Extending incompressible SPH framework for simulation of axisymmetric free-surface flows
From MaRDI portal
Publication:1656250
DOI10.1016/J.ENGANABOUND.2017.07.026zbMath1403.76171OpenAlexW2751676096MaRDI QIDQ1656250
Gourabananda Pahar, Md Rushdie Ibne Islam, Anirban Dhar
Publication date: 10 August 2018
Published in: Engineering Analysis with Boundary Elements (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1016/j.enganabound.2017.07.026
Particle methods and lattice-gas methods (76M28) Probabilistic methods, particle methods, etc. for initial value and initial-boundary value problems involving PDEs (65M75)
Related Items (2)
An accurate SPH volume adaptive scheme for modeling strongly-compressible multiphase flows. II: Extension of the scheme to cylindrical coordinates and simulations of 3D axisymmetric problems with experimental validations ⋮ Axisymmetric free-surface flow simulation using the moving surface mesh particle method and application to drop formation
Cites Work
- Unnamed Item
- \(\delta \)-SPH model for simulating violent impact flows
- Accuracy and stability in incompressible SPH (ISPH) based on the projection method and a new approach
- Comparisons of weakly compressible and truly incompressible algorithms for the SPH mesh free particle method
- An SPH projection method
- Cylindrical smoothed particle hydrodynamics
- Simulating 2D open-channel flows through an SPH model
- Variational and momentum preservation aspects of smooth particle hydrodynamic formulations
- Incompressible SPH for free surface flows
- Numerical simulation of column charge underwater explosion based on SPH and BEM combination
- Modified smoothed particle hydrodynamics (MSPH) basis functions for meshless methods, and their application to axisymmetric Taylor impact test
- SPH in spherical and cylindrical coordinates
- Dynamic flow-based particle splitting in smoothed particle hydrodynamics
- A simple SPH algorithm for multi‐fluid flow with high density ratios
This page was built for publication: Extending incompressible SPH framework for simulation of axisymmetric free-surface flows
