Motions of a cantilevered flexible plate in viscous channel flow driven by a constant pressure drop

Tetlow, G. A.; Lucey, Anthony D.

doi:10.1002/cnm.1225

Cited by 23 publications

(21 citation statements)

References 29 publications

(72 reference statements)

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“…Based on their numerical results, when both upper and lower inlets are open, a flutter-type instability is initiated at a critical Reynolds number, while if one of the inlets is closed, a divergence-type instability occurs at a critical velocity. Although Tetlow and Lucey (2009) imposed a constant pressure drop along the channel rather than 70 assuming velocity-driven flow, flutter instabilities similar to those found by Balint and Lucey (2005) were observed.…”

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confidence: 63%

“…In contrast to the studies mentioned above, Balint and Lucey (2005) and Tetlow and Lucey (2009) included viscous effects directly in their instability analysis by solving the Navier-Stokes 60 equation in a 2D channel surrounding a cantilever plate. Whereas Balint and Lucey (2005) modeled the motion of a thin plate using linear plate theory under differential pressure, Tetlow and Lucey (2009), added a tension term defined as the skin friction force acting on both the upper and lower sides of the plate.…”

mentioning

confidence: 99%

“…Whereas Balint and Lucey (2005) modeled the motion of a thin plate using linear plate theory under differential pressure, Tetlow and Lucey (2009), added a tension term defined as the skin friction force acting on both the upper and lower sides of the plate. In both studies, the finite element method was employed in order to solve the unsteady, laminar Navier-Stokes equations in a channel geometry with inlet boundaries above and below the flexible plate and to estimate fluid loads interfacing with the plate.…”

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confidence: 99%

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Interaction between a simplified soft palate and compressible viscous flow

Khalili

Larsson

Müller

2016

Journal of Fluids and Structures

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Fluid-structure interaction in a simplified 2D model of the upper airways is simulated to study flow-induced oscillation of the soft palate in the pharynx. The goal of our research has been a better understanding of the mechanisms of the Obstructive Sleep Apnea Syndrome and snoring by taking into account compressible viscous flow. The inspiratory airflow is described by the 2D compressible Navier-Stokes equations, and the soft palate is modeled as a flexible plate by the linearized EulerBernoulli thin beam theory. Fluid-structure interaction is handled by the arbitrary LagrangianEulerian formulation. The fluid flow is computed by utilizing 4 th order accurate summation by parts difference operators and the 4 th order accurate classical Runge-Kutta method which lead to very accurate simulation results. The motion of the cantilevered plate is solved numerically by employing the Newmark time integration method. The numerical schemes for the structure are verified by comparing the computed frequencies of plate oscillation with the associated second mode eigenfrequency in vacuum. Vortex dynamics is assessed for the coupled fluid-structure system when both airways are open and when one airway is closed. The effect of mass ratio, rigidity and damping coefficient of the plate on the oscillatory behaviour is investigated. An acoustic analysis is carried out to characterize the acoustic wave propagation induced by the plate oscillation. It is observed that the acoustic wave corresponding to the quarter wave mode along the length of the duct is the dominant frequency. However, the frequency of the plate oscillation is recognizable in the acoustic pressure when reducing the amplitude of the quarter wave mode.

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confidence: 63%

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confidence: 99%

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confidence: 99%

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Interaction between a simplified soft palate and compressible viscous flow

Khalili

Larsson

Müller

2016

Journal of Fluids and Structures

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“…The omission of a tension cross-term is justified by the near independence between deformations of the perpendicular fibres that constitute the material. Also neglected are the effects of geometric non-linearity because the amplitude-towavelength ratio of the deformations is small, and the effects of fluid friction and in-plane deformation because these are typically an order of magnitude smaller than the out-of-plane effects modelled herein (see, for example, reference [14]). …”

Section: Computational Investigationmentioning

confidence: 99%

A predictive capability for the aerodynamic deformation of convertible car roofs

Knight

Lucey

Shaw³

2010

Proceedings of the Institution of Mechanical Engineers, Part D:

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The flow-induced deformation of a membrane in a flow is studied using experimental and computational approaches in a configuration that represents the effect of the aerodynamic load on a convertible car roof. The computational method couples a commercial computational fluid dynamics code with an in-house structural code to predict membrane deformation. A converged statically deformed state, within 1 per cent difference in the displacement variable, is reached after three iterations between the fluid and structural codes. The predictions of membrane deformation are shown to agree well with the experimental results. The key outcome is the demonstration of methodology that will be useful in the engineering design of convertible car roofs.

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“…The flow-plate configuration has been extended to that of a flexible plate mounted in plane-channel flow; see Auré gan and Depollier (1995) and Guo and Païdoussis (2000). All of these studies predict that the plate loses its stability through flutter that sets in beyond a critical uniform flow speed or Reynolds number in the case of viscous channel flow; for the latter refinements, see Balint and Lucey (2005) and Tetlow and Lucey (2009). For short plates the flutter mode is predicted to comprise mainly a combination of the first and second in vacuo modes while for long plates, or plates with heavy fluid loading, the critical mode is dominated by higher-order mode content.…”

Section: Introductionmentioning

confidence: 98%

The effect of inertial inhomogeneity on the flutter of a cantilevered flexible plate

Howell

Lucey

Pitman

2011

Journal of Fluids and Structures

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a b s t r a c tWe study the effect of adding discrete structural mass on the linear stability of an otherwise homogeneous cantilevered-free flexible plate immersed in uniform axial flow. The methods of Howell et al. that mixed numerical simulation with eigenvalue analysis are simply extended for the present study. An ideal two-dimensional flow is assumed wherein the rotationality of the boundary-layers is modelled by vortex elements on the solid-fluid interface and the imposition of the Kutta condition at the plate's trailing edge. The EulerBernoulli beam model is used for the structural dynamics. It is shown that addition of mass to the plate can be either stabilising or destabilising, depending upon the location of the added mass, and how its inclusion modifies the energy exchanges of the corresponding homogeneous structure. Our results therefore suggest a straightforward means by which the critical flow speed at which low-amplitude flutter sets in can be passively controlled in engineering applications.

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Motions of a cantilevered flexible plate in viscous channel flow driven by a constant pressure drop

Cited by 23 publications

References 29 publications

Interaction between a simplified soft palate and compressible viscous flow

Interaction between a simplified soft palate and compressible viscous flow

A predictive capability for the aerodynamic deformation of convertible car roofs

The effect of inertial inhomogeneity on the flutter of a cantilevered flexible plate

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