Effect of turbulence–chemistry interactions on chemical pathways for turbulent hydrogen–air premixed flames

Effect of turbulence–chemistry interactions on chemical pathways for turbulent hydrogen–air premixed flames

This paper considers the kinetic pathways of hydrogen oxidation in turbulent, premixed H2–air flames. It assesses the relative roles of different reaction steps in H2 oxidation relative to laminar flames, and the degree to which turbulence–chemistry interactions alters the well understood oxidation...

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Bibliographic Details
Published in:Combustion and flame Vol. 176; pp. 191 - 201
Main Authors: Dasgupta, Debolina, Sun, Wenting, Day, Marc, Lieuwen, Tim
Format: Journal Article
Language:English
Published: New York Elsevier Inc 01-02-2017
Elsevier BV
Subjects:
Aerodynamics
Air conditioners
Counterflow
Flames
Hydrogen
Impact analysis
Kinetics
Oxidation
Premixed flames
Reactors
Studies
Turbulence
Turbulent combustion
Turbulent–chemistry interactions
Turbulent combustion
Turbulent–chemistry interactions
Premixed flames
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Summary:This paper considers the kinetic pathways of hydrogen oxidation in turbulent, premixed H2–air flames. It assesses the relative roles of different reaction steps in H2 oxidation relative to laminar flames, and the degree to which turbulence–chemistry interactions alters the well understood oxidation pathway that exist in laminar flames. This is done by analyzing the turbulent, lean (ϕ= 0.4), H2–air flame DNS database from Aspden et al. [17]. The relative roles of dominant reaction steps in heat release and radical formation/consumption are analyzed at different Karlovitz numbers and compared with laminar stretched flame calculations from counterflow flames and perfectly stirred reactors. It is found that both the progress variable conditioned and spatially integrated contributions of the dominant reactions remain qualitatively similar between a highly turbulent and a laminar unstretched flame. Larger changes, up to a factor of about two, occur in the relative roles of reactions with secondary influences on heat release and radical production/consumption. These results suggest that the kinetic routes through which H2 is oxidized remain essentially constant between laminar, unstretched flames and high Karlovitz number flames.
ISSN:0010-2180
1556-2921
DOI:10.1016/j.combustflame.2016.09.029