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在线阅读Partic. vol. 10 no. 2 pp. 229-235 (April 2012) doi: 10.1016/j.partic.2011.11.010
Modelling die filling with charged particles using DEM/CFD
Emmanuel Nkem Nwose, Chunlei Pei, Chuan-Yu Wu*
Highlights
Abstract
The effects of electrostatic charge on powder flow behaviour during die filling in a vacuum and in air were analysed using a coupled discrete element method and computational fluid dynamics (DEM/CFD) code, in which long range electrostatic interactions were implemented. The present 2D simulations revealed that both electrostatic charge and the presence of air can affect the powder flow behaviour during die filling. It was found that the electrostatic charge inhibited the flow of powders into the die and induced a loose packing structure. At the same filling speed, increasing the electrostatic charge led to a decrease in the fill ratio which quantifies the volumetric occupancy of powder in the die. In addition, increasing the shoe speed caused a further decrease in the fill ratio, which was characterised using the concept of critical filling speed. When the electrostatic charge was low, the air/particle interaction was strong so that a lower critical filling speed was obtained for die filling in air than in a vacuum. With high electrostatic charge, the electrostatic interactions became dominant. Consequently, similar fill ratio and critical filling speed were obtained for die filling in air and in a vacuum.
Graphical abstract
Formation of clusters during die filling with oppositely charged particles.
Keywords
DEM; CFD; Electrostatics; Die filling; Powder flow; Cohesion; Charged particles
c.y.wu@bham.ac.uk
