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| Fast Calculation Method of Magnetic Field and Short-Circuit Electromagnetic Force of Transformer Based on Proper Orthogonal Decomposition and Discrete Empirical Interpolation Method |
| Wang Qingyu1, Tian Songbo1, Zeng Qiang2, Wu Zehua3, Cheng Jianwei3 |
1. School of Electrical Engineering Xi’an Jiaotong University Xi’an 710049 China; 2. Dongguan Power Supply Bureau Guangdong Power Grid Corporation Dongguan 523000 China; 3. CSG Electric Power Research Institute Guangzhou 510663 China |
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Abstract Short-circuit faults have a significant impact on the internal state of the transformer. When a sudden short-circuit accident, the transformer will be subjected to short-circuit current impact in a very short period of time, and the electromagnetic force borne by the windings will increase sharply, which may lead to winding deformation or even destruction. For the digital transformation of new power systems, the rapid analysis of the internal dynamic process of the transformer under the action of short-circuit current can effectively support the system decision-making and overhaul strategy. However, subject to the traditional numerical calculation methods, in the calculation of transient nonlinear magnetic field, the solution of each time step is a nonlinear problem, which requires multiple iterations of calculation and high computational time cost, and it is difficult to meet the requirements of digital application in the field of physical field simulation of power equipment. In order to improve the efficiency of online short-circuit resistance analysis and evaluation of transformers, this paper proposes a fast calculation method based on proper orthogonal decomposition (POD) and discrete empirical interpolation method (DEIM). electromagnetic force of transformer based on POD and DEIM. Firstly, the nonlinear transient control equations for the calculation of transformer electromagnetic force are derived based on the Galerkin finite element method; secondly, using the POD method, a reduced order model is established to reduce the order of the finite element equations and improve the computational efficiency; then, in order to solve the inefficiency of the POD method for solving the nonlinear problems, the nonlinear terms in the finite element equations are processed by interpolation method based on the DEIM algorithm. which reduces the formation time of the nonlinear stiffness matrix in each iteration step and further improves the computational efficiency. Finally, this paper establishes a short-circuit electromagnetic force calculation model based on the actual distribution of 220 kV transformer windings, and validates the proposed reduced-order algorithm by comparing it with commercial simulation software. In this paper, the effectiveness of the POD-DEIM order reduction algorithm in 220 kV transformer short-circuit electromagnetic force is investigated, and the following conclusions are obtained: (1) Using the POD method, the order reduction subspace is constructed by singular value decomposition and selecting the eigenvectors as constructing the order reduction subspace, so that the order of the equation is reduced from 204 232 to 6. (2) Combining DEIM with POD, the interpolation points in the nonlinear terms are constructed by selecting the interpolation matrix, which reduces the update time of the nonlinear terms in each iteration step, reduces the overall solution time of the equation (from 1 299 s to 132.6 s). (3) The computational results of the POD-DEIM reduced-order algorithm are basically consistent with those of the COSOL software and the full-order model, and the maximum relative error of the internal leakage flux of the transformer and the short-circuit electromagnetism of each winding is no more than 3.5%; in terms of the computational time, the computational efficiency of the reduced-order model is improved by a factor of 9.8 compared with that of the COSOL software and the full-order model. The results suggest that the reduced-order algorithm has a certain value of application in the rapid computation of short-circuit electromagnetic force in power transformers.
