Assessment of the Amplification Factor Transport Transition Model for High-Mach Number Flows

Koen J. Groot; Jay M. Patel; Caleb A. Saiyasak; James G. Coder; Douglas L. Stefanski; Helen L. Reed

doi:10.2514/6.2021-2830

Assessment of the Amplification Factor Transport Transition Model for High-Mach Number Flows

Koen J. Groot
, Jay M. Patel
, Caleb A. Saiyasak
, James G. Coder
, Douglas L. Stefanski
, Helen L. Reed

Multiphysics Modeling and Flows

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

6 Scopus citations

Abstract

In its present state, the Amplification Factor Transport (AFT) model provides an efficient alternative for high-fidelity stability methods for complex geometries subject to low-speed conditions considered in the industrial-production CFD environment. Its performance has not yet been documented for the typical transition scenarios in hypersonic conditions. The goal of the present study is to apply the AFT model to a yawed- and flared-cone configuration, for which the laminar flows respectively support the crossflow and second-mode instability mechanisms, and to compare the amplification results against high-fidelity results computed with Linear Parabolized Stability Equations (LPSE). High-resolution viscous-flow solutions are provided with OVERFLOW and COFFE. For the yawed-cone case, the AFT model yields the largest amplification in a region of the flow where the expected crossflow instability is not amplified (in the leeward symmetry plane) according to LPSE. For the flared-cone case with a wall-temperature slightly lower than the adiabatic value, the AFT model yields extremely large amplification factors (in excess of 100), exceeding the computed LPSE amplification of secondmode instability results by a factor 14. Upon considering a cold-wall condition, the model shows much smaller amplification factors, which is the opposite with respect to the expected behavior of the second mode. The AFT model does not adequately capture the crossflow and second-mode instability mechanisms in its present state.

Original language	English
Title of host publication	AIAA Aviation and Aeronautics Forum and Exposition, AIAA AVIATION Forum 2021
Publisher	American Institute of Aeronautics and Astronautics Inc, AIAA
ISBN (Print)	9781624106101
DOIs	https://doi.org/10.2514/6.2021-2830
State	Published - 2021
Event	AIAA Aviation and Aeronautics Forum and Exposition, AIAA AVIATION Forum 2021 - Virtual, Online Duration: Aug 2 2021 → Aug 6 2021

Publication series

Name	AIAA Aviation and Aeronautics Forum and Exposition, AIAA AVIATION Forum 2021

Conference

Conference	AIAA Aviation and Aeronautics Forum and Exposition, AIAA AVIATION Forum 2021
City	Virtual, Online
Period	08/2/21 → 08/6/21

Funding

This work is supported by the DoD HPCMP Hypersonic Vehicle Simulation Institute under agreement FA7000-20-2-0003 (TPOC: Dr. Russell Cummings, USAFA). We thank Dr. Travis Kocian at the Computational Stability & Transition Lab at Texas A&M for the useful discussions.

Access to Document

10.2514/6.2021-2830

Cite this

Groot, K. J., Patel, J. M., Saiyasak, C. A., Coder, J. G., Stefanski, D. L., & Reed, H. L. (2021). Assessment of the Amplification Factor Transport Transition Model for High-Mach Number Flows. In AIAA Aviation and Aeronautics Forum and Exposition, AIAA AVIATION Forum 2021 Article AIAA 2021-2830 (AIAA Aviation and Aeronautics Forum and Exposition, AIAA AVIATION Forum 2021). American Institute of Aeronautics and Astronautics Inc, AIAA. https://doi.org/10.2514/6.2021-2830

Groot, Koen J. ; Patel, Jay M. ; Saiyasak, Caleb A. et al. / Assessment of the Amplification Factor Transport Transition Model for High-Mach Number Flows. AIAA Aviation and Aeronautics Forum and Exposition, AIAA AVIATION Forum 2021. American Institute of Aeronautics and Astronautics Inc, AIAA, 2021. (AIAA Aviation and Aeronautics Forum and Exposition, AIAA AVIATION Forum 2021).

@inproceedings{83fdd2bf6d5549faabb18bbf3bf2a965,

title = "Assessment of the Amplification Factor Transport Transition Model for High-Mach Number Flows",

abstract = "In its present state, the Amplification Factor Transport (AFT) model provides an efficient alternative for high-fidelity stability methods for complex geometries subject to low-speed conditions considered in the industrial-production CFD environment. Its performance has not yet been documented for the typical transition scenarios in hypersonic conditions. The goal of the present study is to apply the AFT model to a yawed- and flared-cone configuration, for which the laminar flows respectively support the crossflow and second-mode instability mechanisms, and to compare the amplification results against high-fidelity results computed with Linear Parabolized Stability Equations (LPSE). High-resolution viscous-flow solutions are provided with OVERFLOW and COFFE. For the yawed-cone case, the AFT model yields the largest amplification in a region of the flow where the expected crossflow instability is not amplified (in the leeward symmetry plane) according to LPSE. For the flared-cone case with a wall-temperature slightly lower than the adiabatic value, the AFT model yields extremely large amplification factors (in excess of 100), exceeding the computed LPSE amplification of secondmode instability results by a factor 14. Upon considering a cold-wall condition, the model shows much smaller amplification factors, which is the opposite with respect to the expected behavior of the second mode. The AFT model does not adequately capture the crossflow and second-mode instability mechanisms in its present state.",

author = "Groot, \{Koen J.\} and Patel, \{Jay M.\} and Saiyasak, \{Caleb A.\} and Coder, \{James G.\} and Stefanski, \{Douglas L.\} and Reed, \{Helen L.\}",

