Abstract
With increasing deployment of offshore wind farms further from shore and in deeper waters, the efficient and effective planning of operation and maintenance (O&M) activities has received considerable attention from wind energy developers and operators in recent years. The O&M planning of offshore wind farms is a complicated task, as it depends on many factors such as asset degradation rates, availability of resources required to perform maintenance tasks (e.g., transport vessels, service crew, spare parts, and special tools) as well as the uncertainties associated with weather and climate variability. A brief review of the literature shows that a lot of research has been conducted on optimizing the O&M schedules for fixed-bottom offshore wind turbines; however, the literature for O&M planning of floating wind farms is too limited. This paper presents a stochastic Petri network (SPN) model for O&M planning of floating offshore wind turbines (FOWTs) and their support structure components, including floating platform, moorings and anchoring system. The proposed model incorporates all interrelationships between different factors influencing O&M planning of FOWTs, including deterioration and renewal process of components within the system. Relevant data such as failure rate, mean-time-to-failure (MTTF), degradation rate, etc. are collected from the literature as well as wind energy industry databases, and then the model is tested on an NREL 5 MW reference wind turbine system mounted on an OC3-Hywind spar buoy floating platform. The results indicate that our proposed model can significantly contribute to the reduction of O&M costs in the floating offshore wind sector.
Highlights
The wind energy industry is expanding its frontiers throughout the world, and wind power is gradually taking over the market from fossil fuels
To overcome some of these challenges, floating offshore maintenance. To overcome of these challenges, floating offshore wind turbines (FOWTs) are becoming economically attractive optionattractive for wind energy projects water wind turbines (FOWTs)an are becoming an economically option for windinenergy depths greater than
To overcome this research gap, this paper proposes a stochastic Petri network (SPN) model for operation and maintenance (O&M) planning of FOWT systems and their associated support structure components, including floating platform, catenary mooring lines and anchoring system
Summary
The wind energy industry is expanding its frontiers throughout the world, and wind power is gradually taking over the market from fossil fuels. According to the Crown Estate’s report [5], the UK currently has the largest operational capacity of offshore wind in Europe, representing 45% of the total installed capacity. Fits, the deepwater have deala greater with a greater scale of challenges than shalthe deepwater windwind farmsfarms have to dealtowith scale of challenges than shallow-water low-water wind as constraints the design constraints of fixed-bottom a wide wind farms, suchfarms, as thesuch design of fixed-bottom structures, astructures, wide variation of variation of weather conditions, and the need to hire expensive machinery or access weather conditions, and the need to hire expensive machinery or access equipment for equipment for[9] To overcome of these challenges, floating offshore wind turbines (FOWTs) are becoming economically attractive optionattractive for wind energy projects water wind turbines (FOWTs)an are becoming an economically option for windinenergy depths greater than.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
