot spot temperature (HST) whale optimization algorithm (WOA) oil immersed transformer block washer structural optimization.

收稿日期: 2023-07-04

PACS:

TM403.2

基金资助:国家重点研发计划（2021YFB2401700）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,研究方向为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。E-mail：liugang_em@163.com

作者简介: 高成龙男,1999年生,硕士研究生,研究方向为多物理场理论及其应用优化。E-mail：cg_01041024@163.com

引用本文:

刘刚, 高成龙, 胡万君, 刘云鹏, 李琳. 基于鲸鱼优化算法超参数优化的径向基函数响应面模型的油浸式变压器绕组挡板结构优化[J]. 电工技术学报, 2024, 39(17): 5331-5343. Liu Gang, Gao Chenglong, Hu Wanjun, Liu Yunpeng, Li Lin. Optimization of Winding Block Washer Structure for Oil Immersed Transformers Based on Radial Basis Function Response Surface Model with Whale Optimization Algorithm Hyper-Parameters Optimization. Transactions of China Electrotechnical Society, 2024, 39(17): 5331-5343.

链接本文:

https://dgjsxb.ces-transaction.com/CN/10.19595/j.cnki.1000-6753.tces.231064 https://dgjsxb.ces-transaction.com/CN/Y2024/V39/I17/5331

