Evaporation of volatile droplets subjected to flame-like conditions

This work assesses Lagrangian droplet evaporation models frequently used in spray combustion simula-tions, with the purpose of identifying the influence of modeling decisions on the single droplet behavior. Besides more simplistic models, the evaluated strategies include a simple method to incorporate Stefan flow effects in the heat transfer (Bird's correction), a method to consider the interaction of Stefan flow with the heat and mass transfer films (Abramzon-Sirignano model), and a method to incorporate non-equilibrium thermodynamics (Langmuir-Knudsen model). The importance of each phenomena is quanti-fied analytically and numerically under various conditions. Evaporation models ignoring Stefan flow are found to be invalid under the studied conditions. The Langmuir-Knudsen model is also deemed inade-quate for high temperature evaporation, while Bird's correction and the Abramzon-Sirignano model are identified as the most relevant for numerical studies of spray combustion systems. Latter is the most elaborate model studied here, as it considers Reynolds number effects beyond the empirical correlation of Ranz and Marshall derived for low-transfer rates. Thus, the Abramzon-Sirignano model is identified as the state of the art alternative in the scope of this study. (c) 2022 Elsevier Ltd. All rights reserved.

Automated summary

This study assesses Lagrangian droplet evaporation models commonly used in spray combustion simulations, aiming to identify the influence of modeling decisions on individual droplet behavior. The most suitable models for numerical studies of spray combustion systems are determined.