Digital Twin for Floating Offshore Wind Foundations Operation and Maintenance Management

Abstract In the offshore industry, environmental conditions typically have a significant effect on operation performance, maintenance, and total costs. In this study, predictive maintenance tools were developed in the context of a floating testbed structure (FTB), a cylindrical buoy with features representative of the maintenance needs of floating offshore wind foundations. The FTB was measured dynamically and statistically over the local weather conditions at a harbor in Portugal. A digital twin of the FTB was constructed using the data to assess mooring line loads and hydrodynamic responses at a different place in the Atlantic Ocean. One major factor restricting operation and maintenance is exposure to dynamic motion. A limiting criterion was demonstrated for heavy manual work based on short-length moving root-mean-square (RMS) values of vibration, acceleration, and roll/pitch. For operational state, history, and statistical analysis, RMS values were profiled as to time-at-level to evaluate the probability of a maintenance weather window and the suitability for maintenance deployment. FTB digital twin data was used to analyze mooring line loading and remaining useful life (RUL) to provide deterministic decision-making support for justified inspections and structural health monitoring (SHM) under different marine sea state conditions. The approaches shown can also be used for flagging sea-state conditions that are leading to premature failures and reduced lifetime.