Source terms for calculations of vaporizing and burning fuel sprays with non-unity Lewis numbers in gases with temperature-dependent thermal conductivities
Liquid-fueled burners are used in a number of propulsion devices ranging from internal
combustion engines to gas turbines. The structure of spray flames is quite complex and
involves a wide range of time and spatial scales in both premixed and non-premixed
modes (Williams 1965; Luo et al. 2011). A number of spray-combustion regimes can be
observed experimentally in canonical scenarios of practical relevance such as counterflow
diffusion flames (Li 1997), as sketched in figure 1, and for which different microscalemodelling strategies are needed. In this study, source terms for the conservation equations are calculated for heating, vaporizing and burning sprays in the single-droplet combustion regime. The present analysis provides extended formulation for source terms, which include non-unity Lewis numbers and variable thermal conductivities