Korean Journal of Chemical Engineering, Vol.30, No.3, 761-770, 2013
CFD study of hydrodynamics behavior of a vibrating fluidized bed using kinetic-frictional stress model of granular flow
The hydrodynamics of a vertically vibrating fluidized bed was studied using an Eulerian-Eulerian twofluid model (TFM) incorporating the kinetic theory of granular flow and including the frictional stress effects. Influences of frictional stresses, vibration amplitudes and frequency on behavior of the particles were studied. In the case with vertical vibration, the numerical results showed three regions of solid concentration along the bed height: a low particle concentration region near the bottom of the bed, a high concentration region in the middle of the bed, and a transition region at top of the bed. The accuracy of results was found to be closely related to the inclusion of the frictional stresses. Ability of the two-fluid model for predicting the hydrodynamics of vibrating fluidized beds was discussed and confirmed.
[References]
Geldart D, Powder Technol. , 7 , 285, 1973
Mawatari Y, Koide T, Tatemoto Y, Takeshita T, Noda K, Adv. Powder Technol. , 12 (2), 157, 2001
Mawatari Y, Koide T, Tatemoto Y, Uchida S, Noda K, Powder Technol. , 123 , 69, 2001
Mori S, Yamamoto A, Iwata S, Haruta T, Yamada I, Mizutani E, AIChE Symp. Ser. , In: (2nd Ed.), 86 , 88, 1990
Wang Y, Wang TJ, Yang Y, Jin Y, Powder Technol. , 127 (3), 196, 2002
Luo ZF, Fan MM, Zhao YM, Tao XX, Chen QR, Chen ZQ, Powder Technol. , 187 (2), 119, 2008
Tai SC, Hsiau SS, Powder Technol. , 194 (3), 159, 2009
Xuejun Z, Shichao Y, Xiaoheng P, Exp. Therm. Fluid. Sci. , 32 , 1279, 2008
Naeini SE, Spelt JK, Powder Technol. , 195 (2), 83, 2009
Tatemoto Y, Mawatari Y, Noda K, Chem. Eng. Sci. , 60 (18), 5010, 2005
Tatemoto Y, Mawatari Y, Yasukawa T, Noda K, Chem. Eng. Sci. , 59 (2), 437, 2004
Mantle MD, Sederman AJ, Gladden LF, Huntley JM, Martin TW, Wildman RD, Shattuck MD, Powder Technol. , 179 (3), 164, 2008
Xuejun Z, Shichao Y, Xiaoheng P, Exp. Therm. Fluid. Sci. , 32 , 1279, 2008
Li X, Wang SY, Lu HL, Liu GD, Chen JH, Liu YK, Powder Technol. , 197 (1-2), 25, 2010
Ren B, Zhong WQ, Jin BS, Yuan ZL, Lu Y, Energy Fuels , 25 (9), 4095, 2011
Oevermann M, Gerber S, Behrendt F, Particuology. , 7 , 307, 2009
Zhao T, Takei M, Doh DH, Flow Meas. Instrum. , 21 , 212, 2010
Ibsen CH, Helland E, Hjertager BH, Solberg T, Tadrist L, Occelli R, Powder Technol. , 149 (1), 29, 2004
Deen NG, Annaland MV, Van der Hoef MA, Kuipers JAM, Chem. Eng. Sci. , 62 (1-2), 28, 2007
Passalacqua A, Marmo L, Chem. Eng. Sci. , 64 (12), 2795, 2009
Zhong WQ, Zhang MY, Jin BS, Yuan ZL, Powder Technol. , 175 (2), 90, 2007
Wang XF, Jin BS, Zhong WQ, Chem. Eng. Process. , 48 (2), 695, 2009
Wang JW, Ge W, Li JH, Chem. Eng. Sci. , 63 (6), 1553, 2008
Pei P, Zhang K, Ren J, Wen D, Wu G, Particuology. , 8 , 425, 2010
