Lateral edge effects on heat/mass transfer on a finite width surface within a turbulent boundary layer
journal contributionposted on 2019-04-17, 14:45 authored by Matteo Angelino, Richard J. Goldstein, Fabio Gori
Numerical simulations of the local heat/mass transfer on a finite width surface within a turbulent boundary layer are presented. Different approaches to the RANS modelling of the turbulent heat/mass flux are compared to Large Eddy Simulations (LES). Mass transfer experiments conducted with the naphthalene sublimation technique are used as validation. The isotropic eddy viscosity model, Simple Gradient Diffusion Hypothesis (SGDH), is shown to underestimate the span-wise effects. Its anisotropic extension, Generalized Gradient Diffusion Hypothesis (GGDH), improves the prediction, but still does not account for near-wall contribution in strongly dissimilar velocity and temperature/concentration fields, even in combination with a wall-sensitive second-moment closure model such as the Elliptic Blending Reynolds Stress Model (EB-RSM). A more complete turbulent heat flux model based on the elliptic blending approach, the Elliptic Blending GGDH (EB-GGDH) presents very good agreement with LES and with the experiments, confirming the need for more advanced turbulent heat flux modelling in applications with strong three-dimensional effects.
University of Minnesota and the University of Rome Tor Vergata.
- Aeronautical, Automotive, Chemical and Materials Engineering
- Aeronautical and Automotive Engineering
Published inInternational Journal of Heat and Mass Transfer
Pages32 - 40
CitationANGELINO, M., GOLDSTEIN, R.J. and GORI, F., 2019. Lateral edge effects on heat/mass transfer on a finite width surface within a turbulent boundary layer. International Journal of Heat and Mass Transfer, 138, pp.32-40.
- AM (Accepted Manuscript)
Publisher statementThis paper was accepted for publication in the journal International Journal of Heat and Mass Transfer and the definitive published version is available at https://doi.org/10.1016/j.ijheatmasstransfer.2019.04.016.