Entropy Generation Assessment for Wall-Bounded Turbulent Shear Flows Based on Reynolds Analogy Assumptions

• Published in: Entropy (Basel, Switzerland) Vol. 21; no. 12; p. 1157
• Main Authors: Ziefuss, Matthias, Karimi, Nader, Ries, Florian, Sadiki, Amsini, Mehdizadeh, Amirfarhang
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 26.11.2019; MDPI
• Subjects: Computational fluid dynamics; Design optimization; Entropy; Fluid flow; Fluids; Heat transfer; Navier-Stokes equations; Nuclear energy; Nuclear power plants; Shear flow; Simulation; Thermodynamics; Turbulence models; Turbulent heat transfer; Unsteady state
• ISSN: 1099-4300; 1099-4300
• DOI: 10.3390/e21121157

Heat transfer modeling plays a major role in design and optimization of modern and efficient thermal-fluid systems. Further, turbulent flows are thermodynamic processes, and thus, the second law of thermodynamics can be used for critical evaluations of such heat transfer models. However, currently available heat transfer models suffer from a fundamental shortcoming: their development is based on the general notion that accurate prediction of the flow field will guarantee an appropriate prediction of the thermal field, known as the . In this work, an assessment of the capability of the in predicting turbulent heat transfer when applied to shear flows of fluids of different Prandtl numbers will be given. Towards this, a detailed analysis of the predictive capabilities of the concerning entropy generation is presented for steady and unsteady state simulations. It turns out that the provides acceptable results only for mean entropy generation, while fails to predict entropy generation at small/sub-grid scales.