基于硬件在环阻抗测试的双馈风机控制参数辨识综合实验平台OA
Integrated experimental platform for identifying control parameters of doubly fed induction generators based on hardware-in-the-loop impedance testing
该文构建了一个基于硬件在环(HIL)阻抗测试的双馈风机(DFIG)控制器参数辨识实验平台,平台基于转子侧与网侧变流器控制回路、锁相环耦合等因素构建了双馈风机等效阻抗模型,并建立了控制器参数与阻抗频响的显式映射关系,采用了改进粒子群优化(PSO)算法以解决传统参数辨识方法易陷入局部最优、对数据变化适应性差的问题.实验表明,该平台能有效解决工程现场参数封装不可见问题,将最新科研成果转化为实验教学资源,为学生深入理解并网稳定性问题、培养学生工程实践与创新能力提供了支撑.
[Objective]This study aims to enhance the teaching quality of electrical engineering courses and address students'challenges in traditional laboratory instruction,specifically,difficulties in bridging theory with practice and insufficient hands-on experience with cutting-edge engineering problems.It considers two critical industry trends:increasing penetration of doubly fed induction generators(DFIGs)in power systems and the growing prominence of DFIG-related grid stability issues.Commercial wind turbines typically utilize encapsulated controllers with opaque parameters,which pose considerable challenges for power system stability analyses and controller optimization.To tackle these interconnected issues,this paper designs and develops an experimental platform dedicated to the parameter identification of DFIG controllers.[Methods]The platform leverages an improved particle swarm optimization(PSO)algorithm,and its operation is driven by impedance scanning data obtained from a hardware-in-the-loop(HIL)system.First,the study derives an analytical equivalent impedance model for DFIGs that explicitly considers rotor-side converter(RSC)and grid-side converter(GSC)control loops and phase-locked loop coupling effects.Building upon this model,the study establishes a clear mapping relationship between key controller parameters and the system's frequency-domain impedance response.The model focuses on four critical controller parameters:for the rotor side,the d-axis current loop proportional gain(KP,d,RSC)and integral time constant(TI,d,RSC),and for the grid side,the d-axis current loop proportional gain(KP,d,GSC)and integral time constant(TI,d,GSC).The core of parameter identification relies on the enhanced PSO algorithm,which employs Latin hypercube sampling combined with Gaussian perturbations for population initialization to effectively enhance population diversity.During the iterative process,the algorithm adopts a dynamic frequency weighting approach,assigning distinct weights to impedance errors across different frequency bands.This weighting prioritizes frequency ranges that are critical for system stability analysis,thereby ensuring more targeted optimization.Concurrently,the algorithm integrates a dynamic parameter management module,which successfully prevents the algorithm from being trapped in local optima by implementing particle perturbations based on boundary expansion and clustering detection.To ensure that the identification results are comprehensive and accurate,the fitness function integrates three key components:impedance magnitude-frequency error,phase-frequency error,and parameter grouping error.The experimental platform,constructed using the OP4510 real-time simulation system and National Instruments data acquisition boards,can perform standard impedance scans and collect high-precision frequency response data.Experimental tests were conducted on three double-fed wind turbines under varying active power output conditions(1.0,0.5,and 0.1 per unit).For each test condition,the proposed improved PSO parameter identification method was applied to identify the four key controller parameters.[Results]The results indicate that the improved PSO algorithm effectively fits the measured impedance curves,demonstrating strong approximation capabilities.To enhance the reliability of parameter estimates,identification results across multiple operating conditions were weighted and averaged,yielding robust parameter values.These weighted parameters were then substituted back into the DFIG impedance model for validation.This step revealed significant reductions in impedance fitting errors,confirming the effectiveness of the proposed method and its engineering feasibility.Beyond its research applications,the developed experimental platform serves as a cutting-edge engineering practice tool,addressing a notable gap in current experimental teaching protocols for new energy power systems.By employing a visual,hands-on approach,the platform enables students to develop a deeper understanding of the intrinsic relationships between system impedance,controller parameter identification techniques,and system stability.This enriches electrical engineering students'practical knowledge and holds significant value for cultivating innovative thinking and the ability to solve complex engineering problems.[Conclusions]The methodological framework and experimental validation presented herein provide a concrete contribution to the field of wind turbine controller analysis and pedagogical development in practical engineering education.By synthesizing advanced algorithmic optimization with real-time HIL experimentation,this study establishes a reproducible and effective paradigm to tackle similar black-box identification challenges in modern power electronic systems while serving as an invaluable resource to bridge the gap between theory and industrial practice.
张旭;王群;许鑫;王江涛;王纪宇;谢宇涵;房潇宇;周芝梅;谢小荣
中国矿业大学(北京) 机械与电气工程学院,北京 100083中国矿业大学(北京) 机械与电气工程学院,北京 100083中国矿业大学(北京) 机械与电气工程学院,北京 100083中国矿业大学(北京) 机械与电气工程学院,北京 100083中国矿业大学(北京) 机械与电气工程学院,北京 100083中国矿业大学(北京) 机械与电气工程学院,北京 100083中国矿业大学(北京) 机械与电气工程学院,北京 100083深圳市国电科技通信有限公司,广东 深圳 518110清华大学 电机工程与应用电子技术系,北京 100084
信息技术与安全科学
改进PSO双馈风机阻抗扫描参数辨识实验教学平台
improved particle swarm optimizationdouble-fed wind turbineimpedance scanningparameter identificationexperimental teaching platform
《实验技术与管理》 2026 (4)
142-150,9
北京市自然科学基金项目(L244005)国家自然科学基金项目(52107135)中央高校基本科研业务费(2024ZKPYJD07)中国矿业大学(北京)研究生教育教学改革项目(YJG2025011)中国矿业大学(北京)研究生"课程思政"示范课程建设项目(YKCSZSF2024006)
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