Thermal Energy Challenge Network
Lead Research Organisation:
Durham University
Department Name: Engineering
Abstract
Tackling climate change, providing energy security and delivering sustainable energy solutions are major challenges faced by civil society. The social, environmental and economic cost of these challenges means that it is vital that there is a research focus on improving the conversion and use of thermal energy. A great deal of research and development is continuing to take place to reduce energy consumption and deliver cost-effective solutions aimed at helping the UK achieve its target of reducing greenhouse gas emissions by 80 per cent by 2050. Improved thermal energy performance impacts on industry through reduced energy costs, reduced emissions, and enhanced energy security. Improving efficiency and reducing emissions is necessary to increase productivity, support growth in the economy and maintain a globally competitive manufacturing sector.
In the UK, residential and commercial buildings are responsible for approximately 40% of the UK's total non-transport energy use, with space heating and hot water accounting for almost 80% of residential and 60% of commercial energy use. Thermal energy demand has continued to increase over the past 40 years, even though home thermal energy efficiency has been improving.
Improved thermal energy conversion and utilisation results in reduced emissions, reduced costs for industrial and domestic consumers and supports a more stable energy security position. In the UK, thermal energy (heating and cooling) is the largest use of energy in our society and cooling demand set to increase as a result of climate change. The need to address the thermal energy challenge at a multi-disciplinary level is essential and consequently this newly established network will support the technical, social, economic and environmental challenges, and the potential solutions. It is crucial to take account of the current and future economic, social, environmental and legislative barriers and incentives associated with thermal energy. The Thermal Energy Challenge Network will support synergistic approaches which offer opportunities for improved sustainable use of thermal energy which has previously been largely neglected. This approach can result in substantial energy demand reductions but collaboration and networking is essential if this is to be achieved. A combination of technological solutions working in a multi-disciplinary manner with engineers, physical scientists, and social scientists is essential and this will be encouraged and supported by the Thermal Energy Challenge Network.
In the UK, residential and commercial buildings are responsible for approximately 40% of the UK's total non-transport energy use, with space heating and hot water accounting for almost 80% of residential and 60% of commercial energy use. Thermal energy demand has continued to increase over the past 40 years, even though home thermal energy efficiency has been improving.
Improved thermal energy conversion and utilisation results in reduced emissions, reduced costs for industrial and domestic consumers and supports a more stable energy security position. In the UK, thermal energy (heating and cooling) is the largest use of energy in our society and cooling demand set to increase as a result of climate change. The need to address the thermal energy challenge at a multi-disciplinary level is essential and consequently this newly established network will support the technical, social, economic and environmental challenges, and the potential solutions. It is crucial to take account of the current and future economic, social, environmental and legislative barriers and incentives associated with thermal energy. The Thermal Energy Challenge Network will support synergistic approaches which offer opportunities for improved sustainable use of thermal energy which has previously been largely neglected. This approach can result in substantial energy demand reductions but collaboration and networking is essential if this is to be achieved. A combination of technological solutions working in a multi-disciplinary manner with engineers, physical scientists, and social scientists is essential and this will be encouraged and supported by the Thermal Energy Challenge Network.
Planned Impact
Industry and business will benefit through knowledge transfer of innovative technology, best practice and behaviour related research to improve thermal energy management. The result will be advanced development, reduced fuel costs, lower greenhouse gas emissions and improving efficiency to allow them to provide thermal energy management solutions into a growing international market. Industry and business will also benefit from the opportunity to engage with researchers in order to input to inform future research strategies, identify challenges and communicate their needs and real/perceived barriers. Government and policy makers are increasingly aware of the technological, social and environmental challenges of future energy supply and demand and sustainability targets. They will benefit by having the opportunity to input their identified knowledge gaps and requirements into the international research effort. They will receive relevant information and data which will provide relevant insight and aide decision making and help shape future energy policy. Benefits will be gained from the knowledge transfer of robust technical, social and economic solutions from the academic community. The forecast of future need and identification of challenges taking account of barriers, incentives, trade-offs and opportunities to exploit effective thermal energy management across sectors will support policy and regulatory interventions. Academic researchers will benefit from the Network through the opportunity to disseminate research outcomes as widely as possible via an array of pathways as outlined in the proposal, including presentation at the conferences and journal publication in special issues. Academic researchers will also benefit from the availability of a centralised resource library on the website and the opportunity to engage with a wide range of international stakeholders. The general population will benefit as the technical, economic, social and sustainable solutions disseminated through the Network will ultimately result in reduced energy bills and this will contribute towards tackling the important issue of fuel poverty. Society as a whole will also benefit from the positive impact due to reductions in greenhouse gas emissions.
