Flow-regime transitions in fluidized beds of non-spherical particles 被引量：4

Flow-regime transitions in fluidized beds of non-spherical particles

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摘要 Fluidized beds frequently involve non-spherical particles, especially if biomass is present. For spheri- cal particles, numerous experimental investigations have been reported in the literature. In contrast, complex-shaped particles have received much less attention. There is a lack of understanding of how par- ticle shape influences flow-regime transitions. In this study, differently shaped Geldart group D particles are experimentally examined. Bed height, pressure drop, and their respective fluctuations are analyzed. With increasing deviation of particle shape from spheres, differences in flow-regime transitions occur with a tendency for the bed to form channels instead of undergoing smooth fluidization. The correlations available in the literature for spherical particles are limited in their applicability when used to predict regime changes for complex-shaped particles. Hence, based on existing correlations, improvements are derived. Fluidized beds frequently involve non-spherical particles, especially if biomass is present. For spheri- cal particles, numerous experimental investigations have been reported in the literature. In contrast, complex-shaped particles have received much less attention. There is a lack of understanding of how par- ticle shape influences flow-regime transitions. In this study, differently shaped Geldart group D particles are experimentally examined. Bed height, pressure drop, and their respective fluctuations are analyzed. With increasing deviation of particle shape from spheres, differences in flow-regime transitions occur with a tendency for the bed to form channels instead of undergoing smooth fluidization. The correlations available in the literature for spherical particles are limited in their applicability when used to predict regime changes for complex-shaped particles. Hence, based on existing correlations, improvements are derived.

作者 H. Kruggel-Emden K. Vollmari

机构地区 Ruhr-Universitaet Bochum

出处《Particuology》 SCIE EI CAS CSCD 2016年第6期1-15,共15页 颗粒学报（英文版）

关键词 Fluidized bed Flow regimes Non-spherical particles Pressure drop and fluctuations Bed height Fluidized bed Flow regimes Non-spherical particles Pressure drop and fluctuations Bed height

分类号 TQ051.13 [化学工程] O357 [理学—流体力学]

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