note = "Publisher Copyright: {\textcopyright} 2021, American Institute of Aeronautics and Astronautics Inc, AIAA. All rights reserved.; AIAA Aviation and Aeronautics Forum and Exposition, AIAA AVIATION Forum 2021 ; Conference date: 02-08-2021 Through 06-08-2021",

year = "2021",

doi = "10.2514/6.2021-2830",

language = "English",

isbn = "9781624106101",

series = "AIAA Aviation and Aeronautics Forum and Exposition, AIAA AVIATION Forum 2021",

publisher = "American Institute of Aeronautics and Astronautics Inc, AIAA",

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}

Groot, KJ, Patel, JM, Saiyasak, CA, Coder, JG, Stefanski, DL & Reed, HL 2021, Assessment of the Amplification Factor Transport Transition Model for High-Mach Number Flows. in AIAA Aviation and Aeronautics Forum and Exposition, AIAA AVIATION Forum 2021., AIAA 2021-2830, AIAA Aviation and Aeronautics Forum and Exposition, AIAA AVIATION Forum 2021, American Institute of Aeronautics and Astronautics Inc, AIAA, AIAA Aviation and Aeronautics Forum and Exposition, AIAA AVIATION Forum 2021, Virtual, Online, 08/2/21. https://doi.org/10.2514/6.2021-2830

Assessment of the Amplification Factor Transport Transition Model for High-Mach Number Flows. / Groot, Koen J.; Patel, Jay M.; Saiyasak, Caleb A. et al.
AIAA Aviation and Aeronautics Forum and Exposition, AIAA AVIATION Forum 2021. American Institute of Aeronautics and Astronautics Inc, AIAA, 2021. AIAA 2021-2830 (AIAA Aviation and Aeronautics Forum and Exposition, AIAA AVIATION Forum 2021).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

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AU - Groot, Koen J.

AU - Patel, Jay M.

AU - Saiyasak, Caleb A.

AU - Coder, James G.

AU - Stefanski, Douglas L.

AU - Reed, Helen L.

PY - 2021

Y1 - 2021

N2 - In its present state, the Amplification Factor Transport (AFT) model provides an efficient alternative for high-fidelity stability methods for complex geometries subject to low-speed conditions considered in the industrial-production CFD environment. Its performance has not yet been documented for the typical transition scenarios in hypersonic conditions. The goal of the present study is to apply the AFT model to a yawed- and flared-cone configuration, for which the laminar flows respectively support the crossflow and second-mode instability mechanisms, and to compare the amplification results against high-fidelity results computed with Linear Parabolized Stability Equations (LPSE). High-resolution viscous-flow solutions are provided with OVERFLOW and COFFE. For the yawed-cone case, the AFT model yields the largest amplification in a region of the flow where the expected crossflow instability is not amplified (in the leeward symmetry plane) according to LPSE. For the flared-cone case with a wall-temperature slightly lower than the adiabatic value, the AFT model yields extremely large amplification factors (in excess of 100), exceeding the computed LPSE amplification of secondmode instability results by a factor 14. Upon considering a cold-wall condition, the model shows much smaller amplification factors, which is the opposite with respect to the expected behavior of the second mode. The AFT model does not adequately capture the crossflow and second-mode instability mechanisms in its present state.

AB - In its present state, the Amplification Factor Transport (AFT) model provides an efficient alternative for high-fidelity stability methods for complex geometries subject to low-speed conditions considered in the industrial-production CFD environment. Its performance has not yet been documented for the typical transition scenarios in hypersonic conditions. The goal of the present study is to apply the AFT model to a yawed- and flared-cone configuration, for which the laminar flows respectively support the crossflow and second-mode instability mechanisms, and to compare the amplification results against high-fidelity results computed with Linear Parabolized Stability Equations (LPSE). High-resolution viscous-flow solutions are provided with OVERFLOW and COFFE. For the yawed-cone case, the AFT model yields the largest amplification in a region of the flow where the expected crossflow instability is not amplified (in the leeward symmetry plane) according to LPSE. For the flared-cone case with a wall-temperature slightly lower than the adiabatic value, the AFT model yields extremely large amplification factors (in excess of 100), exceeding the computed LPSE amplification of secondmode instability results by a factor 14. Upon considering a cold-wall condition, the model shows much smaller amplification factors, which is the opposite with respect to the expected behavior of the second mode. The AFT model does not adequately capture the crossflow and second-mode instability mechanisms in its present state.

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U2 - 10.2514/6.2021-2830

DO - 10.2514/6.2021-2830

M3 - Conference contribution

AN - SCOPUS:85126827860

SN - 9781624106101

T3 - AIAA Aviation and Aeronautics Forum and Exposition, AIAA AVIATION Forum 2021

BT - AIAA Aviation and Aeronautics Forum and Exposition, AIAA AVIATION Forum 2021

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Groot KJ, Patel JM, Saiyasak CA, Coder JG, Stefanski DL, Reed HL. Assessment of the Amplification Factor Transport Transition Model for High-Mach Number Flows. In AIAA Aviation and Aeronautics Forum and Exposition, AIAA AVIATION Forum 2021. American Institute of Aeronautics and Astronautics Inc, AIAA. 2021. AIAA 2021-2830. (AIAA Aviation and Aeronautics Forum and Exposition, AIAA AVIATION Forum 2021). doi: 10.2514/6.2021-2830

Assessment of the Amplification Factor Transport Transition Model for High-Mach Number Flows

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