화학공학소재연구정보센터
Korean Journal of Chemical Engineering, Vol.17, No.3, 273-279, May, 2000
The Characteristics of Particle Flow in the Overflow and Underflow Standpipe of Fluidized Beds
E-mail:
Characteristics of particle flow in standpipes of a 10cm I.D. ×120cm high fluidized bed were investigated. The standpipes used in this experiment were vertical overflow and vertical underflow standpipes. Sand particles and polyethylene powders were employed as the bed materials. The effects of standpipe diameter, gas velocity and particle properties on the solid flow rate were determined. The experimental results showed that the flow behaviors of solids through the overflow and underflow standpipes are different with variations of operating conditions. For both standpipes, the mass flow rate of solids was strongly dependent on the standpipe diameter. For the overflow standpipe, the increase of gas velocity increased the solids flow rate. But for the underflow standpipe it decreased the solids flow rate. From the measured pressure drops, solid fractions in the standpipes were determined by the momentum balance. The obtained experimental data of solids mass flow rate were well correlated with the pertinent dimensionless groups for underflow as well as overflow standpipes. Characteristics of particle flow in standpipes of a 10cm I.D. ×120cm high fluidized bed were investigated. The standpipes used in this experiment were vertical overflow and vertical underflow standpipes. Sand particles and polyethylene powders were employed as the bed materials. The effects of standpipe diameter, gas velocity and particle properties on the solid flow rate were determined. The experimental results showed that the flow behaviors of solids through the overflow and underflow standpipes are different with variations of operating conditions. For both standpipes, the mass flow rate of solids was strongly dependent on the standpipe diameter. For the overflow standpipe, the increase of gas velocity increased the solids flow rate. But for the underflow standpipe it decreased the solids flow rate. From the measured pressure drops, solid fractions in the standpipes were determined by the momentum balance. The obtained experimental data of solids mass flow rate were well correlated with the pertinent dimensionless groups for underflow as well as overflow standpipes.
  1. Burkell JJ, Grace JR, Zhao J, Lim CJ, "Measurement of Solids Circulation Rates in Circulating Fluidized Beds," Circulating Fluidized Bed Technology II, Pergamon Press, 501 (1998)
  2. Davidson JF, Clift R, Harrison D, "Fluidization," 2nd ed., Academic Press (1985)
  3. Geldart D, "Gas Fluidization Technology," John Wiley & Sons (1986)
  4. Ginestra JC, Rangachari S, Jackson R, Powder Technol., 27, 69 (1980) 
  5. Grace JR, Avidan AA, Knowlton TM, "Circulating Fluidized Beds," Blackie Academic & Professional (1996)
  6. Jones PJ, Leung LS, Powder Technol., 20, 145 (1978) 
  7. Knowlton TM, Hirsan I, Hydrocarb. Process., 57, 149 (1978)
  8. Leung LS, Powder Technol., 16, 1 (1977) 
  9. Leung LS, Jones PJ, Knowlton TM, Powder Technol., 19, 7 (1978) 
  10. Leva M, "Fluidization," McGraw-Hill, New York (1959)
  11. Levenspil O, Kunii D, "Fluidization Engineering," 2nd ed., Butterworth-Heinemann (1991)
  12. Ozawa M, Tobita S, Mii T, Tomoyasu Y, "Flow Pattern and Flow Behavior of Solid Particles in L-valve," Circulating Fluidized Bed Technology III, Pergamon Press, 615 (1991)
  13. Picciotti M, "Specify Standpipes and Feeder Valves for Packed Beds," Chemical Engineering Progress, January, 54 (1995)
  14. Rhodes M, "Introduction to Particle Technology," John Wiley & Sons (1998)
  15. Rudolph V, Chong YO, Nicklin DJ, "Standpipe Modelling for Circulating Fluidized Beds," Circulating Fluidized Bed Technology III, Pergamon Press, 49 (1991)
  16. Zhang JY, Rudolph V, Powder Technol., 97(2), 109 (1998)