Your search keyword '"Dunham, Chris"' showing total 4 results

1. A holistic design approach for 5th generation smart local energy systems: Project GreenSCIES.

Author

Revesz, Akos, Dunham, Chris, Jones, Phil, Bond, Carole, Fenner, Russell, Mody, Sagar, Nijjhar, Rajvant, Marques, Catarina, and Maidment, Graeme

Subjects

*SMART cities, *HEAT storage, *WASTE heat, *INTERNAL rate of return, *HEATING from central stations, *BUILDING-integrated photovoltaic systems, *HEAT pumps, *CARBON emissions

Abstract

This paper introduces a project called GreenSCIES; an InnovateUK funded detailed design project to develop a Smart Local Energy System (SLES) delivering a significant carbon saving for local residents, schools and businesses. The SLES is centred around a 5th Generation District Heating and Cooling (5DHC) network in the London Borough of Islington. The local energy system will deliver low carbon heating, cooling, power and e-mobility charging powered by renewable energy and waste heat, sourced from the local area. The proposed SLES will manage and balance the supply, storage (both thermal and electrical) and use of local energy across mobility, power and heat vectors. It will do so using smart control technologies, bringing significant energy efficiency and security as well as social, environmental and economic benefits to Islington. The paper introduces the holistic SLES design approach developed by the GreenSCIES consortium, building upon an initial feasibility study previously published by the authors. The design methodology described takes technical and commercial aspects of a SLES design into account, whilst also explaining the importance of effective stakeholder engagement and co-design with local communities. The paper also provides a technical overview around the intended operation of ambient loop and heat pumps alongside long and short term thermal energy storage. A technical approach selected for integrating electric vehicles (EVs) and solar photovoltaic (PV) is also discussed in detail, alongside the control system architecture developed for the integrated SLES. The paper subsequently moves into demonstrating the benefits of the integrated SLES through a focused scheme design called New River, demonstrating integrated SLES performance compared to conventional systems in a real setting, through a comprehensive energy model. The results presented from a techno-economic analysis demonstrate that significant carbon savings and an attractive internal rate of return of (10%) can be achieved. The results presented show that even the smaller constructible "New River" scheme will save more 5000 tons of CO 2 e annually. This is a reduction in carbon emissions by 80% over conventional systems and, therefore a major decarbonisation solution in large cities across the world. The GreenSCIES approach presented in this paper is replicable worldwide and could become a central part of delivering nations' net zero carbon strategy. • Ambient loops integrated with EV and PV could help decarbonise urban areas. • Aquifer Thermal Energy Storage provides a novel way of balancing the system. • The Behind the Meter electrical connection approach is cost-effective. • Significant carbon savings and an attractive internal rate of return. • The holistic SLES design approach is replicable and it can be used as a guide. [ABSTRACT FROM AUTHOR]

Published

2022

2. Optimisation of Smart Local Energy Systems with Aquifer Thermal Energy Storage in Cities.

Author

Revesz, Akos, Williams, Huw, Findlay, John, Dunham, Chris, Jones, ,Phil, Moggeridge, Michael, Riddle, Anthony, and Maidment, Graeme

Subjects

*HEAT storage, *GEOLOGICAL carbon sequestration, *AQUIFERS, *HYDROGEOLOGY, *BOREHOLES

