CFD Simulation of Different Flow Regimes of the Spout Fluidized Bed with Draft Plates

Bruna Sene Alves Araújo; Kássia Graciele dos Santos

doi:10.4028/www.scientific.net/MSF.899.89

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HomeMaterials Science ForumMaterials Science Forum Vol. 899CFD Simulation of Different Flow Regimes of the...

CFD Simulation of Different Flow Regimes of the Spout Fluidized Bed with Draft Plates

Abstract:

Spout fluidized bed has shown promising for gas-solid contact operations with and without chemical reactions, such as drying, coating, granulation, gasification, pyrolysis, etc. This is because these beds combine features from both spouted and fluidized beds. The other point is the ability to treat chemical transformations involving both heat and mass transfer in combination with particles of various sizes. Therefore, it is extremely important the knowledge of fluid dynamic of the bed, mainly for scale-up projects, which makes computer simulation an essential tool. Researches using the Computation Fluid Dynamics (CFD) proved to be very effective in predicting of particles dynamic in this type of bed. In Computation Fluid Dynamics, the two phases are treated as interpenetration continuous, and these phases are described by equations of conservation of mass, momentum and energy. The goal of the present work was to simulate using CFD experimental fluid dynamics data of a spout fluidized bed. Eight distinct flow regimes were identified which showed up in good agreement with the regime map presented in literature. The results showed that the technique was efficient for the simulation of the hydrodynamic of the bed presented.

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Periodical:

Materials Science Forum (Volume 899)

Pages:

89-94

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.899.89

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Online since:

July 2017

Authors:

Bruna Sene Alves Araújo*, Kássia Graciele dos Santos

Keywords:

Computational Fluid Dynamics (CFD), Dratf Tube, Fluidization, Regime Flow Map, Spouting

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References

[1] V.S. Sutkar, N.G. Deen, J.A.M. Kuipers: Chem. Eng. Sci. Vol. 86 (2013), p.124.

Google Scholar

[2] A. Chatterjee: Ind. Eng. Chem. Process Des. Dev. Vol. 9 (1970), p.340.

Google Scholar

[3] J.M. Link, L.A. Cuypers, N.G. Deen, J.A.M. Kuipers: Chem. Eng. Sci. Vol. 60 (2005), p.3425.

Google Scholar

[4] V.S. Sutkar, N.G. Deen, J.A.M., V. Salikov, S. Antonyuk, S. Heinrich, J.A.M. Kuipers: Powder Tech. 270 (2015), p.537.

DOI: 10.1016/j.powtec.2013.11.030

Google Scholar

[5] H. Nagashima, Y. Kawashiri, K. Suzukawa, T. Ishikura: Procedia Eng. Vol. 102 (2015), p.952.

Google Scholar

[6] S.H. Hosseini, M. Zivdan, R. Rahimi: Eng. Process Vol. 48 (2009), p.1539.

Google Scholar

[7] K.G. Santos, V.V. Murata, M.A.S. Barrozo: Can. J. Chem. Eng. Vol. 87 (2009), p.211.

Google Scholar

[8] D. Gidaspow, R. Bezbaruah, J. Ding, Hydrodynamics of Circulating Fluidized Beds: Kinetic Theory Approach, In: Proc. of the 7th Engineering Foundation Conference on Fluidization, 1992. pp.75-82.

Google Scholar

[9] C.K.K. Lun, S.B. Aavage, D. J. Jeffrey, N. Chepurniy: J. Fluid Mech, Vol 140 (1984) 223-256.

Google Scholar