Effects of wavelength on vortex structure and turbulence kinetic energy transfer of flow over undulated cylinders

TL;DR

This study investigates how different undulation wavelengths on a seal whisker-inspired cylinder influence vortex structures and turbulence energy transfer, revealing optimal geometries for force reduction in flow control.

Contribution

It provides new insights into how undulation wavelength modifications affect vortex dynamics and turbulence energy transfer, aiding bio-inspired flow control design.

Findings

Maximum force reduction occurs at specific undulation wavelengths.

Flow patterns include vortex rollers and hairpin vortices.

Altered vortex structures change turbulence energy production and dissipation.

Abstract

Passive flow control research is commonly utilized to provide desirable drag and oscillating lift reduction across a range of engineering applications. This research explores the spanwise undulated cylinder inspired by seal whiskers, shown to reduce lift and drag forces when compared to smooth cylinders. Although the fluid flow over this unique complex geometry has been documented experimentally and computationally, investigations surrounding geometric modifications to the undulation topography have been limited, and fluid mechanisms by which force reduction is induced have not been fully examined. Five undulation wavelength variations of the undulated cylinder model are simulated at Reynolds number $\Rey=250$ and compared with results from a smooth elliptical cylinder. Vortex structures and turbulence kinetic energy (TKE) transfer in the wake are analyzed to explain how undulation wavelength affects force reduction. Modifications to the undulation wavelength generate a variety of flow patterns including alternating vortex rollers and hairpin vortices. Maximum force reduction is observed at wavelengths that are large enough to allow hairpin vortices to develop without intersecting each other and small enough to prevent the generation of additional alternating flow structures. The differences in flow structures modify the magnitude and location of TKE production and dissipation due to changes in mean and fluctuating strain. Decreased TKE production and increased dissipation in the near wake result in overall lower TKE and reduced body forces. Understanding the flow physics linking geometry to force reduction will guide appropriate parameter selection in bio-inspired design applications.