This paper proposes the use of a generalized finite difference method for the numerical simulation of free surface single phase flows during mould filling process which are common in some industrial processes particularly in the area of metal casting. A novel and efficient idea for the computation of the normal vectors for free surface flows is introduced and presented for the first time. The incompressible Navier–Stokes equations are numerically solved by the well-known Chorin's projection method. After we showed the main ideas behind the meshless approach, some numerical results in two and three dimensions are presented corresponding to mould filling process simulation
Numerical simulation of mold filling in low pressure die casting is considered in this study. The ph...
In this work it is studied and analyzed the possible advantages to simulate the mold filling process...
Simulation of mould filling in high pressure die casting has been an attractive area of research for...
The aim of this work is to achieve a meshfree implementation for the numerical prediction of 3D flow...
In this paper we consider several aspects related to the application of the pseudo‐concentration tec...
Modern casting processes allow the precise production of parts with complex shapes. Especially mold ...
A finite element based, explicit, time-marching scheme is developed for the analysis of three-dimens...
The simulation of low Froude number mould filling problems on fixed meshes presents significant diff...
The aim of this work was to extend numerical model of mould filling phenomena previously presented...
This paper presents a simulation procedure for the mould-filling processes in which a field-analysis...
Mould filling processes, in which a material flow front advances through a mould, are typical exampl...
International audienceThe Navier-Stokes incompressible model is used to describe two-dimensional met...
In the casting of metals, tundish flow, welding, converters, and other metal processing applications...
Accurate representation of the coupled effects between turbulent fluid flow with a free surface, hea...
AbstractBased on finite element theory, using FLUENT software and three-dimensional model to simulat...
Numerical simulation of mold filling in low pressure die casting is considered in this study. The ph...
In this work it is studied and analyzed the possible advantages to simulate the mold filling process...
Simulation of mould filling in high pressure die casting has been an attractive area of research for...
The aim of this work is to achieve a meshfree implementation for the numerical prediction of 3D flow...
In this paper we consider several aspects related to the application of the pseudo‐concentration tec...
Modern casting processes allow the precise production of parts with complex shapes. Especially mold ...
A finite element based, explicit, time-marching scheme is developed for the analysis of three-dimens...
The simulation of low Froude number mould filling problems on fixed meshes presents significant diff...
The aim of this work was to extend numerical model of mould filling phenomena previously presented...
This paper presents a simulation procedure for the mould-filling processes in which a field-analysis...
Mould filling processes, in which a material flow front advances through a mould, are typical exampl...
International audienceThe Navier-Stokes incompressible model is used to describe two-dimensional met...
In the casting of metals, tundish flow, welding, converters, and other metal processing applications...
Accurate representation of the coupled effects between turbulent fluid flow with a free surface, hea...
AbstractBased on finite element theory, using FLUENT software and three-dimensional model to simulat...
Numerical simulation of mold filling in low pressure die casting is considered in this study. The ph...
In this work it is studied and analyzed the possible advantages to simulate the mold filling process...
Simulation of mould filling in high pressure die casting has been an attractive area of research for...