On the turbulent flow field over riblets of various groove sizes at low Reynolds number

TL;DR

This study uses direct numerical simulations to analyze how different sizes of V-groove riblets affect turbulent flow and drag in a low Reynolds number channel, revealing size-dependent flow features and drag variations.

Contribution

It provides new insights into the size effects of V-groove riblets on turbulence dynamics and drag, using detailed DNS analysis at low Reynolds numbers.

Findings

Smaller riblets produce turbulence profiles similar to plane channel flow.

Larger riblets induce near-wall flow lodging and secondary flows.

Riblet size correlates with increased viscous drag and turbulence alterations.

Abstract

In this work, low Reynolds number turbulent flow through a corrugated channel, formed by standard V-groove riblets, are investigated via direct numerical simulations (DNS). The simulations attempt to assess the variation of flow dynamics caused by a change in the characteristic size of the V-groove riblets. Such characterization of size effects provides a means to identify the local flow features arising from fluid-riblet interaction, and to investigate their relevance to the change in viscous drag and turbulence statistics. The present simulations confirmed an improved variation trend when the flow dynamics is examined in the light of the groove size. At the lower end of the range of groove size considered, the profiles of turbulence statistics more or less resemble the plane channel flow, except for a systematic shift with the groove size. When the groove size becomes increasingly large, the lodging of near-wall flow structures and the generation of mean secondary flows tend to be more apparent. The collective impact of the lodging of flow structures and the mean secondary flow correlates with the increase in viscous drag, and leads to significant alterations of the turbulence statistics.