Techno-economic assessment of blast furnace gas pre-combustion decarbonisation integrated with the power generation
Techno-economic assessment of blast furnace gas pre-combustion decarbonisation integrated with the power generation
Aiming at the iron and steel industry decarbonisation with blast furnace gas (BFG) utilisation, a techno-economic feasibility of the pre-combustion carbon capture with methyl diethanolamine (MDEA) is evaluated herein. The effectiveness of water gas shift (WGS) implementation on the capture performance is also investigated. The integration of a power plant with decarbonised fuel from the capture unit is taken into account from both technical and economic perspectives. Aspen Plus® is used to develop the process. The results obtained from the techno-economic analysis showed that the WGS implementation increases the capture efficiency from 46.5% to 83.8%, with increased CO2 capture cost from € 39.8/tCO2 to €44.3/tCO2. The sensitivity analysis on the effect of 1) different BFG composition and 2) different carbon capture rate (CCR) on the capture unit integrated with WGS performance is performed. The obtained results revealed that BFG with a lower calorific value is less practical from a techno-economic point of view as it increases the specific primary energy consumption for CO2 capture avoidance (SPECCA) from 3.3MJLHV/kgCO2 to 3.8MJLHV/kgCO2. Moreover, the lower CCR increases the thermal energy of the H2-rich gas from the capture unit from 266.8 MW to 269.6 MW. The techno-economic advantages of the based case do not results beneficial for na environment point of view since at lower CCR the specific CO2 emissions increase from 51 kgCO2/GJLHV to 70 kgCO2/GJLHV. The fully integrated power plant to the capture unit reveals that the 37.52% (without WGS) and 24.27% (with WGS) efficiencies are achievable through the com bined cycle integration. For the combined cycle, the integration of WGS reactor will reduce the CO2 specific emission to 675.1 kgCO2/MWh in comparison to 1391.5 kgCO2/MWh for the case with no WGS.
Khallaghi, Navid
f174b488-3b3e-4591-a3f1-e252c8158539
Abbas, Syed Zaheer
3b02900e-fef6-40e1-acf7-96f26bfde4a8
Manzolini, Giampaolo
44103c13-787f-4c2d-9522-7d390ce6197f
Coninck, Eric De
c1590245-5dcb-4b31-a977-e931190d2a00
Spallina, Vincenzo
e87fad8c-a44b-48a6-9da6-f60de3ce87a5
1 March 2022
Khallaghi, Navid
f174b488-3b3e-4591-a3f1-e252c8158539
Abbas, Syed Zaheer
3b02900e-fef6-40e1-acf7-96f26bfde4a8
Manzolini, Giampaolo
44103c13-787f-4c2d-9522-7d390ce6197f
Coninck, Eric De
c1590245-5dcb-4b31-a977-e931190d2a00
Spallina, Vincenzo
e87fad8c-a44b-48a6-9da6-f60de3ce87a5
Khallaghi, Navid, Abbas, Syed Zaheer, Manzolini, Giampaolo, Coninck, Eric De and Spallina, Vincenzo
(2022)
Techno-economic assessment of blast furnace gas pre-combustion decarbonisation integrated with the power generation.
Energy Conversion and Management, 255, [115252].
(doi:10.1016/j.enconman.2022.115252).
Abstract
Aiming at the iron and steel industry decarbonisation with blast furnace gas (BFG) utilisation, a techno-economic feasibility of the pre-combustion carbon capture with methyl diethanolamine (MDEA) is evaluated herein. The effectiveness of water gas shift (WGS) implementation on the capture performance is also investigated. The integration of a power plant with decarbonised fuel from the capture unit is taken into account from both technical and economic perspectives. Aspen Plus® is used to develop the process. The results obtained from the techno-economic analysis showed that the WGS implementation increases the capture efficiency from 46.5% to 83.8%, with increased CO2 capture cost from € 39.8/tCO2 to €44.3/tCO2. The sensitivity analysis on the effect of 1) different BFG composition and 2) different carbon capture rate (CCR) on the capture unit integrated with WGS performance is performed. The obtained results revealed that BFG with a lower calorific value is less practical from a techno-economic point of view as it increases the specific primary energy consumption for CO2 capture avoidance (SPECCA) from 3.3MJLHV/kgCO2 to 3.8MJLHV/kgCO2. Moreover, the lower CCR increases the thermal energy of the H2-rich gas from the capture unit from 266.8 MW to 269.6 MW. The techno-economic advantages of the based case do not results beneficial for na environment point of view since at lower CCR the specific CO2 emissions increase from 51 kgCO2/GJLHV to 70 kgCO2/GJLHV. The fully integrated power plant to the capture unit reveals that the 37.52% (without WGS) and 24.27% (with WGS) efficiencies are achievable through the com bined cycle integration. For the combined cycle, the integration of WGS reactor will reduce the CO2 specific emission to 675.1 kgCO2/MWh in comparison to 1391.5 kgCO2/MWh for the case with no WGS.
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Published date: 1 March 2022
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Local EPrints ID: 474506
URI: http://eprints.soton.ac.uk/id/eprint/474506
ISSN: 0196-8904
PURE UUID: 0209e7cb-5297-4e0d-8e0e-4a6065024ff7
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Date deposited: 23 Feb 2023 17:40
Last modified: 17 Mar 2024 04:18
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Author:
Navid Khallaghi
Author:
Syed Zaheer Abbas
Author:
Giampaolo Manzolini
Author:
Eric De Coninck
Author:
Vincenzo Spallina
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