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Received: 09 October 2024
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[1] 欧强, 罗隆福, 李勇, 等. 一种电力变压器短路累积机械损伤评价方法[J]. 电工技术学报, 2024, 39(8): 2578-2590. Ou Qiang, Luo Longfu, Li Yong, et al.An evaluation method for short-circuit cumulative mechanical damage of power transformer[J]. Transactions of China Electrotechnical Society, 2024, 39(8): 2578-2590. [2] 律方成, 汪鑫宇, 王平, 等. 基于振动偏离及加权熵的多次短路冲击下变压器绕组机械形变辨识[J]. 电工技术学报, 2023, 38(11): 3022-3032. Lü Fangcheng, Wang Xinyu, Wang Ping, et al.Mechanical deformation identification of transformer winding under multiple short-circuit impacts based on vibration deviation and weighted entropy[J]. Trans-actions of China Electrotechnical Society, 2023, 38(11): 3022-3032. [3] 白翠粉, 高文胜, 程建伟, 等. 基于半Markov过程的变压器故障率分析[J]. 高电压技术, 2015, 41(12): 3916-3921. Bai Cuifen, Gao Wensheng, Cheng Jianwei, et al.Failure rate analysis of transformers based on semi-Markov process[J]. High Voltage Engineering, 2015, 41(12): 3916-3921. [4] 靳铭凯, 郭鹏鸿, 陈维江, 等. 磁场-结构场双向耦合作用对变压器绕组轴向振动过程的影响[J]. 高电压技术, 2023, 49(8): 3296-3304. Jin Mingkai, Guo Penghong, Chen Weijiang, et al.Two-way magnetic-structural coupling effect on vibration process of power transformer windings[J]. High Voltage Engineering, 2023, 49(8): 3296-3304. [5] 张凡, 吴书煜, 徐征宇, 等. 变压器绕组非线性动力学模型及多次短路冲击下的振动特征[J]. 高电压技术, 2022, 48(12): 4882-4892. Zhang Fan, Wu Shuyu, Xu Zhengyu, et al.Nonlinear vibration model of transformer windings and their vibration characteristics during multiple short circuits[J]. High Voltage Engineering, 2022, 48(12): 4882-4892. [6] 陈彬, 梁旭, 肖乔莎, 等. 绕组布置方式对高频变压器漏磁场和电磁力的影响分析[J]. 高压电器, 2022, 58(2): 95-102. Chen Bin, Liang Xu, Xiao Qiaosha, et al.Analysis on influence of winding layout on leakage magnetic field and electromagnetic force of high-frequency transformer[J]. High Voltage Apparatus, 2022, 58(2): 95-102. [7] 潘超, 葛佳柔, 刘天舒, 等. 单相变压器首端匝间短路电磁振动特性研究[J]. 电力工程技术, 2019, 38(6): 147-153, 166. Pan Chao, Ge Jiarou, Liu Tianshu, et al.The electromagnetic vibration characteristics of the first end of single-phase transformer[J]. Electric Power Engineering Technology, 2019, 38(6): 147-153, 166. [8] 司马文霞, 孙佳琪, 杨鸣, 等. 计及铁心非线性的变压器空间动态磁场加速计算方法[J]. 电工技术学报, 2025, 40(5):1559-1574. Sima Wenxia, Sun Jiaqi, Yang Ming, et al.Research on accelerated calculation method of space dynamic magnetic field of transformer considering core nonlinearity[J]. Transactions of China Electrotechnical Society, 2025, 40(5):1559-1574. [9] 邓祥力, 朱慧, 刘世明, 等. 适用于变压器保护的数字孪生建模技术研究[J]. 电网技术, 2022, 46(12): 4982-4993. Deng Xiangli, Zhu Hui, Liu Shiming, et al.Research on digital twin modeling technology suitable for transformer protection[J]. Power System Technology, 2022, 46(12): 4982-4993. [10] 童孝忠, 吴思洋, 程东俊. 利用非均匀网格有限差分法模拟一维大地电磁响应[J]. 工程地球物理学报, 2018, 15(2): 124-130. Tong Xiaozhong, Wu Siyang, Cheng Dongjun.Modeling of one dimensional magnetotelluric responses using non-uniform grids finite difference method[J]. Chinese Journal of Engineering Geophysics, 2018, 15(2): 124-130. [11] 骆仁松, 汪涛, 文继峰, 等. 大功率高频变压器三维温升计算及优化设计方法[J]. 