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Issue
Korean Journal of Chemical Engineering,
Vol.26, No.3, 874-878, 2009
Effect of bed height on the carbon dioxide capture by carbonation/regeneration cyclic operations using dry potassium-based sorbents
Park YC, Jo SH, Park KW, Park YS, Yi CK
The effect of bed height on CO2 capture was investigated by carbonation/regeneration cyclic operations using a bubbling fluidized bed reactor. We used a potassium-based solid sorbent, SorbKX35T5 which was manufactured by the Korea Electric Power Research Institute. The sorbent consists of 35% K2CO3 for absorption and 65% supporters for mechanical strength. We used a fluidized bed reactor with an inner diameter of 0.05 m and a height of 0.8 m which was made of quartz and placed inside of a furnace. The operating temperatures were fixed at 70 ℃ and 150 ℃ for carbonation and regeneration, respectively. The carbonation/regeneration cyclic operations were performed three times at four different L/D (length vs diameter) ratios such as one, two, three, and four. The amount of CO2 captured was the most when L/D ratio was one, while the period of maintaining 100% CO2 removal was the longest as 6 minutes when L/D ratio was three. At each cycle, CO2 sorption capacity (g CO2/g sorbent) was decreased as L/D ratio was increased. The results obtained in this study can be applied to design and operate a large scale CO2 capture process composed of two fluidized bed reactors.
Keywords: Solid Sorbent; Fluidized Bed Reactor; CO2 Capture; Carbonation/Regeneration; Bed Height
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[Cited By]
  1. Park KW, Park YS, Park YC, Jo SH, Yi CK, Korean Chemical Engineering Research, 47(3), 349, 2009
  2. Yi CK, Korean Chemical Engineering Research, 48(2), 140, 2010
  3. Choi JH, Yi CK, Jo SH, Korean Journal of Chemical Engineering, 28(4), 1144, 2011
  4. Kim KC, Park YC, Jo SH, Yi CK, Korean Journal of Chemical Engineering, 28(10), 1986, 2011
  5. Choi JH, Youn PS, Kim KC, Yi CK, Jo SH, Ryu HJ, Park YC, Korean Chemical Engineering Research, 50(3), 516, 2012
  6. Zaman M, Lee JH, Korean Journal of Chemical Engineering, 30(8), 1497, 2013
  7. Choi JH, Yi CK, Jo SH, Ryu HJ, Park YC, Korean Journal of Chemical Engineering, 31(2), 194, 2014
  8. Kim K, Yang S, Lee JB, Eom TH, Ryu CK, Lee HJ, Bae TS, Lee YB, Lee SJ, Korean Journal of Chemical Engineering, 32(4), 677, 2015
  9. Kim JY, Lim H, Woo JM, Jo SH, Moon JH, Lee SY, Lee HJ, Yi CK, Lee JS, Min BM, Park YC, Korean Chemical Engineering Research, 55(3), 419, 2017
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