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Issue
Korean Journal of Chemical Engineering,
Vol.18, No.6, 831-837, 2001
Oxidation and Reduction Characteristics of Oxygen Carrier Particles and Reaction Kinetics by Unreacted Core Model
Ryu HJ, Bae DH, Han KH, Lee SY, Jin GT, Choi JH
The reaction kinetics of the oxygen carrier particles, which are used as bed material for a fluidized bed chemical looping combustor (CLC), has been studied experimentally by a conventional thermal gravimetrical analysis technique. The weight percent of nickel and nickel oxide in oxygen carrier particles and reaction temperature were considered as experimental variables. After oxidation reaction, the pure nickel particle was sintered and unsuitable to use as fluidizing particles. The oxidation reaction rate increased with increasing weight percent of nickel in oxygen carrier particles and reaction temperature. The rate of reduction shows maximum point with weight percent of nickel oxide (57.8%) and reaction temperature (750 or 800 ℃) increased. In this work, the reaction between air and Ni/bentonite particle was described by a special case of unreacted core model in which the global reaction rate is controlled by product layer diffusion resistance. However, the reaction between CH4 and NiO/bentonite particle was described by unreacted core model in which the global reaction rate is controlled by chemical reaction resistance. The temperature dependence of the effective diffusivity of oxidation reaction and reaction rate constant of reduction reaction could be calculated from experimental data and fitted to the Arrhenius equation.
Keywords: Chemical Looping Combustor (CLC); Oxidation; Reduction; Kinetics; Rnreacted Core Model
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[Cited By]
  1. Ryu HJ, Lim NY, Bae DH, Jin GT, Korean Journal of Chemical Engineering, 20(1), 157, 2003
  2. Song KS, Seo YS, Yoon HK, Cho SJ, Korean Journal of Chemical Engineering, 20(3), 471, 2003
  3. Ryu HJ, Bae DH, Jin GT, Korean Journal of Chemical Engineering, 20(5), 960, 2003
  4. Ryu HJ, Bae DH, Jo SH, Jin GT, Korean Chemical Engineering Research, 42(1), 107, 2004
  5. Ryu HJ, Jin GT, Korean Chemical Engineering Research, 42(5), 588, 2004
  6. Ryu HJ, Jin GT, Korean Journal of Chemical Engineering, 24(3), 527, 2007
  7. Ryu HJ, Shun DW, Bae DH, Park MH, Korean Journal of Chemical Engineering, 26(2), 523, 2009
  8. Song Q, Xiao R, Deng Z, Shen L, Zhang M, Korean Journal of Chemical Engineering, 26(2), 592, 2009
  9. Son SR, Go KS, Kim SD, Korean Chemical Engineering Research, 48(2), 185, 2010
  10. Baek JI, Ryu CK, Eom TH, Lee JB, Jeon WS, Yi J, Korean Journal of Chemical Engineering, 28(11), 2211, 2011
  11. Lee DY, Ryu HJ, Shun DW, Bae DH, Baek JI, Korean Journal of Chemical Engineering, 35(6), 1257, 2018
  12. Kumai E, Shimono F, Tanaka M, Watanabe T, Hoshino T, Hosoda S, Kanamori H, Fujita Y, Journal of Industrial and Engineering Chemistry, 107, 239, 2022
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