Title : ( Study of Convergence Time for Rarefied Gas Simulations Using an Unstructured DSMC Solver )
Authors: ,
Full TextAbstract
This article studies the required convergence time for direct-simulation Monte Carlo (DSMC) simulations of rarefied gas flows. An arbitrary-geometry DSMC solver (RGS2D) with an efficient particle-tracking algorithm is introduced and employed for macro-/micro-scale flow applications. Convergence time study is performed by tracing different heat and flow parameters such as intermolecular collision rate, number of particles, drag coefficient, inlet/outlet mass flow rate, and distributions over the wall, i.e., pressure coefficient, skin friction coefficient, heat transfer coefficient, and wall collision rate. The results indicate that the required simulation time depends on the capturing parameter.
Keywords
, DSMC, Rarefied Gas, Convergence Time, Unstructured Mesh
@article{paperid:1047649,
author = {, },
title = {Study of Convergence Time for Rarefied Gas Simulations Using an Unstructured DSMC Solver},
journal = {Numerical Heat Transfer Part B: Fundamentals},
year = {2015},
volume = {68},
number = {1},
month = {April},
issn = {1040-7790},
pages = {75--91},
numpages = {16},
keywords = {DSMC; Rarefied Gas; Convergence Time; Unstructured Mesh},
}
%0 Journal Article
%T Study of Convergence Time for Rarefied Gas Simulations Using an Unstructured DSMC Solver
%A ,
%J Numerical Heat Transfer Part B: Fundamentals
%@ 1040-7790
%D 2015
