Periodic linear quadratic integrator control for individual blade pitch angle control of floating offshore wind turbine

被引:0
|
作者
Jikuya, Ichiro [1 ]
Kondo, Shingo [2 ]
Hara, Naoyuki [3 ]
机构
[1] Faculty of Frontier Engineering, Institute of Science and Engineering, Kanazawa University, Kakuma, Kanazawa, Ishikawa,920-1192, Japan
[2] Division of Electrical Engineering and Computer Science, Graduate School of Natural Science and Technology, Kanazawa University, Kakuma, Kanazawa, Ishikawa,920-1192, Japan
[3] Graduate School of Engineering, Osaka Prefecture University, 1-1 Gakuen-cho, Naka-ku, Sakai, Osaka,599-8531, Japan
来源
IEEJ Transactions on Electronics, Information and Systems | 2020年 / 140卷 / 09期
关键词
Offshore oil well production - Offshore wind turbines - Turbomachine blades - Matrix algebra;
D O I
10.1541/ieejeiss.140.1074
中图分类号
学科分类号
摘要
Periodic linear quadratic integrator control is applied to the individual blade pitch angle control of floating offshore turbine to reduce fatigue load as well as to improve power output. A methodology for selecting weighting matrices of optimal control is discussed in detail; in particular, the optimization of the phase parameter in the periodic input weighting matrix results in synchronization with the operating point of blade flapwise bending mode. The proposed method is applied to the NREL 5MWwind turbine model and shows the reduction in blade flapwise bending compared with the averaged linear quadratic integrator. © 2020 The Institute of Electrical Engineers of Japan.
引用
收藏
页码:1074 / 1081
相关论文
共 50 条
  • [1] Machine Learning Control for Floating Offshore Wind Turbine Individual Blade Pitch Control
    Velino, James
    Kang, SungKu
    Kane, Michael B.
    [J]. JOURNAL OF COMPUTING IN CIVIL ENGINEERING, 2022, 36 (06)
  • [2] Machine Learning Control for Floating Offshore Wind Turbine Individual Blade Pitch Control
    Kane, Michael B.
    [J]. 2020 AMERICAN CONTROL CONFERENCE (ACC), 2020, : 237 - 241
  • [3] Individual blade pitch control of floating offshore wind turbines
    Namik, H.
    Stol, K.
    [J]. WIND ENERGY, 2010, 13 (01) : 74 - 85
  • [4] An Individual Blade Pitch Control Strategy for Floating Offshore Wind Turbine Bearing Coupling of Dynamic Loads
    Liang, Yu
    Zhou, Lawu
    Han, Bing
    Yang, Binyou
    Luo, Bingqian
    [J]. 2019 25TH IEEE INTERNATIONAL CONFERENCE ON AUTOMATION AND COMPUTING (ICAC), 2019, : 185 - 191
  • [5] Individual Blade Pitch Control with Wind Preview Information for Floating Offshore Wind Turbines
    Tsuya T.
    Hara N.
    Konishi K.
    [J]. IEEJ Transactions on Electronics, Information and Systems, 2022, 142 (09) : 1008 - 1020
  • [6] ADAPTIVE INDIVIDUAL BLADE PITCH CONTROL TO REDUCE PLATFORM PITCH MOTION OF A FLOATING OFFSHORE WIND TURBINE: PRELIMINARY STUDY
    Magar, Kaman Thapa
    Balas, Mark J.
    [J]. PROCEEDINGS OF THE ASME CONFERENCE ON SMART MATERIALS, ADAPTIVE STRUCTURES AND INTELLIGENT SYSTEMS, 2014, VOL 1, 2014,
  • [7] Individual Blade Pitch Control of a Spar-Buoy Floating Wind Turbine
    Namik, Hazim
    Stol, Karl
    [J]. IEEE TRANSACTIONS ON CONTROL SYSTEMS TECHNOLOGY, 2014, 22 (01) : 214 - 223
  • [8] Research on pitch control of floating offshore wind turbine
    Yu, Wan
    Ding, Qinwei
    Li, Chun
    Hao, Wenxing
    Han, Zhiwei
    [J]. Taiyangneng Xuebao/Acta Energiae Solaris Sinica, 2021, 42 (01): : 143 - 148
  • [9] INDIVIDUAL BLADE PITCH CONTROL FOR ALLEVIATION OF VIBRATORY LOADS ON FLOATING OFFSHORE WIND TURBINES
    Pustina, Luca
    Pasquali, Claudio
    Serafini, Jacopo
    Lugni, Claudio
    Gennaretti, Massimo
    [J]. PROCEEDINGS OF ASME 2021 40TH INTERNATIONAL CONFERENCE ON OCEAN, OFFSHORE AND ARCTIC ENGINEERING (OMAE2021), VOL 9, 2021,
  • [10] Fatigue Loads Alleviation of Floating Offshore Wind Turbine Using Individual Pitch Control
    Wang, Lei
    Wang, Bikun
    Song, Yongduan
    Zeng, Qingchuan
    [J]. ADVANCES IN VIBRATION ENGINEERING, 2013, 12 (04): : 377 - 390
12345