Development of a discrete element model with moving realistic geometry to simulate particle motion in a Mi-Pro granulator

N.j. Watson; M.j.w. Povey; G.k. Reynolds; Y. Ding; B.h. Xu

doi:10.1016/j.compchemeng.2016.06.021

Development of a discrete element model with moving realistic geometry to simulate particle motion in a Mi-Pro granulator

N.j. Watson
, M.j.w. Povey
, G.k. Reynolds
, Y. Ding
, B.h. Xu

Research output: Contribution to journal › Article › peer-review

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Abstract

This paper presents the implementation of a methodology incorporating a 3D CAD geometry into a 3D discrete element method (DEM) code; discussing some of the issues which were experienced. The 3D CAD model was discretised into a finite element mesh and the finite wall method was employed for contact detection between the elements and the spherical particles. The geometry was based on a lab scale Mi-Pro granulator. Simulations were performed to represent dry particle motion in this piece of equipment. The model was validated by high speed photography of the particle motion at the surface of the Mi-Pro's clear bowl walls. The results indicated that the particle motion was dominated by the high speed impeller and that a roping regime exists. The results from this work give a greater insight into the particle motion and can be used to understand the complex interactions which occur within this equipment.

Original language	English
Pages (from-to)	234-247
Journal	Computers & Chemical Engineering
Volume	93
Early online date	1 Jul 2016
DOIs	https://doi.org/10.1016/j.compchemeng.2016.06.021
Publication status	Published - 4 Oct 2016

Keywords

Discrete element method
High shear mixers
Particle velocity field
Contact detection
Moving boundary

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10.1016/j.compchemeng.2016.06.021

Watson_et_al_Development_of_a_discrete_Computers_and_Chemical_Engineering_2016
Checked 8/9/2016
Accepted author manuscript, 1.49 MBLicence: Creative Commons: Attribution-NonCommercial-NoDerivs (CC BY-NC-ND)

Cite this

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title = "Development of a discrete element model with moving realistic geometry to simulate particle motion in a Mi-Pro granulator",

abstract = "This paper presents the implementation of a methodology incorporating a 3D CAD geometry into a 3D discrete element method (DEM) code; discussing some of the issues which were experienced. The 3D CAD model was discretised into a finite element mesh and the finite wall method was employed for contact detection between the elements and the spherical particles. The geometry was based on a lab scale Mi-Pro granulator. Simulations were performed to represent dry particle motion in this piece of equipment. The model was validated by high speed photography of the particle motion at the surface of the Mi-Pro's clear bowl walls. The results indicated that the particle motion was dominated by the high speed impeller and that a roping regime exists. The results from this work give a greater insight into the particle motion and can be used to understand the complex interactions which occur within this equipment.",

keywords = "Discrete element method, High shear mixers, Particle velocity field, Contact detection, Moving boundary",

author = "N.j. Watson and M.j.w. Povey and G.k. Reynolds and Y. Ding and B.h. Xu",

year = "2016",

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doi = "10.1016/j.compchemeng.2016.06.021",

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T1 - Development of a discrete element model with moving realistic geometry to simulate particle motion in a Mi-Pro granulator

AU - Watson, N.j.

AU - Povey, M.j.w.

AU - Reynolds, G.k.

AU - Ding, Y.

AU - Xu, B.h.

PY - 2016/10/4

Y1 - 2016/10/4

N2 - This paper presents the implementation of a methodology incorporating a 3D CAD geometry into a 3D discrete element method (DEM) code; discussing some of the issues which were experienced. The 3D CAD model was discretised into a finite element mesh and the finite wall method was employed for contact detection between the elements and the spherical particles. The geometry was based on a lab scale Mi-Pro granulator. Simulations were performed to represent dry particle motion in this piece of equipment. The model was validated by high speed photography of the particle motion at the surface of the Mi-Pro's clear bowl walls. The results indicated that the particle motion was dominated by the high speed impeller and that a roping regime exists. The results from this work give a greater insight into the particle motion and can be used to understand the complex interactions which occur within this equipment.

AB - This paper presents the implementation of a methodology incorporating a 3D CAD geometry into a 3D discrete element method (DEM) code; discussing some of the issues which were experienced. The 3D CAD model was discretised into a finite element mesh and the finite wall method was employed for contact detection between the elements and the spherical particles. The geometry was based on a lab scale Mi-Pro granulator. Simulations were performed to represent dry particle motion in this piece of equipment. The model was validated by high speed photography of the particle motion at the surface of the Mi-Pro's clear bowl walls. The results indicated that the particle motion was dominated by the high speed impeller and that a roping regime exists. The results from this work give a greater insight into the particle motion and can be used to understand the complex interactions which occur within this equipment.

KW - Discrete element method

KW - High shear mixers

KW - Particle velocity field

KW - Contact detection

KW - Moving boundary

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DO - 10.1016/j.compchemeng.2016.06.021

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EP - 247

JO - Computers & Chemical Engineering

JF - Computers & Chemical Engineering

ER -

Development of a discrete element model with moving realistic geometry to simulate particle motion in a Mi-Pro granulator

Abstract

Keywords

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