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About
Colleges

Industrial Thermal Energy Recovery Conversion and Management

The main aim of the I-ThERM project is to investigate, design, build and demonstrate innovative plug and play waste heat recovery solutions and the optimum utilization of energy within and outside the plant perimeter for selected applications with high replicability and energy recovery potential in the temperature range 70oC- 1000oC

Waste heat recovery systems offer significant energy savings and substantial greenhouse gas emission reductions. The waste heat recovery market is projected to exceed €45.0 billion by 2018, but for this projection to materialise and for the European manufacturing and user industry to benefit from these developments, technological improvements and innovations need to take place aimed at improving the energy efficiency of heat recovery equipment and reducing installed costs.

The aim of the project is to develop and demonstrate technologies and processes for efficient and cost-effective heat recovery from industrial facilities in the temperature range of 70oc to 1000oc and the optimum integration of these technologies with the existing energy system or for over the fence export of recovered heat and generated electricity if appropriate.

To achieve this challenging aim, and ensure wide application of the technologies and approaches developed, the project brings together RTD providers, technology providers and large and SME users who will provide demonstration sites for the technologies.

The project will focus on two-phase innovative heat transfer technologies (heat pipes-HP) for the recovery of heat from medium and low-temperature sources and the use of this heat for (a) within the same facility or export over the fence; (b) for generation of electrical power; or a combination of (a) and (b) depending on the needs.

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 - Brunel University 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