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Details of Grant 

EPSRC Reference: EP/M023893/1
Title: CFD Modelling of the acoustic response of sprays
Principal Investigator: Garmory, Dr A
Other Investigators:
Researcher Co-Investigators:
Project Partners:
Rolls-Royce Plc (UK)
Department: Aeronautical and Automotive Engineering
Organisation: Loughborough University
Scheme: First Grant - Revised 2009
Starts: 15 January 2016 Ends: 14 July 2017 Value (£): 97,129
EPSRC Research Topic Classifications:
Aerodynamics Combustion
Heat & Mass Transfer
EPSRC Industrial Sector Classifications:
Aerospace, Defence and Marine
Related Grants:
Panel History:
Panel DatePanel NameOutcome
25 Feb 2015 Engineering Prioritisation Panel Meeting 25 February 2015 Announced
Summary on Grant Application Form
For the foreseeable future burning fossil fuels will be essential in the energy generation and transport sectors, particularly in aviation. Mitigating the environmental impacts of this is a key priority. In order to meet important, and increasingly stringent, regulatory limits on NOx emissions "lean burn" combustors are seen as a vital step. Lean burn combustors use more air in the combustion zone to reduce the flame temperature and the formation of pollutants. The downside to this is that the "thermoacoustic" stability of the flame is reduced. Fluctuations in heat release lead to pressure waves which affect the flow of fuel and air into the combustor which in turn can affect the heat release. This two-way coupling can lead to a feedback loop causing large, and damaging, pressure oscillations. For lean burn technology to be successfully developed this thermoacoustic instability must be controlled. Numerical simulation tools have a vital part to play in this. If the stability or otherwise of a design can be predicted in a computational simulation, without the need for testing a physical prototype then a great deal of resources can be saved. Accurate numerical simulation can also give a deeper understanding of the physical processes involved than experiments alone.

Most gas turbines and all aero engines use liquid fuel. The fuel is broken up into a spray which mixes with and evaporates into a swirling air flow. One of the major hurdles standing in the way of accurate simulation of thermoacoustic behaviour in burners of this type is how to model the effect of acoustic pressure waves on the formation and transport of the spray. Currently assumptions and empirical relations have to be used to define the time varying air and fuel inlet conditions and these are of questionable applicability. In particular they take no account of the delay or "phase shift" in the aerodynamic response of the airflow to a pressure wave, which is vital for capturing the true unsteady behaviour of a combustion system. This proposal aims to overcome this hurdle by developing properly validated computational methods for simulating sprays in complex swirling flows under the influence of acoustic waves.

Validation of this method requires access to appropriate experimental data. Such data has recently been produced at Loughborough University (LU). A typical lean burn fuel atomizer, in which fuel is injected between two co-annular swirling air streams, has been tested with acoustic forcing. Data is available for the time varying fuel droplet size, number and velocity at several locations in the flow. This data will be used in the following ways:

1. Methods of deriving accurate spray and air inlet conditions for a range of acoustic excitation frequencies will be developed. These will be tested by comparison with the experimental data from close to the injector and also compared to the current simplified method of deriving the spray inlet conditions. The errors associated with the assumptions in all methods will be studied systematically. The prediction of air flow response to a pressure wave in the separate airflow passages of the fuel injector will be improved by the use of a compressible CFD method developed at LU.

2. Simulations of the spray transport process in the presence of acoustic forcing will be carried out using the inlet conditions developed in the first part of the proposal. These simulations, validated against experimental data taken further downstream, will be a thorough test of the inlet conditions and of the modelling methods employed. They will also provide a deeper understanding of the flow physics involved. This will include the effects of turbulent mixing and acoustic forcing on droplets of different sizes and the relative importance of the different airflow streams in the injector. This understanding, coupled with improved boundary conditions will be of great value in designing low emission combustors of the future.

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Organisation Website: http://www.lboro.ac.uk