Applied Chemical Engineering

In this paper, the preparation of potassium carbonate modified SiO₂-Al₂O₃ composite aerogel, the carbonation characteristics of K₂CO₃ and the decarburization characteristics of regeneration cycle were studied. The influence of loading rate on CO₂ adsorption was studied by using a fixed bed reactor, and the microstructure of the samples was analyzed by combining SEM and BET. The results show that during the alkali fusion sintering of Na₂CO₃, the Si-O-Si and Si-O-Al bonds break, the crystal structure is destroyed, and the covalent bond of mullite is transformed into the ionic bond of nepheline. Through orthogonal test, taking the specific surface area of aerogel as the measurement index, the optimal calcination conditions are determined as follows: 900 ℃, reaction for 60 min, Na₂CO₃ addition ratio of 0.5. The more K₂CO₃ is loaded, the less the corresponding active sites on the surface of the carrier. When the loading is 30%, the maximum CO₂ adsorption capacity is 2.86 mmol·g^–1. Excess K₂CO₃ will plug the pore structure, destroy the diffusion of CO₂, and reduce the diffusion and utilization efficiency. The percentage of mesoporous pore volume decreased from 94.21% to 89.32%, indicating that the active component K₂CO₃ was mainly filled in the mesoporous. After 10 cycle regeneration tests, the CO₂ adsorption capacity of the adsorbent decreased by 10.49%. The pore structure of the adsorbent was stable and the decarburization performance was excellent.

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