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Title: Dispersion of clusters of nanoscale silica particles using batch rotor-stators
Authors: Kamaly, Shah W.
Tarleton, Alan C.
Ozcan-Taskin, N. Gul
Keywords: Nanoparticle dispersion
Fragmentation
Breakup
Rotor-stator
Deagglomeration
Aerosil 200 V
Issue Date: 2017
Publisher: Elsevier and The Society of Powder Technology Japan © The Society of Powder Technology Japan
Citation: KAMALY, S.W., TARLETON, A.C. and OZCAN-TASKIN, N.G., 2017. Dispersion of clusters of nanoscale silica particles using batch rotor-stators. Advanced Powder Technology, 28 (9), pp. 2357-2365.
Abstract: Nanoparticle powders added into a liquid medium form structures which are much larger than the primary particle size (aggregates and agglomerates)-typically of the order of 10’s of microns. An important process step is therefore the deagglomeration of these clusters to achieve as fine a dispersion as possible. This paper reports the findings of a study on the dispersion of hydrophilic fumed silica nanoparticle clusters, Aerosil 200 V, in water using two batch rotor-stators: MICCRA D-9 and VMI. The MICCRA D-9 head consists of a set of teeth for the stator and another for the rotor, whereas the VMI has a stator with slots and a rotor which consists of a 4-bladed impeller attached to an outer set of teeth. The dispersion process, studied at different power input values and over a range of concentrations (1, 5, 10 wt.%), was monitored through the evolution of PSD. Erosion was found to be the dominant breakage mechanism irrespective of operating conditions or rotor-stator type. The smallest attainable size was also found to be independent of the power input or the design of the rotor-stator. Break up kinetics increased upon the increase of power input, and this also depended on the rotor-stator design. With MICCRA D-9 which has smaller openings on both the stator and rotor, the break up rate was faster. Increasing the particle concentration decreased break up kinetics. It could also be shown that operating at high concentrations can still be beneficial as the break up rate is higher when assessed on the basis of specific power input per mass of solids.
Description: This paper is closed access until 3rd July 2018.
Version: Accepted for publication
DOI: 10.1016/j.apt.2017.06.017
URI: https://dspace.lboro.ac.uk/2134/25901
Publisher Link: http://dx.doi.org/10.1016/j.apt.2017.06.017
ISSN: 0921-8831
Appears in Collections:Closed Access (Chemical Engineering)

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