Palavras-chave
Como Citar
Resumo
The World Energy consumption has been increasing steadily since industrialization, this recent increase is also the major cause for the raise of CO2 concentration in the atmosphere. Fossil fuels play a central role in our energy consumption; actually the CCS technology and their operations in power systems must get a prominent role in reducing total CO2 emissions. An attempt to tackle the problem of solvent based Post Combustion Carbon Capture process optimization requires the availability of a rigorous process model along with a design methodology. During the modeling, much physical and chemical process should be considered in order to get more realistic results, this complexity process addressed as Reactive Separation. This report presents detailed descriptions of the process sections as well as technical documentation for the ASPEN Plus simulations including the design basis, models employed, key assumptions, design parameters, convergence algorithms, concentration and temperature profiles and calculated outputs. The main purpose is to minimize the amount of energy required in the desorption process through the optimum operating condition to the actual CO2 absorption experimental setup. The case of study is on MEA 30wt% in a coal Hired power plant. Electrolytic method is considered; the sensitive analysis was used for the Optimization.
Referências
Arachchige, U. S. P. R., & Melaeen, M. C. (2012). Aspen plus Simulation CO2 removal from Coal and gas fired power plants. Energy Procedia, 391-399.
ASPEN Tchnology (2008). Aspen Plus manual, Physical Property Model.
Chavarro Montenegro, H. J. (2011). Novel Solvents For CO2 Capture Flowsheet Analysis (pp.31-32). Manchester: University of Manchester.
Colin F. Alie (2004). CO2 Capture with MEA: Integrating the Absorption Process and Steam Cycle of an Existing Coal-Fired Power Plant. Master Thesis: Ontario, Canada.
Dugas, R. E., (2006). Pilot Plant Study of Carbon Dioxide Capture by Aqueous Monoethanolamine. Austin [Texas] USA: The University of Texas.
EPA (2008). Air Emissions Inventories. Recupered of
http://www.epa.gov/ttn/chief/net/2008inventory.html;2008 [accessed 18.07.12].
Freguia, S. (2002). Modeling of CO2 removal from Flue Gas with Mono-ethanolamine. Master Thesis, University of Texas, USA.
Global CCS Institute (2013). The Global Status of CCS: 2013. Melbourne, Australia.
Kohl A., Nielson R.(1997). Gas Purification (5th Edition). Houston [TX] USA: Guft Publishing Company.
Kothandaraman, A. (2010). Monoethanolamine System. Carbon Dioxide. In: Chemical Absorpion: A solvent compartion study (Charpter 3). USA: Massachusetts Institute of Technology.
Krótki, Aleksander (2008). Laboratory Studies of Post-combustion CO2. In Absorption with MEA and AMP Solvents (-z. pp. 371-378). Recovered DOI 10.1007/s13369-015-2008.
Manepalli, J. (2010). Green Energy Technology, Economics and Policy. In Ways of “greening the economy’ (pp. 293–307). Vienna: CRC Press Inc.
Mirfendereski, Y. M. (2008). Techno-Economic Assessment of Carbon Capture and Sequestration Technologies in the Fossil Fuel-based Power Sector of the Global Energy-Economy System. Master Thesis, Berlin Technical University, Berlin, Germany.
MIT — Massachusetts Institute of Technology (2007) “The future of coal — options for carbon constrained world 2007”.
OECD/IEA (2013). Redrawing The Energy-Climate Map World Energy Outlook Special Report, 2013, International Energy Agency, Paris, France.
Stefania Moioli, L. A. (2013). Regeneration Section of CO2 Capture Plan by MEA Scrubbing with Rate Based model. The Italian Association of Chemical Engineering Journal, 32, 1849-1854.
A Labor e Engenho utiliza a licença do Creative Commons (CC), preservando assim, a integridade dos artigos em ambiente de acesso aberto.
Downloads
