An anti-diffusive Lagrange-Remap scheme for multi-material compressible flows with an arbitrary number of components
Marie Billaud Friess; Samuel Kokh
ESAIM: Proceedings (2012)
- Volume: 35, page 203-209
- ISSN: 1270-900X
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topFriess, Marie Billaud, and Kokh, Samuel. Denis Poisson, Fédération, and Trélat, E., eds. " An anti-diffusive Lagrange-Remap scheme for multi-material compressible flows with an arbitrary number of components ." ESAIM: Proceedings 35 (2012): 203-209. <http://eudml.org/doc/251291>.
@article{Friess2012,
abstract = {We propose a method dedicated to the simulation of interface flows involving an arbitrary number m of compressible components. Our task is two-fold: we first introduce a m-component flow model that generalizes the two-material five-equation model of [2,3]. Then, we present a discretization strategy by means of a Lagrange-Remap [8,10] approach following the lines of [5,7,12]. The projection step involves an anti-dissipative mechanism derived from [11,12]. This feature allows to prevent the numerical diffusion of the material interfaces. We present two-dimensional simulation results of three-material flow.},
author = {Friess, Marie Billaud, Kokh, Samuel},
editor = {Denis Poisson, Fédération, Trélat, E.},
journal = {ESAIM: Proceedings},
language = {eng},
month = {4},
pages = {203-209},
publisher = {EDP Sciences},
title = { An anti-diffusive Lagrange-Remap scheme for multi-material compressible flows with an arbitrary number of components },
url = {http://eudml.org/doc/251291},
volume = {35},
year = {2012},
}
TY - JOUR
AU - Friess, Marie Billaud
AU - Kokh, Samuel
AU - Denis Poisson, Fédération
AU - Trélat, E.
TI - An anti-diffusive Lagrange-Remap scheme for multi-material compressible flows with an arbitrary number of components
JO - ESAIM: Proceedings
DA - 2012/4//
PB - EDP Sciences
VL - 35
SP - 203
EP - 209
AB - We propose a method dedicated to the simulation of interface flows involving an arbitrary number m of compressible components. Our task is two-fold: we first introduce a m-component flow model that generalizes the two-material five-equation model of [2,3]. Then, we present a discretization strategy by means of a Lagrange-Remap [8,10] approach following the lines of [5,7,12]. The projection step involves an anti-dissipative mechanism derived from [11,12]. This feature allows to prevent the numerical diffusion of the material interfaces. We present two-dimensional simulation results of three-material flow.
LA - eng
UR - http://eudml.org/doc/251291
ER -
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