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Improved physical modelling techniques for new high capacity floating offshore wind turbines DoS: Dr Martyn Hann ([email protected] , tel.: +44 1752 586130) 2nd Supervisor: Dr Sanjay
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Funding providers: EPSRC and STRIP5 Prosperity Partnership Subject areas: Photovoltaics, Perovskites, Module design, Engineering Project start date: 1 October 2024 (Enrolment open from mid-September) Project description: This 4-year PhD position offers an exciting opportunity to join the STRIPS...
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4 Jun 2024 Job Information Organisation/Company Swansea University Department Central Research Field Engineering » Materials engineering Researcher Profile First Stage Researcher (R1) Country United Kingdom Application Deadline 1 Jul 2024 - 23:59 (Europe/London) Type of Contract Other Job...
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Supervisor(s) Professor Will Coombs, Durham University Professor Charles Augarde, Durham University Enquiries email: [email protected] Project description Floating wind offers the possibility
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To meet the needs of growth in the low-carbon economy, achieve the UK CO2 emissions-targets and ensure resilient low-cost energy, offshore wind power permanent magnet generators offer an affordable
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Floating wind offers the possibility of opening up energy resource in deeper water than feasible with fixed solutions (e.g. monopiles or jackets) which become impractical in water depths over 45m
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@hull.ac.uk Project description The pursuit of clean and sustainable energy solutions has led to the exploration of innovative methods for harnessing wind energy. One such innovation is the development
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, and attentional lapses, alongside extreme weather. Additionally, according to statistics from a manufacturing company, 40% of wind turbine errors are due to human error. Working long hours in harsh
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and reliability of offshore wind turbines through advanced digital twin and machine learning technologies. This project will investigate existing digital twin and machine learning models and find
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This study will investigate the pivotal role of wind turbine owners’ decisions and the policy alternatives aimed at increasing the integration of offshore wind energy into electricity grids. In