TY  - JOUR
VL  - 14
A1  - Gilassi, S.
A1  - Rahmanian, N.
JF  - International Journal of Chemical Reactor Engineering
UR  - https://www.scopus.com/inward/record.uri?eid=2-s2.0-84959305458&doi=10.1515%2fijcre-2014-0142&partnerID=40&md5=7e91838b23d1ee94b05c04c735f6f3b0
Y1  - 2016///
ID  - scholars7212
KW  - Absorption; Atmospheric composition; Computational fluid dynamics; Efficiency; Ethanolamines; Finite element method; Flow of gases; Gas absorption; Laminar flow; Mass transfer; Phase interfaces
KW  -  Amine solutions; CFD modelling; Gas-liquid interface; Hollow-fibre membrane; Laminar flow conditions; Mass transfer modeling; N-methyldiethanolamine; Removal efficiencies
KW  -  Carbon dioxide
N2  - A mass transfer model was developed to capture CO2 from a gas mixture in hollow fibre membrane contactors under laminar flow conditions. The axial and radial diffusions through membrane and convection in tube and shell sides with chemical reaction were investigated. COMSOL software was used to numerically solve a system of non-linear equations with boundary conditions by use of the finite element method. Three different amine solutions of monoethanolamine (MEA), diethanolamine (DEA) and n-methyldiethanolamine (MDEA) were chosen as absorbent in lumen to consider the mass transfer rate of CO2 and its removal efficiency. The modelling results were compared with experimental data available in the literature and a good agreement was observed. The CFD results revealed that MEA had the best performance for CO2 removal as compared to DEA and MDEA under various operating conditions due to the different CO2 loading factor of absorbents. Furthermore, efficiency of CO2 removal was highly dependent on the absorbent concentration and flow rate, increasing of the gas flow rate caused a reduction in gas residence time in the shell and consequently declined CO2 mass transfer. The modelling results showed the effect of absorbent concentration on the CO2 mass transfer was improved due to availability of absorbent reactants at the gas-liquid interface. © 2016 by De Gruyter 2016.
IS  - 1
EP  - 61
PB  - Walter de Gruyter GmbH
SN  - 15426580
TI  - CFD Modelling of a Hollow Fibre Membrane for CO2 Removal by Aqueous Amine Solutions of MEA, DEA and MDEA
SP  - 53
N1  - cited By 11
AV  - none
ER  -