Adaptive finite volume-particle method for free surface flows

TL;DR

This paper introduces an adaptive hybrid finite volume-particle method combining Eulerian and Lagrangian approaches for improved free surface flow simulation accuracy and efficiency.

Contribution

It presents a novel adaptive framework with seamless mesh-particle conversion and buffer algorithms, enhancing free surface tracking and computational performance.

Findings

Achieves higher accuracy than pure SPH methods.

Demonstrates improved computational efficiency.

Successfully models complex free surface phenomena.

Abstract

This study proposes a novel adaptive finite volume-particle method (AFVPM) for accurate and efficient free surface flow simulations. The proposed AFVPM synergistically combines the Eulerian finite volume method (FVM) on unstructured meshes with the Lagrangian smoothed particle hydrodynamics (SPH) approach. Specifically, the mesh-based FVM is employed in the bulk flow regions to leverage its computational efficiency and numerical accuracy, while a weakly compressible SPH formulation is applied in the vicinity of the interface to maintain robust free-surface tracking capabilities. A key innovation of this framework is a block-based dynamic and adaptive conversion strategy between Eulerian mesh regions and Lagrangian particle regions and a buffer region-based cell-particle algorithm is designed to ensure seamless data communication across the Eulerian mesh-Lagrangian particle interface. Furthermore, isothermal gas-kinetic scheme (GKS) incorporating gravitational effects is utilized to calculate the fluxes in the mesh regions. The performance and reliability of the proposed AFVPM are validated through a series of benchmark cases that involve complex free surface phenomena. Numerical results demonstrate that AFVPM achieves superior accuracy and efficiency compared to full SPH approaches.