Large eddy simulations (LES) of turbulent non-premixed swirling flames based on the
Sydney swirl burner experiments under different flame characteristics are used to
uncover the underlying instability modes responsible for the centre jet precession and
large scale recirculation zone. The selected flame series known as SMH flames have a
fuel mixture of methane-hydrogen (50:50 by volume). The LES solves the governing
equations on a structured Cartesian grid using a finite volume method, with
turbulence and combustion modelling based on the localised dynamic Smagorinsky
model and the steady laminar flamelet model respectively. The LES results are
validated against experimental measurements and overall the LES yields good
qualitative and quantitative agreement with the experimental observations. Analysis
showed that the LES predicted two types of instability modes near fuel jet region and
bluff body stabilized recirculation zone region. The Mode I instability defined as
cyclic precession of a centre jet is identified using the time periodicity of the centre jet
in flames SMH1 and SMH2 and the Mode II instability defined as cyclic expansion
and collapse of the recirculation zone is identified using the time periodicity of the
recirculation zone in flame SMH3. Finally frequency spectra obtained from the LES
are found to be in good agreement with the experimentally observed precession
frequencies.
History
School
Mechanical, Electrical and Manufacturing Engineering
Citation
RANGA-DINESH, K.K.J., ....et al., 2009. Identification and analysis of instability in non-premixed swirling flames using LES. Combustion Theory and Modelling, 13 (6), pp.947–971.