This study reports on a preliminary investigation concerning the role of water vapour in calcium looping cycles, and is based on results of an experimental campaign performed in a lab-scale fluidized bed reactor under operating conditions that are representative of a realistic calcium looping process. Tests have been designed so as to characterize the effect of steam in either the calcination or the carbonation stages, or in both. A reference limestone has been used as sorbent. Uptake of CO2 by the Ca-based sorbent with and without exposure to steam during the calcination and carbonation stages has been correlated with results of porosimetric characterization of the samples. Results indicate that exposure to steam is beneficial as it improves in any case the ultimate CO2 uptake. Exposure to steam during the calcination stage favours the development of accessible porosity, inducing incremental CO2 uptake in the order of 10% with respect to a reference no-steam case. Exposure to steam during the carbonation stage is also favourable, due to the positive role of steam as a “catalyst” for CO2 diffusion through the sorbent CaCO3-based product layer. Synergistic effects were observed when steam was added during both the calcination and carbonation stages, resulting in a very pronounced increase of sorbent CO2 capture capacity as compared with the no-steam case.
Calcium looping for post-combustion CO2 capture – Effect of water vapour / Coppola, Antonio; Montagnaro, Fabio; Scala, Fabrizio; Salatino, Piero. - (2016), pp. 1-5. (Intervento presentato al convegno 39th Meeting of the Italian Section of The Combustion Institute tenutosi a Napoli nel 4-6 Luglio 2016).
Calcium looping for post-combustion CO2 capture – Effect of water vapour
COPPOLA, ANTONIO;MONTAGNARO, FABIO;SCALA, FABRIZIO;SALATINO, PIERO
2016
Abstract
This study reports on a preliminary investigation concerning the role of water vapour in calcium looping cycles, and is based on results of an experimental campaign performed in a lab-scale fluidized bed reactor under operating conditions that are representative of a realistic calcium looping process. Tests have been designed so as to characterize the effect of steam in either the calcination or the carbonation stages, or in both. A reference limestone has been used as sorbent. Uptake of CO2 by the Ca-based sorbent with and without exposure to steam during the calcination and carbonation stages has been correlated with results of porosimetric characterization of the samples. Results indicate that exposure to steam is beneficial as it improves in any case the ultimate CO2 uptake. Exposure to steam during the calcination stage favours the development of accessible porosity, inducing incremental CO2 uptake in the order of 10% with respect to a reference no-steam case. Exposure to steam during the carbonation stage is also favourable, due to the positive role of steam as a “catalyst” for CO2 diffusion through the sorbent CaCO3-based product layer. Synergistic effects were observed when steam was added during both the calcination and carbonation stages, resulting in a very pronounced increase of sorbent CO2 capture capacity as compared with the no-steam case.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.