Journal
COMBUSTION AND FLAME
Volume 161, Issue 11, Pages 2801-2814Publisher
ELSEVIER SCIENCE INC
DOI: 10.1016/j.combustflame.2014.04.018
Keywords
MILD combustion; Flameless combustion; Direct numerical simulation (DNS); Minkowski functionals; Autoignition; Flame propagation
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Funding
- Nippon Keidanren
- Cambridge Overseas Trust
- EPSRC
- Office of Science and Technology through EPSRCs High End Computing Programme
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Direct numerical simulation (DNS) results of turbulent MILD premixed and conventional (undiluted) premixed combustion have been investigated to shed light on the physical aspects of reaction zones and their morphology in MILD combustion. Results of a premixed case are used for comparative analyses. The analyses show that the regions with strong chemical activity in MILD combustion are distributed over a substantial portion of the computational domain unlike in the premixed case where these regions are confined to a small portion of the domain. Also, interactions of reaction zones are observed in MILD combustion with their spatial extent increasing with dilution level. These interactions give an appearance of distributed combustion for MILD conditions. The morphology of these reaction zones is investigated using the Minkowski functionals and shapefinders commonly employed in cosmology. Predominant sheet-like structures are observed for the premixed combustion case whereas a pancake-like structure is observed as the most probable shape for the MILD cases. Spatial and statistical analyses of various fluxes involved in a progress variable transport equation are conducted to study autoignitive or propagative characteristics of MILD reaction zones. The results suggest that there are local regions with autoignition, propagating-flames, and their coexistence for the conditions considered in this study. Typically, reaction dominated or ignition front and propagating-flame dominated regions are entangled for high dilution cases. Scalar gradient plays a strong role on whether reaction or propagating-flame dominated activities are favoured locally. (c) 2014 The Combustion Institute. Published by Elsevier Inc. All rights reserved.
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