Hybrid RANS-LES closure for separated flows in the transitional regime

The aerodynamics of modern rotorcraft is highly complex and has proven to be an arduous challenge for computational fluid dynamics (CFD). Flow features such as massively separated boundary layers or transition to turbulence are common in engineering applications and need to be accurately captured in...

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Bibliographic Details
Main Author: Hodara, Joachim
Other Authors: Smith, Marilyn J.
Format: Others
Language:en_US
Published: Georgia Institute of Technology 2016
Subjects:
CFD
Online Access:http://hdl.handle.net/1853/54995
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spelling ndltd-GATECH-oai-smartech.gatech.edu-1853-549952016-06-15T03:39:06ZHybrid RANS-LES closure for separated flows in the transitional regimeHodara, JoachimCFDTurbulence modelingTransition to turbulenceNumerical methodsReverse flowAerodynamicsHybrid RANS-LESThe aerodynamics of modern rotorcraft is highly complex and has proven to be an arduous challenge for computational fluid dynamics (CFD). Flow features such as massively separated boundary layers or transition to turbulence are common in engineering applications and need to be accurately captured in order to predict the vehicle performance. The recent advances in numerical methods and turbulence modeling have resolved each of these issues independent of the other. First, state-of-the-art hybrid RANS-LES turbulence closures have shown great promise in capturing the unsteady flow details and integrated performance quantities for stalled flows. Similarly, the correlation-based transition model of Langtry and Menter has been successfully applied to a wide range of applications involving attached or mildly separated flows. However, there still lacks a unified approach that can tackle massively separated flows in the transitional flow region. In this effort, the two approaches have been combined and expended to yield a methodology capable of accurately predicting the features in these highly complex unsteady turbulent flows at a reasonable computational cost. Comparisons are evaluated on several cases, including a transitional flat plate, circular cylinder in crossflow and NACA 63-415 wing. Cost and accuracy correlations with URANS and prior hybrid URANS-LES approaches with and without transition modeling indicate that this new method can capture both separation and transition more accurately and cost effectively. This new turbulence approach has been applied to the study of wings in the reverse flow regime. The flight envelope of modern helicopters has increased significantly over the last few decades, with design concepts now reaching advance ratios up to μ = 1. In these extreme conditions, the freestream velocity exceeds the rotational speed of the blades, and a large region of the retreating side of the rotor disk experiences reverse flow. For a conventional airfoil with a sharp trailing edge, the reverse flow regime is generally characterized by massive boundary layer separation and bluff body vortex shedding. This complex aerodynamic environment has been utilized to evaluate the new hybrid transitional approach. The assessment has proven the efficiency of the new hybrid model, and it has provided a transformative advancement to the modeling of dynamic stall.Georgia Institute of TechnologySmith, Marilyn J.Menon, SureshRuffin, Stephen M.Jones, Anya R.Zhou, Hao-MinLee-Rausch, Elizabeth2016-05-27T13:23:34Z2016-05-27T13:23:34Z2016-052016-04-04May 20162016-05-27T13:23:34ZDissertationapplication/pdfhttp://hdl.handle.net/1853/54995en_US
collection NDLTD
language en_US
format Others
sources NDLTD
topic CFD
Turbulence modeling
Transition to turbulence
Numerical methods
Reverse flow
Aerodynamics
Hybrid RANS-LES
spellingShingle CFD
Turbulence modeling
Transition to turbulence
Numerical methods
Reverse flow
Aerodynamics
Hybrid RANS-LES
Hodara, Joachim
Hybrid RANS-LES closure for separated flows in the transitional regime
description The aerodynamics of modern rotorcraft is highly complex and has proven to be an arduous challenge for computational fluid dynamics (CFD). Flow features such as massively separated boundary layers or transition to turbulence are common in engineering applications and need to be accurately captured in order to predict the vehicle performance. The recent advances in numerical methods and turbulence modeling have resolved each of these issues independent of the other. First, state-of-the-art hybrid RANS-LES turbulence closures have shown great promise in capturing the unsteady flow details and integrated performance quantities for stalled flows. Similarly, the correlation-based transition model of Langtry and Menter has been successfully applied to a wide range of applications involving attached or mildly separated flows. However, there still lacks a unified approach that can tackle massively separated flows in the transitional flow region. In this effort, the two approaches have been combined and expended to yield a methodology capable of accurately predicting the features in these highly complex unsteady turbulent flows at a reasonable computational cost. Comparisons are evaluated on several cases, including a transitional flat plate, circular cylinder in crossflow and NACA 63-415 wing. Cost and accuracy correlations with URANS and prior hybrid URANS-LES approaches with and without transition modeling indicate that this new method can capture both separation and transition more accurately and cost effectively. This new turbulence approach has been applied to the study of wings in the reverse flow regime. The flight envelope of modern helicopters has increased significantly over the last few decades, with design concepts now reaching advance ratios up to μ = 1. In these extreme conditions, the freestream velocity exceeds the rotational speed of the blades, and a large region of the retreating side of the rotor disk experiences reverse flow. For a conventional airfoil with a sharp trailing edge, the reverse flow regime is generally characterized by massive boundary layer separation and bluff body vortex shedding. This complex aerodynamic environment has been utilized to evaluate the new hybrid transitional approach. The assessment has proven the efficiency of the new hybrid model, and it has provided a transformative advancement to the modeling of dynamic stall.
author2 Smith, Marilyn J.
author_facet Smith, Marilyn J.
Hodara, Joachim
author Hodara, Joachim
author_sort Hodara, Joachim
title Hybrid RANS-LES closure for separated flows in the transitional regime
title_short Hybrid RANS-LES closure for separated flows in the transitional regime
title_full Hybrid RANS-LES closure for separated flows in the transitional regime
title_fullStr Hybrid RANS-LES closure for separated flows in the transitional regime
title_full_unstemmed Hybrid RANS-LES closure for separated flows in the transitional regime
title_sort hybrid rans-les closure for separated flows in the transitional regime
publisher Georgia Institute of Technology
publishDate 2016
url http://hdl.handle.net/1853/54995
work_keys_str_mv AT hodarajoachim hybridranslesclosureforseparatedflowsinthetransitionalregime
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