Litcius/Paper detail

A free flexible flap in channel flow

Chang Xu, Xuechao Liu, Kui Liu, Yongfeng Xiong, Haibo Huang

2022Journal of Fluid Mechanics16 citationsDOI

Abstract

Fine fibre immersed in different flows is ubiquitous. For a fibre in shear flows, most motion modes appear in the flow-gradient plane. Here the two-dimensional behaviours of an individual flexible flap in channel flows are studied. The nonlinear coupling of the fluid inertia ( $\textit {Re}$ ), flexibility of the flap ( $K$ ) and channel width ( $W$ ) is discovered. Inside a wide channel (e.g. $W=4$ ), as $K$ decreases, the flap adopts rigid motion, springy motion, snake turn and complex mode in sequence. It is found that the fluid inertia tends to straighten the flap. Moreover, $\textit {Re}$ significantly affects the lateral equilibrium location $y_{eq}$ , therefore affecting the local shear rate and the tumbling period $T$ . For a rigid flap in a wide channel, when $\textit {Re}$ exceeds a threshold, the flap stays inclined instead of tumbling. As $\textit {Re}$ further increases, the flap adopts swinging mode. In addition, there is a scaling law between $T$ and $\textit {Re}$ . For the effect of $K$ , through the analysis of the torque generated by surrounding fluid, we found that a smaller $K$ slows down the tumbling of the flap even if $y_{eq}$ is comparable. As $W$ decreases, the wall confinement effect makes the flap easier to deform and closer to the centreline. The tumbling period would increase and the swinging mode would be more common. When $W$ further decreases, the flaps are constrained to stay inclined, parabolic-like or one-end bending configurations moving along with the flow. Our study may shed some light on the behaviours of a free fibre in flows.

Topics & Concepts

InertiaPhysicsMechanicsFlow (mathematics)Channel (broadcasting)Coupling (piping)Materials scienceClassical mechanicsTelecommunicationsComputer scienceMetallurgyLattice Boltzmann Simulation StudiesFluid Dynamics and Turbulent FlowsBlood properties and coagulation