Carbon Dioxide Capture from Model Marine Diesel Engine Exhaust by means of K₂CO₃-Based Sorbents

Abstract

The on-board ship installation of a high-efficiency and low-cost CO₂ separation unit seems to be an attractive option to comply with recent regulations aimed at reducing the carbon footprint derived from the maritime sector. Our research group is currently developing a capture and storage scheme based on the use of potassium carbonate for CO₂ conversion into solid potassium bicarbonate.
In this paper, we summarize preliminary CO₂ capture tests on both raw and alumina-supported K₂CO₃ carried out in a fixed bed apparatus under typical model marine diesel engine exhaust composition (CO₂ 5 %, H₂O 5 %, N₂ 90 % by vol.) and temperatures (60 - 105 °C). Carbonation data for the parent bulk K₂CO₃ showed a maximum capture capacity of 0.138 mmol g^-1 corresponding to a nearly 2 % sorbent utilization factor. An increase in the operating temperature produced a reduction of the carbonation capacity and faster capture kinetics. The alumina-supported sorbent tested at 60 °C displayed enhanced CO₂ capture capacity with a maximum conversion degree of 43 %. This testifies the positive effect derived by the dispersion of the active phase onto a substrate with large surface area in the CO₂ capture process, likely for a remarkable reduction of diffusion limitations during the carbonation reaction in the case of nano-sized potassium carbonate with respect to granular sorbents.