[1] Abdali A, Abedi A, Mazlumi K, et al.Novel hotspot temperature prediction of oil-immersed distribution transformers: an experimental case study[J]. IEEE Transactions on Industrial Electronics, 2023, 70(7): 7310-7322.
[2] Tan Youbo, Yu Xiaoling, Ji Shengchang, et al.Parametric study and optimization of a full-scale converter transformer winding[J]. International Journal of Heat and Mass Transfer, 2021, 181: 121861.
[3] Rahimpour E, Barati M, Schäfer M.An investigation of parameters affecting the temperature rise in windings with zigzag cooling flow path[J]. Applied Thermal Engineering, 2007, 27(11/12): 1923-1930.
[4] Torriano F, Campelo H, Quintela M, et al.Numerical and experimental thermofluid investigation of different disc-type power transformer winding arrangements[J]. International Journal of Heat and Fluid Flow, 2018, 69: 62-72.
[5] Tan Youbo, Yu Xiaoling, Wang Xiaolin, et al.Interaction analysis and multi-response optimization of transformer winding design parameters[J]. International Communications in Heat and Mass Transfer, 2022, 137: 106233.
[6] 刘刚, 郝世缘, 胡万君, 等. 基于子循环自适应串行交错时间匹配算法的油浸式变压器绕组瞬态温升计算[J]. 电工技术学报, 2024, 39(4): 1185-1197.
Liu Gang, Hao Shiyuan, Hu Wanjun, et al.Transient temperature rise calculation of oil immersed transformer winding based on sub cyclic adaptive staggered time matching algorithm[J]. Transactions of China Electrotechnical Society, 2024, 39(4): 1185-1197.
[7] 武卫革, 杜振斌, 刘刚, 等. 大型油浸式变压器绕组温度场仿真及验证[J]. 华北电力大学学报(自然科学版), 2020, 47(6): 68-74.
Wu Weige, Du Zhenbin, Liu Gang, et al.Simulation and verification of winding temperature field for large oil immersed transformer[J]. Journal of North China Electric Power University (Natural Science Edition), 2020, 47(6): 68-74.
[8] 王晓晗. 基于等效导热系数法的油浸式电力变压器绕组流—热耦合分析[D]. 保定: 华北电力大学, 2021.
Wang Xiaohan.Analysis of Flow-thermal coupling of oil-immersed power transformer windings based on equivalent thermal conductivity method[D]. Baoding: North China Electric Power University, 2021.
[9] 刘刚, 高成龙, 胡万君, 等. 基于改进的连续局部枚举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, 2023, 38(23): 6266-6278.
Liu Gang, Gao Chenglong, Hu Wanjun, et al.Optimized design of transformer electrostatic ring based on radial basis function response surface method with enhanced successful local enumeration sampling[J]. Transactions of China Electrotechnical Society, 2023, 38(23): 6266-6278.
[10] 温志伟, 熊斌, 程自然. 强化液冷牵引变压器电磁结构设计及优化[J]. 电工技术学报, 2021, 36(增刊02): 460-466.
Wen Zhiwei, Xiong Bin, Cheng Ziran.Electromagnetic design and optimization of enhanced liquid-cooling traction transformer[J]. Transactions of China Electrotechnical Society, 2021, 36(S02): 460-466.
[11] Ding Zheshi, Fan Xianhao, Song Boshu, et al.NSGA-Ⅱ model-based dielectric frequency response parameters for aging and moisture analysis of transformer insulation[J]. IEEE Transactions on Instrumentation and Measurement, 2022, 71: 3518710.
[12] Zhou Lei, Yang Dingye, Zhai Xiaolin, et al.GA-STT: human trajectory prediction with group aware spatial-temporal transformer[J]. IEEE Robotics and Automation Letters, 2022, 7(3): 7660-7667.
[13] 刘道生, 魏博凯, 蔡昌万, 等. 基于混沌自适应遗传算法的非晶合金干式变压器优化设计[J]. 高压电器, 2022, 58(10): 40-47.
Liu Daosheng, Wei Bokai, Cai Changwan, et al.Optimization design of amorphous alloy metal dry-type transformer based on chaotic adaptive genetic algorithm[J]. High Voltage Apparatus, 2022, 58(10): 40-47.
[14] 陈彬, 曹红霞, 王帅兵, 等. 基于响应面法的多绕组中频变压器绝缘结构优化设计[J]. 绝缘材料, 2023, 56(4): 68-76.
Chen Bin, Cao Hongxia, Wang Shuaibing, et al.Optimization design of insulation structure of multi-winding medium frequency transformer based on response surface method[J]. Insulating Materials, 2023, 56(4): 68-76.
[15] 赵玉顺, 戴义贤, 庄加才, 等. 基于热固耦合的中频变压器绝缘材料性能参数优化配合方法[J]. 电工技术学报, 2023, 38(4): 1051-1063.
Zhao Yushun, Dai Yixian, Zhuang Jiacai, et al.Optimization of insulation material performance parameters for medium frequency transformers based on thermosolid coupling[J]. Transactions of China Electrotechnical Society, 2023, 38(4): 1051-1063.
