5th order Modeling, Control and Steady-State Validation of Wind Turbine Based on DFIG

2022 International Conference on Emerging Trends in Electrical, Control, and Telecommunication Engineering (ETECTE) Pub Date : 2022-12-02 DOI:10.1109/ETECTE55893.2022.10007095

Muhammad Uzair Khalid, H. Khalid, Afzaal A. Khan, Hasaan Farooq, Muhammad Muzammil Farooqi

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Abstract

With the high penetration of power electronics-based wind farms being integrated into power grids, proper modeling and control of large wind turbines is a prominent challenge in modern power systems. Thus, accurate mathematical modeling of the Doubly-fed induction generator (DFIG) along with its control is desperately needed. In this paper, modeling, control, and steady-state validation of a 5th order model of DFIG is presented. A vector control scheme is developed for the stator side and rotor side converters to keep constant DC link voltage and to capture maximum power from the wind. The d-q synchronous coordinate system is utilized to derive 5th order DFIG model in which the q-axis of the rotating coordinate system rotates at the nominal grid frequency. Stator flux, rotor flux, and rotor speed were selected as state variables for state space representation of the DFIG model. Experimentally, the simulations are done in EMTDC/PSCAD and the results were carried out on 1.73 MVA DFIG-based Industrial Wind Turbine data and then validate it with the actual one.

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基于DFIG的风力机五阶建模、控制及稳态验证

随着以电力电子为基础的风力发电场的高度普及，大型风力涡轮机的正确建模和控制是现代电力系统中的一个突出挑战。因此，迫切需要对双馈感应发电机(DFIG)及其控制进行精确的数学建模。本文介绍了一种五阶DFIG模型的建模、控制和稳态验证。提出了一种定子侧和转子侧变流器的矢量控制方案，以保持直流链路电压恒定，并从风中获取最大功率。利用d-q同步坐标系导出了旋转坐标系q轴以标称栅格频率旋转的五阶DFIG模型。选取定子磁链、转子磁链和转子转速作为状态变量，对DFIG模型进行状态空间表示。实验上，在EMTDC/PSCAD中进行了仿真，并在基于1.73 MVA dfig的工业风力机数据上进行了仿真，并与实际数据进行了验证。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 International Conference on Emerging Trends in Electrical, Control, and Telecommunication Engineering (ETECTE)

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