A Machine Learning Approach for Determining the Turbulent Diffusivity in Film Cooling Flows | Zendy

Pedro M. Milani | Zendy; Julia Ling | Zendy; Gonzalo Sáez-Mischlich | Zendy; Julien Bodart | Zendy; John K. Eaton | Zendy

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A Machine Learning Approach for Determining the Turbulent Diffusivity in Film Cooling Flows

Author(s) -

Pedro M. Milani,

Julia Ling,

Gonzalo Sáez-Mischlich,

Julien Bodart,

John K. Eaton

Publication year - 2017

Publication title -

journal of turbomachinery

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 0.972

H-Index - 112

eISSN - 1528-8900

pISSN - 0889-504X

DOI - 10.1115/1.4038275

Subject(s) - reynolds averaged navier–stokes equations , turbulence , mechanics , thermal diffusivity , simple algorithm , heat flux , jet (fluid) , flow (mathematics) , computer science , materials science , statistical physics , mathematics , thermodynamics , physics , heat transfer

In film cooling flows, it is important to know the temperature distribution resulting from the interaction between a hot main flow and a cooler jet. However, current Reynolds-averaged Navier-Stokes (RANS) models yield poor temperature predictions. A novel approach for RANS modeling of the turbulent heat flux is proposed, in which the simple gradient diffusion hypothesis (GDH) is assumed and a machine learning algorithm is used to infer an improved turbulent diffusivity field. This approach is implemented using three distinct data sets: two are used to train the model and the third is used for validation. The results show that the proposed method produces significant improvement compared to the common RANS closure, especially in the prediction of film cooling effectiveness

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