Advanced search
Publication Cover
Particulate Science and Technology
An International Journal
Volume 33, 2015 - Issue 6
Submit an article Journal homepage
507
Views
5
CrossRef citations to date
0
Altmetric
Original Articles

Hydrodynamic Study of Gas–Solid Internally Circulating Fluidized Bed Using Multiphase CFD Model

Ravi GujjulaDepartment of Petroleum Engineering, KL University, Vijayawada, Andhra Pradesh, India
&
Narasimha MangadoddyDepartment of Chemical Engineering, Indian Institute of Technology Hyderabad, Telangana, IndiaCorrespondence[email protected]
Pages 593-609 | Published online: 23 Sep 2015

References

  • Abu-Zaid, S., and G. Ahmadi. 1990. A simple kinetic model for rapid granular flows including frictional losses. ASCE Journal of Engineering Mechanics 116:379–389.
  • Ahmadi, G., and D. N. Ma. 1986. A kinetic model for granular flows of nearly elastic particles ingrain-inertia regime. International Journal of Bulk Solid Storage Soils 2:8–16.
  • Ahmadi, G., and M. Shahinpoor. 1983. A kinetic model for rapid flow of granular materials. International Journal of Non-Linear Mechanics 19:177–186.
  • Ahuja, G. N., and A. W. Patwardhan. 2008. CFD and experimental studies of solids hold-up distribution and circulation patterns in gas–solid fluidized beds. Chemical Engineering Journal 143:147–160.
  • Arastoopour, H., P. Pakdel, and M. Adewumi. 1990. Hydrodynamic analysis of dilute gas–solids flow in a vertical pipe. Powder Technology 62:163–170.
  • Beetstra, R., M. A. van der Hoef, and J. A. M. Kuipers. 2007. Numerical study of segregation using a new drag force correlation for polydisperse systems derived from lattice-Boltzmann simulations. Chemical Engineering Science 62:246–255.
  • Benjapon, CH., D. Gidaspow, and P. Piumsomboona. 2011. Two- and three-dimensional CFD modeling of Geldart A particles in a thin bubbling fluidized bed: Comparison of turbulence and dispersion coefficient. Chemical Engineering Journal 171:301–313.
  • Benyahia, S., H. Arastoopour, T. Knowlton, and H. Massah. 2000. Simulation of particles and gas flow behavior in the riser section of a circulating fluidized bed using the kinetic theory approach for the particulate phase. Powder Technology 112:24–33.
  • Burugupalli, V. R. 1988. Process analysis of a twin fluidized bed biomass gasification system. Industrial and Engineering Chemistry Research 27:304–312.
  • Chalermsinsuwana, B., D. Gidaspow, and b. Pornpote Piumsomboona. 2011. Two- and three-dimensional CFD modeling of Geldart A particles in a thin bubbling fluidized bed : Comparison of turbulence and dispersion coefficient. Chemical Engineering Journal 171:301–313.
  • Chan, C. K., Y. C. Guo, and K. S. Lau. 2005. Numerical modeling of gas-particle flow using a comprehensive kinetic theory with turbulence modulation. Powder Technology 150:42–55.
  • Ding, J, and D. Gidaspow. 1990. A Bubbling Fluidization Model Using Kinetic Theory of Granular Flow. AIChE Journal 36:523–538.
  • Ergun, S. 1952. Fluid flow through packed columns. Chemical Engineering Progress 48:89–94.
  • Feng, Y., T. Smith, Peter J. Witt., Christian Doblin, Seng Lim, and M. Phil Schwarz. 2012. CFD modeling of gas–solid flow in an internally circulating fluidized bed. Powder Technology 219:78–85.
  • Feng, Y. Q., Witt, P. Doblin, C. Lim, and P. Schwarz. 2010. CFD modeling of gas-solids flow in an internally circulation fluidized bed. In The 10th China-Japan Symposium on Fluidization. Tokyo.
  • Gera, D. M., Y. Gautam, T. Tsuji, Kawaguchi, and T. Tanaka. 1998. Computer simulation of bubbles in large-particle fluidized beds. Powder Technology 98:38–47.
  • Gibilaro, L. G., R. Di Felice, and S. P. Waldram. 1985. Generalized friction factor and drag coefficient correlations for fluid–particle interactions. Chemical Engineering Science 40:1817–1823.
