Dynamics Simulation For Horizontal-axis Wind Turbines

被引:0
|
作者
Mao, Xuning [1 ]
Li, Jishun [2 ,3 ]
Liu, Yi [1 ,2 ]
机构
[1] Henan Univ Sci & Technol, Sch Mechatron Engn, Luoyang 471003, Peoples R China
[2] Henan Univ Sci & Technol, Henan Key Lab Machinery Design & Tranmiss Syst, Luoyang 471003, Peoples R China
[3] State Key Lab Min Heavy Equipment, Luoyang 471039, Peoples R China
来源
ADVANCED RESEARCH ON ADVANCED STRUCTURE, MATERIALS AND ENGINEERING | 2012年 / 382卷
关键词
AeroDyn; FAST; ADAMS; wind turbine; Fan blade roots; ENERGY;
D O I
10.4028/www.scientific.net/AMR.382.129
中图分类号
TU [建筑科学];
学科分类号
0813 ;
摘要
In this study, the dynamic characteristics of three-blade horizontal-axis wind turbines were simulated, based on the aerodynamic software AeroDyn, wind turbine design software FAST and mechanical dynamics simulation software ADAMS. AeroDyn and FAST are Interface codes for ADAMS. As the pre-processor of ADAMS, FAST code helps to build wind turbine model as well as constrains,while AeroDyn code applies wind field data to the model. At last the model was imported into ADAMS to be simulated. In this way, the dynamic operating characteristics of three-blade horizontal-axis wind turbines can be obtained. And the load-time curves of the blade roots can also be gotten. Results show that the method adopted is feasible and reliable.
引用
收藏
页码:129 / +
页数:2
相关论文
共 50 条
  • [31] Effect of background turbulence on the wakes of horizontal-axis and vertical-axis wind turbines
    van der Deijl, W.
    Schmitt, F.
    Sicot, C.
    Barre, S.
    Hoelling, M.
    Obligado, M.
    [J]. JOURNAL OF WIND ENGINEERING AND INDUSTRIAL AERODYNAMICS, 2024, 253
  • [32] Large Eddy Simulation of flow around a single and two in-line horizontal-axis wind turbines
    Allah, Veisi Amin
    Mayam, Mohammad Hossein Shafiei
    [J]. ENERGY, 2017, 121 : 533 - 544
  • [33] A cheap, reliable and efficient regulator for small horizontal-axis wind-turbines
    Mejía, ER
    Filipek, JW
    Salazar, JST
    [J]. APPLIED ENERGY, 2003, 74 (1-2) : 229 - 237
  • [34] Review of control strategy of large horizontal-axis wind turbines yaw system
    Yang, Jian
    Fang, Lingqi
    Song, Dongran
    Su, Mei
    Yang, Xuebing
    Huang, Lingxiang
    Joo, Young Hoon
    [J]. WIND ENERGY, 2021, 24 (02) : 97 - 115
  • [35] Analysis of throw distances of detached objects from horizontal-axis wind turbines
    Sarlak, Hamid
    Sorensen, Jens N.
    [J]. WIND ENERGY, 2016, 19 (01) : 151 - 166
  • [36] APPLICATION OF THE VORTEX THEORY TO HIGH-SPEED HORIZONTAL-AXIS WIND TURBINES
    MAEKAWA, H
    [J]. BULLETIN OF THE JSME-JAPAN SOCIETY OF MECHANICAL ENGINEERS, 1984, 27 (229): : 1460 - 1466
  • [37] Investigation of Wake Effects on Aeroelastic Responses of Horizontal-Axis Wind-Turbines
    Jeong, Min-Soo
    Kim, Sang-Woo
    Lee, In
    Yoo, Seung-Jae
    Park, K. C.
    [J]. AIAA JOURNAL, 2014, 52 (06) : 1133 - 1144
  • [38] A Comparative study on the aeromechanic performances of upwind and downwind horizontal-axis wind turbines
    Wang, Zhenyu
    Tian, Wei
    Hu, Hui
    [J]. ENERGY CONVERSION AND MANAGEMENT, 2018, 163 : 100 - 110
  • [39] A Modified Free Wake Vortex Ring Method for Horizontal-Axis Wind Turbines
    Dong, Jing
    Vire, Axelle
    Ferreira, Carlos Simao
    li, Zhangrui
    van Bussel, Gerard
    [J]. ENERGIES, 2019, 12 (20)
  • [40] A solution-based stall delay model for horizontal-axis wind turbines
    Dowler, Joshua Lyle
    Schmitz, Sven
    [J]. WIND ENERGY, 2015, 18 (10) : 1793 - 1813
12345