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the forefront of wind energy technology and energy systems research. The department has 4 divisions: i) Materials and Components for Wind Energy, ii) Wind Turbine Technology, iii) Wind Energy Systems, and iv
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to investigate flow-induced forces in hydraulic turbines under varying operational conditions and how these forces affect the degradation and lifetime of the machines. About the position The position is based
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targets groundbreaking advancements in sustainability and efficiency, innovations like hydrogen-powered flights and ultra-high gas turbine temperatures are gaining focus. This shift has created an urgent
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renewable energy systems playing a pivotal role in transitioning away from fossil fuels. Wind turbines, solar photovoltaics and hydropower form the backbone of low-emission (“green”) electricity generation
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for wind turbines, with the ultimate objective of including structural health information in windfarm asset management to optimise structural lifetime consumption while guaranteeing optimal power production
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work with fish behavior, engineering geology, turbine design, variable speed operation, etc. It involves fundamental research including a literature study and CFD modelling with the use of real case
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repair and maintenance of gas turbine engines. Applicants are invited to undertake a fully funded three-year PhD programme in partnership with Rolls-Royce to address key challenges in soft robotics
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the environmental noise sources, aerofoil noise is one of the major contributors, including noise from aircraft wing, aeroengine fan and wind turbines. Therefore, it is crucial to effectively reduce them for a quiet
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relevant to multiple applications, including small aircraft, drones, turbines, and other systems reliant on efficient fluid flow around foils. The project offers a unique opportunity to gain experience in
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the University of Nottingham. This project aligns with Rolls-Royce’s technical needs to develop automated and hybrid tooling solutions for in-situ/on-wing repair and maintenance of gas turbine engines