  • Gidaspow, D. 1994. Multiphase flow and fluidization: Continuum and kinetic theory description, New York: Academic Press.
  • Gidaspow, D., and R. Mostofi. 2003. Maximum carrying capacity and granular temperature of A, B, and C particles. AIChE Journal 49:831–843.
  • Gidaspow, D., J. Jonghwun, and R. K. Singh. 2004. Hydrodynamics of Fluidization using Kinetic Theory: An Emerging Paradigm 2002 Flour-Daniel Lecture. Powder Technology 148:123–141.
  • Helland, E., H. Bournot, R. Occelli, and L. Tadrist. 2007. Drag reduction and cluster formation in a circulating fluidised bed. Chemical Engineering Science 62:148–158.
  • Hosseini, S., G. Ahmadi, c. Rahimi, c. Mortaza, and Mohsen. 2010. CFD studies of solids hold-up distribution and circulation patterns in gas–solid fluidized beds. Powder Technology 200:202–215.
  • Hosseini, S. H., M. Zivdar, R. Rahimi, and A. Samimi. 2009. CFD simulation of gas–solid bubbling fluidized bed containing the FCC particles. Korean J. Chem. Eng. 26:1405–1413.
  • Huilin, L., H. Yurong, L. Wentie, D. Jianmin, D. Gidaspow, and J. Bouillard. 2004. Computer simulations of gas–solid flow in spouted beds using kinetic-frictional stress model of granular flow. Chemical Engineering Science 59:865–878.
  • Ishikura, T., and H. Nagashima. 2003. Hydrodynamics of a spouted bed with a porous draft tube containing a small amount of finer particles. Powder Technology 131:56–65.
  • Jeon, J. H., and S. D. Kim. 2010. Hydrodynamic characteristics of binary solids mixtures in a square internally circulating fluidized bed. Journal of Chemical Engineering of Japan 43(2):126–131.
  • Johnson, P. C., and R. Jackson. 1987. Frictional–collisional constitutive relations for granular materials with application to plane shearing. Journal of Fluid Mechanics 176:67–93.
  • Jung, J., D. Gidaspow, and Isaac K. Gamwo. 2005. Measurement of two kinds of granular temperatures, stresses and dispersion in bubbling beds. Industrial & Engineering Chemistry Research 44:1329–1341.
  • Kim, Y. J., J. M. Lee, and S. D. Kim. 2000. Modeling of coal gasification in an internally circulating fluidized bed reactor with draught tube. Fuel 79:69.
  • Kim, Y. T., B. H. Song, and S. D. Kim. 1997. Entrainment of solids in an internally circulating fluidized bed with draft tube. Chemical Engineering Journal 66:105–110.
  • Kuipers, J. A. M., K. J. van Duin, F. P. H. van Beckum, and W. P. M. van Swaaij. 1992. A numerical model of gas-fluidized beds. Chemical Engineering Science 47:1913.
  • Lun, C. K. K., S. B. Savage, D. J. Jeffrey, and N. Chepurniy. 1984. Kinetic theories for granular flow:inelastic particles in Couette flow and slightly inelastic particles in a general flow field. Journal of Fluid Mechanics 140:223–256.
  • Marschall, K. J., and L. Mleczko. 1999. CFD modeling of an internally circulating fluidized-bed reactor. Chemical Engineering Science 54:2085–2093.
  • Mathiesen, V., T. Solberg, H. Arastoopour, and H. Hjertager. 1999. Experimental and computational study of multiphase gas-particle in a CFB riser. AIChE Journal 45:2503–2518.
  • McKeen, T., and T. Pugsley. 2003. Simulation and experimental validation of a freely bubbling bed of FCC catalyst. Powder Technology 129:139–152.
  • Müller, C. R., J. F. Davidson, J. S. Dennis, and A. L. Hayhurst. 2007. A study of the motion and eruption of a bubble at the surface of a two-dimensional fluidized bed using particle image velocimetry (PIV). Industrial & Engineering Chemistry Research 46:1642–1652.
  • Neri, A., and D. Gidaspow. 2000. Riser hydrodynamics: Simulation using kinetic theory. AIChE Journal 46:52–67.
  • Passalacqua, A., and L. Marmo. 2009. A critical comparison of frictional stress models applied to the simulation of bubbling fluidized beds. Chemical Engineering Science 64(12): 2795–2806.
  • Patankar, S. V. 1980. Numerical Heat Transfer and Fluid Flow. Newyork, NY: Hemisphere Publishing Corporation.
