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Optimising energy management in industry

Completed

The UK Government the EU and the international community, in general, have ambitious targets for the reduction of Greenhouse Gas Emissions (GHG) and Global Warming. Even though emission reduction targets to 2020 are likely to be met by the UK, longer-term targets to 2050 and 2100 are unlikely to be met without substantial changes to policy and technological approaches in the generation, distribution and utilisation of energy.

Globally, industrial energy use is responsible for 33% of greenhouse gas emissions. In the UK, industrial emissions have reduced in recent years and are now estimated to contribute between 20-25% of total emissions. Approximately 70% of the energy demand of the industrial sector is for heat. All heating processes result in significant quantities of waste heat, up to 50% in some cases, and is widely acknowledged that there is significant potential for heat recovery, estimated at between 18-40 TWh/yr or £0.18-0.4 billion per year at today's energy prices.

As yet, most of this potential has remained unexploited due to technical, economic and organisational factors. Other opportunities for energy efficiency and decarbonisation include the optimisation of steam systems that are responsible for 35% of industrial energy use, the use of bioenergy, particularly from organic and other wastes generated on site, and whole industrial site energy integration and optimisation.

To exploit the potential offered by energy efficiency, heat recovery and conversion to electrical or thermal energy at a higher or lower temperature and utilise the opportunities offered by waste to energy conversion and energy integration a number of major challenges need to be addressed.

These include:

i) development and application of technologies for data acquisition at high enough granularity to enable detailed analysis of performance at component, process and system level,

ii) methodologies for the optimal design of technologies to provide confidence in their performance at the implementation stage,

iii) tools for performance analysis and control optimisation in real time,

iv) modeling of energy flows at site level to provide optimisation of energy management based on energy, environmental and economic considerations, and

iv) investigation and development of business models that overcome barriers and encourage the adoption of new energy-efficient and demand reduction technologies.


Meet the Principal Investigator(s) for the project

Professor Savvas Tassou
Professor Savvas Tassou - Academic and Professional Qualifications BSc (1st Class Honours) Mechanical Engineering PhD Department of Mechanical Engineering. Thesis titled `An Investigation of the Criteria to Give Optimum Performance from a Variable Capacity Heat Pump\'. MBA Master of Business Administration. CEng Chartered Engineer. MIMechE Corporate member of the Institution of Mechanical Engineers. MASHRAE Member of the American Society of Heating Refrigerating and Air Conditioning Engineers.. MIIR – Member of International Institute of Refrigeration FInstR - Fellow of the Institute of Refrigeration Academic Career 1978 - 1981 Research Assistant - University of Westminster 1981 - 1986 Lecturer in thermofluids and energy - University of Westminster 1986 to date - Lecturer/Senior Lecturer/Reader/Professor in Thermodynamics and Building Services Engineering - СʪÃÃÊÓƵ London 2001 - 2004 - Head of Department of Mechanical Engineering 2004 - 2014 - Head of School of Engineering and Design 2014 to date - Director of Institute of Energy Futures

Related Research Group(s)

HPHEs technology2

Heat Pipe and Thermal Management - Thermal management; Energy efficiency development; Emission reduction; Energy recovery; Heat-pipe technology; Heat exchangers; Fluid dynamics.


Partnering with confidence

Organisations interested in our research can partner with us with confidence backed by an external and independent benchmark: The Knowledge Exchange Framework. Read more.


Project last modified 21/11/2023