A particle-based method using the mesh-constrained discrete point approach for two-dimensional Stokes flows

• Published in: Mechanical Engineering Journal Vol. 9; no. 5; p. 22-00204
• Main Authors: MATSUDA, Takeharu, TSUKUI, Kohsuke, II, Satoshi
• Format: Journal Article
• Language: English
• Published: The Japan Society of Mechanical Engineers 2022
• Subjects: Cartesian grids; Continuum mechanics; Least-squares approximation; Mesh constrained approach; Meshless particle method; Stokes flow
• ISSN: 2187-9745; 2187-9745
• DOI: 10.1299/mej.22-00204

Meshless methods inherently do not require mesh topologies and are practically used for solving partial differential equations in continuum mechanics. However, these methods generally tend to have a higher computational load than conventional mesh-based methods because calculation stencils for spatial discretization become large. In this study, a novel approach for the use of compact stencils in meshless methods is proposed, called the mesh-constrained discrete point (MCD) approach. The MCD approach introduces a Cartesian mesh system to the background of a domain. And the approach rigorously constrains the distribution of discrete points (DPs) in each mesh by solving a dynamic problem with nonlinear constraints. This can avoid the heterogeneity of the DP distribution at the mesh-size level and impose compact stencils with a fixed degree of freedom for derivative evaluations. A fundamental formulation for arrangements of DPs and an application to unsteady Stokes flows are presented in this paper. Numerical tests were performed for the distribution of DPs and flow problems in co-axial and eccentric circular channels. The proposed MCD approach achieved a reasonable distribution of DPs independently of the spatial resolution with a few iterations in pre-processing. Additionally, solutions using the obtained DP distributions in Stokes flow problems were in good agreement with theoretical and reference solutions. The results also confirmed that the numerical accuracies of velocity and pressure achieved the expected convergence order, even when compact stencils were used.