November 22, 2024
Rouhollah Fatehi

Rouhollah Fatehi

Academic Rank: Associate professor
Address: School of Engineering
Degree: Ph.D in Mechanical Engineering
Phone: 07731222170
Faculty: Faculty of Engineering

Research

Title Density-based smoothed particle hydrodynamics methods for incompressible flows
Type Article
Keywords
Density-based approaches, Smoothed particle hydrodynamics (SPH), Incompressible flow, Preconditioned dual time-stepping method, Augmented Lagrangian method
Journal COMPUTERS & FLUIDS
DOI https://doi.org/10.1016/j.compfluid.2019.02.018
Researchers Rouhollah Fatehi (First researcher) , Amin Rhmat (Second researcher) , Nima Tofighi (Third researcher) , Mehmet Yildiz (Fourth researcher) , Mostafa Safdari Shadloo (Fifth researcher)

Abstract

In this study, we have introduced two new iterative density-based Smoothed Particle Hydrodynamics (SPH) methods to model incompressible flows, namely, preconditioned dual time-stepping, and augmented Lagrangian method. The performance of these new methods are compared with each other and also with a modified version of the well-known weakly compressible SPH (WC-SPH) method through solving three carefully chosen incompressible flow problems: a laminar incompressible channel flow over a backward-facing step, a 2D stiff pressure decay problem and Taylor-Green vortices flow. For the first test problem, the results are compared with available data in literature. Moreover, it is observed that the two iterative methods provide a better accuracy in terms of smoother pressure field and also smaller magnitude of the velocity divergence across the computational domain. In the second test problem, it is shown that the preconditioned dual time-stepping and the augmented Lagrangian SPH methods yield rather smooth pressure fields, and converge to the exact solution, while the pressure field computed by the WC-SPH method oscillates even after very long time. As for the third test case, the iterative methods are compared with WC-SPH method for different iteration numbers and particle resolutions.