%0 Journal Article %1 SOTGIU2019108454 %A Sotgiu, Corrado %A Weigand, Bernhard %A Semmler, Klaus %A Wellinger, Philipp %D 2019 %J International Journal of Heat and Fluid Flow %K myown from:pwe weigand %P 108454 %R https://doi.org/10.1016/j.ijheatfluidflow.2019.108454 %T Towards a general data-driven explicit algebraic Reynolds stress prediction framework %U http://www.sciencedirect.com/science/article/pii/S0142727X18311408 %V 79 %X We propose a method to extend linear eddy-viscosity models up to a second order formulation using machine learning algorithms. The method is applicable to any turbulence model equipped with a transport equation for the wall-normal component of the Reynolds stress tensor v2 and is based on our ITALO framework (Sotgiu et al., 2018). We implement and test our extension using as base the elliptic-blending k−ϵ−ϕ−α linear eddy-viscosity model of Billiard and Laurence (2011). Neural networks are used to derive scalar functional forms for the nonlinear part of the Reynolds stress constitutive equation. The networks have been trained with data from a planar channel at Reτ=1020 and a two-dimensional periodic channel perturbed with corrugations at Reb=32,156. The test cases comprise channel flows at Reynolds numbers ranging from Reτ=180 to Reτ=1020, a periodic square duct at Reb=10,320, and a periodic ribbed channel at Reb=37,200. A comparison with other nonlinear eddy-viscosity models is reported. The new proposed model shows very good agreement with the reference data.

@article{SOTGIU2019108454, abstract = {We propose a method to extend linear eddy-viscosity models up to a second order formulation using machine learning algorithms. The method is applicable to any turbulence model equipped with a transport equation for the wall-normal component of the Reynolds stress tensor v2 and is based on our ITALO framework (Sotgiu et al., 2018). We implement and test our extension using as base the elliptic-blending k−ϵ−ϕ−α linear eddy-viscosity model of Billiard and Laurence (2011). Neural networks are used to derive scalar functional forms for the nonlinear part of the Reynolds stress constitutive equation. The networks have been trained with data from a planar channel at Reτ=1020 and a two-dimensional periodic channel perturbed with corrugations at Reb=32,156. The test cases comprise channel flows at Reynolds numbers ranging from Reτ=180 to Reτ=1020, a periodic square duct at Reb=10,320, and a periodic ribbed channel at Reb=37,200. A comparison with other nonlinear eddy-viscosity models is reported. The new proposed model shows very good agreement with the reference data.}, added-at = {2019-08-05T07:59:15.000+0200}, author = {Sotgiu, Corrado and Weigand, Bernhard and Semmler, Klaus and Wellinger, Philipp}, biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2bc488ed4cc4c7ef7ee6113a11f8d94a9/itlr}, doi = {https://doi.org/10.1016/j.ijheatfluidflow.2019.108454}, interhash = {dfb50cb81d5dbe9d6fe9a620d38a4985}, intrahash = {bc488ed4cc4c7ef7ee6113a11f8d94a9}, issn = {0142-727X}, journal = {International Journal of Heat and Fluid Flow}, keywords = {myown from:pwe weigand}, pages = 108454, timestamp = {2019-08-05T05:59:15.000+0200}, title = {Towards a general data-driven explicit algebraic Reynolds stress prediction framework}, url = {http://www.sciencedirect.com/science/article/pii/S0142727X18311408}, volume = 79, year = 2019 }