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Time domain analysis procedures for fatigue assessment of a semi-submersible wind turbine
Abstract Long term time domain analysis of the nominal stress for fatigue assessment of the tower and platform members of a three-column semi-submersible was performed by fully coupled time domain analyses in Simo-Riflex-AeroDyn. By combining the nominal stress ranges with stress concentration factors, hot spot stresses for fatigue damage calculation can be obtained. The aim of the study was to investigate the necessary simulation duration, number of random realisations and bin sizes for the discretisation of the joint wind and wave distribution. A total of 2316 3-h time domain simulations, were performed. In mild sea states with wind speeds between 7 and 9 m/s, the tower and pontoon experienced high fatigue damage due to resonance in the first bending frequency of the tower from the tower wake blade passing frequency (3P). Important fatigue effects seemed to be captured by 1 h simulations, and the sensitivity to number of random realisations was low when running simulations of more than 1 h. Fatigue damage for the tower base converged faster with simulation duration and number of random realisations than it did for the platform members. Bin sizes of 2 m/s for wind, 1 s for wave periods and 1 m for wave heights seemed to give acceptable estimates of total fatigue damage. It is, however, important that wind speeds that give coinciding 3P and tower resonance are included and that wave periods that give the largest pitch motion are included in the analysis.
Highlights Long term fatigue damage analysis for a semi-submersible wind turbine was performed. The emphasis was on the sensitivity to simulation duration, number of seeds and bin size for selecting of environmental conditions. 501 environmental conditions with 10,800 s durations were simulated with up to 10 seeds in a coupled time domain analysis tool. Simulating 7 × 3600 s gave insignificant errors compared to 10 × 10,800 s simulations.
Time domain analysis procedures for fatigue assessment of a semi-submersible wind turbine
Abstract Long term time domain analysis of the nominal stress for fatigue assessment of the tower and platform members of a three-column semi-submersible was performed by fully coupled time domain analyses in Simo-Riflex-AeroDyn. By combining the nominal stress ranges with stress concentration factors, hot spot stresses for fatigue damage calculation can be obtained. The aim of the study was to investigate the necessary simulation duration, number of random realisations and bin sizes for the discretisation of the joint wind and wave distribution. A total of 2316 3-h time domain simulations, were performed. In mild sea states with wind speeds between 7 and 9 m/s, the tower and pontoon experienced high fatigue damage due to resonance in the first bending frequency of the tower from the tower wake blade passing frequency (3P). Important fatigue effects seemed to be captured by 1 h simulations, and the sensitivity to number of random realisations was low when running simulations of more than 1 h. Fatigue damage for the tower base converged faster with simulation duration and number of random realisations than it did for the platform members. Bin sizes of 2 m/s for wind, 1 s for wave periods and 1 m for wave heights seemed to give acceptable estimates of total fatigue damage. It is, however, important that wind speeds that give coinciding 3P and tower resonance are included and that wave periods that give the largest pitch motion are included in the analysis.
Highlights Long term fatigue damage analysis for a semi-submersible wind turbine was performed. The emphasis was on the sensitivity to simulation duration, number of seeds and bin size for selecting of environmental conditions. 501 environmental conditions with 10,800 s durations were simulated with up to 10 seeds in a coupled time domain analysis tool. Simulating 7 × 3600 s gave insignificant errors compared to 10 × 10,800 s simulations.
Time domain analysis procedures for fatigue assessment of a semi-submersible wind turbine
Kvittem, Marit I. (author) / Moan, Torgeir (author)
Marine Structures ; 40 ; 38-59
2014-10-18
22 pages
Article (Journal)
Electronic Resource
English
Time domain analysis procedures for fatigue assessment of a semi-submersible wind turbine
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