Vun S, Naser J, Witt P, Powder Technol. , 204 (1), 11, 2010
Lu HL, He YR, Liu WT, Ding JM, Gidaspow D, Bouillard J, Chem. Eng. Sci. , 59 (4), 865, 2004
Shuyan W, Xiang L, Huilin L, Long Y, Dan S, Yurong H, Yonglong D, Powder Technol. , 196 (2), 184, 2009
Patil DJ, Annaland MV, Kuipers JAM, Chem. Eng. Sci. , 60 (1), 57, 2005
Patil DJ, Annaland AV, Kuipers JAM, Chem. Eng. Sci. , 60 (1), 73, 2005
Hosseini SH, Ahmadi G, Rahimi R, Zivdar M, Esfahany MN, Powder Technol. , 200 (3), 202, 2010
Hosseini SH, Zivdar M, Rahimi R, Chem. Eng. Process. , 48 (11-12), 1539, 2009
Srivastava A, Sundaresan S, Powder Technol. , 129 (1-3), 72, 2003
Azizi S, Hosseini SH, Moraveji M, Ahmadi G, Particuology. , 8 , 415, 2010
Rahimi MR, Azizi S, Chem. Prod. Process Model. , 6 , 1, 2011
Wang SY, Liu YJ, Liu YK, Wei LX, Dong Q, Wang CS, Powder Technol. , 199 (3), 238, 2010
Ishikura T, Nagashima H, Ide M, Powder Technol. , 131 (1), 56, 2003
Johnson PC, Nott P, Jackson R, J. Fluid Mech. , 210 , 501, 1990
Hosseini SH, Ahmadi G, Razavi BS, Zhong WQ, Energy Fuels. , 24 , 6086, 2010
Acosta-Iborra A, Hernandez-Jimenez F, de Vega M, Briongos JV, Chem. Eng. J. , 261 , 198, 2012
Zhang X, Ahmadi G, J. Comput. Multiphase Flows. , 4 , 41, 2012
Ellison J, Ahmadi G, Regel L, Wilcox W, Microgravity Sci.Tec. , 8 , 140, 1995
Ma D, Ahmadi G, Int. J. Multiphase Flow. , 16 , 341, 1990
Ahmadi G, Ma D, Int. J. Multiphase Flow. , 16 , 323, 1990
Gidaspow D, Multiphase flow and fluidization, continuum and kinetic theory descriptions, Academic Press, Boston, 1994
Carnahan NF, Starling KE, J. Chem. Phys. , 51 , 635, 1969
Ma D, Ahmadi G, J. Chem. Phys. , 84 , 3449, 1986
Benyahia S, Syamlal M, O’Brien TJ, “Summary of MFIX Equations 2012-1.” From URL https://mfix.netl.doe.gov/documentation/MFIXEquations2012-1.pdf, January, 2012
van Wachem BGM, Schouten JC, van den Bleek CM, Krishna R, Sinclair JL, AIChE J. , 47 (5), 1035, 2001
Boemer A, Qi H, Renz U, Int. J. Multiph. Flow , 23 (5), 927, 1997
Min J, Drake JB, Heindel TJ, Fox RO, AIChE J. , 56 , 1434, 2009
Azizi S, Hosseini SH, Ahmadi G, Moraveji M, Chem. Eng. Technol. , 33 (3), 421, 2010
Schaeffer DG, J. Diff. Equ. , 66 , 19, 1987
Johnson PC, Jackson R, J. Fluid Mech. , 176 , 67, 1987
Benyahia S, Ind. Eng. Chem. Res. , 47 (22), 8926, 2008
Lettieri P, Micale G, Cammarata L, Colman D, Computational fluid-dynamics simulations of gas-fluidized beds: A preliminary investigation of different modelling approaches, In Proceedings of the 10th Germany Workshop on Two-Phase Flow Predictions, 2002
Bertola F, Vanni M, Baldi G, Int. J. Chem. Reactor Eng. , 1 , A3, 2003
Syamlal M, Rogers W, O’Brien TJ, MFIX documentation: Theory guide, Tech. Rep. DOE/METC-94/1004 (DE9400087), Morgantown Energy Technology Center, Morgantown, West Virginia, 1993
Savage SB, J. Fluid Mech. , 377 , 1, 1998
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