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Ice-Rubber Friction for Tyres |
Dr Jane Blackford
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Materials and Processes |
The aim of this project is to gain a better understanding of the nature of the interface between rubber and ice. It is a collaborative project with Michelin. We use tribological testing and materials characterisation techniques in a specially designed cold room facility to do this. Ultimately this knowledge will be used to improve tyre traction on ice.
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IMPACT: Implantable Microsystems for Personalised Anti-Cancer Therapy |
Professor Alan Murray
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Bioengineering |
IMPACT is a 5-year, £5.2M research project, funded by an EPSRC Programme Grant, to develop new approaches to cancer treatment, using implanted, smart sensors on silicon, fabricated in the University's Scottish Microelectronics Centre. IMPACT will use miniaturised, wireless sensor chips the size of a grass seed to monitor the minute-to-minute status of an individual tumour. This will allow RT to be targeted in space and time to damage cancer cells as much as possible. The team consists of engineers, chemists, veterinary clinicians, social scientists and human cancer specialists, led by Prof Alan Murray from the University's School of Engineering.
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IFPRI Grindability Project: modelling, measurement and mill fingerprinting |
Prof. Jin Ooi
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Infrastructure and Environment |
This project aims to develop a robust methodology to characterise the grindability of particulate products in milling operations which will in turn provide a step-change in mill fingerprinting and optimisation. This involves developing a “grindability test” to measure the comminution characteristics of the particulates which, when coupled with the computational modelling work to characterise the milling function, will evaluate the milling performance measures including energy utilisation, breakage kernels for scale-up modelling such as population balance model of the mill.
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IDCORE: Industrial Doctoral Centre in Offshore Renewable Energy |
Professor David Ingram
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Energy Systems |
The drive to meet the UK’s ambitious deployment targets for offshore renewable energy technologies requires the development of new techniques and technologies to design, build, install, operate, and maintain devices in hostile environments at affordable economic cost with minimal environmental impact. It requires a supply of highly trained scientists and engineers to deliver their skills across the sector. The Universities of Edinburgh, Strathclyde and Exeter together with the Scottish Association for Marine Science and HR-Wallingford form a partnership to deliver the EPSRC/ETI Industrial Doctorate Centre in Offshore Renewable Energy (IDCORE).
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High Performance Computing Support for United Kingdom Consortium on Turbulent Reacting Flows (UKCTRF) |
Dr Stephen Welch
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Infrastructure and Environment |
The proposed UK Consortium on Turbulent Reacting Flows will perform high-fidelity computational simulations (i.e. Reynolds Averaged Navier-Stokes simulations (RANS), Large Eddy Simulation (LES) and Direct Numerical Simulations (DNS)) by utilising national High Performance Computing (HPC) resources to address the challenges related to energy through the fundamental physical understanding and modelling of turbulent reacting flows. Engineering applications range from the formulation of reliable fire-safety measures to the design of energy-efficient and environmentally-friendly internal combustion engines and gas turbines.
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Health and Safety in Voluntary Sector Construction |
Dr Martin Crapper
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Infrastructure and Environment |
This research, conducted using sociological methods, investigates how these volunteer workers of railway sector construct safety in their volunteering environment.
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HARP: High capacity network Architecture with Remote radio heads & Parasitic antenna arrays |
Dr Tharmalingam Ratnarajah
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Imaging, Data and Communications |
To bring distributed multi-antenna wireless access to reality by combining two powerful emerging technologies:
radio remote heads (RRHs), which allow for widely geographically distributed access via radio-over-fibre connections to a central base station; and
electronically steerable passive array radiators – ESPARs, which provide multi-antenna-like functionality with a single active RF chain only
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Ground Penetrating Radar (GPR) Modelling |
Dr Antonis Giannopoulos
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Infrastructure and Environment |
Welcome to GPR Max, a ground penetrating radar simulation tool.
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Geobag Revetments for river bank reinforcement in Bangladesh |
Dr Martin Crapper
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Infrastructure and Environment |
This project aims at the production of guidelines for the safe design of revetments, which are often constructed manually by local farmers, with little engineering input.
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GREENNET An early stage training network in enabling technologies for GREEN radio |
Professor Harald Haas
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Imaging, Data and Communications |
Greenet is an Initial Training Network (ITN) Marie Curie project that is focused on the analysis, design, and optimization of energy efficient wireless communication systems and networks.
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