This paper investigates the application of K2CO3 supported onto porous alumina, as sorbent for selective CO2 capture in marine applications. Alumina-functionalized sorbents were prepared by incipient wetness impregnation achieving K2CO3 loadings from 3.6 to 14.1% wt. Carbonation tests were performed in a fixed-bed column at temperatures between 60 and 105 °C, as those typically occurring at the outlet of a scrubber and/or a waste heat recovery unit, with a model diesel engine exhaust (5% vol. CO2, 5% vol. H2O, balance N2). According to the carbonate loading, the sorbents may reach conversion degrees of carbonate up to 90% and overall capture capacity up to 0.66 mol kg−1 sorbent. Experimental data showed higher conversion degree and capture capacity compared with unsupported K2CO3, which is affected by significant intraparticle diffusion limitations. Steam regeneration tests performed in a fixed-bed column on the sorbent with 3.6% wt K2CO3 loading revealed that a temperature of 120 °C assures almost complete recovery of captured CO2 while preserving the sorbent carbonation degree for 10 consecutive carbonation/regeneration cycles. The preliminary design of a temperature swing carbonation/regeneration unit for on-board ship installation was performed for the reference case study of a passenger ship equipped with a 4.35MW marine engine fueled with marine gas oil and with a commercial seawater scrubber for SO2 removal. The proposed unit appeared able to cut up to 30% carbon dioxide emission by using the sorbent containing 3.6% wt K2CO3 and operating the carbonation and regeneration stage at 60 and 120 °C, respectively.

Utilization of alumina-supported K2CO3as CO2-selective sorbent: A promising strategy to mitigate the carbon footprint of the maritime sector / Erto, Alessandro; Balsamo, Marco; Paduano, LIANA PASQUALINA; Lancia, Amedeo; Di Natale, Francesco. - In: JOURNAL OF CO2 UTILIZATION. - ISSN 2212-9820. - 24:(2018), pp. 139-148. [10.1016/j.jcou.2017.12.014]

Utilization of alumina-supported K2CO3as CO2-selective sorbent: A promising strategy to mitigate the carbon footprint of the maritime sector

Erto, Alessandro;Balsamo, Marco
;
PADUANO, LIANA PASQUALINA;Lancia, Amedeo;Di Natale, Francesco
2018

Abstract

This paper investigates the application of K2CO3 supported onto porous alumina, as sorbent for selective CO2 capture in marine applications. Alumina-functionalized sorbents were prepared by incipient wetness impregnation achieving K2CO3 loadings from 3.6 to 14.1% wt. Carbonation tests were performed in a fixed-bed column at temperatures between 60 and 105 °C, as those typically occurring at the outlet of a scrubber and/or a waste heat recovery unit, with a model diesel engine exhaust (5% vol. CO2, 5% vol. H2O, balance N2). According to the carbonate loading, the sorbents may reach conversion degrees of carbonate up to 90% and overall capture capacity up to 0.66 mol kg−1 sorbent. Experimental data showed higher conversion degree and capture capacity compared with unsupported K2CO3, which is affected by significant intraparticle diffusion limitations. Steam regeneration tests performed in a fixed-bed column on the sorbent with 3.6% wt K2CO3 loading revealed that a temperature of 120 °C assures almost complete recovery of captured CO2 while preserving the sorbent carbonation degree for 10 consecutive carbonation/regeneration cycles. The preliminary design of a temperature swing carbonation/regeneration unit for on-board ship installation was performed for the reference case study of a passenger ship equipped with a 4.35MW marine engine fueled with marine gas oil and with a commercial seawater scrubber for SO2 removal. The proposed unit appeared able to cut up to 30% carbon dioxide emission by using the sorbent containing 3.6% wt K2CO3 and operating the carbonation and regeneration stage at 60 and 120 °C, respectively.
2018
Utilization of alumina-supported K2CO3as CO2-selective sorbent: A promising strategy to mitigate the carbon footprint of the maritime sector / Erto, Alessandro; Balsamo, Marco; Paduano, LIANA PASQUALINA; Lancia, Amedeo; Di Natale, Francesco. - In: JOURNAL OF CO2 UTILIZATION. - ISSN 2212-9820. - 24:(2018), pp. 139-148. [10.1016/j.jcou.2017.12.014]
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11588/697564
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