The Characteristic Length Scale of the Intermediate Structure in Zero-Pressure-Gradient Boundary Layer Flow

TL;DR

This paper investigates the intermediate structure of zero-pressure-gradient turbulent boundary layers, identifying two characteristic length scales and comparing them with classical models using recent experimental data.

Contribution

It introduces and compares two length scales in the intermediate structure of turbulent boundary layers, challenging classical wake region models.

Findings

Both length scales are close in value.

The structure follows Reynolds-number-dependent scaling laws.

Results disagree with classical wake region models.

Abstract

In a turbulent boundary layer over a smooth flat plate with zero pressure gradient, the intermediate structure between the viscous sublayer and the free stream consists of two layers: one adjacent to the viscous sublayer and one adjacent to the free stream. When the level of turbulence in the free stream is low, the boundary between the two layers is sharp and both have a self-similar structure described by Reynolds-number-dependent scaling (power) laws. This structure introduces two length scales: one --- the wall region thickness --- determined by the sharp boundary between the two intermediate layers, the second determined by the condition that the velocity distribution in the first intermediate layer be the one common to all wall-bounded flows, and in particular coincide with the scaling law previously determined for pipe flows. Using recent experimental data we determine both these length scales and show that they are close. Our results disagree with the classical model of the "wake region".