Flow-excited membrane instability at moderate Reynolds numbers

TL;DR

This study investigates the fluid-structure interaction and instability of a 3D flexible membrane in unsteady flow at moderate Reynolds numbers, revealing stability regimes, frequency lock-in phenomena, and implications for membrane wing design.

Contribution

It introduces a high-fidelity numerical framework to analyze membrane instability, phase diagrams for stability regimes, and an analytical formula for natural frequency considering added mass effects.

Findings

Identification of deformed-steady and dynamic balance stability regimes.

Discovery of frequency synchronization leading to self-sustained vibrations.

Dependence of membrane mode transition on vortex shedding and natural frequency lock-in.

Abstract

In this paper, we study the fluid-structure interaction (FSI) of a three-dimensional (3D) flexible membrane immersed in an unsteady separated flow at moderate Reynolds numbers. We employ a body-conforming variational FSI solver based on the recently developed partitioned iterative scheme for the coupling of turbulent fluid flow with nonlinear structural dynamics. Of particular interest is to understand the flow-excited instability of a 3D flexible membrane as a function of the non-dimensional mass ratio, Reynolds number and aeroelastic number. For a wide range of the parameters, we examine two distinctive stability regimes of fluid-membrane interaction: deformed-steady state (DSS) and dynamic balance state (DBS). We propose stability phase diagrams to demarcate the DSS and DBS regimes for the parameter space of mass ratio vs. Reynolds number and mass ratio vs. aeroelastic number. Based on the aeroelastic mode analysis, we observe a frequency synchronization between the vortex shedding frequency and the membrane vibration frequency which leads to self-sustained vibrations in the dynamic balance state. To characterize the origin of the frequency lock-in, we derive an approximate analytical formula for the nonlinear natural frequency by considering the added mass effect and employing a large deflection theory for a simply supported rectangular membrane. Through our systematic high-fidelity numerical investigation, we find that the onset of the membrane vibration and the mode transition has a dependence on the frequency lock-in between the natural frequency of the tensioned membrane and the vortex shedding frequency or its harmonics. These findings on the fluid-elastic instability of membranes have implications for the design and development of control strategies for membrane wing-based unmanned systems and drones.