Development of internally circulating fluidized bed reactor performance for enhancing direct air CO2 capture

Name: Munyapa Limahksohn

Organization : Chulalongkorn University. Faculty of Science

Name: Chatiya Tripoonsuk

Organization : Chulalongkorn University. Faculty of Science

Name: Benjapon Chalermsinsuwan

Organization : Chulalongkorn University. Faculty of Science

Name: Pornpote Piumsomboon

Organization : Chulalongkorn University. Faculty of Science

Email : pornpote.p@chula.ac.th

keyword: Heat regeneration

LCSH: Carbon dioxide -- Environmental aspects

LCSH: Carbon sequestration

LCSH: Greenhouse gases

Abstract: Climate change, mainly driven by greenhouse gas emissions such as carbon dioxide (CO₂), poses a critical challenge to global environmental stability. CO₂ capture technologies play a vital role in achieving this goal. Recently, several carbon capture technologies have been proposed. Among them, the gaseous-solid adsorption is a promising alternative. In this research, the internally circulating fluidized bed (ICFB) reactor, combining CO₂ adsorption and sorbent regeneration processes in a single unit, was chosen for the direct air CO₂ capture process due to its compact configuration. This study uses alumina as a solid sorbent and focuses on determining the proper operating regeneration conditions to achieve the best performance of the ICFB system. Since CO₂ desorption is endothermic, heating is necessary to improve solid sorbent regeneration and system efficiency. Three key parameters of the process operation were investigated. These are the regeneration temperature, gas velocity, and heater placement in the downer. Results reveal that the ICFB system can operate continuously. Both the downer temperature and heating location consequently have an impact on the overall CO₂ capture performance. Under room-temperature adsorption and desorption, CO₂ concentration initially drops sharply before gradually increasing and stabilizing. With heat-assisted regeneration, CO₂ concentration in the riser remains lower than the inlet concentration by 30% when the system reaches a steady state, improving adsorption performance. However, excessively high regeneration temperatures negatively impact adsorption. The findings highlight the importance of thermal management in the downer and offer practical insights for optimizing ICFB reactor configurations.

King Mongkut's University of Technology North Bangkok. Central Library

Address: BANGKOK

Email: library@kmutnb.ac.th

Created: 2025

Modified: 2025-08-04

Issued: 2025-08-04

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BibliograpyCitation : In Thai Institute of Chemical Engineering and Applied Chemistry and Khon Kaen University. Faculty of Engineering. The 34th Thai Institute of Chemical Engineering and Applied Chemistry International Conference (TIChE 2025) (TIChE 2025 TIChE-SG-32). Bangkok : Thai Institute of Chemical Engineering and Applied Chemistry, 2025

eng

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