Projection and detection procedures for long-term wave climate change impact on fatigue damage of offshore floating structures

Zou, Tao and Kaminski, Miroslaw Lech and Li, Hang and Tao, Longbin; (2020) Projection and detection procedures for long-term wave climate change impact on fatigue damage of offshore floating structures. In: Proceedings of the ASME 2020 39th International Conference on Ocean, Offshore and Arctic Engineering. American Society of Mechanical Engineers(ASME), Virtual, Online. ISBN 9780791884324 (https://doi.org/10.1115/OMAE2020-18350)

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Abstract

The climate change may affect the long-term wave statistics and consequently affect the cumulative fatigue damage. This paper aims to project the trend of annual fatigue damage of offshore floating structures and to detect the climate change impact on the future fatigue damage by coupling a conventional fatigue design method with climate and wave models. Firstly, climate scenarios are selected to project the global radiative forcing level over decadal or century time scales. Secondly, climate models are used to simulate atmosphere circulations and to obtain the wind field data. Thirdly, wave conditions are simulated by coupling wind driven wave models to climate models. Fourthly, stress analysis and fatigue assessments are conducted to project the annual fatigue damage. At last, control simulations are carried out in order to identify the range of natural variability and to detect the human-induced change. A case study is presented in the Sable field offshore South Africa. The results indicate that the significant wave height is considerably influenced by the human-induced climate change. However, this change induced by human activities is still partially masked by the dominant natural variability. In addition, both the significant wave height and the annual fatigue damage increase over century time-scales.

ORCID iDs

Zou, Tao, Kaminski, Miroslaw Lech, Li, Hang and Tao, Longbin ORCID logoORCID: https://orcid.org/0000-0002-8389-7209;