Performance Evaluation of an Inventive CO2 Gas Separation Inorganic Ceramic Membrane
| Autor: | Ngozi Nwogu, Kajama, Mohammed, Gobina, Edward |
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| Jazyk: | angličtina |
| Rok vydání: | 2015 |
| Předmět: | |
| DOI: | 10.5281/zenodo.1107103 |
| Popis: | Atmospheric carbon dioxide emissions are considered as the greatest environmental challenge the world is facing today. The tasks to control the emissions include the recovery of CO2 from flue gas. This concern has been improved due to recent advances in materials process engineering resulting in the development of inorganic gas separation membranes with excellent thermal and mechanical stability required for most gas separations. This paper, therefore, evaluates the performance of a highly selective inorganic membrane for CO2 recovery applications. Analysis of results obtained is in agreement with experimental literature data. Further results show the prediction performance of the membranes for gas separation and the future direction of research. The materials selection and the membrane preparation techniques are discussed. Method of improving the interface defects in the membrane and its effect on the separation performance has also been reviewed and in addition advances to totally exploit the potential usage of this innovative membrane. {"references":["Takaba H, Mizukami K, Kubo M, Stirling A, Miyamoto A. The effect of\ngas molecule affinities on CO 2 separation from the CO 2/N 2 gas\nmixture using inorganic membranes as investigated by molecular\ndynamics simulation. Journal of Membrane Science. 1996; 121(2):251-\n259.","Niswander R, Edwards D, DuPart M, Tse J. A more energy efficient\nproduct for carbon dioxide separation. Separation Science and\nTechnology. 1993; 28(1-3):565-578.","Rao AB, Rubin ES. A technical, economic, and environmental\nassessment of amine-based CO2 capture technology for power plant\ngreenhouse gas control. Environmental science & technology. 2002;\n36(20):4467-4475.","Herzog H, Drake E, Adams E. CO2 capture, reuse, and storage\ntechnologies for mitigating global climate change. A White Paper. 1997","Nwogu NC and Gobina G. Advanced Membrane Design for Improved\nCarbon Dioxide Capture. Abstracts of Papers of the American Chemical\nSociety: Amer Chemical Soc 1155 16th St, Nw, Washington, Dc 20036\nUsa; 2013.","Nwogu N, Kajama M, Okon E, Shehu H, Gobina E. Testing of Gas\nPermeance Techniques of a Fabricated CO2 Permeable Ceramic\nMembrane for Gas Separation Purposes. 2014.","Nwogu NC, Gobina E, Kajama MN. Improved carbon dioxide capture\nusing nanostructured ceramic membranes. Low Carbon Economy. 2013;\n4(03):125.","Kluiters S. Status review on membrane systems for hydrogen separation.\nEnergy Research Centre of the Netherlands: Petten, The Netherlands.\n2004; 168.","El‐Halwagi MM. Synthesis of reverse‐osmosis networks for waste\nreduction. AIChE Journal. 1992; 38(8):1185-1198.\n[10] Pan C. Gas separation by permeators with high‐flux asymmetric\nmembranes. AIChE Journal. 1983; 29(4):545-552.\n[11] Rui Z, Anderson M, Lin Y, Li Y. Modeling and analysis of carbon\ndioxide permeation through ceramic-carbonate dual-phase membranes.\nJournal of Membrane Science. 2009; 345(1):110-118.\n[12] Krovvidi K, Kovvali A, Vemury S, Khan A. Approximate solutions for\ngas permeators separating binary mixtures. Journal of Membrane\nScience. 1992; 66(2):103-118.\n[13] Qi R, Henson MA. Modeling of spiral-wound permeators for\nmulticomponent gas separations. Industrial & Engineering Chemistry\nResearch. 1997; 36(6):2320-2331.\n[14] Coker D, Freeman B, Fleming G. Modeling multicomponent gas\nseparation using hollow‐fiber membrane contactors. AIChE Journal.\n1998; 44(6):1289-1302.\n[15] Bounaceur R, Lape N, Roizard D, Vallieres C, Favre E. Membrane\nprocesses for post-combustion carbon dioxide capture: a parametric\nstudy. Energy. 2006; 31(14):2556-2570."]} |
| Databáze: | OpenAIRE |
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