Three-dimensional simulation of a solid-liquid flow by the DEM-SPH method
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- 作者:Xiaosong Suna ; song@dem.t.u-tokyo.ac.jp ; Mikio Sakaib ; mikio_sakai@n.t.u-tokyo.ac.jp ; Yoshinori Yamadaa
- 关键词:Solid&ndash ; liquid flow ; Two-phase flow ; Fluid&ndash ; particle interaction ; Discrete element method ; Smoothed particle hydrodynamics ; Wall boundary conditions
- 刊名:Journal of Computational Physics
- 出版年:2013
- 出版时间:1 September, 2013
- 年:2013
- 卷:248
- 期:Complete
- 页码:147-176
- 全文大小:4278 K
文摘
In this paper, we describe a new Lagrangian-Lagrangian algorithm, which is referred to be the DEM-SPH method, for solid-liquid flows involving free surfaces. The DEM solid phase and the SPH liquid phase are coupled using the local averaging technique described by Lagrangian approaches, where both the continuity equation and the interaction force, i.e. drag force, are connected with the local mean voidage. Conservative forms of momentum transformation are derived for the DEM-SPH interaction via a variational approach. By introducing a correction to the SPH approximation with explicit inclusion of boundary information, arbitrary boundaries can be modeled without any extra wall particles, where the boundary is used commonly for both DEM and SPH phases. We deploy level-set distance functions to efficiently construct and evaluate this boundary model. To examine the validity of the present method, we perform three-dimensional simulations of a dynamic flow in a solid-liquid dam break and a quasi-steady flow in a rotating cylindrical tank; and we conduct validation experiments to justify the simulation results. In the dam-break problem, positions of wave fronts during the collapse are computed and compared with experimental measurements; for the circulating tank, some macroscopic aspects of the steady flow, e.g. the shape, dimension and velocity profile of the solid bed, are obtained for validation data. In both cases, the simulation results are in good agreement with those of the experiment. Consequently, the DEM-SPH method is proved to be adequate in modeling solid-liquid flows through this study.