The Network website will provide open access to progress reports, research publications and advertise activities, such as conferences, forums and workshops. It will also provide general information about thermal energy challenges and important results in a way that is accessible and interesting to the non-research community. It will host a dedicated secure section for research outcomes and other confidential data. By organising international conferences, this pathway would provide an important opportunity for the research community (private and public) to reach a wide audience of other researchers, industry and policymakers. The Network will produce full length conference proceedings. High impact journals, such as Applied Energy, will be engaged to produce Special Editions resulting from the conferences. The Special Editions will be an efficient means to extend the impact to a wider group of audience and stimulate future work. The Network will establish strong links with UK, European and worldwide networks and Research Centres in order to disseminate research activity. A number of forums and workshops will be run strategically at different locations in the UK to facilitate effective engagement and communication among the stakeholders. Future need, research challenges and strategies will be identified by gathering feedback via questionnaires and interactive sessions at the Network events.
The Network website will provide open access to progress reports, research publications and advertise activities, such as conferences, forums and workshops. It will also provide general information about thermal energy challenges and important results in a way that is accessible and interesting to the non-research community. It will host a dedicated secure section for research outcomes and other confidential data. By organising international conferences, this pathway would provide an important opportunity for the research community (private and public) to reach a wide audience of other researchers, industry and policymakers. The Network will produce full length conference proceedings. High impact journals, such as Applied Energy, will be engaged to produce Special Editions resulting from the conferences. The Special Editions will be an efficient means to extend the impact to a wider group of audience and stimulate future work. The Network will establish strong links with UK, European and worldwide networks and Research Centres in order to disseminate research activity. A number of forums and workshops will be run strategically at different locations in the UK to facilitate effective engagement and communication among the stakeholders. Future need, research challenges and strategies will be identified by gathering feedback via questionnaires and interactive sessions at the Network events.
Organisations
Publications
Ling-Chin, J
(2019)
Handbook of Energy Economics
Lu Y
(2019)
Study of a novel hybrid refrigeration system for industrial waste heat recovery
in Energy Procedia
M R
(2019)
Carbon mitigation unit costs of building retrofits and the scope for carbon tax, a case study
in Energy and Buildings
Ogolla J
(2019)
Influence of Inlet Drying Air Temperature and Milk Flow Rate on the Physical, Optical and Thermal Properties of Spray-Dried Camel Milk Powders
in Food and Bioprocess Technology
Pathare P
(2019)
Novel Technologies and Systems for Food Preservation -
Siqueiros E
(2019)
Energy Recovery from Brewery Waste: experimental and modelling perspectives
in Energy Procedia
Smallbone A
(2020)
Erratum to: "Levelised Cost of Storage for Pumped Heat Energy Storage in comparison with other energy storage technologies" [Energy Convers. Manage. 152 (2017) 221-228]
in Energy Conversion and Management
Wang R
(2019)
Comparative Analysis of Small-Scale Organic Rankine Cycle Systems for Solar Energy Utilisation
in Energies
Wang R
(2020)
Energy saving technologies and mass-thermal network optimization for decarbonized iron and steel industry: A review
in Journal of Cleaner Production
Yu X
(2019)
Experimental investigation of two-phase flow and heat transfer performance in a cooling gallery under forced oscillation
in International Journal of Heat and Mass Transfer
Zhou J
(2019)
Investigating the impact of building's facade on the building's energy performance - a case study
in Energy Procedia
Description | A Network for Heating and Cooling Research to Enable a Net-Zero Carbon Future (H+C Zero Network) |
Amount | £1,159,698 (GBP) |
Funding ID | EP/T022906/1 |
Organisation | Engineering and Physical Sciences Research Council (EPSRC) |
Sector | Public |
Country | United Kingdom |
Start | 10/2020 |
End | 09/2024 |
Description | A network for hydrogen-fuelled transportation (Network-H2) |
Amount | £966,315 (GBP) |
Funding ID | EP/S032134/1 |
Organisation | Engineering and Physical Sciences Research Council (EPSRC) |
Sector | Public |
Country | United Kingdom |
Start | 10/2019 |
End | 09/2024 |
Description | UK-India Foundation Industries Sustainable Thermal Energy Management Collaboration (UK-India FI-SusTEM Collaboration) |
Amount | £79,923 (GBP) |
Funding ID | 10019361 |
Organisation | Innovate UK |
Sector | Public |
Country | United Kingdom |
Start | 11/2021 |
End | 03/2022 |