Computational Simulation of Shock-Bubble Interaction, using a Front-Tracking/Ghost Fluid Method

Computational Simulation of Shock-Bubble Interaction, using a Front-Tracking/Ghost Fluid Method

Show other versions (1)

A front tracking/ghost fluid method was used to simulate fluid interfaces in a shock–bubble interaction problem. The method captures fluid interfaces, using explicit front-tracking and defines interface conditions, using the ghost-fluid method. In order to demonstrate the accuracy and the capability...

Full description

Bibliographic Details
Main Authors: A. Razmi, M. Taeibi-Rahni, H. R. Massah, H. Terashima, H. Moezzi
Format: Article
Language:English
Published: Isfahan University of Technology 2019-01-01
Series:Journal of Applied Fluid Mechanics
Subjects:
Computational simulation; Front tracking/ghost fluid method; Shock-bubble interaction; Supersonic flow.
Online Access:http://jafmonline.net/JournalArchive/download?file_ID=48599&issue_ID=254
id doaj-780cb6a4e99c45cbb42fba6456f872b8
record_format Article
spelling doaj-780cb6a4e99c45cbb42fba6456f872b82020-11-25T00:25:47ZengIsfahan University of Technology Journal of Applied Fluid Mechanics1735-35722019-01-01122631645.Computational Simulation of Shock-Bubble Interaction, using a Front-Tracking/Ghost Fluid MethodA. Razmi0M. Taeibi-Rahni1H. R. Massah2H. Terashima3H. Moezzi4Department of Aerospace Engineering, Sharif University, Tehran, P.O.B. 113658539, IranDepartment of Aerospace Engineering, Sharif University of Technology, Tehran, IranAcoustical Engineering Society of Iran, Tehran, IranFaculty of Engineering, Hokkaido University, JapanDepartment of Aerospace Engineering, Sharif University, Tehran, P.O.B. 113658539, IranA front tracking/ghost fluid method was used to simulate fluid interfaces in a shock–bubble interaction problem. The method captures fluid interfaces, using explicit front-tracking and defines interface conditions, using the ghost-fluid method. In order to demonstrate the accuracy and the capability tracking of the approach used, an air-helium and anair-R22 shock-bubble interaction cases were simulated. The computational results were compared with reliable experimental and computational studies, showing close agreements.http://jafmonline.net/JournalArchive/download?file_ID=48599&issue_ID=254Computational simulation; Front tracking/ghost fluid method; Shock-bubble interaction; Supersonic flow.
collection DOAJ
language English
format Article
sources DOAJ
author A. Razmi
M. Taeibi-Rahni
H. R. Massah
H. Terashima
H. Moezzi
spellingShingle A. Razmi
M. Taeibi-Rahni
H. R. Massah
H. Terashima
H. Moezzi
Computational Simulation of Shock-Bubble Interaction, using a Front-Tracking/Ghost Fluid Method
Journal of Applied Fluid Mechanics
Computational simulation; Front tracking/ghost fluid method; Shock-bubble interaction; Supersonic flow.
author_facet A. Razmi
M. Taeibi-Rahni
H. R. Massah
H. Terashima
H. Moezzi
author_sort A. Razmi
title Computational Simulation of Shock-Bubble Interaction, using a Front-Tracking/Ghost Fluid Method
title_short Computational Simulation of Shock-Bubble Interaction, using a Front-Tracking/Ghost Fluid Method
title_full Computational Simulation of Shock-Bubble Interaction, using a Front-Tracking/Ghost Fluid Method
title_fullStr Computational Simulation of Shock-Bubble Interaction, using a Front-Tracking/Ghost Fluid Method
title_full_unstemmed Computational Simulation of Shock-Bubble Interaction, using a Front-Tracking/Ghost Fluid Method
title_sort computational simulation of shock-bubble interaction, using a front-tracking/ghost fluid method
publisher Isfahan University of Technology
series Journal of Applied Fluid Mechanics
issn 1735-3572
publishDate 2019-01-01
description A front tracking/ghost fluid method was used to simulate fluid interfaces in a shock–bubble interaction problem. The method captures fluid interfaces, using explicit front-tracking and defines interface conditions, using the ghost-fluid method. In order to demonstrate the accuracy and the capability tracking of the approach used, an air-helium and anair-R22 shock-bubble interaction cases were simulated. The computational results were compared with reliable experimental and computational studies, showing close agreements.
topic Computational simulation; Front tracking/ghost fluid method; Shock-bubble interaction; Supersonic flow.
url http://jafmonline.net/JournalArchive/download?file_ID=48599&issue_ID=254
work_keys_str_mv AT arazmi computationalsimulationofshockbubbleinteractionusingafronttrackingghostfluidmethod
AT mtaeibirahni computationalsimulationofshockbubbleinteractionusingafronttrackingghostfluidmethod
AT hrmassah computationalsimulationofshockbubbleinteractionusingafronttrackingghostfluidmethod
AT hterashima computationalsimulationofshockbubbleinteractionusingafronttrackingghostfluidmethod
AT hmoezzi computationalsimulationofshockbubbleinteractionusingafronttrackingghostfluidmethod
_version_ 1725347035886911488

Similar Items