CFD study of the HIFiRE-5 flight experiment

Ryan Gosse; Rodger Kimmel; Heath B. Johnson

CFD study of the HIFiRE-5 flight experiment

Ryan Gosse, Rodger Kimmel, Heath B. Johnson

Aerospace Engineering and Mechanics

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

23 Scopus citations

Abstract

Boundary layer transition on the HIFiRE 5 flight vehicle was studied using Parabolized Stability Equation (PSE) analysis. Four trajectory points were selected to cover the range of the flight where transition is expected to occur on the vehicle. In order to calculate the PSE, a mean flow solution was generated using a finite-volume Navier-Stokes solver. The stability analysis was then conducted on the two symmetry planes of the vehicle. It was found that the leading edge planes are expected to follow second mode instability growth. The centerline cases experienced a much more complicated growth that was mainly driven by second mode, but also showed higher growth modes. In particular for the lowest altitude case, the higher modes showed to contribute to the maximum N factor growth. This was caused by the complex boundary layer profile that was induced by a pair of vortices along the centerline of the vehicle.

Original language	English (US)
Title of host publication	40th AIAA Fluid Dynamics Conference
State	Published - 2010
Event	40th AIAA Fluid Dynamics Conference - Chicago, IL, United States Duration: Jun 28 2010 → Jul 1 2010

Publication series

Name	40th AIAA Fluid Dynamics Conference

Other

Other	40th AIAA Fluid Dynamics Conference
Country/Territory	United States
City	Chicago, IL
Period	6/28/10 → 7/1/10

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title = "CFD study of the HIFiRE-5 flight experiment",

abstract = "Boundary layer transition on the HIFiRE 5 flight vehicle was studied using Parabolized Stability Equation (PSE) analysis. Four trajectory points were selected to cover the range of the flight where transition is expected to occur on the vehicle. In order to calculate the PSE, a mean flow solution was generated using a finite-volume Navier-Stokes solver. The stability analysis was then conducted on the two symmetry planes of the vehicle. It was found that the leading edge planes are expected to follow second mode instability growth. The centerline cases experienced a much more complicated growth that was mainly driven by second mode, but also showed higher growth modes. In particular for the lowest altitude case, the higher modes showed to contribute to the maximum N factor growth. This was caused by the complex boundary layer profile that was induced by a pair of vortices along the centerline of the vehicle.",

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year = "2010",

language = "English (US)",

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AU - Gosse, Ryan

AU - Kimmel, Rodger

AU - Johnson, Heath B.

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N2 - Boundary layer transition on the HIFiRE 5 flight vehicle was studied using Parabolized Stability Equation (PSE) analysis. Four trajectory points were selected to cover the range of the flight where transition is expected to occur on the vehicle. In order to calculate the PSE, a mean flow solution was generated using a finite-volume Navier-Stokes solver. The stability analysis was then conducted on the two symmetry planes of the vehicle. It was found that the leading edge planes are expected to follow second mode instability growth. The centerline cases experienced a much more complicated growth that was mainly driven by second mode, but also showed higher growth modes. In particular for the lowest altitude case, the higher modes showed to contribute to the maximum N factor growth. This was caused by the complex boundary layer profile that was induced by a pair of vortices along the centerline of the vehicle.

AB - Boundary layer transition on the HIFiRE 5 flight vehicle was studied using Parabolized Stability Equation (PSE) analysis. Four trajectory points were selected to cover the range of the flight where transition is expected to occur on the vehicle. In order to calculate the PSE, a mean flow solution was generated using a finite-volume Navier-Stokes solver. The stability analysis was then conducted on the two symmetry planes of the vehicle. It was found that the leading edge planes are expected to follow second mode instability growth. The centerline cases experienced a much more complicated growth that was mainly driven by second mode, but also showed higher growth modes. In particular for the lowest altitude case, the higher modes showed to contribute to the maximum N factor growth. This was caused by the complex boundary layer profile that was induced by a pair of vortices along the centerline of the vehicle.

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M3 - Conference contribution

AN - SCOPUS:78649487496

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T3 - 40th AIAA Fluid Dynamics Conference

BT - 40th AIAA Fluid Dynamics Conference

T2 - 40th AIAA Fluid Dynamics Conference

Y2 - 28 June 2010 through 1 July 2010

ER -

CFD study of the HIFiRE-5 flight experiment

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