考虑温度影响的车用驱动电机磁场分步泛化实时求解方法OA
A Stepwise Generalized Real-Time Solution for the Magnetic Field of Automotive Drive Motors Considering Temperature Effects
准确快速量化温度对电磁性能的影响对电机的可靠运行、状态监测与优化设计具有重要意义.但是,车用永磁同步驱动电机工况复杂,工作温度动态多变,温度影响下电机励磁特性会发生变化,电机磁路也呈现高度非线性特征,传统有限元或热网络方法难以实现考虑温度的磁场快速准确求解.该文结合机器学习领域的迁移学习思想,提出一种在不同温度、不同电机工作点下分步泛化的磁场快速求解方法.首先采用本征正交分解对磁场矩阵进行降维,构建低维特征空间;然后结合迁移学习策略,将常温模型参数迁移至不同温度工况,显著减少训练数据需求;最后采用 Kriging 插值算法建立温度-工作点-磁场的映射关系,实现任意工况电机磁场的实时预测.结果表明,完成神经网络训练与插值后,所提方法实时计算完整电周期磁场的时间为 0.95 s,相较于有限元求解方法,大幅降低了磁场求解所用时间;泛化范围内重构平均磁通密度相对误差不超过 2.34%.通过搭载探测线圈的样机实验平台,验证了所提方法的有效性和准确性.提出的分步泛化策略为解决电机多场耦合中的温度-磁场的复杂交互关系提供了新的技术途径.
Accurate and fast quantification of the effect of temperature on electromagnetic performance is of great significance for reliable operation,condition monitoring,and optimized design of motors.However,the working conditions of automotive permanent magnet synchronous drive motors are complex,and the working temperature is dynamic and variable.The motor's excitation characteristics change with temperature,and its magnetic circuit exhibits highly nonlinear behavior.It is difficult to obtain a fast,accurate solution for the magnetic field that accounts for temperature using traditional finite-element or thermal-network methods.This paper proposes a fast solution method for the magnetic field with stepwise generalization across different temperatures and motor operating points. First,an electromagnetic simulation model of the motor accounting for temperature is established,and the magnetic field matrix is extracted from the simulation results.Secondly,a step-by-step generalization-solving method is proposed based on a migration-learning neural network and an interpolation algorithm.The magnetic field matrix is reduced using the POD algorithm to construct a low-dimensional feature space,and a neural network is trained to learn magnetic field features at different temperatures.The neural network and Kriging interpolation algorithm construct the mapping relationship of operating the point-temperature-magnetic field step by step.Finally,a prototype experimental platform is built to verify the proposed method. The results show that the proposed method calculates the magnetic field over a complete electric cycle in 0.95 s,which is 1.12%of the time required by the finite element method.The relative error of the reconstructed average magnetic density in the generalized range does not exceed 2.34%.The proposed step-by-step generalization strategy provides a new way to solve the complex temperature-magnetic field interactions in multi-field coupling of electric machines. The following conclusions can be drawn.(1)The proposed method has good generalization performance and meets the requirements of fast and accurate magnetic field reconstruction.(2)The proposed method effectively scales down the training cost of the neural network.Compared with a traditional data-driven neural network trained on 50%of the training set,the parameter freezing method further reduces network training time.The total training time of the network in the proposed method is 26.74%that of the neural network in the control group.(3)An experimental prototype with search coils is prepared,and the proposed method is verified.
王耀;程远;丁岭;崔淑梅;徐杰
哈尔滨工业大学电气工程及自动化学院 哈尔滨 150001哈尔滨工业大学电气工程及自动化学院 哈尔滨 150001哈尔滨工业大学电气工程及自动化学院 哈尔滨 150001||哈尔滨工业大学郑州研究院 郑州 450000哈尔滨工业大学电气工程及自动化学院 哈尔滨 150001哈尔滨工业大学材料科学与工程学院 哈尔滨 150001
信息技术与安全科学
永磁同步电机分步泛化迁移学习磁场计算
Permanent magnet synchronous machinestepwise generalizationtransfer learningmagnetic field computing
《电工技术学报》 2026 (10)
3273-3286,14
黑龙江省"双一流"新一轮建设学科协同创新成果建设资助项目(LJGXCG2022-065).
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