UKERC Energy Data Centre: Projects

Projects: Projects for Investigator
UKERC Home >> UKERC Energy Data Centre >> Projects >> Choose Investigator >> All Projects involving >> EP/L015943/1
 
Reference Number EP/L015943/1
Title EPSRC Centre for Doctoral Training in Gas Turbine Aerodynamics
Status Started
Energy Categories ENERGY EFFICIENCY(Transport) 25%;
FOSSIL FUELS: OIL, GAS and COAL(Oil and Gas, Oil and gas combustion) 50%;
NOT ENERGY RELATED 25%;
Research Types Basic and strategic applied research 100%
Science and Technology Fields ENGINEERING AND TECHNOLOGY (Mechanical, Aeronautical and Manufacturing Engineering) 100%
UKERC Cross Cutting Characterisation Not Cross-cutting 80%;
Other (Energy technology information dissemination) 20%;
Principal Investigator Dr RJ Miller
No email address given
Engineering
University of Cambridge
Award Type Standard
Funding Source EPSRC
Start Date 01 April 2014
End Date 31 December 2022
Duration 105 months
Total Grant Value £5,285,158
Industrial Sectors Aerospace; Defence and Marine; Energy
Region East of England
Programme NC : Engineering
 
Investigators Principal Investigator Dr RJ Miller , Engineering, University of Cambridge (99.995%)
  Other Investigator Professor L He , Engineering Science, University of Oxford (0.001%)
Professor Dame A Dowling , Engineering, University of Cambridge (0.001%)
Dr G Pullan , Engineering, University of Cambridge (0.001%)
Dr J Carrotte , Aeronautical and Automotive Engineering, Loughborough University (0.001%)
Dr GJ Page , Aeronautical and Automotive Engineering, Loughborough University (0.001%)
  Industrial Collaborator Project Contact , Dyson Appliances Ltd (0.000%)
Project Contact , Siemens plc (0.000%)
Project Contact , Mitsubishi Corporation, Japan (0.000%)
Project Contact , Rolls-Royce PLC (0.000%)
Web Site
Objectives
Abstract A new generation of gas turbine engines is required to meet future environmental and commercial targets. This requirement applies to gas turbines used for a wide range of applications including aircraft propulsion and power generation. To date, many performance improvements have been made through improved understanding of the complex aerodynamic processes occurring within a gas turbine engine. However, meeting future challenges and targets will require the adoption of a multi-disciplinary and integrated design methodology. In such a methodology, the complex aerodynamic processes, and the design of individual components, can not be considered in isolation. Instead, the design process must include (i) the strong links/interaction between the aerodynamics and other aerothermal processes (e.g. heat transfer, acoustics, fuel break up) and (ii) the interaction between the different gas turbine components. To facilitate this approach, an EPSRC Centre of Doctoral Training in Gas Turbine Aerodynamics is proposed involving Cambridge, Loughborough and Oxford Universities. These three universities have been specifically chosen because of their track record of research excellence in the aerodynamics of the three major components of a gas turbine (compressor, combustor and turbine). In addition to their aerodynamics expertise these universities also undertake world class research in the fields with which aerodynamics interacts (e.g. heat transfer, acoustics, two phase flows). The proposed CDT is fully aligned with the strategies of all three institutions to promote long term industrial engagement and collaboration, as strongly endorsed in the institutional letters of support.Students will spend the first year of their training studying for an MRes in Gas Turbine Aerodynamics. The intention is for this course to become the world's premiere gas turbine course, training the next generation of research and industry leaders. All three institutions, and the industry partners of the CDT, will contribute to the teaching of this course to ensure that the students aquire the broad range of knowledge required to meet future technical challenges. This contrasts to the current approach whereby students typically study a narrow range of methods and techniques applicable to a specific component challenge. The approach proposed here will enable the students to be exposed to a wide range of theoretical, experimental and numerical techniques applicable to the design of different components of a gas turbine engine, with emphasis being placed on a more integrated and multi-disciplinary design philosophy. Time spent at the different institutions will also expose the students to the cutting edge research being undertaken in these different areas. In the following three years, the students will undertake high impact and innovative research projects inspired by industrial collaboration.To successfully innovate and translate innovation into a product requires close engagement between academia and industry. The CDT has assembled a group of companies which span the entire gas turbine products range including Rolls-Royce in gas turbines for aerospace, industrial and marine applications, Mitsubishi Heavy Industries in large gas turbines for power generation and Siemens UK for small gas turbines for power and pumping. In addition, technologies developed for use in gas turbines are now being actively developed for a range of other purposes. An example of this is Dyson who has invested significant research funding into the development high efficiency axial compressors for use in domestic products. The CDT will be open to such companies who can benefit directly both from the facilities available, the research undertaken within the individual projects and the design methods developed. In the longer term, these companies will also benefit from the potential employees and industry leaders that the CDT will produce.
Publications (none)
Final Report (none)
Added to Database 16/06/14