Meshless Lagrangian SPH method applied to isothermal lid-driven cavity flow at low-Re numbers

Meshless Lagrangian SPH method applied to isothermal lid-driven cavity flow at low-Re numbers

SPH is a recent particle method applied in the cavities study, without many results available in the literature. The lid-driven cavity flow is a classic problem of the fluid mechanics, extensively explored in the literature and presenting a considerable complexity. The aim of this paper is to presen...

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Bibliographic Details
Published in:Computational particle mechanics Vol. 5; no. 4; pp. 467 - 475
Main Authors: Fraga Filho, C. A. D., Chacaltana, J. T. A., Pinto, W. J. N.
Format: Journal Article
Language:English
Published: Cham Springer International Publishing 01-10-2018
Springer Nature B.V
Subjects:
Cavity flow
Classical and Continuum Physics
Collocation methods
Computational fluid dynamics
Computational Science and Engineering
Computer simulation
Energy conservation
Engineering
Finite element method
Fluid flow
Fluid mechanics
FORTRAN
Mathematical analysis
Mathematical models
Meshless methods
Programming languages
Theoretical and Applied Mechanics
Velocity distribution
Navier–Stokes equations
Low Reynolds numbers
Incompressible Newtonian fluid
Physical laws of conservation
SPH particle method
Lid-driven cavity
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Summary:SPH is a recent particle method applied in the cavities study, without many results available in the literature. The lid-driven cavity flow is a classic problem of the fluid mechanics, extensively explored in the literature and presenting a considerable complexity. The aim of this paper is to present a solution from the Lagrangian viewpoint for this problem. The discretization of the continuum domain is performed using the Lagrangian particles. The physical laws of mass, momentum and energy conservation are presented by the Navier–Stokes equations. A serial numerical code, written in Fortran programming language, has been used to perform the numerical simulations. The application of the SPH and comparison with the literature (mesh methods and a meshless collocation method) have been done. The positions of the primary vortex centre and the non-dimensional velocity profiles passing through the geometric centre of the cavity have been analysed. The numerical Lagrangian results showed a good agreement when compared to the results found in the literature, specifically for Re < 100.00 . Suggestions for improvements in the SPH model presented are listed, in the search for better results for flows with higher Reynolds numbers.
ISSN:2196-4378
2196-4386
DOI:10.1007/s40571-018-0183-x