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Field
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explore the challenges of pumping cryogenic hydrogen in multi-phase flows, particularly under off-design, low-flow conditions, through structured design, advanced modelling, and experimental validation
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different components a forecasting system, e.g. numerical weather predictions and flood dynamics modelling, need to be better understood, quantified and minimised. Methodology: The aim of this exciting PhD
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deep inside confined spaces, such as pipes and vessels. Kinematics, static and dynamic models of the snake robot. Localisation of the snake robot with various sensory feedback, including vision and Fibre
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cyclic loading, varied surface conditions, and exposure to gaseous impurities, and advanced numerical modelling (Finite Element Analysis), this project aims to significantly enhance our understanding
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advanced simulation methods, including Reynolds-Averaged Navier-Stokes (RANS), Direct Numerical Simulations (DNS), and/or Large Eddy Simulations (LES), will be employed to accurately model the complex flow
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tests of low-emissions concretes Numerical modelling (e.g. modal, FEM, or equivalent) of a concrete FOWT concept (e.g. VolturnUS) under cyclic wave, wind, and current loading for conditions found around
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, computational modelling and experimental work. You’ll join a pioneering multidisciplinary team that values equity, diversity, and inclusion, gaining unique expertise in turbomachinery pump development, hydrogen
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under controlled conditions designed to reveal the underlying mechanisms of biomineralisation in marine calcifying organisms. The task of this PDRA is to assist in the design of a numerical model of
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include: Theoretical modelling of nanoscale effects and processes in SNAP Development of experimental methods of picometre-precise fabrication of miniature optical devices at the surface of an optical fibre
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effectors (https://www.youtube.com/watch?v=A_CTqVFJ7Jc). At the Rolls-Royce UTC, we have a unique capability to design, model, and develop robotic systems tailored for operations in restrictive environments