Abstract
The number of installed floating offshore wind turbines (FOWTs) has doubled since 2017, quadrupling the total installed capacity, and is expected to increase significantly over the next decade. Consequently, there is a growing consideration towards the main challenges for FOWT projects: monitoring the system’s integrity, extending the lifespan of the components, and maintaining FOWTs safely at scale. Effectively and efficiently addressing these challenges would unlock the wide-scale deployment of FOWTs. In this work, we focus on one of the most critical components of the FOWTs, the Mooring Lines (MoLs), which are responsible for fixing the structure to the seabed. The primary mechanical failure mechanisms in MoLs are extreme load and fatigue, both of which are functions of the axial tension. An effective solution to detect long-term drifts in the mechanical response of the MoLs is to develop a Digital Twin (DT) able to accurately predict the behaviour of the healthy system to compare with the actual one. Moreover, we will develop another DT able to accurately predict the near future axial tension as an effective tool to improve the lifespan of the MoLs and the safety of FOWT maintenance operations. In fact, by changing the FOWT operational settings, according to the DT prediction, operators can increase the lifespan of the MoLs by reducing the stress and, additionally, in the case where FOWT operational maintenance is in progress, the prediction from the DT can serve as early safety warning to operators. Authors will leverage operational data collected from the world’s first commercial floating-wind farm [the Hywind Pilot Park (https://www.equinor.com/en/what-we-do/floating-wind/hywind-scotland.html.)] in 2018, to investigate the effectiveness of DTs for the prediction of the MoL axial tension for the two scenarios depicted above. The DTs will be developed using state-of-the-art data-driven methods, and results based on real operational data will support our proposal.
Highlights
Floating wind is one of the fastest-growing sectors within the Offshore Renewable Energy Industry and internationally recognised as one of the most promising renewable energy sources to satisfy a significant proportion of global energy demands (Carbon Trust 2015)
Physical Models (PMs) and Data-Driven Models (DDMs) can be used to detect long- term drifts in the mechanical response of the Mooring Lines (MoLs) by developing a Digital Twin (DT) able to accurately predict the behaviour of the healthy system to compare with the actual one
The DT prediction could be used to change the floating offshore wind turbines (FOWTs) operational settings to increase the lifespan of the MoLs by reducing the stress and, in the case where FOWT operational maintenance is in progress, serve as an early safety warning to operators
Summary
Floating wind is one of the fastest-growing sectors within the Offshore Renewable Energy Industry and internationally recognised as one of the most promising renewable energy sources to satisfy a significant proportion of global energy demands (Carbon Trust 2015). The ability to economically deploy floating offshore wind turbines (FOWTs) in deepwater areas, that were previously unfeasible for development using fixed-bottom turbines, is one of the fundamental driving forces behind the success of floating wind (Carbon Trust 2018). Journal of Ocean Engineering and Marine Energy a significant amount work required to address the unique aspects to floating wind: monitoring the system’s integrity, extending the lifespan of the components, and maintaining FOWTs safely at scale (Carbon Trust 2015, 2018, 2020). Due to the success of Pilot FOWTs around the world, the industry is focused on addressing these remaining challenges before deploying FOWTs at scale in deepwater (Carbon Trust 2020). The use, monitoring, and maintenance of the station-keeping devices (i.e., the Mooring Lines—MoLs) devoted to anchor the FOWT structure in place pose some of the most prominent challenges to overcome (Carbon Trust 2020)
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