Discrete Particle Simulation Of Particulate Systems: A Review Of Major Applications And Findings

Author(s)
A.B. Yu, H.P. Zhu, R.Y. Yang, Z.Y. Zhou
Publisher
Elsevier
Source
Chemical Engineering Science
Keywords
Computational fluid dynamics, Discrete element method, Granular dynamics, Particle flow, particle packing, Particle–Fluid Flow
Year
2008

Understanding and modelling the dynamic behaviour of particulate systems has been a major research focus worldwide for many years. Discrete particle simulation plays an important role in this area. This technique can provide dynamic information, such as the trajectories of and transient forces acting on individual particles, which is difficult to obtain by the conventional experimental techniques. Consequently, it has been increasingly used by various investigators for different particulate processes. In spite of the large bulk volume, little effort has been made to comprehensively review and summarize the progress made in the past. To overcome this gap, we have recently completed a review of the major work in this area in two separate parts. The first part has been published [Zhu, H.P., Zhou, Z.Y., Yang, R.Y., Yu, A.B., 2007. Discrete particle simulation of particulate systems: theoretical developments. Chemical Engineering Science 62, 3378–3392.], which reviews the major theoretical developments. This paper is the second one, aiming to provide a summary of the studies based on discrete particle simulation in the past two decades or so. The studies are categorized into three subject areas: particle packing, particle flow, and particle–fluid flow. The major findings are discussed, with emphasis on the microdynamics including packing/flow structure and particle–particle, particle–fluid and particle–wall interaction forces. It is concluded that discrete particle simulation is an effective method for particle scale research of particulate matter. The needs for future research are also discussed.

Keywords: Discrete Element Method, Computational Fluid Dynamics, Particle Packing, Particle Flow, Particle–Fluid Flow, Granular Dynamics

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