Abstract.- Published work.- Acknowledgements.- List of Contents.- List of Figures.- List of Tables.- Nomenclature.- Chapter 1: Introduction.- Chapter 2: Review of the Literature.- Chapter 3: Liquid Desiccant Air Conditioning System Modelling and Analysis.- Chapter 4: SOFC Tri-Generation System Modelling and Analysis.- Chapter 5: Component Evaluation of a Novel Integrated Liquid Desiccant Air Conditioning System (IDCS).- Chapter 6: Component Evaluation of a Separate Liquid Desiccant Air Conditioning System (SDCS).- Chapter 7: Tri-Generation System Integration and Evaluation.- Chapter 7: Tri-Generation System Integration and Evaluation.- Chapter 8: Economic and Environmental Assessment.- Chapter 9: Conclusions and Future Work.- References.
Theo Elmer obtained his PhD from The Faculty of Engineering at The University of Nottingham under the supervision of Professor Saffa Riffat. His PhD thesis presents the design, development and testing of a novel proof-of-concept tri-generation system based on solid oxide fuel cell (SOFC) and liquid desiccant air conditioning technology to provide electricity, heating and cooling to building applications. The theme of the work sits within the topics of low-carbon & sustainable energy technologies, building services and low carbon building applications. The PhD was funded by the EPSRC CDT in Fuel Cells and Their Fuels. During his PhD numerous international conferences were attended and journal articles published relating to the doctoral work. Theo Elmer was also successful in securing funding from the EU Marie Curie International Research Staff Exchange Scheme for a research secondment to China. Following the completion of his PhD, Theo Elmer was awarded a research fellowship in the Architecture, Energy and Environment Research Group based at The University of Nottingham investigating low-carbon technologies for building applications.
The thesis has critically examined, both theoretically and experimentally, a novel tri-generation system concept - with encouraging system performance demonstrated. The thesis establishes the significant potential of the novel tri-generation system in providing effective built environment decarbonisation through decentralised generation; strengthening the case for a future hydrogen economy.
In response to the critical need to decarbonise the built environment, alternative methods for more effective energy utilisation need to be explored including tri-generation systems. The thesis presents the design, development and testing of a novel proof-of-concept tri-generation system based on solid oxide fuel cell (SOFC) and liquid desiccant air conditioning technology to provide electricity, heating and cooling to building applications. No previous work has been reported on such a system. The theme of the work sits within the topics of low-carbon and sustainable energy technologies, building services and low carbon building applications.