Techno-economic assessment and optimization of a solar-assisted industrial post-combustion CO2 capture and utilization plant

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Show simple item record Shirmohammadi, Reza Aslani, Alireza Ghasempour, Roghayeh Romeo, Luis M. Petrakopoulou, Foteini Konstantina 2022-04-28T09:05:55Z 2022-04-28T09:05:55Z 2021-11
dc.identifier.bibliographicCitation Díaz-Caneja, C. M., Alloza, C., Gordaliza, P. M., Fernández-Pena, A., de Hoyos, L., Santonja, J., Buimer, E. E. L., van Haren, N. E. M., Cahn, W., Arango, C., Kahn, R. S., Hulshoff Pol, H. E., Schnack, H. G., & Janssen, J. (2021). Sex Differences in Lifespan Trajectories and Variability of Human Sulcal and Gyral Morphology. Cerebral Cortex, 31(11), 5107–5120.
dc.identifier.issn 2352-4847
dc.description.abstract This paper studies the techno-economic feasibility of the solar-assisted regeneration process of the largest industrial CO2 removal monoethanolamine-based plant in Iran. The plant incorporating parabolic troughs is modelled using System Advisor Model software and the weather data are derived from the European Commission's Photovoltaic Geographical Information System. Sensitivity analyses are realized to evaluate the effect of important parameters, i.e., the solar multiple and the hours of storage, and to reveal the optimum case. The studied impacts are linked to the overall net energy generation and the levelized cost of heat (LCOH). The optimum case is found to have a solar multiple of 3.1 and 18-hours of storage, resulting in a solar share of 0.7 and a LCOH of 3.85 (¢/kWh). When compared to the base case (solar multiple of 2 and 6 h of storage), the optimum solution results in a similar LCOH but it achieves the generation of an additional 16,112 MWhth annually. The thermal energy supplied by the solar system leads to an annual reduction in the natural gas consumption of approximately 3.8 million m3 that results in a CO2 emission reduction of 7.1 kton.
dc.description.sponsorship The corresponding authors would like to acknowledge the University of Tehran and the Iran’s National Elites Foundation for providing support at this work. The authors would also like to thank Paul Gilman from SAM support at the National Renewable Energy Laboratory. Last but not least, technical supports of the Kermanshah Petrochemical Industries Co. and the Shahrekord Carbon Dioxide Co. are gratefully acknowledged. Fontina Petrakopoulou would like to thank the Spanish Min- istry of Science, Innovation and Universities and the Universi- dad Carlos III de Madrid (Ramón y Cajal Programme, RYC-2016- 20971).
dc.format.extent 15
dc.language.iso eng
dc.publisher Elsevier
dc.rights (copyright) 2021 The Authors
dc.rights Atribución 3.0 España
dc.subject.other Industrial process heat
dc.subject.other Parabolic trough collector
dc.subject.other Parametric analysis
dc.subject.other Solar-assisted carbon capture systems
dc.subject.other System advisor model
dc.title Techno-economic assessment and optimization of a solar-assisted industrial post-combustion CO2 capture and utilization plant
dc.type article
dc.subject.eciencia Energías Renovables
dc.rights.accessRights openAccess
dc.relation.projectID Gobierno de España. RYC-2016-20971
dc.type.version publishedVersion
dc.identifier.publicationfirstpage 7390
dc.identifier.publicationlastpage 7404
dc.identifier.publicationtitle Energy Reports
dc.identifier.publicationvolume 7
dc.identifier.uxxi AR/0000030416
dc.contributor.funder Ministerio de Ciencia, Innovación y Universidades (España)
dc.contributor.funder Universidad Carlos III de Madrid
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