Abstract
A piperazine (PZ)-promoted methyldiethanolamine (MDEA) solution for a carbon dioxide (CO2) removal process from the flue gas of a large-scale coal power plant has been simulated. An Aspen Plus® was used to perform the simulation process. Initially, the effects of MDEA/PZ concentration ratio and stripper pressure on the regeneration energy of CO2 capture process were investigated. The MDEA/PZ concentration ratio of 35/15 wt.% (35 wt. MDEA and 15 wt.% PZ) was selected as an appropriate concentration. The reboiler duty of 3.235 MJ/kg CO2 was obtained at 35/15 wt.% concentration ratio of MDEA/PZ. It was considered a reference or base case, and process modifications including rich vapor compression (RVC) process, cold solvent split (CSS), and the combination of both processes were investigated to check its effect on the energy requirement. A total equivalent work of 0.7 MJe/kg CO2 in the RVC and a reboiler duty of 2.78 MJ/kg CO2 was achieved in the CSS process. Similarly, the total equivalent work, reboiler duty, and condenser duty of 0.627 MJe/kg CO2, 2.44 MJ/kg CO2, and 0.33 MJ/kg CO2, respectively, were obtained in the combined process. The reboiler duty and the total equivalent work were reduced by about 24.6 and 16.2%, respectively, as compared to the reference case. The total energy cost saving was 1.79 M$/yr. Considering the additional equipment cost in the combined process, the total cost saving was 0.67 M$ per year.
Highlights
Carbon dioxide (CO2) capture through post-combustion with chemical solvent absorption approach is a promising and leading technology
It is shown that the reboiler duty of MDEA/PZ-based CO2 capture process is lower than the MEA-based process
The rich vapor compression (RVC) with cold solvent split (CSS) process can save 16.2% of total equivalent energy, which is greater than 8.4% of RVC+CSS and 3.3% of lean vapor compression (LVC)+CSS in MEA-based processes
Summary
Carbon dioxide (CO2) capture through post-combustion with chemical solvent absorption approach is a promising and leading technology It is a flexible and viable technique to abate CO2 emissions from the flue gas of power plants [1,2]. Aqueous amine solvents are mostly used for CO2 capture processes from coal power plants and are considered at a mature stage of technical development [3]. These amines are classified into primary amines (monoethanolamine (MEA) and diglycolamine (DGA)), Secondary amines (diisopropylamine (DIPA) and diethanolamine (DEA)), and tertiary amines (N-methyldiethanolamine (MDEA) and triethanolamine (TEA)). In the case of tertiary amines, unlike primary and secondary amines, the reactivity is low but they require less heat of regeneration [4]
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