Coupling of stabilized total Lagrangian and weakly compressible SPH models for challenging fluid–elastic structure interaction problems

Coupling of stabilized total Lagrangian and weakly compressible SPH models for challenging fluid–elastic structure interaction problems

A numerical model based on the total Lagrangian (TL) and weakly compressible (WC) smoothed particle hydrodynamics (SPH) coupling is developed for complex hydroelastic FSI problems. In this coupling scheme, the fluid phase is based on the WCSPH formulation improved by a numerical diffusion term. A TL...

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Bibliographic Details
Published in:Computational particle mechanics 2023-11, Vol.10 (6), p.1811-1825
Main Authors: Yilmaz, Ada, Kocaman, Selahattin, Demirci, Mustafa
Format: Article
Language:eng
Subjects:
Cantilever members
Cantilever plates
Classical and Continuum Physics
Compressibility
Computational Science and Engineering
Constitutive models
Coupling
Deformation effects
Elastic deformation
Elastic plates
Engineering
Formability
Free vibration
Mathematical models
Numerical models
Smooth particle hydrodynamics
Solid phases
Stress distribution
Theoretical and Applied Mechanics
Time integration
Water circulation
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Summary:A numerical model based on the total Lagrangian (TL) and weakly compressible (WC) smoothed particle hydrodynamics (SPH) coupling is developed for complex hydroelastic FSI problems. In this coupling scheme, the fluid phase is based on the WCSPH formulation improved by a numerical diffusion term. A TLSPH framework, stabilized by the hourglass control scheme and artificial viscous force, is employed for the solid phase, based on a linear-elastic constitutive model. The proposed model is verified using a variety of benchmark tests involving the free oscillation of a cantilever plate, the hydrostatic water column on an elastic plate, and dam-break flows interacting with deformable solid domains. In addition, the effect of time integration on the solution accuracy of the proposed model is investigated using two different time-integration schemes in the literature with/without a predictor–corrector stage required for multiple calculations in each time step. Comparisons indicate that the proposed model computations obtained with both time-integration schemes have a reasonable agreement with experimental and other numerical model results and provide smooth pressure/stress fields without numerical instability thanks to special treatments. Although numerical computations obtained with both of the time-integration schemes are generally quite similar, it is observed that the time-integration scheme with a predictor–corrector stage provides higher stability in specific cases.
ISSN:2196-4378
2196-4386