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Frontiers of Chemical Science and Engineering

ISSN 2095-0179

ISSN 2095-0187(Online)

CN 11-5981/TQ

Postal Subscription Code 80-969

2018 Impact Factor: 2.809

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Front Chem Eng Chin    2009, Vol. 3 Issue (1) : 68-72    https://doi.org/10.1007/s11705-009-0130-8
RESEARCH ARTICLE
Effects of baffles on separation of aqueous ethanol solution with hollow fibers
Zhihong YANG1, Guoliang ZHANG1(), Lan LIN1, Danping REN1, Qin MENG2, Hongzi ZHANG2
1. College of Biological and Environmental Engineering, Zhejiang University of Technology, Hangzhou 310014, China; 2. College of Materials Science and Chemical Engineering, Zhejiang University, Hangzhou 310027, China
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Abstract

The effects of baffles on the operation and mass-transfer characteristics in novel hollow fiber membrane contactor used in distillation were investigated. Hollow fiber membranes, coated with a 7 μm polydimethyl-siloxane, were operated as structural packing in the separation of ethanol-water solutions. The parallel flow mode was chosen for separation due to the stronger driving force of the concentration difference, in which liquid flows through the lumens of the fibers and vapor flows countercurrent-wise outside the fibers. Two baffles were installed on the shell side of the membrane contactors to enhance separation, which had a round shape with a semi-lunar hole. The results show that both baffled and unbaffled membrane contactors gave better, more productive separations than traditional packing in distillation, such as the excellent Sulzer Gauze BX structured packing. The baffled membrane contactors performed better than unbaffled ones, especially at high vapor velocities. The minimal HTU of membrane contactor with baffles could reach as low as 4.5 cm, and almost all the contactors could work well above the limit where flooding normally occurs in conventional cases. Theoretical analysis predicted that baffles helped membrane module to obtain a higher mass-transfer coefficient and a smaller mass-transfer resistance. Finally, theoretical mass-transfer coefficient and experimental value were compared as well as the contribution of each individual mass-transfer coefficients among liquid, gas and membrane.
Keywords hollow fiber      membrane contactor      baffle      mass-transfer      ethanol-water     
Corresponding Author(s): ZHANG Guoliang,Email:guoliangz@zjut.edu.cn   
Issue Date: 05 March 2009
 Cite this article:   
Lan LIN,Danping REN,Zhihong YANG, et al. Effects of baffles on separation of aqueous ethanol solution with hollow fibers[J]. Front Chem Eng Chin, 2009, 3(1): 68-72.
 URL:  
https://academic.hep.com.cn/fcse/EN/10.1007/s11705-009-0130-8
https://academic.hep.com.cn/fcse/EN/Y2009/V3/I1/68
Fig.1  Resistance-in-series model for the hollow fiber membrane
Fig.2  Distillation apparatus
Fig.3  Variation of distillation concentration with time (Baffles can improve distillation obviously, especially at a higher vapour velocity)
Fig.4  Hollow fiber membrane contactor operate above flooding (The data usually are at fluxes above the normal flooding limit, shown as the solid line)
Fig.5  versus factor (The module with baffles can obtain smaller values)
lower velocityhigher velocity
no baffletwo bafflesno baffletwo baffles
flow velocity/(cm?s-1)vG1 = 69.1vG2 = 62.5vG1 = 118.1vG2 = 121.3
individual mass-transfer coeffcient
liquid/(cm?s-1)kL1 =6.28×10-4kL2 =5.49×10-4kL1 =9.73×10-4kL2 =8.25×10-4
vapor/(cm?s-1)kG1 =2.00kG2 =2.04kG1 =3.16kG2 =3.36
membrane/(cm?s-1)kM =1
Tab.1  Estimates of mass-transfer coefficient with different hollow fiber modules in ethanol-water system
Fig.6  Overall mass-transfer coefficient versus vapor velocity (The solid symbols are theoretical prediction based on mass transfer calculation)
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