TY - JOUR AU - Phanpa, Kasidit AU - Wongwailikhit, Kritchart AU - Dammee, Rawadee AU - Sairiam, Sermpong AU - Jamnongwong, Marupatch AU - Painmanakul, Pisut PY - 2018/07/31 Y2 - 2024/03/29 TI - Study of Aeration and CO<sub>2</sub> Absorption Using Filtration Membranes in Terms of Physical Properties and Mass Transfer Parameters JF - Engineering Journal JA - Eng. J. VL - 22 IS - 4 SE - DO - 10.4186/ej.2018.22.4.83 UR - https://engj.org/index.php/ej/article/view/2206 SP - 83-95 AB - <p>Hollow fiber membrane contactor is nowadays one of the alternative absorption processes for conventional bubble columns. In this work, the performances of microporous hollow fiber membranes for aeration and CO<sub>2</sub> absorption were investigated. The membranes used in this work were adapted from filtration membranes which are significantly cheaper than conventional absorption membranes. The effects of operating variables such as average pore sizes, gas flow rates, liquid flow rates, amounts of hollow fiber membrane, and concentrations of chemical solution on the gas-liquid absorption rate were determined. For oxygen-water absorption, the overall mass transfer coefficient (k<sub>L</sub>a), which corresponding to the absorption rate, increased with the increase of membrane porous diameter. The k<sub>L</sub>a was also enhanced with the increase of the liquid flow rate and the number of membranes while the gas flow rate was rarely influent. For carbon dioxide absorption, the increase in liquid flow rate and the carbon dioxide concentration resulted in higher mass transfer rate. Moreover, adding sodium carbonate in absorbent improved the k<sub>L</sub>a value up to 2.2 folds, comparing with physical absorption. The comparison between membrane contractor and bubble column indicated that the utilization of filtration membranes had more efficiency comparing to bubble column due to its high surface area and adaptability when operating with the same size.</p> ER -