电工技术学报, 2023, 38(18): 4994-5005, 5016. Luo Rensong, Wang Tao, Wen Jifeng, et al.Three-dimensional temperature calculation and optimization design method for high power high-frequency trans-former[J]. Transactions of China Electrotechnical Society, 2023, 38(18): 4994-5005, 5016. [12] Guo Wei, Xie Shejuan, Du Yali, et al.A numerical simulation method for high-frequency eddy current testing considering displacement current effect[J]. IEEE Transactions on Magnetics, 2024, 60(3): 1-4. [13] Jin Zichao, Cao Yue, Li Shuwang, et al.A kernel-free boundary integral method for 2-D magnetostatics analysis[J]. IEEE Transactions on Magnetics, 2023, 59(4): 1-19. [14] Yin Shuli, Di Rienzo L, Ma Xikui, et al.Efficient BEM computation of the impedance of axisymmetric air-core inductors[J]. IEEE Transactions on Electromagnetic Compatibility, 2022, 64(2): 585-589. [15] Domenig L D, Roppert K, Kaltenbacher M.Incor-poration of a 3-D energy-based vector hysteresis model into the finite element method using a reduced scalar potential formulation[J]. IEEE Transactions on Magnetics, 2024, 60(6): 1-8. [16] Li Yang, Zou Jun, Li Yongjian, et al.Prediction of core loss in transformer laminated core under DC bias based on generalized preisach model[J]. IEEE Trans-actions on Magnetics, 2024, 60(3): 1-5. [17] 周红军, 赵志刚, 张亚东, 等. 绕组压紧力对变压器油箱振动特性影响的有限元分析[J]. 变压器, 2024, 61(3): 45-51. Zhou Hongjun, Zhao Zhigang, Zhang Yadong, et al.Finite element analysis of influence of winding pressing force on vibration characteristics of transformer oil tank[J]. Transformer, 2024, 61(3): 45-51. [18] 谢德馨, 姚缨英, 白保东, 等. 三维涡流场的有限元分析[M]. 2版. 北京: 机械工业出版社, 2008. [19] 张重远, 刘迪程, 高成龙, 等. 基于Twin Builder的110 kV油浸式变压器3维磁场降阶模型及损耗分析[J]. 高电压技术, 2024, 50(3): 941-951. Zhang Zhongyuan, Liu Dicheng, Gao Chenglong, et al.Three-dimensional magnetic field model order reduction and loss analysis of 110 kV oil-immersed transformer based on twin builder[J]. High Voltage Engineering, 2024, 50(3): 941-951. [20] Li Bin, Wang Qinglong, Zhang Zhongyi, et al.Electromagnetic analysis for axial-flux induction planar motor based on reduced order coefficient matrix[J]. IEEE Transactions on Magnetics, 2024, 60(5): 1-11. [21] 刘刚, 郝世缘, 胡万君, 等. 基于POD-αATS的油浸变压器瞬态温升降阶自适应变步长计算方法[J]. 中国电机工程学报, 2024, 44(16): 6656-6667. Liu Gang, Hao Shiyuan, Hu Wanjun, et al.Adaptive variable step size calculation method for transient temperature rise and fall of oil immersed transformer based on POD-αATS[J]. Proceedings of the CSEE, 2024, 44(16): 6656-6667. [22] 荆澜涛, 董雪情, 杨超, 等. 面向数字孪生应用的变压器温度场有限元降阶建模方法研究[J]. 高电压技术, 2023, 49(6): 2408-2419. Jing Lantao, Dong Xueqing, Yang Chao, et al.Research on finite element reduced order modeling method of transformer temperature field for digital twin application[J]. High Voltage Engineering, 2023, 49(6): 2408-2419. [23] Sato Y, Igarashi H.Model reduction of three-dimensional eddy current problems based on the method of snapshots[J]. IEEE Transactions on Magnetics, 2013, 49(5): 1697-1700. [24] Henneron T, Clenet S.Model-order reduction of multiple-input non-linear systems based on POD and DEI methods[J]. IEEE Transactions on Magnetics, 2015, 51(3): 1-4. [25] Henneron T, Montier L, Pierquin A, et al.Comparison of DEIM and BPIM to speed up a POD-based nonlinear magnetostatic model[J]. IEEE Transactions on Magnetics, 2017, 53(6): 1-4. [26] Chi Cheng, Yang Fan, Ren Zhuoxiang.Reduced order model based on combined POD/LDEIM-Q for non-linear thermoelectric coupling[J]. IEEE Transactions on Magnetics, 2022, 58(9): 1-4. [27] 刘刚, 胡万君, 郝世缘, 等. 油浸式变压器绕组瞬态温升降阶快速计算方法[J]. 电工技术学报, 2024, 39(3): 643-657. Liu Gang, Hu Wanjun, Hao Shiyuan, et al.Reduced order calculation method of steady temperature rise of oil immersed power transformer[J]. Transactions of China Electrotechnical Society, 2024, 39(3): 643-657. |
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