Short-term fatigue analysis for tower base of a spar-type wind turbine under stochastic wind-wave loads |
Li, Haoran
(State Key Laboratory of Ocean Engineering, Shanghai Jiao Tong University)
Hu, Zhiqiang (School of Marine Science and Technology, Newcastle University) Wang, Jin (State Key Laboratory of Ocean Engineering, Shanghai Jiao Tong University) Meng, Xiangyin (School of Marine Science and Technology, Newcastle University) |
1 | TC88-MT I E C, 2005. IEC 61400-3: Wind turbines-part 1: Design Requirements. International Electro-technical Commission, Geneva. |
2 | Argyriadis, K., Klose, M., 2007. Analysis of offshore wind turbines with jacket structures. In: The Seventeenth International Offshore and Polar Engineering Conference. Lisbon, Portugal. |
3 | Bachynski, E.E., 2014. Design and Dynamic Analysis of Tension Leg Platform Wind Turbines. Norwegian University of Science and Technology. |
4 | Dong, W., Moan, T., Gao, Z., 2011. Long-term fatigue analysis of multi-planar tubular joints for jacket-type offshore wind turbine in time domain. Eng. Struct. 33 (6), 2002-2014. DOI |
5 | Dong, W., Moan, T., Gao, Z., 2012. Fatigue reliability analysis of the jacket support structure for offshore wind turbine considering the effect of corrosion and inspection. Reliab. Eng. Syst. Saf. 106, 11-27. DOI |
6 | Gao, Z., Moan, T., 2008. Frequency-domain fatigue analysis of wide-band stationary Gaussian processes using a trimodal spectral formulation. Int. J. Fatigue 30 (10), 1944-1955. DOI |
7 | Gao, Z., Moan, T., 2010. Long-term fatigue analysis of offshore fixed wind turbines based on time-domain simulations. In: Proceedings of PRADS, Rio de Janeiro, Brazil. |
8 | Haid, L., Stewart, G., Jonkman, J., et al., 2013. Simulation-length requirements in the loads analysis of offshore floating wind turbines. In: ASME 2013 32nd International Conference on Ocean. Offshore and Arctic Engineering, Nantes, France. |
9 | Hayman, G.J., 2015. MExtemes Manual Version 1.00. Technical Report. NREL, Golden, Colorado, USA. |
10 | Hayman, G., 2012. MLife Theory Manual for Version 1.00. Technical Report. NREL, Golden, Colorado, USA. |
11 | Jonkman, J.M., 2007. Dynamics Modeling and Loads Analysis of an Offshore Floating Wind Turbine. University of Colorado at Boulder. |
12 | Jonkman, J., 2010. Definition of the Floating System for Phase IV of OC3. Technical Report, NREL/TP-500-47535. NREL, Golden, Colorado, USA. |
13 | Jonkman, J.M., Buhl Jr., M.L., 2005. FAST User's Guide. Technical Report, NREL/EL-500-38230. NREL, Golden, Colorado, USA. |
14 | Jonkman, J.B., Kilcher, L., 2012. TurbSim User's Guide: Version 1.06.0. Technical Report. NREL, Golden, Colorado, USA. |
15 | Jonkman, J., Butterfield, S., Musial, W., 2009. Definition of a 5-MW Reference Wind Turbine for Offshore System Development. Technical Report, NREL/TP-500-38060. NREL, Golden, Colorado, USA. |
16 | Jonkman, J.M., Robertson, A.N., Hayman, G.J., 2014. HydroDyn User's Guide and Theory Manual. Technical Report. NREL, Golden, Colorado, USA. |
17 | Kuhn, M.J., 2001. Dynamics and Design Optimization of Offshore Wind Energy Conversion Systems. Delft University of Technology, TU Delft. |
18 | Kvittem, M.I., 2014. Modelling and Response Analysis for Fatigue Design of a Semi-submersible Wind Turbine. Norwegian University of Science and Technology. |
19 | Kvittem, M.I., Moan, T., 2015. Frequency versus time domain fatigue analysis of a semisubmersible wind turbine tower. J. Offshore Mech. Arct. Eng. 137 (1), 011901. |
20 | Kvittem, M.I., Moan, T., 2015. Time domain analysis procedures for fatigue assessment of a semi-submersible wind turbine. Mar. Struct. 40, 38-59. DOI |
21 | Long, H., Moe, G., 2012. Preliminary design of bottom-fixed lattice offshore wind turbine towers in the fatigue limit state by the frequency domain method. J. Offshore Mech. Arct. Eng. 134 (3), 031902. DOI |
22 | Roald, L., Jonkman, J., Robertson, A., et al., 2013. The effect of second-order hydrodynamics on floating offshorewind turbines. Energy Proc 35, 253-264. |
23 | Matsuishi, M., Endo, T., 1968. Fatigue of Metals Subjected to Varying Stress. Japan Society of Mechanical Engineers, Fukuoka, Japan, pp. 37-40. |
24 | Melchers, R.E., 1987. Structural Reliability Analysis and Prediction. Structural Reliability Analysis & Prediction. |
25 | Moriarty, P.J., Hansen, A.C., 2005. AeroDyn Theory Manual. Technical Report, NREL/TP-500-36881. NREL, Golden, Colorado, USA. |
26 | Seidel, M., Ostermann, F., Curvers, A., et al., 2009. Validation of offshore load simulations using measurement data from the DOWNVInD project. In: Proceedings of European Offshore Wind Conference, Stockholm, Sweden. |
27 | Veritas, D.N., 2010. DNV-RP-C203. Fatigue Design of Offshore Steel Structures. |
28 | Ma, Yu, 2014. Research on Dynamic Analysis for a Spar Type Offshore Floating Wind Turbine. Shanghai Jiao Tong University. |
29 | Li, L., Gao, Z., Moan, T., 2013. Joint environmental data at five European offshore sites for design of combined wind and wave energy devices. In: ASME 2013 32nd International Conference on Ocean. Offshore and Arctic Engineering, Nantes, France. |
30 | Ma, Yu, Hu, Z., Xiao, L., 2015. Wind-wave induced dynamic response analysis for motions and mooring loads of a spar-type offshore floating wind turbine. J. Hydrodyn. Ser. B 26 (6), 865-874. DOI |
31 | https://nwtc.nrel.gov/FAQ. |
32 | Van Der Tempel, J., 2006. Design of Support Structures for Offshore Wind Turbines. Delft University of Technology, TU Delft. |