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Received March 14, 2011
Accepted April 13, 2011
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삼상유동층 공정에서 수력학적 Similarity 해석

Analysis of Hydrodynamic Similarity in Three-Phase Fluidized Bed Processes

1충남대학교 화학공학과, 305-764 대전시 유성구 궁동 220 2충남대학교 녹색에너지 전문대학원, 305-764 대전시 유성구 궁동 220
1Department of Chemical Engineering, Chungnam National University, 220 Gung-dong, Yuseong-gu, Daejeon 305-764, Korea 2Graduate School of Green Energy Technology, Chungnam National University, 220 Gung-dong, Yuseong-gu, Daejeon 305-764, Korea
Korean Chemical Engineering Research, December 2011, 49(6), 790-797(8), NONE Epub 28 November 2011
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Abstract

삼상유동층에서 수력학적 유사성을 규모인자(scaling factor)를 이용하여 해석하였다. 규모인자는 직경이 다른 두 종류의 삼상유동층간의 기체, 액체, 그리고 고체입자의 체류량과 단위면적당 유효부피흐름속도를 기준으로 정의하였다. 두 종류 삼상유동층의 직경은 각각 0.102 m와 0.152 m이었다. 여과된 압축공기, 물 그리고 밀도가 2,500 kg/m3인 유리구슬을 각각 기체, 액체 그리고 유동고체입자로 사용하였다. 각 삼상유동층에서 각 상들의 체류량은 정압강하법에의해 결정하였다. 기체 및 액체의 유속 그리고 고체유동입자의 크기가 각 상들을 기준으로한 규모인자와 유효부피흐름 속도를 기준으로한 규모인자에 미치는 영향을 검토하였다. 직경이 다른 두 삼상유동층에서 기체 체류량의 편차는 기체와 액체의 유속이 증가함에 따라 감소하였으나 유동입자의 크기가 증가함에 따라 증가하였다. 직경이 다른 두 종류 삼상유동층에서 액체 체류량 편차는 기체와 액체 그리고 고체유동입자의 크기가 증가함에 따라 감소하였다. 두 종류 삼상유동층에서 고체입자 체류량 편차는 기체유속과 유동입자의 크기가 증가함에 따라 증가하였으나 액체의 유속이 증가함에 따라 감소하였다. 직경이 다른 두 종류 삼상유동층에서 유효부피흐름속도를 매개로 한 규모인자는 기체유속과 유동입자의 크기가 증가함에 따라 감소하였으나 액체의 유속이 증가함에 따라 증가하였다. 본 연구에서 정의된 규모인자는 삼상유동층 공정의 수력학적 유사성을 해석하는데 효과적으로 사용될 수 있었다.
Hydrodynamic similarity was analyzed by employing scaling factor in three phase fluidized beds. The scaling factor was defined based on the holdups of gas, liquid and solid particles and effectivity volumetric flux of fluids between the two kinds of fluidized beds with different column diameter. The column diameter of one was 0.102 m and that of the other was 0.152 m. Filtered compressed air, tap water and glass bead of which density was 2,500 kg/m3 were used as gas, liquid and solid phases, respectively. The individual phase holdups in three phase fluidized beds were determined by means of static pressure drop method. Effects of gas and liquid velocities and particle size on the scaling factors based on the holdups of each phase and effective volumetric flux of fluids were examined. The deviation of gas holdup between the two kinds of three phase fluidized beds decreased with increasing gas or liquid velocity but increased with increasing fluidized particle size. The deviation of liquid holdup between the two fluidized beds_x000D_ decreased with increasing gas or liquid velocity or size of fluidized solid particles. The deviation of solid holdup between the two fluidized beds increased with increasing gas velocity or particle size, however, decreased with increasing liquid velocity. The deviation of effective volumetric flux of fluids between the two fluidized beds decreased with increasing gas velocity or particle size, but increased with increasing liquid velocity. The scaling factor, which was defined in this study, could be effectively used to analyze the hydrodynamic similarity in three phase fluidized processes.

References

Fan, L. S., Gas-Liquid-Solid Fluidization Engineering, Butterworths, Stonehair, Ma. (1989)
Kim SD, Kang Y, Chem. Eng. Sci., 52(21-22), 3639 (1997)
Kim SD, Kang Y, “Hydrodynamic, Heat and Mass Transfer in Inverse and Circulating Three-phase Fluidized-bed Reactors for Waste Water Treatment,” Studies In Surface Science And Catalyst, 159, 103 (2006)
Kang Y, Lee KI, Shin IS, Son SM, Kim SD, Jung, H, Korea Chem. Eng. Res., 45, 451 (2008)
Kim SD, Kang Y, “Dispersion Phase Characteristics in t Hree-phase Fluidized Beds,”Mixed Flow Hydridynamics, Advanced Eng. Fluid Meckanics Series, Gulf Pub. Co. New York (1996)
Wild G, Saberian M, Schwarty J, Charpentier JE, Int’l Chem. Eng., 24, 639 (1984)
Lefebvre S, Guy C, Chaouki J, Chem. Eng. J., 133(1-3), 85 (2007)
Kang Y, Ko MH, Woo KJ, Kim SD, Park SG, Yashima M, Fan LT, I&EC Res., 37, 4137 (1998)
Cho YJ, Song PS, Kim SH, Kang Y, Kim SD, J. Chem. Eng. Jpn., 34(2), 254 (2001)
Son SM, Shin HJ, Kang SH, Kang Y, Kim SD, J. Korean Ind. Eng. Chem., 15(6), 652 (2004)
Kang Y, Kim SD, Chem. Ind. Technol., 13(1), 27 (1995)
Lee KI, Son SM, Kim UY, Kang Y, Kang SH, Kim SD, Lee JK, Seo YC, Kim WH, Chem. Eng. Sci., 62(24), 7060 (2007)
Son SM, Kang SH, Kang Y, Kim SD, Korean Chem. Eng. Res., 44(5), 505 (2006)
Kang Y, Kim SD, Particulate Sci. Technol., 6, 133 (1988)
Shin KS, Song PS, Lee CG, Kang SH, Kang Y, Kim SD, Kim SJ, AIChE J., 51(2), 671 (2005)
Lin TJ, Chiu HT, Catalysis Today., 79, 159 (203)
Wan L, Alvareg-cuenca M, Upreti SR, Lohi A, Chem. Eng. Processing : Process Intensification., Doi:10.1016/J.Cep. 2009. 10. 012 (2009)
Ramesh KV, Raju GMJ, Sarma GVS, Sarma CB, Chem. Eng. J., 145(3), 393 (2009)
Jena HM, Roy GK, Meikap BC, Chem. Eng. Res. Des., 86(11A), 1301 (2008)

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