Universiti Teknologi Malaysia Institutional Repository

Effect of voidage on the collapsing bed dynamics of fine particles: a detailed region-wise study

Ali, Syed Sadiq and Arsad, Agus and Roberts, Kenneth L. and Mohammad Asif, Mohammad Asif (2022) Effect of voidage on the collapsing bed dynamics of fine particles: a detailed region-wise study. Nanomaterials, 12 (12). pp. 1-21. ISSN 2079-4991

[img] PDF
1MB

Official URL: http://dx.doi.org/10.3390/nano12122019

Abstract

Bed collapse experiments provide vital information about fluidized bed hydrodynamics. In this study, the region-wise bed collapse dynamics of glass beads, titania (TiO2), and hydrophilic nanosilica (SiO2) particles with widely different voidages (ε) of 0.38, 0.80, and 0.98, respectively, were carefully investigated. These particles belonged to different Geldart groups and exhibited varied hysteresis phenomena and fluidization indices. The local collapse dynamics in the lower, lower-middle, upper-middle, and upper regions were carefully monitored in addition to the distributor pressure drop to obtain greater insight into the deaeration behavior of the bed. While the collapse dynamics of glass beads revealed high bed homogeneity, the upper middle region controlled the collapse process in the case of titania due to the size-based segregation along the bed height. The segregation behavior was very strong for nanosilica, with the slow settling fine agglomerates in the upper bed regions controlling its collapse dynamics. The collapse time of the upper region was 25 times slower than that of the lower region containing mainly large agglomerates. The spectral analysis confirmed the trend that was observed in the pressure transients. The clear presence of high frequency events at 20 and 40 Hz was observed in the nanosilica due to agglomerate movements. The residual air exiting the plenum was strongly affected by the bed voidage, being lowest for the nanosilica and highest for the glass beads.

Item Type:Article
Uncontrolled Keywords:bed voidage, collapse bed, fluidization, hydrodynamics, nanosilica, purge flow
Subjects:Q Science > Q Science (General)
T Technology > TP Chemical technology
Divisions:Chemical and Energy Engineering
ID Code:103348
Deposited By: Yanti Mohd Shah
Deposited On:01 Nov 2023 09:15
Last Modified:01 Nov 2023 09:15

Repository Staff Only: item control page