Assessment of CFD Capability for Hypersonic Shock Wave Laminar Boundary Layer Interactions

Assessment of CFD Capability for Hypersonic Shock Wave Laminar Boundary Layer Interactions

The goal of this study is to assess CFD capability for the prediction of shock wave laminar boundary layer interactions at hypersonic velocities. More specifically, the flow field over a double-cone configuration is simulated using both perfect gas and non-equilibrium Navier–Stokes models. Computati...

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Bibliographic Details
Main Authors: Mehrnaz Rouhi Youssefi, Doyle Knight
Format: Article
Language:English
Published: MDPI AG 2017-04-01
Series:Aerospace
Subjects:
CFD
hypersonic
shock wave
laminar
real gas
non-equilibrium
Online Access:http://www.mdpi.com/2226-4310/4/2/25
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spelling doaj-f5cb5df2ab874059b78cb084bb1c2d932020-11-24T23:54:50ZengMDPI AGAerospace2226-43102017-04-01422510.3390/aerospace4020025aerospace4020025Assessment of CFD Capability for Hypersonic Shock Wave Laminar Boundary Layer InteractionsMehrnaz Rouhi Youssefi0Doyle Knight1Department of Mechanical and Aerospace Engineering, Rutgers—The State University of New Jersey, New Brunswick, NJ 08903, USADepartment of Mechanical and Aerospace Engineering, Rutgers—The State University of New Jersey, New Brunswick, NJ 08903, USAThe goal of this study is to assess CFD capability for the prediction of shock wave laminar boundary layer interactions at hypersonic velocities. More specifically, the flow field over a double-cone configuration is simulated using both perfect gas and non-equilibrium Navier–Stokes models. Computations are compared with recent experimental data obtained from measurements conducted in the LENS XX (Large Energy National Shock Expansion Tunnel Version 2) at the Calspan University of Buffalo Research Center (CUBRC). Four separate cases of freestream conditions are simulated to examine the models for a range of stagnation enthalpies from 5.44 MJ/kg to 21.77 MJ/kg and Mach numbers from 10.9 to 12.82.http://www.mdpi.com/2226-4310/4/2/25CFDhypersonicshock wavelaminarreal gasnon-equilibrium
collection DOAJ
language English
format Article
sources DOAJ
author Mehrnaz Rouhi Youssefi
Doyle Knight
spellingShingle Mehrnaz Rouhi Youssefi
Doyle Knight
Assessment of CFD Capability for Hypersonic Shock Wave Laminar Boundary Layer Interactions
Aerospace
CFD
hypersonic
shock wave
laminar
real gas
non-equilibrium
author_facet Mehrnaz Rouhi Youssefi
Doyle Knight
author_sort Mehrnaz Rouhi Youssefi
title Assessment of CFD Capability for Hypersonic Shock Wave Laminar Boundary Layer Interactions
title_short Assessment of CFD Capability for Hypersonic Shock Wave Laminar Boundary Layer Interactions
title_full Assessment of CFD Capability for Hypersonic Shock Wave Laminar Boundary Layer Interactions
title_fullStr Assessment of CFD Capability for Hypersonic Shock Wave Laminar Boundary Layer Interactions
title_full_unstemmed Assessment of CFD Capability for Hypersonic Shock Wave Laminar Boundary Layer Interactions
title_sort assessment of cfd capability for hypersonic shock wave laminar boundary layer interactions
publisher MDPI AG
series Aerospace
issn 2226-4310
publishDate 2017-04-01
description The goal of this study is to assess CFD capability for the prediction of shock wave laminar boundary layer interactions at hypersonic velocities. More specifically, the flow field over a double-cone configuration is simulated using both perfect gas and non-equilibrium Navier–Stokes models. Computations are compared with recent experimental data obtained from measurements conducted in the LENS XX (Large Energy National Shock Expansion Tunnel Version 2) at the Calspan University of Buffalo Research Center (CUBRC). Four separate cases of freestream conditions are simulated to examine the models for a range of stagnation enthalpies from 5.44 MJ/kg to 21.77 MJ/kg and Mach numbers from 10.9 to 12.82.
topic CFD
hypersonic
shock wave
laminar
real gas
non-equilibrium
url http://www.mdpi.com/2226-4310/4/2/25
work_keys_str_mv AT mehrnazrouhiyoussefi assessmentofcfdcapabilityforhypersonicshockwavelaminarboundarylayerinteractions
AT doyleknight assessmentofcfdcapabilityforhypersonicshockwavelaminarboundarylayerinteractions
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