Modelling of lifted turbulent diffusion flames in a channel mixing layer by the flame hole dynamics

Authors
Kim, JKim, JS
Issue Date
2006-02
Publisher
TAYLOR & FRANCIS LTD
Citation
COMBUSTION THEORY AND MODELLING, v.10, no.1, pp.21 - 37
Abstract
The partial quenching structure of turbulent diffusion flames in a turbulent mixing layer is investigated by the method of flame hole dynamics as an effort to develop a prediction model for the turbulent flame lift off. The essence of the flame hole dynamics is derivation of the random walk mapping. from the flame-edge theory, which governs expansion or contraction of the quenching holes initially created by the local quenching events. The numerical simulation for the flame hole dynamics is carried out in two stages. First, a direct numerical simulation is performed for a constant-density fuel-air channel mixing layer to obtain the background turbulent flow and mixing fields, from which a time series of two-dimensional scalar-dissipation-rate array is extracted. Subsequently, a Lagrangian simulation of the flame hole random walk mapping, projected to the scalar dissipation rate array, yields a temporally evolving turbulent extinction process and its statistics on partial quenching characteristics. In particular, the probability of encountering the reacting state, while conditioned with the instantaneous scalar dissipation rate, is examined to reveal that the conditional probability has a sharp transition across the crossover scalar dissipation rate. at which the flame edge changes its direction of propagation. This statistical characteristic implies that the flame edge propagation instead of the local quenching event is the main mechanism controlling the partial quenching events in turbulent flames. In addition, the conditional probability can be approximated by a heavyside function across the crossover scalar dissipation rate.
Keywords
BOUNDARY-LAYER; PROPAGATION; SIMULATION; BOUNDARY-LAYER; PROPAGATION; SIMULATION; flame edge; flame hole dynamics; partially quenched turbulent flame; random walk
ISSN
1364-7830
URI
https://pubs.kist.re.kr/handle/201004/135784
DOI
10.1080/13647830500304425
Appears in Collections:
KIST Article > 2006
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