On the Existence of Logarithmic Terms in the Drag Coefficient and Nusselt Number of a Single Sphere at High Reynolds Numbers

Abstract

At the beginning of the second half of the twentieth century, Proudman and Pearson (J. Fluid. Mech.,2(3), 1956, pp.237-262) suggested that the functional form of the drag coefficient (CD) of a single sphere subjected to uniform fluid flow consists of a series of logarithmic and power terms of the Reynolds number (Re).\ In this paper, we will explore the validity of the above statement for Reynolds numbers up to 106 by using a symbolic regression machine learning method.\ The algorithm is trained by available experimental data and data from well-known correlations from the literature for Re ranging from 0.1 to 2× 105.\ Our results show that the functional form of the CD contains powers of (Re), plus the Stokes term, fulfilling partially the statement made above. The logarithmic CD expressions can generalize (extrapolate) beyond the training data and are the first in the literature to predict with acceptable accuracy the rapid decrease (drag crisis) of the CD at high Re.\ We also find a connection between the root of the Re-dependent terms in the CD expression and the first point of laminar separation.\ We did the same analysis for the problem of heat transfer under forced convection around a sphere and found that the logarithmic terms of Re and Peclect number Pe play an essential role in the variation of the Nusselt number Nu.\ The machine learning algorithm independently found the asymptotic solution of Acrivos and Goddard (J. Fluid. Mech., 23(2),1965, pp.273-291).