Numerical and experimental analysis of influence of granule microstructure on its compression breakage

This contribution analyses how the distribution of components within granules, i.e., the granule microstructure, relates to the breakage characteristics of the final product. Granules produced from glass ballotini with a PVP binder by different formation techniques were characterized using X-ray com...

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Bibliographic Details
Published in:Powder technology 2016-10, Vol.299, p.87-97
Main Authors: Dosta, Maksym, Dale, Steven, Antonyuk, Sergiy, Wassgren, Carl, Heinrich, Stefan, Litster, James D.
Format: Article
Language:English
Subjects:
Breakage
Compression
Discrete element method
Granules
Microtomography
Simulation
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Summary:This contribution analyses how the distribution of components within granules, i.e., the granule microstructure, relates to the breakage characteristics of the final product. Granules produced from glass ballotini with a PVP binder by different formation techniques were characterized using X-ray computer microtomography (XRμT) to obtain the particle, binder, and pore distributions within the granules. The deformation and breakage behavior of granules were then obtained using single granule uniaxial compression tests. To better understand the influence of the particle level interactions and granule microstructure influence on their deformation and breakage, discrete element method (DEM) simulations have been performed using the in-house-developed simulation framework MUSEN Dosta et al. (2013) . The granules were generated in a DEM model as a set of primary particles connected with solid bridge bonds. The XRμT measurements were used to reproduce the granule size, shape, and internal microstructure of experimental produced granules. In this way, the force-displacement curves were obtained with DEM using realistic granule microstructures. The range of predicted granule strengths overlapped with the range of experimental measurements in most instances. The simulations were also used to demonstrate that granules with increase binder concentration toward the perimeter of the granule tend to have greater attrition resistance while increasing binder concentration at the core are more resistant to fragmentation. Development of this simulation tool will allow investigators to estimate the stability and predict optimal granule structure. [Display omitted] •Granules of two different types were produced using static and fluidized bed.•Bonded-particle model was reconstructed from microtomography data.•Deformation and breakage behavior was numerically and experimentally analyzed.•Influence of the spatial binder distribution on the granule strength was investigated.
ISSN:0032-5910
1873-328X
DOI:10.1016/j.powtec.2016.05.005