[1] S. Wang, T. Moan, and Z. Jiang. Influence of variability and uncertainty of wind and waves on fatigue damage of a floating wind turbine drivetrain.
Renewable Energy, 181:870–897, 2022. doi:
10.1016/j.renene.2021.09.090.
[2] Z. Yu, C. Zhu, J. Tan, C. Song, and Y. Wang. Fully-coupled and decoupled analysis comparisons of dynamic characteristics of floating offshore wind turbine drivetrain.
Ocean Engineering, 247:110639, 2022. doi:
10.1016/j.oceaneng.2022.110639.
[3] F.K. Moghadam and A.R. Nejad. Online condition monitoring of floating wind turbines drivetrain by means of digital twin.
Mechanical Systems and Signal Processing, 162:108087, 2022. doi:
10.1016/j.ymssp.2021.108087.
[4] W. Shi, C.W. Kim, C.W. Chung, and H.C. Park. Dynamic modeling and analysis of a wind turbine drivetrain using the torsional dynamic model.
International Journal of Precision Engineering and Manufacturing, 14(1):153–159, 2013. doi:
10.1007/s12541-013-0021-2.
[5] M. Todorov and G. Vukov. Parametric torsional vibrations of a drive train in horizontal axis wind turbine. In
Proceeding of the 1st Conference Franco-Syrian about Renewable Energy, pages 1–17, Damas, 24-28 October, 2010.
[6] R.C. Juvinall and K.M. Marshek.
Fundamentals of Machine Component Design. John Wiley & Sons, 2020.
[7] Q. Zhang, J. Kang, W. Dong, and S. Lyu. A study on tooth modification and radiation noise of a manual transaxle.
International Journal of Precision Engineering and Manufacturing, 13(6):1013–1020, 2012. doi:
10.1007/s12541-012-0132-1.
[8] B. Shlecht, T. Shulze, and T. Rosenlocher. Simulation of heavy drive trains with multimegawatt transmission power in SimPACK. In:
SIMPACK Users Meeting, Baden-Baden, Germany, 21-22 March, 2006.
[9] M. Todorov and G. Vukov. Modal properties of drive train in horizontal axis wind turbine.
The Romanian Review Precision Mechanics, Optics & Mechatronics, 40:267–275, 2011.
[10] D. Lee, D.H. Hodges, and M.J. Patil. Multi‐flexible‐body dynamic analysis of horizontal axis wind turbines.
Wind Energy, 5(4):281–300, 2002. doi:
10.1002/we.66.
[11] F.L.J. Linden, P.H. Vazques, and S. Silva. Modelling and simulating the efficiency and elasticity of gearboxes, In Proceeding of the 7th Modelica Conference, pages 270–277, Como, 20-22 September, 2009.
[12] J. Wang, D. Qin, and Y. Ding. Dynamic behavior of wind turbine by a mixed flexible-rigid multi-body model.
Journal of System Design and Dynamics, 3(3):403–419, 2009. doi:
10.1299/jsdd.3.403.
[13] A.A. Shabana.
Computational Dynamics. John Wiley & Sons. 2009.
[14] A.K. Chopra.
Dynamics of Structures. Pearson Education India. 2007.
[15] Y. Park, H. Park, Z. Ma, J. You, J. and W. Shi. Multibody dynamic analysis of a wind turbine drivetrain in consideration of the shaft bending effect and a variable gear mesh including eccentricity and nacelle movement.
Frontiers in Energy Research, 8:604414, 2021. doi:
10.3389/fenrg.2020.604414.
[16] S.R. Singiresu.
Mechanical Vibrations. Addison Wesley. 1995.
[17] R.R. Craig Jr and A.J. Kurdila.
Fundamentals of Structural Dynamics. John Wiley & Sons. 2006.
[18] K.J. Bathe.
Finite Element Procedures. Klaus-Jurgen Bathe. 2006.
[19] Y. Kim, C.W. Kim, S. Lee, and H. Park. Dynamic modeling and numerical analysis of a cold rolling mill.
International Journal of Precision Engineering and Manufacturing, 14(3):407–413. 2013. doi:
10.1007/s12541-013-0056-4.
[20] S.J. Yoon and D.H. Choi. Reliability-based design optimization of slider air bearings.
KSME International Journal, 18(10):1722–1729, 2004. doi:
10.1007/BF02984320.
[21] H.H. Chun,S.J. Kwon, T. and Tak. Reliability-based design optimization of automotive suspension systems.
International Journal of Automotive Technology, 8(6):713–722, 2007.
[22] J. Fang, Y. Gao, G. Sun, and Q. Li. Multiobjective reliability-based optimization for design of a vehicledoor.
Finite Elements in Analysis and Design, 67:13–21, 2013. doi:
10.1016/j.finel.2012.11.007.
[23] Y.L. Young, J.W. Baker, and M.R. Motley. Reliability-based design and optimization of adaptive marine structures.
Composite Structures, 92(2):244–253, 2010. doi:
10.1016/j.compstruct.2009.07.024.
[24] G. Liu, H. Liu, C. Zhu, T. Mao, and G. Hu. Design optimization of a wind turbine gear transmission based on fatigue reliability sensitivity.
Frontiers of Mechanical Engineering, 16(1):61–79, 2021. doi:
10.1007/s11465-020-0611-5.
[25] H. Li, H. Cho, H. Sugiyama, K.K. Choi, and N.J. Gaul. Reliability-based design optimization of wind turbine drivetrain with integrated multibody gear dynamics simulation considering wind load uncertainty.
Structural and Multidisciplinary Optimization, 56 (1):183–201, 2017. doi:
10.1007/s00158-017-1693-5.
[26] C. Luo, B. Keshtegar, S.P. Zhu, O. Taylan, O. and X.P. Niu. Hybrid enhanced Monte Carlo simulation coupled with advanced machine learning approach for accurate and efficient structural reliability analysis.
Computer Methods in Applied Mechanics and Engineering, 388:114218. doi:
10.1016/j.cma.2021.114218.