AI Article Synopsis
- The study investigates the effectiveness of three absorbents – aqueous aminoacetic acid potassium (AAAP), monoethanolamine (MEA), and methyldiethanolamine (MDEA) – for CO2 separation from flue gas using hydrophobic hollow fiber membrane contactors.
- Key factors such as absorbent concentration, flow rates, and cyclic loading of CO2 are analyzed, with MEA showing a mass transfer velocity of 7.1 mol/(m²·s) under specific conditions.
- Results indicate that AAAP effectively removes over 90% of CO2 across a broad concentration range, suggesting that membrane-based absorption is a promising method for CO2 removal from various types of power plant flue gases
Article Abstract
Three typical absorbents such as aqueous of aminoacetic acid potassium (AAAP), monoethanolamine (MEA) and methyldiethanolamine(MDEA) are selected to investigate the performance of CO2 separation from flue gas via membrane contactors made of hydrophobic hollow fiber polypropylene porous membrane. Impacts of absorbents, concentrations and flow rates of feeding gas and absorbent solution, cyclic loading of CO2 on the removal rate and the mass transfer velocity of CO2 are discussed. The results demonstrate that the mass transfer velocity was 7.1 mol x (m2 x s)(-1) for 1 mol x L(-1) MEA with flow rate of 0.1 m x s(-1) and flue gas with that of 0.211 m x s(-1). For 1 mol L(-1) AAAP with flow rate of 0.05 m x s(-1) and flue gas of 0.211 m x s(-1), CO2 removal rate (eta) was 93.2 % and eta was 98% for 4 mol x L(-1) AAAP under the same conditions. AAAP being absorbent, eta was higher than 90% in a wider range of concentrations of CO2. It indicates that membrane-based absorption process is a widely-applied and promising way of CO2 removal from flue gas of power plants, which not only appropriates for CO2 removal of flue gas of widely-used PF and NGCC, but also for that of flue gas of IGCC can be utilized widely in future.
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