Modeling the hydrodynamics of cocurrent gas–solid downers according to energy-minimization multi-scale theory_中国颗粒学会

Modeling the hydrodynamics of cocurrent gas–solid downers according to energy-minimization multi-scale theory_中国颗粒学会

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Partic. vol. 29 pp. 110-119 (December 2016)
doi: 10.1016/j.partic.2016.01.011

Modeling the hydrodynamics of cocurrent gas–solid downers according to energy-minimization multi-scale theory

Zhixin Zhang^{a, b}, Shanwei Hu^a, Xinhua Liu^{a, *}, Hui Zhao^b

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xhliu@ipe.ac.cn

Highlights

• The EMMS theory was adopted to model concurrent downward gas–solid flow. • Multiscale interphase interactions were explicitly considered in the model formulation. • A unified stability condition was proposed for concurrent downward gas–solid flow. • The model was solved without introducing cluster-specific empirical correlations.

Abstract

Cocurrent gas–solid downer reactors have many applications in industry because they possess the technological advantages of a lower pressure drop, shorter residence time, and less solid backmixing when compared with traditional circulating fluidized bed risers. By introducing the concept of particle clusters explicitly, a one-dimensional model with consideration of the interphase interactions between the fluid and particles at both microscale and mesoscale is formulated for concurrent downward gas–solid flow according to energy-minimization multi-scale (EMMS) theory. A unified stability condition is proposed for the differently developed sections of gas–solid flow according to the principle of the compromise in competition between dominant mechanisms. By optimizing the number density of particle clusters with respect to the stability condition, the formulated model can be numerically solved without introducing cluster-specific empirical correlations. The EMMS-based model predicts well the axial hydrodynamics of cocurrent gas–solid downers and is expected to have a wider range of applications than the existing cluster-based models.

Graphical abstract

Keywords

Mathematical modeling; Hydrodynamics; Fluidization; Downer; Cluster; Multiscale