Abstract
In this work, the membrane vacuum regeneration (MVR) process was considered as a promising technology for solvent regeneration in post-combustion CO2 capture and utilization (CCU) since high purity CO2 is needed for a technical valorization approach. First, a desorption test by MVR using polypropylene hollow fiber membrane contactor (PP-HFMC) was carried out in order to evaluate the behavior of physical and physico-chemical absorbents in terms of CO2 solubility and regeneration efficiency. The ionic liquid 1-ethyl-3-methylimidazolium acetate, [emim][Ac], was presented as a suitable alternative to conventional amine-based absorbents. Then, a rigorous two-dimensional mathematical model of the MVR process in a HFMC was developed based on a pseudo-steady-state to understand the influence of the solvent regeneration process in the absorption–desorption process. CO2 absorption–desorption experiments in PP-HFMC at different operating conditions for desorption, varying vacuum pressure and temperature, were used for model validation. Results showed that MVR efficiency increased from 3% at room temperature and 500 mbar to 95% at 310 K and 40 mbar vacuum. Moreover, model deviation studies were carried out using sensitivity analysis of Henry’s constant and pre-exponential factor of chemical interaction, thus as to contribute to the knowledge in further works.
Highlights
Carbon dioxide concentration in the atmosphere is continuing to increase due to the global energy demand, deeply dependent on fossil fuels, due to population and economic growth
On the other hand, strategies are based on CO2 capture and sequestration (CCS), which is centered on CO2 long term storage, and CO2 capture and utilization (CCU) to convert CO2 into useful products [2]
The specific aims of this work are to provide new data of these imidazolium-based ionic liquids (ILs) related to the CO2 desorption behavior and to develop a comprehensive two dimensional (2D) mathematical model to study the CO2 membrane vacuum regeneration in a coupled system of a polypropylene hollow fiber membrane contactors (HFMC) and an IL
Summary
Carbon dioxide concentration in the atmosphere is continuing to increase due to the global energy demand, deeply dependent on fossil fuels, due to population and economic growth. On the one hand, promoting green energy sources, reducing the carbon-based fuel industry are calling attention. On the other hand, strategies are based on CO2 capture and sequestration (CCS), which is centered on CO2 long term storage, and CO2 capture and utilization (CCU) to convert CO2 into useful products [2]. Both types of strategies for
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