[16] 刘刚, 刘西娅, 刘尧, 等. 基于响应面法的变压器静电环绝缘优化设计[J]. 高电压技术, 2022, 48(10): 4163-4171.
Liu Gang, Liu Xiya, Liu Yao, et al.Optimal design of transformer electrostatic ring insulation based on response surface method[J]. High Voltage Engineering, 2022, 48(10): 4163-4171.
[17] 宁倩, 李桥, 高兵, 等. 电—磁—机—声多场边界下的超磁致伸缩Ⅳ型弯张换能器设计方法[J]. 电工技术学报, 2023, 38(12): 3112-3121.
Ning Qian, Li Qiao, Gao Bing, et al.Design of giant magnetostrictive class Ⅳ flextensional transducer under electrical-magnetic-mechanical-acoustic multi-field boundaries[J]. Transactions of China Electrotechnical Society, 2023, 38(12): 3112-3121.
[18] 彭磊, 刘莉, 龙腾. 基于动态径向基函数代理模型的优化策略[J]. 机械工程学报, 2011, 47(7): 164-170.
Peng Lei, Liu Li, Long Teng.Optimization strategy using dynamic radial basis function metamodel[J]. Journal of Mechanical Engineering, 2011, 47(7): 164-170.
[19] 陈鑫. 高超声速飞行器气动—热—结构建模及模型降阶研究[D]. 北京: 北京理工大学, 2015.
Chen Xin.Studies on aerodynamic—structural—thermal modeling and reduced order modeling of hypersonic vehicles[D]. Beijing: Beijing Institute of Technology, 2015.
[20] Jin Ruichen, Chen Wei, Simpson T.Comparative studies of metamodeling techniques under multiple modeling criteria[C]//8th Symposium on Multidis-ciplinary Analysis and Optimization, Long Beach, CA, USA, 2000: 4801.
[21] 王振宇, 王春华, 张靖周. 涡轮集气腔结构参数优化研究[J]. 中南大学学报(自然科学版), 2022, 53(7): 2756-2765.
Wang Zhenyu, Wang Chunhua, Zhang Jingzhou.Research on structural parameter optimization of turbine coolant collection/distribution plenum[J]. Journal of Central South University (Science and Technology), 2022, 53(7): 2756-2765.
[22] 袁发庭, 施文菀, 王玥, 等. 基于多物理场仿真的油浸式变压器温度特性分析及散热器优化[J]. 高电压技术, 2024, 50(1): 221-231.
Yuan Fating, Shi Wenyu, Wang Yue, et al.Temperature characteristic analysis and radiator optimization of oil-immersed transformer based on multi-physical field simulation[J]. High Voltage Engineering, 2024, 50(1): 221-231.
[23] 陈伟根, 滕黎, 刘军, 等. 基于遗传优化支持向量机的变压器绕组热点温度预测模型[J]. 电工技术学报, 2014, 29(1): 44-51.
Chen Weigen, Teng Li, Liu Jun, et al.Transformer winding hot-spot temperature prediction model of support vector machine optimized by genetic algorithm[J]. Transactions of China Electrotechnical Society, 2014, 29(1): 44-51.
[24] 李英顺, 阚宏达, 王德彪, 等. 一种基于KPCA-WOA-SVM火控系统故障诊断方法[J]. 火炮发射与控制学报, 2023, 44(4): 14-19.
Li Yingshun, Kan Hongda, Wang Debiao, et al.A fault diagnosis method for fire control systems based on KPCA-WOA-SVM[J]. Journal of Gun Launch & Control, 2023, 44(4): 14-19.
[25] 冯增喜, 李嘉乐, 葛珣, 等. 融合多策略改进鲸鱼优化算法及其应用[J/OL]. 计算机集成制造系统, 2023: 1-23[2023-04-25]. http:///kns.cnki.net/kcms/detail/11.5946.tp.20230104.1215.014.html.
Feng Zengxi, Li Jiale, Ge Jun, et al. Integrating multiple strategies to improve the whale optimization algorithm and its application[J/OL]. Computer Integrated Manufacturing Systems, 2023: 1-23[2023-04-25]. http://kns.cnki.net/kcms/detail/11.5946.tp.20230104.1215.014.html.
[26] 李畸勇, 张伟斌, 赵新哲, 等. 改进鲸鱼算法优化支持向量回归的光伏最大功率点跟踪[J]. 电工技术学报, 2021, 36(9): 1771-1781.
Li Jiyong, Zhang Weibin, Zhao Xinzhe, et al.Global maximum power point tracking for PV array based on support vector regression optimized by improved whale algorithm[J]. Transactions of China Electrotechnical Society, 2021, 36(9): 1771-1781.
[27] 安国庆, 史哲文, 马世峰, 等. 基于RF特征优选的WOA-SVM变压器故障诊断[J]. 高压电器, 2022, 58(2): 171-178.
An Guoqing, Shi Zhewen, Ma Shifeng, et al.Fault diagnosis of WOA-SVM transformer based on RF feature optimization[J]. High Voltage Apparatus, 2022, 58(2): 171-178.
[28] 刘会兰, 常庚垚, 赵书涛, 等. 溯源弹簧形变过程的断路器振动信号递归量化分析辨识方法[J]. 电工技术学报, 2024, 39(8): 2567-2577.
Liu Huilan, Chang Gengyao, Zhao Shutao, et al.Recursive quantification analysis and identification method for circuit breaker vibration signal tracing spring deformation process[J]. Transactions of China Electrotechnical Society, 2024, 39(8): 2567-2577.