Analytical solution for an acoustic boundary layer around an oscillating rigid sphere

Klaseboer, Evert; Sun, Qiang; Chan, Derek Y. C.

doi:10.1063/5.0033933

Cited by 5 publications

(2 citation statements)

References 26 publications

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“…However, k can be complex, and equation (1) then represents an acoustic wave in a medium with absorption. As an example we can mention the description of acoustic boundary layers around a sphere in a viscous liquid [40], which was based on the Navier equation ( 23), but with complex kʼs. There are other types of variations of the Helmholtz equation as well.…”

Section: Other Physical Systems With Helmholtz Equationsmentioning

confidence: 99%

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Helmholtz equation and non-singular boundary elements applied to multi-disciplinary physical problems

Klaseboer¹,

Sun²

2022

Commun. Theor. Phys.

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The famous scientist Hermann von Helmholtz was born 200 years ago. Many complex physical wave phenomena in engineering can effectively be described using one or a set of equations named after him: the Helmholtz equation. Although this has been known for a long time from a theoretical point of view, the actual numerical implementation has often been hindered by divergence free and/or curl free constraints. There is further a need for a numerical method that is accurate, reliable and takes into account radiation conditions at infinity. The classical boundary element method (BEM) satisfies the last condition, yet one has to deal with singularities in the implementation. We review here how a recently developed singularity-free three-dimensional (3D) boundary element framework with superior accuracy can be used to tackle such problems only using one or a few Helmholtz equations with higher order (quadratic) elements which can tackle complex curved shapes. Examples are given for acoustics (a Helmholtz resonator among others) and electromagnetic scattering.

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Section: Other Physical Systems With Helmholtz Equationsmentioning

confidence: 99%

“…x = (n • e x ), t 1x = (t 1 • e x ) and t 2x = (t 2 • e x ).If we replace the terms in brackets in equation(44) with equation(42) and equation(40) then:…”

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confidence: 99%

Helmholtz equation and non-singular boundary elements applied to multi-disciplinary physical problems

Klaseboer¹,

Sun²

2022

Commun. Theor. Phys.

Self Cite

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Analytical solution for a vibrating rigid sphere with an elastic shell in an infinite linear elastic medium

Klaseboer

Sun

2022

International Journal of Solids and Structures

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Analytical solution for the quasi-two dimensional non-isothermal fully developed flow of molten salt in a circular pipe

Boraey

Guaily

2021

Physics of Fluids

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In this contribution, a mathematical model is presented for the flow of molten salt in a circular pipe. The fluid density, thermal conductivity, and viscosity are all assumed to be temperature dependent. We show how to derive a new closed-form approximate solution to this problem, valid for low Reynolds numbers and high axial temperature gradients. This regime is chosen to challenge the ability of the model to obtain the correct solution for significant changes in fluid properties. The accuracy of this simplified solution is tested against a numerical solution of the full set of governing equations, and it is found that the maximum error is less than 1.5% for the temperature field and 6% for the velocity field, for Reynolds numbers less than 100. This closed-form solution allows us to gain insight into the effects of various physical parameters upon the flow properties and thermal behavior of the molten salt, and this is illustrated in the results. The solution presented here also serves as a benchmark for numerical solutions of the full model.

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Analytical solution for an acoustic boundary layer around an oscillating rigid sphere

Cited by 5 publications

References 26 publications

Helmholtz equation and non-singular boundary elements applied to multi-disciplinary physical problems

Helmholtz equation and non-singular boundary elements applied to multi-disciplinary physical problems

Analytical solution for a vibrating rigid sphere with an elastic shell in an infinite linear elastic medium

Analytical solution for the quasi-two dimensional non-isothermal fully developed flow of molten salt in a circular pipe

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