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Issue
Korean Journal of Chemical Engineering,
Vol.30, No.2, 295-305, 2013
Experimental investigation and stability analysis on dense-phase pneumatic conveying of coal and biomass at high pressure
Cai L, Jiaying C, Guiling X, Pan X, Xiaoping C, Changsui Z
Conveying characteristics and flow stability are very important for design and control of a conveying system at high pressure. The influences of operating parameters and material properties on conveying characteristics were investigated in an experimental test facility with a conveying pressure up to 4MPa. Wavelet transform and Shannon entropy analysis were applied to analyzing pressure drops through horizontal pipe in order to obtain the stability criterion. Results indicated that the mass flow rate of biomass decreased, while the mass flow rate of pulverized coal increased at first and then decreased with the increase in fluidization velocity. Solid loading ratios for four kinds of powders decreased with the increase in fluidization velocity. Conveying phase diagrams and pressure drops through different test sections of pulverized coal and biomass at high pressure were obtained and analyzed. The influences of coal category, fracture characteristics and particle size on conveying characteristics were determined.
Keywords: Pneumatic Conveying; Flow Characteristics; High Pressure; Stability; Shannon Entropy
[References]
  1. Cowell A, McGlinchey D, Ansell R, Fuel, 84(17), 2256, 2005
  2. Liang C, Chen XP, Xu P, Exp. Therm. Fluid Sci., 35, 1143, 2011
  3. Xiaoping C, Chunlei F, Cai L, Wenhao P, Peng L, Changsui Z, Korean J. Chem. Eng., 24(3), 499, 2007
  4. Pu WH, Zhao CS, Xiong YQ, Liang C, Chen XP, Lu P, Fan CL, Chem. Eng. Technol., 31(2), 215, 2008
  5. Pahk JB, Klinzing GE, J. Chin. Inst. Chem. Eng., 39(2), 143, 2008
  6. Laouar S, Molodtsof Y, Powder Technol., 95(2), 165, 1998
  7. Dai J, Grace JR, Int. J. Multiphas Flow., 36, 78, 2010
  8. Carpinlioglu MO, Gundogdu MY, Powder Handle Process., 12, 145, 2000
  9. Clementson CL, Ileleji KE, Bioresour. Technol., 101(14), 5459, 2010
  10. van der Schaaf J, van Ommen JR, Takens F, Schouten JC, van den Bleek CM, Chem. Eng. Sci., 59(8-9), 1829, 2004
  11. Zhong WQ, Zhang MY, Powder Technol., 152(1-3), 52, 2005
  12. Hay JM, Nelson BH, Briens CL, Bergougnou MA, Chem. Eng. Sci., 50(3), 373, 1995
  13. Ellis N, Briens LA, Grace JR, Bi HT, Lim CJ, Chem. Eng. J., 96(1-3), 105, 2003
  14. Li H, Powder Technol., 125(1), 61, 2002
  15. Wu HJ, Zhou FD, Wu YY, Int. J. Multiph. Flow, 27(3), 459, 2001
  16. Cho YJ, Kim SJ, Nam SH, Kang Y, Kim SD, Chem. Eng. Sci., 56(21-22), 6107, 2001
  17. Zhong WQ, Zhang MY, Powder Technol., 152(1-3), 52, 2005
  18. Liang C, Zhao CS, Chen XP, Pu WH, Lu P, Fan CL, Chem. Eng. Technol., 30(7), 926, 2007
  19. Cai L, Xiaoping C, Changsui Z, Wenhao P, Peng L, Chunlei F, Korean J. Chem. Eng., 26(3), 867, 2009
  20. Liang C, Xu P, Chen XP, Exp. Therm. Fluid Sci., 41, 149, 2012
  21. Yang, Southeast University, 2008
  22. Hyder LM, Bradley MS, Reed AR, Hettiaratchi K, Powder Technol., 112(3), 235, 2000
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