A Spatially Developing One-Dimensional Turbulence (ODT) Study of Soot and Enthalpy Evolution in Meter-Scale Buoyant Turbulent Flames

The interaction between soot and enthalpy evolution in a buoyant turbulent flame, exhibiting key attributes of a fire, is studied using a novel approach. This approach is based on a spatially evolving form of the one-dimensional turbulence (ODT) model that resolves the full range of scales, in a single spatial dimension, from the scale of the plume evolution to that of the soot layers. The model is compared with limited experimental data available. The evolved flow field of a meter-scale flame is then analyzed both in terms of conventional spatial averages and conditional averages. The conditional moments of the terms in the soot and enthalpy evolution equations are analyzed to elucidate the balance between the large-scale evolution (advective terms), the source terms, and the turbulent mixing (dissipative terms). The results show the significant influence of the mixture evolution on the transport of soot relative to the flame (in mixture-fraction space).