Abstract
We consider the stability of flux-driven flow through a long planar rigid channel, where a segment of one wall is replaced by a pre-tensioned hyperelastic (neo-Hookean) solid of finite thickness and subject to a uniform external pressure. We construct the steady configuration of the nonlinear system using Newton's method with spectral collocation and high-order finite differences. In agreement with previous studies, which use an asymptotically thin wall, we show that the thick-walled system always has at least one stable steady configuration, while for large Reynolds numbers the system exhibits three co-existing steady states for a range of external pressures. Two of these steady configurations are stable to non-oscillatory perturbations, one where the flexible wall is inflated (the upper branch) and one where the flexible wall is collapsed (the lower branch), connected by an unstable intermediate branch. We test the stability of these steady configurations to oscillatory perturbations using both a global eigensolver (constructed based on an analytical domain mapping technique) and also fully nonlinear simulations. We find that both the lower and upper branches of steady solutions can become unstable to self-excited oscillations, where the oscillating wall profile has two extrema. In the absence of wall inertia, increasing wall thickness partially stabilises the onset of oscillations, but the effect remains weak until the wall thickness becomes comparable to the width of the undeformed channel. However, with finite wall inertia and a relatively thick wall, higher-frequency modes of oscillation dominate the primary global instability for large Reynolds numbers.
Highlights
Human physiology includes a wide number of examples of fluid flow through flexible-walled conduits including blood flow through the circulation, air flow through the lungs and upper airways, urine flows in the excretory system and peristaltic flows through the colon
Results from the experiments are well summarised elsewhere (e.g. Bertram 2003; Grotberg & Jensen 2004; Heil & Hazel 2011), but we note that these self-excited oscillations occur in distinct frequency bands (Bertram, Raymond & Pedley 1990), and exhibit complicated nonlinear limit cycles which can be characterised using the methods of dynamical systems (Bertram, Raymond & Pedley 1991)
P = 0 (§ 3.3), before using our new model to examine the role of membrane pre-tension (§ 3.4), the dynamics of oscillations growing from the upper branch of steady solutions (§ 3.5) as well as the role of wall thickness (§ 3.6) and wall inertia (§ 3.7) on the nonlinear steady solutions and the accompanying onset of oscillation
Summary
Human physiology includes a wide number of examples of fluid flow through flexible-walled conduits including blood flow through the circulation (from rapid flow in the heart and large arteries to slow viscous flows through the capillaries), air flow through the lungs and upper airways, urine flows in the excretory system and peristaltic flows through the colon. We treat the elastic solid as a pre-tensioned hyperelastic material of uniform initial thickness with non-negligible density and subject to a uniform external pressure We validate this numerical method against the steady predictions of Heil (2004), who considered an identical set-up with a thin shell model for the wall (§ 3.1), use unsteady simulations to examine the transition between the upper and lower branches of steady solutions (§ 3.2), examine the onset of self-excited oscillations from these steady solutions. (§ 3.3), before using our new model to examine the role of membrane pre-tension (§ 3.4), the dynamics of oscillations growing from the upper branch of steady solutions (§ 3.5) as well as the role of wall thickness (§ 3.6) and wall inertia (§ 3.7) on the nonlinear steady solutions and the accompanying onset of oscillation
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