University of Limerick researchers pioneer robotic solution for floating wind farm maintenance

University of Limerick research team offshore pioneer robotic offshore wind farm inspection. UL CRIS team Anthony Weir, Helio Musselwhite-Veitch, Luke Fitzgerald, Cillian Fahy, and Phillipe Cardoso Santos.

University of Limerick research team pioneer a robotic solution for the inspection of floating offshore wind farms

Developed by University of Limerick (UL) researchers, the remote-operated vehicle has been successfully tested at WindFloat Atlantic, the world’s first semi-submersible floating offshore wind farm, and the results will help prepare for the challenges of maintaining these structures.

The intervention, repair and maintenance survey was carried out by a team from the Centre for Robotics and Intelligent Systems (CRIS) at UL.

Regular inspections and maintenance are vital for offshore wind farms, whether bottom-fixed or floating and currently, these tasks rely heavily on human intervention. However, with the industry’s growth and advancements, there is an increased emphasis on enhancing reliability and reducing operational costs.

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A fleet of Field Robots, subsea Remotely Operated Vehicles (ROVs) and Unmanned Aerial Vehicles (UAVs) were used by the team to survey the Ocean Winds’ WindFloat Atlantic off the coast of Portugal.

It offered the UL researchers a unique opportunity to perform the inspection tasks on a fully operational floating offshore wind farm, testing the technology in real-life conditions.

The survey yielded high-resolution, geo-referenced 3D models of structures above and below the waterline. The datasets and findings will be accessible through gold open-access articles and proceedings, benefiting the public, academia, and government.

Professor Daniel Toal, Co-Director of UL CRIS believes the “significance” of the research should be seen in Ireland’s offshore wind strategy context “which aims to achieve 37 Gigawatts of offshore renewable energy capacity by 2050.

He said, “This target also includes six Gigawatts of floating offshore wind farms on the West Coast and plans for the Shannon Estuary. Achieving this goal requires the development of intervention, repair and maintenance capacities and capabilities to ensure offshore operations are efficient and cost-effective.”

Conducted as part of the ATLANTIS project call for testing marine technology solutions for inspecting offshore wind structures, the testing was funded by the Sustainable Energy Authority of Ireland (SEAI) Robots for Wind Farm project.

Ocean Winds, as the majority owner, developer and operator of the WindFloat Atlantic floating offshore wind farm, has been a key testing partner for the ATLANTIS project and a hub for innovative solutions and pilots. MaREI, a Science Federation Ireland (SFI) Centre for Energy Climate, Marine Research and Innovation, also supported the survey.

One of the challenges in inspecting a floating turbine is the movement of the structure, an effect that the UL team successfully minimised by using an adaptive control system for the remote-operated vehicle, as well as customised machine vision algorithms used in the image post-processing.

Dr Phillipe Santos, Chief CRIS scientist for the trials at WindFloat Atlantic said they were “very proud” of the results of the trials and believe “this is just the beginning of a groundbreaking partnership.”.

He said, “CRIS has been developing exceptional robotic capabilities that can transform the way we approach offshore wind farm inspections.”

Speaking about the groups goals, he added, “Our goal is to continuously innovate and develop robotic technologies that increase efficiency, reduce costs, and most importantly, improve safety by minimising the need for human workers to operate in hazardous conditions.”

José Pinheiro, Ocean Winds country manager for South Europe and project director for WindFloat Atlantic mentioned, “At Ocean Winds, we are thrilled to support University of Limerick’s use of our operating project to test their remote-operated vehicle. These initiatives are essential for advancing the floating offshore wind sector to commercial scale, as well as continually improving operation and maintenance strategies for bottom-fixed installations. This collaboration not only drives innovation but also sets a precedent for implementation in other countries and projects.”

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