Is media shape important for grinding performance in stirred mills?

This study investigates how the shape of grinding media in stirred mills influences grinding performance. Specifically transport properties, stress distribution, energy dissipation and liner wear are all shown to be sensitive to media shape. [Display omitted] ► Media flow and energy use in a tower m...

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Bibliographic Details
Published in:Minerals engineering 2011-01, Vol.24 (2), p.138-151
Main Authors: Sinnott, Matthew D., Cleary, Paul W., Morrison, Rob D.
Format: Article
Language:English
Subjects:
Comminution
Discrete element method
Discrete Element Method (DEM)
Grinding
Mathematical models
Media
Mills
Reduction
Sand
Stirred mills
Towers
Transport
Walls
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Summary:This study investigates how the shape of grinding media in stirred mills influences grinding performance. Specifically transport properties, stress distribution, energy dissipation and liner wear are all shown to be sensitive to media shape. [Display omitted] ► Media flow and energy use in a tower mill depends on media shape from DEM simulations. ► Behaviour of blocky media is significantly different from that of spherical media. ► Blocky media - poor media and slurry transport; more dilation in grind zone; reduced active bed volume. ► Lower power draw for blocky media – high liner wear rate and reduced media collisional power. Models for understanding the basic concepts of fine grinding and how they apply to the design of stirred media mills have not yet matured. While spherical media in tower mills has previously been studied, real grinding media shape in stirred mills can range from spherical (steel/ceramic balls) to highly non-spherical (sand or slag) resulting in very different media and grinding dynamics. Handling the contact mechanics of non-spherical particles is a challenge for numerical models, and very few studies dealing with non-spherical particle shape exist in the literature. Discrete Element Method (DEM) simulations of dry media flow in a pilot-scale tower mill are performed for four cases with different shaped grinding media, in order to understand how flow and energy utilisation within a stirred mill depend on media shape. Differences in media transport, stress distribution, energy dissipation, and liner wear were observed in the tower mill for the spherical and non-spherical cases. A significant departure from sphericity of the media leads to strong dilation of the bed, reduced bulk density, and a reduction in active volume and collisional power levels leading to a reduction in power draw for the mill. In addition, highly non-spherical media tend to pack tightly near the mill walls forming a near solid layer around the inside of the mill shell which results in poorer transport and mixing, as well as increased wear rates on the screw impeller. Grinding performance in stirred mills appears to deteriorate strongly when using highly non-spherical media.
ISSN:0892-6875
1872-9444
DOI:10.1016/j.mineng.2010.10.016