A minimal potential energy model for predicting stratification pattern in binary and ternary solid-liquid fluidized beds

Predicting the stratification pattern of a binary or ternary solid-liquid fluidized bed requires not only the calculation of the volume fractions of particles in mixed and mono-component layers but also the specification of the order and the thickness of the layers in the bed. A model was developed...

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Veröffentlicht in:	Chemical engineering science 1996, Vol.51 (3), p.341-351
Hauptverfasser:	Funamizu, Naoyuki, Takakuwa, Tetsuo
Format:	Artikel
Sprache:	eng
Schlagworte:	Acrylics Activated carbon Applied sciences Calculations Chemical engineering Exact sciences and technology Fluidization Glass Mathematical models Mixtures Optimization Particles (particulate matter) Solid solutions Thermal stratification Thermodynamic stability Volume fraction
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container_title	Chemical engineering science
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creator	Funamizu, Naoyuki Takakuwa, Tetsuo
description	Predicting the stratification pattern of a binary or ternary solid-liquid fluidized bed requires not only the calculation of the volume fractions of particles in mixed and mono-component layers but also the specification of the order and the thickness of the layers in the bed. A model was developed for such prediction on the hypothesis that the total potential energy of particles in a bed is minimal. Experiments were carried out for a solid system consisting of glass beads, activated carbon and acrylic particles. The experimental results verified the predicted stratification patterns computed on the basis of the hypothesis adopted in this study.
doi_str_mv	10.1016/0009-2509(95)00282-0
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subjects	Acrylics Activated carbon Applied sciences Calculations Chemical engineering Exact sciences and technology Fluidization Glass Mathematical models Mixtures Optimization Particles (particulate matter) Solid solutions Thermal stratification Thermodynamic stability Volume fraction
title	A minimal potential energy model for predicting stratification pattern in binary and ternary solid-liquid fluidized beds
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