Numerical study of multiphase mixing of micron sized aggregates in opposed jets fluidized bed

Farid MU, Unger L, dos Santos DA, Bück A (2026)

Publication Type: Journal article

Publication year: 2026

Journal

Chemical Engineering Research & Design Elsevier

Book Volume: 227

Pages Range: 223-233

DOI: 10.1016/j.cherd.2026.01.056

Abstract

Fine aggregates are considered as essential elements in the production of a wide range of food, pharmaceutical as well as other chemical products. In process industry, mixing of such particles is a crucial operation which controls the quality, texture and attributes of the final product. However, mixing becomes quite challenging while dealing with cohesive particles because of strong inter particulate forces, mostly van der Waals or capillary forces. A strong external force is required to overcome the cohesive forces and eventually, to agitate and mix such aggregates. With several advantages, mixing of such aggregates can be carried out in gas phase regime using fluidized bed systems. However, gas-solid environment yields to turbulence multiphase flow dynamics which needs to be investigated for optimum performance. In the current study, a two-way coupled Euler-Lagrange CFD model has been developed for the investigation of hydrodynamics and mixing of multiphase flows in an opposed jets fluidized bed. In total two phases were selected including air as a gas phase whereas TiO2 was considered as the solid phase. Particles were placed in the domain at known quantity and different streams of air jet were injected with the help of three nozzles mounted in the bottom and side walls of the apparatus. As a result, fluid dynamically different zones were formed such as stressing zone and mixing zone. Increasing air flow rate, the suspension and mixing of particles is improved. However, very high air injections results in formation of wall bounded layer of particles which negatively effects the mixing. High particle concentration was found near the wall in case of air flow rate injected at a flow rate of 0.003 kg/s. Further investigations are planned in order to further explore effect of dynamic classifier, particle size distribution and mass loading.

Authors with CRIS profile

Laura Unger Professur für Partikeltechnik

Involved external institutions

Otto-von-Guericke-Universität Magdeburg DE Germany (DE) UFG - Universidade Federal de Goiás BR Brazil (BR)

How to cite

APA:

Farid, M.U., Unger, L., dos Santos, D.A., & Bück, A. (2026). Numerical study of multiphase mixing of micron sized aggregates in opposed jets fluidized bed. Chemical Engineering Research & Design, 227, 223-233. https://doi.org/10.1016/j.cherd.2026.01.056

MLA:

Farid, Muhammad Usman, et al. "Numerical study of multiphase mixing of micron sized aggregates in opposed jets fluidized bed." Chemical Engineering Research & Design 227 (2026): 223-233.

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