Unified Flow and Thermal Law-of-the-wall Complete Formulations for Type-A Turbulent Boundary Layers
Duo Wang, Heng Li, Ting Yu, Bochao Cao, Hongyi Xu

TL;DR
This paper develops unified analytical formulations for velocity and temperature profiles in Type-A turbulent boundary layers, validated by DNS and experimental data, advancing the classical law-of-the-wall theory.
Contribution
It introduces a complete, Reynolds-number independent law-of-the-wall formulation for Type-A TBL, including damping and enhancement functions, applicable to velocity and temperature profiles.
Findings
Unified law-of-the-wall formulations validated by DNS and experiments.
Introduction of general damping and enhancement functions for TBL modeling.
Applicability of formulations to both velocity and temperature in Type-A TBL.
Abstract
In-depth analyses of existing direct numerical simulations (DNS) data from various sources supported a logical and important classification of generic turbulent boundary layers (TBL), namely Type-A, -B and -C TBL, based on distribution patterns of time-averaged wall-shear stress. Among these types, Type-A TBL and its related law, as represented by the DNS data of turbulence on a zero-pressure-gradient semi-infinite flat-plate, was investigated in terms of analytical formulations of velocity independent on Reynolds ( ) number. With reference to the analysis from von Karman in developing the conventional law-of-the-wall, the current study first physically distinguished the time-averaged local scale used by von Karman from the ensemble-averaged scale defined in the paper, and then derived the governing equations with the -independency under the ensemble-averaged scales. Based on indicator…
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Taxonomy
TopicsFluid Dynamics and Turbulent Flows · Wind and Air Flow Studies · Heat Transfer Mechanisms
