Damien Violeau scite author profile

International audienceWall boundary conditions in smoothed particle hydrodynamics (SPH) is a key issue to perform accurate simulations. We propose here a new approach based on a renormalising factor for writing all boundary terms. This factor depends on the local shape of a wall and on the position of a particle relative to the wall, which is described by segments (in two-dimensions), instead of the cumbersome fictitious or ghost particles used in most existing SPH models. By solving a dynamic equation for the renormalising factor, we significantly improve traditional wall treatment in SPH, for pressure forces, wall friction and turbulent conditions. The new model is demonstrated for cases including hydrostatic conditions for still water in a tank of complex geometry and a dam break over triangular bed profile with sharp angle where significant improved behaviour is obtained in comparison with the conventional boundary techniques. The latter case is also compared with a finite volume and volume-of-fluid scheme. The performance of the model for a two-dimensional laminar flow in a channel is demonstrated where the profiles of velocity are in agreement with the theoretical ones, demonstrating that the derived wall shear stress balances the pressure gradient. Finally, the performance of the model is demonstrated for flow in a schematic fish pass where both the velocity field and turbulent viscosity fields are satisfactorily reproduced compared with mesh-based codes

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Fluid Mechanics and the SPH Method

Violeau¹

2012

211

156

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Smoothed particle hydrodynamics (SPH) for free-surface flows: past, present and future

Violeau

Rogers

2016

Journal of Hydraulic Research

392

149

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Numerical modelling of complex turbulent free‐surface flows with the SPH method: an overview

Violeau¹,

Issa²

2006

Numerical Methods in Fluids

225

137

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SUMMARYThe gridless smoothed particle hydrodynamics (SPH) method is now commonly used in computational fluid dynamics (CFD) and appears to be promising in predicting complex free-surface flows. However, increasing flow complexity requires appropriate approaches for taking account of turbulent effects, whereas some authors are still working without any turbulence closure in SPH. A review of recently developed turbulence models adapted to the SPH method is presented herein, from the simplistic point of view of a one-equation model involving mixing length to more sophisticated (and thus realistic) models like explicit algebraic Reynolds stress models (EARSM) or large eddy simulation (LES). Each proposed model is tested and validated on the basis of schematic cases for which laboratory data, theoretical or numerical solutions are available in the general field of turbulent free-surface incompressible flows (e.g. open-channel flow and schematic dam break). They give satisfactory results, even though some progress should be made in the future in terms of free-surface influence and wall conditions. Recommendations are given to SPH users to apply this method to the modelling of complex free-surface turbulent flows.

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Damien Violeau

Comparisons of weakly compressible and truly incompressible algorithms for the SPH mesh free particle method

Unified semi‐analytical wall boundary conditions for inviscid, laminar or turbulent flows in the meshless SPH method

Fluid Mechanics and the SPH Method

Smoothed particle hydrodynamics (SPH) for free-surface flows: past, present and future

Numerical modelling of complex turbulent free‐surface flows with the SPH method: an overview

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