Application of the Direct Simulation Monte Carlo Method to Nanoscale Heat Transfer between a Soot Particle and the Surrounding Gas

摘要

Laser-Induced Incandescence(LII)technique has been widely used to measure soot volume fraction and primary particle size in flames and engine exhaust. Currently there is lack of quantitative understanding of the shielding effect of aggregated soot particles on its conduction heat loss rate to the surrounding gas. The conventional approach for this problem would be the application of the Monte Carlo(MC)method.This method is based on simulation of the trajectories of individual molecules and calculation of the heat transfer at each of the molecule/molecule collisions and the molecule/particle collisions.As the first step toward calculating the heat transfer between a soot aggregate and the surrounding gas,the Direct Simulation Monte Carlo(DSMC)method was used in this study to calculate the heat transfer rate between a single spherical aerosol particle and its cooler surrounding gas under different conditions of temperature,pressure,and the accommodation coefficient.A well-defined and simple hard sphere model was adopted to describe molecule/molecule elastic collisions.A combination of the specular reflection and completely diffuse reflection model was used to consider molecule/particle collisions.The results obtained by DSMC are in good agreement with the known analytical solution of heat transfer rate for an isolated,motionless sphere in the free-molecular regime.Further the DSMC method was applied to calculate the heat transfer in the transition regime.Our present DSMC results agree very well with published DSMC data.