Jump conditions for unsteady small perturbations at fluid–solid interfaces in the presence of initial flow and prestress

Treyssède, Fabien; Tahar, Mabrouk Ben

doi:10.1016/j.wavemoti.2008.10.003

Cited by 10 publications

(9 citation statements)

References 29 publications

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“…One assumes small displacements superimposed onto the prestressed static state, with a time harmonic e −iωt dependence. Expressing variables in the prestress configuration, the equilibrium equations of elastodynamics un-der prestress are given in the frequency domain by 16,17 :…”

Section: A Dynamics Of Prestressed Structuresmentioning

confidence: 99%

Investigation of the interwire energy transfer of elastic guided waves inside prestressed cables

Treyssède¹

2016

The Journal of the Acoustical Society of America

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Elastic guided waves are of interest for the non-destructive evaluation of cables. Cables are most often multi-wire structures, and understanding wave propagation requires numerical models accounting for the helical geometry of individual wires, the interwire contact mechanisms and the effects of prestress. In this paper, a modal approach based on a so-called semi-analytical finite element method and taking advantage of a biorthogonality relation is proposed in order to calculate the forced response under excitation of a cable, multi-wired, twisted, and prestressed. The main goal of this paper is to investigate how the energy transfers from a given wire, directly excited, to the other wires in order to identify some localization of energy inside the active wire as the waves propagate along the waveguide. The power flow of the excited field is theoretically derived and an energy transfer parameter is proposed to evaluate the level of energy localization inside a given wire. Numerical results obtained for different polarizations of excitation, central and peripheral, highlight how the energy may localize, spread, or strongly change in the cross-section as waves travel along the axis. In particular, a compressional mode localized inside the central wire is found, with little dispersion and significant excitability.

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Section: A Dynamics Of Prestressed Structuresmentioning

confidence: 99%

Investigation of the interwire energy transfer of elastic guided waves inside prestressed cables

Treyssède¹

2016

The Journal of the Acoustical Society of America

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“…The boundary conditions corresponding to impermeable material walls to the mean flow (boundary S 2 ) are simply given by the following relationship [23,24]:…”

Section: Boundary Conditionsmentioning

confidence: 99%

Perfectly Matched Layer for Galbrun׳s aeroacoustic equation in a cylindrical coordinates system with an axial and a swirling steady mean flow

Baccouche

Tahar

Moreau

2016

Journal of Sound and Vibration

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“…In the bottom right results are plotted for formulation (24). For this formulation the velocities on either side of the vortex sheet are explicit variables, and the trailing edge velocities have been set to zero.…”

Section: Velocity As An Explicit Variablementioning

confidence: 99%

“…b Note that without the SUPG method the model is very sensitive to the properties of the vortex sheet termination. (12), (14) and (24). Top left:…”

Section: Vortex Sheet Discretisationmentioning

confidence: 99%

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Implementation of a Vortex Sheet in a Finite Element Model Based on Potential Theory for Exhaust Noise Predictions

Prinn

Gabard

Bériot

2012

18th AIAA/CEAS Aeroacoustics Conference (33rd AIAA Aeroacoustics Conference)

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Predicting sound propagation through the jet exhaust of an aero-engine presents the specific difficulty of representing the refraction effect of the mean flow shear. This is described by the linearised Euler equations, but this model remains rather expensive to solve numerically. The other model commonly used in industry, the linearised potential theory, is faster to solve but needs to be modified to represent a shear layer. This paper presents a way to describe a vortex sheet in a finite element model based on the linearised potential theory. The key issues to address are the continuity of pressure and displacement that have to be enforced across the vortex sheet, as well as the implementation of the Kutta condition at the nozzle lip. Validation results are presented by comparison with analytical results. It is shown that the discretization of the continuity conditions is crucial to obtain a robust and accurate numerical model.

show abstract

Jump conditions for unsteady small perturbations at fluid–solid interfaces in the presence of initial flow and prestress

Cited by 10 publications

References 29 publications

Investigation of the interwire energy transfer of elastic guided waves inside prestressed cables

Investigation of the interwire energy transfer of elastic guided waves inside prestressed cables

Perfectly Matched Layer for Galbrun׳s aeroacoustic equation in a cylindrical coordinates system with an axial and a swirling steady mean flow

Implementation of a Vortex Sheet in a Finite Element Model Based on Potential Theory for Exhaust Noise Predictions

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