Abstract

This paper provides an overview of a systematic approach for the performance optimisation of smart local energy systems (SLES) using central London, UK as a case study. Key components of the SLES are linked in decentralised energy centres, which are connected through an ultra-low temperature (also called ambient loop) 5th generation heating & cooling (5DHC) network. The 5DHC approach requires a means of balancing the heat and coolth in the ambient loop. This work has identified that the introduction of Aquifer thermal energy stores (ATES) system could be a novel way of achieving that balancing mechanism as well as to provide heat and coolth store interseasonally. This paper describes a comprehensive study, which investigated the potential of using the London aquifer system for supplying and balancing the thermal loads of a 5DHC network in Central London. The paper first introduces a currently ongoing detailed design project called GreenSCIES - Green Smart Community Integrated Energy Systems. Then it presents the methodology applied for evaluating the opportunity for implementing and optimising the scheme making use of an ATES system. Results of novel and comprehensive numerical groundwater modelling of the ATES system behaviour at the proposed location are presented and discussed in detail. Furthermore, the results are discussed in relation to optimal location, design and operational regime of the boreholes in order to achieve maximum performance of the proposed 5DHC scheme. [ABSTRACT FROM AUTHOR]

Published

2022

3. Developing novel 5th generation district energy networks.

Author

Revesz, Akos, Jones, Phil, Dunham, Chris, Davies, Gareth, Marques, Catarina, Matabuena, Rodrigo, Scott, Jim, and Maidment, Graeme

Subjects

*RENEWABLE energy sources, *WASTE heat, *HEAT storage, *ELECTRIC pumps, *ENERGY demand management, *DATA libraries, *SERVER farms (Computer network management)

Abstract

Integrated smartly controlled energy networks have the potential to deliver significant reductions in carbon emissions, improve air quality and reduce energy costs for end-users across the world. This paper introduces a novel methodology for the development of integrated thermal, power and mobility 5th generation (5G) smart energy networks. The proposed 5G concept builds on state of the art by connecting flexible electricity demands such as heat pumps, and electric vehicles to intermittent, renewable and secondary energy sources and storage using artificial intelligence to facilitate optimal control and to maximise revenue and carbon savings. The proposed innovative method is being applied in central London through the development of two independent 5G smart energy schemes. The proposed schemes will incorporate a range of different renewables and secondary energy sources, for example, waste heat from local data centres and the London Underground that will supply a large proportion of the energy demand of the overall district network capacity. Both networks will operate at close to ambient temperature, approximately 15–25 °C as a so-called 'ambient loop' system, with individual heat pumps for each end-user or building connected to the network. The system also integrates thermal and electrical storage to create additional flexibility for the network and smart control for demand-side management. A smart management system flexibly controls individual assets such as heat pumps and electric vehicles in response to price signals reflecting the intermittency of renewable energy sources on the electricity grid. The ambient district thermal loop will distribute low carbon energy to a range of end users. Results presented in this paper provide an understanding of capital costs associated with integrated smart energy systems and the relative performance of individual technologies in a complex system using a techno-economic modelling approach. Overall, this paper demonstrates that the implementation of the 5G concept results in lower energy costs to consumers while at the same time transforming a large existing urban area to a near zero-carbon energy system in terms of heating, cooling, electricity and transport. [ABSTRACT FROM AUTHOR]

Published

2020

4. Initial Assessment of a 5th Generation District Energy Network in Central London.

Author

Revesz, Akos, Marques, Catarina, Davies, Gareth, Matabuena, Rodrigo, Jones, Phil, Dunham, Chris, and Maidment, Graeme

Subjects

*ENERGY demand management, *HEAT storage, *HEAT pumps, *PERFORMANCE technology, *GENERATIONS, *5G networks

Abstract

The paper introduces a concept design for the UK's first large-scale fifth generation (5G) smart energy network using an area in central London as a case study. The proposed system will incorporate a range of different renewables and secondary energy sources that will supply a large proportion of the energy demand of the overall district network capacity. The network will operate at close to ambient temperature, approximately 15-25°C (59-77°F) as a single loop system, with individual heat pumps for each end user or building connected to the network. The system also integrates thermal and electrical storage to create additional flexibility for the network and smart control for demand-side management. The paper describes the proposed 5G network concept and details the selected components of the system, in particular urban location. Key outcomes of the study presented in this paper provide understanding of the relative performance of individual technologies in a complex system using a techno-economic modelling approach. [ABSTRACT FROM AUTHOR]

Published

2020