TY - JOUR
T1 - Comparative life cycle assessment (LCA) of accelerated carbonation processes Using Steelmaking Slag for CO2 Fixation
AU - Xiao, Li Shan
AU - Wang, Run
AU - Chiang, Pen Chi
AU - Pan, Shu Yuan
AU - Guo, Qing Hai
AU - Chang, E. E.
PY - 2014
Y1 - 2014
N2 - Carbon capture, utilization, and storage (CCUS) is one of the most prominent emerging technologies for mitigating global climate change. In this study, a comparative evaluation for CO2 fixation by carbonation of steelmaking slag was performed by life cycle assessment (LCA) using Umberto 5.5.4 software, with the Swiss Eco-invent 2.2 database. Six scenarios of carbonation for basic oxygen furnace slag (BOFS), steel converted slag (SCS), and blended hydraulic slag cement (BHC) in different types of reactors and/or method were established. The environmental impacts for each scenario are quantified using the valuation system of ReCiPe, where global warming potential (GWP), ecosystem quality potential (EQP), and human health potential (HHP) were evaluated. In addition, sensitivity analysis was carried out to evaluate the relevant uncertainties of heating efficiency on the GHG emissions in direct carbonation processes. According to the results of LCA and sensitivity analysis, the direct carbonation of steelmaking slag in a slurry reactor was found to be the most attractive method, since the GWP was the lowest among the selected scenarios. Furthermore, the best available technology (BAT) for CO2 capture by carbonation processes of alkaline wastes was proposed according to the key performance indicators (KPIs) with respect to engineering considerations and environmental impacts. It was concluded that the accelerated carbonation of steelmaking slag should be performed by combining the slurry reactor with a rotating packed bed (RPB) to maximize carbonation conversion and minimize environmental impacts and additional CO2 emissions.
AB - Carbon capture, utilization, and storage (CCUS) is one of the most prominent emerging technologies for mitigating global climate change. In this study, a comparative evaluation for CO2 fixation by carbonation of steelmaking slag was performed by life cycle assessment (LCA) using Umberto 5.5.4 software, with the Swiss Eco-invent 2.2 database. Six scenarios of carbonation for basic oxygen furnace slag (BOFS), steel converted slag (SCS), and blended hydraulic slag cement (BHC) in different types of reactors and/or method were established. The environmental impacts for each scenario are quantified using the valuation system of ReCiPe, where global warming potential (GWP), ecosystem quality potential (EQP), and human health potential (HHP) were evaluated. In addition, sensitivity analysis was carried out to evaluate the relevant uncertainties of heating efficiency on the GHG emissions in direct carbonation processes. According to the results of LCA and sensitivity analysis, the direct carbonation of steelmaking slag in a slurry reactor was found to be the most attractive method, since the GWP was the lowest among the selected scenarios. Furthermore, the best available technology (BAT) for CO2 capture by carbonation processes of alkaline wastes was proposed according to the key performance indicators (KPIs) with respect to engineering considerations and environmental impacts. It was concluded that the accelerated carbonation of steelmaking slag should be performed by combining the slurry reactor with a rotating packed bed (RPB) to maximize carbonation conversion and minimize environmental impacts and additional CO2 emissions.
KW - Environmental impacts
KW - ReCiPe
KW - Rotating packed bed
KW - Sensitivity analysis
KW - Technology assessment
KW - Umberto
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U2 - 10.4209/aaqr.2013.04.0121
DO - 10.4209/aaqr.2013.04.0121
M3 - Article
AN - SCOPUS:84897887150
SN - 1680-8584
VL - 14
SP - 892
EP - 904
JO - Aerosol and Air Quality Research
JF - Aerosol and Air Quality Research
IS - 3
ER -