A finite-volume approach to 1D nonlinear elastic waves: Application to slow dynamics

H. Berjamin; B. Lombard; G. Chiavassa; N. Favrie

doi:10.3813/AAA.919197

A finite-volume approach to 1D nonlinear elastic waves: Application to slow dynamics

H. Berjamin, B. Lombard, G. Chiavassa, N. Favrie

Research output: Contribution to journal › Article › peer-review

Abstract

A numerical method for longitudinal wave propagation in nonlinear elastic solids is presented. Here, we consider polynomial stress-strain relationships, which are widely used in nondestructive evaluation. The large-strain and infinitesimal-strain constitutive laws deduced from Murnaghan’s law are detailed, and polynomial expressions are obtained. The Lagrangian equations of motion yield a hyperbolic system of conservation laws. The latter is solved numerically using a finite-volume method with flux limiters based on Roe linearization. The method is tested on the Riemann problem, which yields nonsmooth solutions. The method is then applied to a continuum model with one scalar internal variable, accounting for the softening of the material (slow dynamics).

Original language	English
Pages (from-to)	561-570
Number of pages	10
Journal	Acta Acustica united with Acustica
Volume	104
Issue number	4
DOIs	https://doi.org/10.3813/AAA.919197
Publication status	Published - 1 Jul 2018
Externally published	Yes

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title = "A finite-volume approach to 1D nonlinear elastic waves: Application to slow dynamics",

abstract = "A numerical method for longitudinal wave propagation in nonlinear elastic solids is presented. Here, we consider polynomial stress-strain relationships, which are widely used in nondestructive evaluation. The large-strain and infinitesimal-strain constitutive laws deduced from Murnaghan{\textquoteright}s law are detailed, and polynomial expressions are obtained. The Lagrangian equations of motion yield a hyperbolic system of conservation laws. The latter is solved numerically using a finite-volume method with flux limiters based on Roe linearization. The method is tested on the Riemann problem, which yields nonsmooth solutions. The method is then applied to a continuum model with one scalar internal variable, accounting for the softening of the material (slow dynamics).",

author = "H. Berjamin and B. Lombard and G. Chiavassa and N. Favrie",

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T2 - Application to slow dynamics

AU - Berjamin, H.

AU - Lombard, B.

AU - Chiavassa, G.

AU - Favrie, N.

N1 - Publisher Copyright: © S. Hirzel Verlag · EAA.

PY - 2018/7/1

Y1 - 2018/7/1

N2 - A numerical method for longitudinal wave propagation in nonlinear elastic solids is presented. Here, we consider polynomial stress-strain relationships, which are widely used in nondestructive evaluation. The large-strain and infinitesimal-strain constitutive laws deduced from Murnaghan’s law are detailed, and polynomial expressions are obtained. The Lagrangian equations of motion yield a hyperbolic system of conservation laws. The latter is solved numerically using a finite-volume method with flux limiters based on Roe linearization. The method is tested on the Riemann problem, which yields nonsmooth solutions. The method is then applied to a continuum model with one scalar internal variable, accounting for the softening of the material (slow dynamics).

AB - A numerical method for longitudinal wave propagation in nonlinear elastic solids is presented. Here, we consider polynomial stress-strain relationships, which are widely used in nondestructive evaluation. The large-strain and infinitesimal-strain constitutive laws deduced from Murnaghan’s law are detailed, and polynomial expressions are obtained. The Lagrangian equations of motion yield a hyperbolic system of conservation laws. The latter is solved numerically using a finite-volume method with flux limiters based on Roe linearization. The method is tested on the Riemann problem, which yields nonsmooth solutions. The method is then applied to a continuum model with one scalar internal variable, accounting for the softening of the material (slow dynamics).

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JO - Acta Acustica united with Acustica

JF - Acta Acustica united with Acustica

IS - 4

ER -

A finite-volume approach to 1D nonlinear elastic waves: Application to slow dynamics

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