  • Patil, D. J., M. van Sint Annaland, and J. A. M. Kuipers. 2005. Critical comparison of hydrodynamics models for gas–solid fluidized beds—part I: Bubbling gas–solid fluidized beds operated with a jet. Chemical Engineering Science 60:57–72.
  • Patil, D. J., and M. van Sint Annaland. 2005. Critical comparison of hydrodynamic models for gas–solid fluidized beds—Part II: freely bubbling gas–solid fluidized beds. Chemical Engineering Science 60:73–84.
  • Polashenski, W., and J. Chen. 1999. Measurement of particle stresses in fast fluidized beds. Industrial & Engineering Chemistry Research 38:705–713.
  • Reuge, N., L. Cadoret, C. Coufort-Saudejaud, S. Pannala, M. Syamlal, and B. Caussat. 2008. Multi-fluid Eulerian modeling of dense gas–solid fluidized bed hydrodynamics; influence of the dissipation parameters. Chemical Engineering Science 22:5540–5551.
  • Schaeffer, D. G. 1987. Instability in the Evolution Equations Describing Incompressible Granular Flow. Journal of Differential. Equations 66. 19–50. 1987
  • Shirvanian, P. A., and J. M. Calo. 2004. Hydrodynamic scaling of a rectangular spouted vessel with a draft duct. Chemical Engineering Journal 103:29–34.
  • Shuyan, W., L. Xiang, L. Huilin, Y. Long, S. Dan, H. Yurong, and D. Yonglong. 2009. Numerical simulations of flow behavior of gas and particles in spouted beds using frictional kinetic stresses model. Powder Technology 196:184–193.
  • Sinclair, J. L., and Jackson, R. 1983. Gas-particle flow in vertical pipe with particle–particle interaction. AIChE Journal 35:1473.
  • Srivastava, A., and S. Sundaresan. 2003. Analysis of a frictional-kinetic model for gas–particle flow. Powder Technology 129:72–85.
  • Syamlal, M., W. Rogers, and T. J. O'Brien. 1993. MFIX documentation: theory guide. In Technical Report DOE/METC-94/1004 (DE9400087). Morgantown Energy Technology Centre, Morgantown, West Virginia.
  • Syamlal, M., and T. J. O'Brien. 1989. Computer simulation of bubbles in a fluidized bed. AIChE Symposium Series 85:22–31.
  • Szafran, R. G., and A. Kmiec. 2007. Periodic fluctuations of flow and porosity in spouted beds. Transport in Porous Media 66:187–200.
  • van Wachem, B. G. M., J. C. Schouten, C. M. van den Bleek, R. Krishna, and J. L. Sinclair. 2001. Comparative analysis of CFD models of dense gas–solid systems. AIChE Journal 47(5): 1035–1051.
  • Wen, C. Y., and Y. H. Yu. 1966. Mechanics of fluidization. Chemical Engineering Progress Symposium Series 62:100–111.
  • Xu, J., J. Tang, W. Wei, and X. Bao. 2009. Minimum spouting velocity in a spout-fluid bed with a draft tube. Canadian Journal of Chemical Engineering 87:274–278.
  • Yang, N., W. Wang, W. Ge, and J. Li. 2003. CFD simulation of concurrent-up gas–solid flow in circulating fluidized beds with structure-dependent drag coefficient. Chemical Engineering Journal 96:71–80.
  • Yang, T., T. Zhang, and H. T. Bi. 2008. A novel continuous reactor for catalytic reduction of NOx – Fixed bed simulation. Canadian Journal of Chemical Engineering 86(3):395–402
  • Zhao, X. L., S. Q. Li, G. Q. Liu, Q. Song, and Q. Yao. 2008. Flow patterns of solids in a two-dimensional spouted bed with draft plates: PIV measurement and DEM simulations. Powder Technology 183:79–87.
  • Zheng, Y., X. Wan, Z. Qian, F. Wei, and Y. Jin. 2001. Numerical simulation of the gas-particle turbulent flow in riser reactor based on k–ϵ–kp–_p–two-fluid model. Chemical Engineering Science 56:6813–6822.
  • Zimmermann, S., and F. Taghipour. 2005. CFD modeling of the hydrodynamics and reaction kinetics of FCC fluidized-bed reactors. Industrial & Engineering Chemistry Research 44:9818–9827.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.