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Characteristics Simulation Method of Megawatt Three-Blade Horizontal Axis Wind Turbine Based on Laboratory Kilowatt Low-Power Motor System | IEEE Journals & Magazine | IEEE Xplore
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Journals & Magazines >IEEE Transactions on Industry... >Volume: 58 Issue: 1

Characteristics Simulation Method of Megawatt Three-Blade Horizontal Axis Wind Turbine Based on Laboratory Kilowatt Low-Power Motor System

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Jinping Xie; Xiaofei Zhang; Shoudao Huang; Fengqin Huang; Zishun Peng; Yuxing Dai
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Abstract:

In this study, a characteristic simulation method of a megawatt three-blade horizontal axis wind turbine (MW-THAWT) is proposed based on a laboratory kilowatt low-power m...Show More

Metadata

Abstract:

In this study, a characteristic simulation method of a megawatt three-blade horizontal axis wind turbine (MW-THAWT) is proposed based on a laboratory kilowatt low-power motor system, which can realize the parameter correspondence and the rotational inertia compensation between the simulation platform and the wind turbine. First, the virtual proportional THAWT model of MW-THAWT is established to make the parameters of the motor and the wind turbine correspond. The control strategies of speed output and torque output are then designed to solve the problem that the conventional method cannot simulate the unstable region. The dynamic simulation strategy combining the shaft torque feedback rotational inertia compensation method and load characteristic simulation is proposed, which can ensure the consistency of the change time and mode between the simulation platform and the wind power system in the dynamic process. Finally, the MW-THAWT simulation experiment platform based on 1.4-KW motor is developed for theoretical verification. The experimental results verify that the proposed method can realize the characteristic simulation of static and dynamic of MW-THAWT in full speed range and is suitable for industrial production and laboratory research of wind turbine.
Published in: IEEE Transactions on Industry Applications ( Volume: 58, Issue: 1, Jan.-Feb. 2022)
Page(s): 645 - 655
Date of Publication: 27 October 2021

ISSN Information:

DOI: 10.1109/TIA.2021.3123116

Funding Agency:

References is not available for this document.
Contents

I. Introduction

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