Benchmark numerical simulations of rarefied non-reacting gas flows using an open-source DSMC code

Rodrigo C. Palharini; Craig White; Thomas J. Scanlon; Richard E. Brown; Matthew K. Borg; Jason M. Reese

doi:10.1016/j.compfluid.2015.07.021

Benchmark numerical simulations of rarefied non-reacting gas flows using an open-source DSMC code

Rodrigo C. Palharini
, Craig White
, Thomas J. Scanlon
, Richard E. Brown
, Matthew K. Borg
, Jason M. Reese

Research output: Contribution to journal › Article › peer-review

60 Scopus citations

Abstract

Validation and verification represent an important element in the development of a computational code. The aim is establish both confidence in the algorithm and its suitability for the intended purpose. In this paper, a direct simulation Monte Carlo solver, called dsmcFoam, is carefully investigated for its ability to solve low and high speed non-reacting gas flows in simple and complex geometries. The test cases are: flow over sharp and truncated flat plates, the Mars Pathfinder probe, a micro-channel with heated internal steps, and a simple micro-channel. For all the cases investigated, dsmcFoam demonstrates very good agreement with experimental and numerical data available in the literature.

Original language	English
Pages (from-to)	140-157
Number of pages	18
Journal	Computers and Fluids
Volume	120
DOIs	https://doi.org/10.1016/j.compfluid.2015.07.021
State	Published - 5 Oct 2015
Externally published	Yes

Keywords

Aerodynamics
Benchmark
DSMC
Low/high speed flows
Open-source
Rarefied gas dynamics

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10.1016/j.compfluid.2015.07.021

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title = "Benchmark numerical simulations of rarefied non-reacting gas flows using an open-source DSMC code",

abstract = "Validation and verification represent an important element in the development of a computational code. The aim is establish both confidence in the algorithm and its suitability for the intended purpose. In this paper, a direct simulation Monte Carlo solver, called dsmcFoam, is carefully investigated for its ability to solve low and high speed non-reacting gas flows in simple and complex geometries. The test cases are: flow over sharp and truncated flat plates, the Mars Pathfinder probe, a micro-channel with heated internal steps, and a simple micro-channel. For all the cases investigated, dsmcFoam demonstrates very good agreement with experimental and numerical data available in the literature.",

keywords = "Aerodynamics, Benchmark, DSMC, Low/high speed flows, Open-source, Rarefied gas dynamics",

author = "Palharini, \{Rodrigo C.\} and Craig White and Scanlon, \{Thomas J.\} and Brown, \{Richard E.\} and Borg, \{Matthew K.\} and Reese, \{Jason M.\}",

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year = "2015",

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doi = "10.1016/j.compfluid.2015.07.021",

language = "English",

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journal = "Computers and Fluids",

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T1 - Benchmark numerical simulations of rarefied non-reacting gas flows using an open-source DSMC code

AU - Palharini, Rodrigo C.

AU - White, Craig

AU - Scanlon, Thomas J.

AU - Brown, Richard E.

AU - Borg, Matthew K.

AU - Reese, Jason M.

PY - 2015/10/5

Y1 - 2015/10/5

N2 - Validation and verification represent an important element in the development of a computational code. The aim is establish both confidence in the algorithm and its suitability for the intended purpose. In this paper, a direct simulation Monte Carlo solver, called dsmcFoam, is carefully investigated for its ability to solve low and high speed non-reacting gas flows in simple and complex geometries. The test cases are: flow over sharp and truncated flat plates, the Mars Pathfinder probe, a micro-channel with heated internal steps, and a simple micro-channel. For all the cases investigated, dsmcFoam demonstrates very good agreement with experimental and numerical data available in the literature.

AB - Validation and verification represent an important element in the development of a computational code. The aim is establish both confidence in the algorithm and its suitability for the intended purpose. In this paper, a direct simulation Monte Carlo solver, called dsmcFoam, is carefully investigated for its ability to solve low and high speed non-reacting gas flows in simple and complex geometries. The test cases are: flow over sharp and truncated flat plates, the Mars Pathfinder probe, a micro-channel with heated internal steps, and a simple micro-channel. For all the cases investigated, dsmcFoam demonstrates very good agreement with experimental and numerical data available in the literature.

KW - Aerodynamics

KW - Benchmark

KW - DSMC

KW - Low/high speed flows

KW - Open-source

KW - Rarefied gas dynamics

UR - https://www.scopus.com/pages/publications/84939792479

U2 - 10.1016/j.compfluid.2015.07.021

DO - 10.1016/j.compfluid.2015.07.021

M3 - Article

AN - SCOPUS:84939792479

SN - 0045-7930

VL - 120

SP - 140

EP - 157

JO - Computers and Fluids

JF - Computers and Fluids

ER -

Benchmark numerical simulations of rarefied non-reacting gas flows using an open-source DSMC code

Abstract

Keywords

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