Entropy generation assessment for wall-bounded turbulent shear flows based on Reynolds analogy assumptions
Entropy generation assessment for wall-bounded turbulent shear flows based on Reynolds analogy assumptions
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.
Ziefuss, Matthias
bb4b5e37-ee97-433e-9f12-03844b0dd279
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
Ries, Florian
13a79c5d-fcf1-4a14-9a88-4836eab83a80
Sadiki, Amsini
628e2b9b-ead9-4a30-a143-411b09b61524
Mehdizadeh, Amirfarhang
e6f27402-32a9-41c8-a937-c2b035df6985
1 November 2019
Ziefuss, Matthias
bb4b5e37-ee97-433e-9f12-03844b0dd279
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
Ries, Florian
13a79c5d-fcf1-4a14-9a88-4836eab83a80
Sadiki, Amsini
628e2b9b-ead9-4a30-a143-411b09b61524
Mehdizadeh, Amirfarhang
e6f27402-32a9-41c8-a937-c2b035df6985
Ziefuss, Matthias, Karimi, Nader, Ries, Florian, Sadiki, Amsini and Mehdizadeh, Amirfarhang
(2019)
Entropy generation assessment for wall-bounded turbulent shear flows based on Reynolds analogy assumptions.
Entropy, 21 (12), [1157].
(doi:10.3390/e21121157).
Abstract
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.
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Published date: 1 November 2019
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Local EPrints ID: 509074
URI: http://eprints.soton.ac.uk/id/eprint/509074
ISSN: 1099-4300
PURE UUID: 3faae7a8-f87d-487f-9e3d-badcc9e772b5
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Date deposited: 10 Feb 2026 18:10
Last modified: 11 Feb 2026 03:18
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Author:
Matthias Ziefuss
Author:
Nader Karimi
Author:
Florian Ries
Author:
Amsini Sadiki
Author:
Amirfarhang Mehdizadeh
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