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accepted all year round Details Conceptual designs for coal-fired power plants seek improved methods of heat and process integration to improve overall plant efficiency using conventional technologies
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membranes for improved CCS applications. The developed pre-pilot membrane modules will be evaluated under a range of different industrially relevant conditions, with a number of different process relevant
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an emerging waste recovery and treatment technology using advanced gasification processes that can recover the useful materials in the waste in addition to harvesting the energy. Computational modelling will be
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modes such as fibre kinking, fibre rupture, matrix cracking or delamination, which makes challenging to calculate an exact prediction of the failure process. However, novel available techniques
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is needed to ensure continued operation of the system during periods of low radiation. This project will investigate the integration of solar energy and biogas to provide heat and electricity to a
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advanced component technologies, next generation burners and heat integration schemes that do not currently exist, but which illustrate the potential for process improvements. Next-generation combustors
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operating conditions will be investigated. This will be complemented by process simulation with the gPROMS or ASPEN software package to investigate the overall system performance and economics. Funding Notes
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correlated to generate new physical insights into the complex interaction process of flame and wall. Funding Notes 1st or 2:1 degree in Engineering, Materials Science, Physics, Chemistry, Applied Mathematics
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complemented by process simulation with the gPROMS or ASPEN software package to investigate the overall system performance and economics. Funding Notes 1st or 2:1 degree in Engineering, Materials Science
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Kevin Hughes, Prof Derek Ingham Application Deadline: Applications accepted all year round Details This project aims to combine computational fluid dynamics, chemical process modelling and virtual system