RANS turbulence model development using CFD-driven machine learning

This paper presents a novel CFD-driven machine learning framework to develop Reynolds-averaged Navier-Stokes (RANS) models. The CFD-driven training is an extension of the gene expression programming method Weatheritt and Sandberg (2016) [8], but crucially the fitness of candidate models is now evalu...

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Veröffentlicht in:	Journal of computational physics 2020-06, Vol.411 (C), p.109413, Article 109413
Hauptverfasser:	Zhao, Yaomin, Akolekar, Harshal D., Weatheritt, Jack, Michelassi, Vittorio, Sandberg, Richard D.
Format:	Artikel
Sprache:	eng
Schlagworte:	Computational fluid dynamics Computational physics Cost function Gene expression Machine learning Nozzles Reynolds averaged Navier-Stokes method Training Turbines Turbomachinery Turbulence modelling Turbulence models Wake mixing
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creator	Zhao, Yaomin Akolekar, Harshal D. Weatheritt, Jack Michelassi, Vittorio Sandberg, Richard D.
description	This paper presents a novel CFD-driven machine learning framework to develop Reynolds-averaged Navier-Stokes (RANS) models. The CFD-driven training is an extension of the gene expression programming method Weatheritt and Sandberg (2016) [8], but crucially the fitness of candidate models is now evaluated by running RANS calculations in an integrated way, rather than using an algebraic function. Unlike other data-driven methods that fit the Reynolds stresses of trained models to high-fidelity data, the cost function for the CFD-driven training can be defined based on any flow feature from the CFD results. This extends the applicability of the method especially when the training data is limited. Furthermore, the resulting model, which is the one providing the most accurate CFD results at the end of the training, inherently shows good performance in RANS calculations. To demonstrate the potential of this new method, the CFD-driven machine learning approach is applied to model development for wake mixing in turbomachines. A new model is trained based on a high-pressure turbine case and then tested for three additional cases, all representative of modern turbine nozzles. Despite the geometric configurations and operating conditions being different among the cases, the predicted wake mixing profiles are significantly improved in all of these a posteriori tests. Moreover, the model equation is explicitly given and available for analysis, thus it could be deduced that the enhanced wake prediction is predominantly due to the extra diffusion introduced by the CFD-driven model. •Turbulence closure trained for wake mixing using CFD-driven machine learning.•Trained model tested for different cases and demonstrated robustness.•Explicitly given model equation shown to be realizable and physically interpretable.
doi_str_mv	10.1016/j.jcp.2020.109413
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A new model is trained based on a high-pressure turbine case and then tested for three additional cases, all representative of modern turbine nozzles. Despite the geometric configurations and operating conditions being different among the cases, the predicted wake mixing profiles are significantly improved in all of these a posteriori tests. Moreover, the model equation is explicitly given and available for analysis, thus it could be deduced that the enhanced wake prediction is predominantly due to the extra diffusion introduced by the CFD-driven model. •Turbulence closure trained for wake mixing using CFD-driven machine learning.•Trained model tested for different cases and demonstrated robustness.•Explicitly given model equation shown to be realizable and physically interpretable.</description><identifier>ISSN: 0021-9991</identifier><identifier>EISSN: 1090-2716</identifier><identifier>DOI: 10.1016/j.jcp.2020.109413</identifier><language>eng</language><publisher>Cambridge: Elsevier Inc</publisher><subject>Computational fluid dynamics ; Computational physics ; Cost function ; Gene expression ; Machine learning ; Nozzles ; Reynolds averaged Navier-Stokes method ; Training ; Turbines ; Turbomachinery ; Turbulence modelling ; Turbulence models ; Wake mixing</subject><ispartof>Journal of computational physics, 2020-06, Vol.411 (C), p.109413, Article 109413</ispartof><rights>2020 Elsevier Inc.</rights><rights>Copyright Elsevier Science Ltd. 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subjects	Computational fluid dynamics Computational physics Cost function Gene expression Machine learning Nozzles Reynolds averaged Navier-Stokes method Training Turbines Turbomachinery Turbulence modelling Turbulence models Wake mixing
title	RANS turbulence model development using CFD-driven machine learning
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