Increased efficiency of a fuel cell using h-BN electrodes and Teflon polymer electrolyte [-C2F4-]n

  • A. Chitsazan Universidad del Zulia
  • M. Monajjemi Department of Chemical Engineering, Central Tehran Branch, Islamic Azad University
  • H. Aghaei Department of Chemistry, Science and research Branch, Islamic Azad University
DOI: https://doi.org/10.46925//rdluz.29.05

Resumen

Graphene and h-BN have been theoretically simulated for hydrogen storage and oxygen diffusion in a single fuel cell unit. Obviously, the efficiency of the PEM hydrogen fuel cells was significantly related to the amount of H2 concentration, the water activities in catalyst substrates and the polymer of the electrolyte membranes, the temperature and the dependence of such variables in the direction of the fuel and air currents between the anode path and the cathode. The single PEM parameter has been estimated and the results show greater fuel cell efficiency using graphene sheets and h-BN. Maximum efficiency is observed with the stoichiometry of the 5H2, 5O2 and 3 C2F4 molecules during adsorption.

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Biografía del autor/a

A. Chitsazan, Universidad del Zulia
Profesor de la Universidad del Zulia
M. Monajjemi, Department of Chemical Engineering, Central Tehran Branch, Islamic Azad University
Professor of Department of Chemical Engineering, Central Tehran Branch, Islamic Azad University
H. Aghaei, Department of Chemistry, Science and research Branch, Islamic Azad University
Professor of Department of Chemistry, Science and research Branch, Islamic Azad University

Citas

Besler, B.H., Merz, K.M., Kollman, P.A. (1990). Atomic charges derived from semi empirical methods J. comp. Chem (11): 431-439, DOI: 10.1002/jcc.540110404

Borup R. (2007). Scientific aspects of polymer electrolyte fuel cell durability and degradation. CHEMICAL REVIEWS, 107(10), 3904-3951.

Bosco , A .D. P., Fronk, M .H. (2000). Fuel cell flooding detection and correction, US Patent 6,103,409.

Chirlian, L.E., Francl, M.M. (1987). Atomic charges derived from electrostatic potentials: A detailed study. J.comp.chem (8): 894-905, DOI: 10.1002/jcc.540080616

Ciureanu, M., (2004). Effects of nafion dehydration in pem fuel cells. Journal of Applied Electrochemistry, 34(7):705-714

Cruz-Manzo, S., Chen, R., Rama P. (2013). Study of current distribution and oxygen diffusion in the fuel cell cathode catalyst layer through electrochemical impedance spectroscopy. International Journal of Hydrogen Energy, 38(3), 1702- 1713

De Bruijn, FA., Dam, VAT., (2008). Janssen GJM. Review: Durability and degradation issues of PEM fuel cell components. Fuel Cells, 8(3), 22

Dutta, S., Shimpalee, S., Van, Zee J W. (2000). Three-dimensional numerical simulation of straight channel pem fuel cells. Journal of Applied Electrochemistry, 2000, 30(2):135-146

Futerko, P., Hsing, I., (2000). Two-dimensional finite-element method study of the resistance of membranes in polymer electrolyte fuel cells, Electrochimica Acta, 45(11):1741-1751

Gurau V. (1998). Two-dimensional model for proton exchange membrane fuel cells. AIChE Journal, 44(11):2410- 2422

Karimi, G. (2011). Along-channel flooding prediction of polymer electrolyte membrane fuel cells. International Journal of Energy Research, 35(10):883-896

Kazmi, I. H., Bhatti, A. I., Iqbal, S. A. (2009). nonlinear observer for pem fuel cell system.Multitopic Conference, IEEE 13th International, pages 1-6

Larminie, J., Dicks, A. (2003). Fuel Cell Systems Explained. J. Wiley

Le ,Canut J. , Abouatallah, R. M., Harrington, D. A., (2006). Detection of membrane drying, fuel cell flooding, and anode catalyst poisoning on pemfc stacks by electrochemical impedance spectroscopy, 153(5): 857-864

Litster, S., McLean, G. (2004). PEM fuel cell electrodes. Journal of Power Sources, 130(1):61, 76

Mollaamin, F. , Pham, T., Dang, D. , Monajjemi, M., Mau Dang, C. (2019). Modelling and Controlling of ion transport rate efficiency in Proton exchange membrane (PEMFC), alkaline (AFC), direct methanol (DMFC), phosphoric acid (PAFC), direct forming acid (DFAFC) and direct carbon (DCFC) fuel cells, Biointerface Research in Applied Chemistry, 9 (4), 2019, 4050 – 4059.

Pasaogullari, U., Wang, C. (2005). Two-phase modeling and flooding prediction of polymer electrolyte fuel cells. Journal of The Electrochemical Society, 152(2): 380-390

Perdew, J. P, Burke, K. (1996). Ernzerhof, Generalized Gradient Approximation Made Simple. Phys. Rev. Lett, (77): 3865-3868

Pukrushpan, J .T., Peng, H., Stefanopoulou, A .G. (2004). Control-oriented modeling and analysis for automotive fuel cell systems. Journal of Dynamic Systems, Measurement and Control, 126:14

Rowe, A., Li, X. (2001). Mathematical modeling of proton exchange membrane fuel cells, Journal of Power Sources, 102(1):82-96

Schmidt, M.W., Baldridge, k.k., Boatz, J.A., Elbert, S.T., Gordon, Ms., Jensen, JH., Koseki, S., Matsunaga, N., Nguyen, K.A et al. (2004). General atomic and molecular electronic structure system. J Compt chem , 14(11): 1347–1363

Schmittinger, W., Vahidi, A., (2008). A review of the main parameters influencing longterm performance and durability of PEM fuel cells. Journal of Power Sources, 180(1):1- 14

Siegel, C. (2008). Review of computational heat and mass transfer modeling in polymerelectrolyte-membrane (pem) fuel cells. Energy, 33(9):1331-1352

Tao, W. Q., Min, C. H., Liu, X. L., He, L. Y., Yin, B. H., Jiang, W. (2006). Parameter sensitivity examination and discussion of PEM fuel cell simulation model validation: Part i. current status of modeling research and model development. Journal of Power Sources, 160(1):359-373

Wang, Z. H., Wang, C .Y., Chen, K. S., (2001). Two-phase flow and transport in the air cathode of proton exchange membrane fuel cells. Journal of Power Sources, 94(1):40- 50

Yao, K. Z., Karan, K., McAuley, K. B., Oosthuizen, P., Peppley, B., Xie, T., (2004). A review of mathematical models for hydrogen and direct methanol polymer electrolyte membrane fuel cells. Fuel Cells, 4(1), 3-29

Zawodzinski, T .A, Derouin ,C., Radzinski, S., Sherman, R. J., Smith, V. T., Springer, T. E., Gottesfeld ,S.’ (1993). Water uptake by and transport through nafion membranes, 140(4):1041-1047.

Zhao, Y., Truhlar, DG. (2008). The M06 suite of density functional for main group thermochemistry, thermochemical kinetics, non-covalent interactions, excited states, and transition elements: two new functional and systematic testing of four M06-class functional and 12 other functional. Theor Chem Account 2008; 120:215–241

Publicado
2020-03-26
Cómo citar
Chitsazan, A., Monajjemi, M., & Aghaei, H. (2020). Increased efficiency of a fuel cell using h-BN electrodes and Teflon polymer electrolyte [-C2F4-]n. Revista De La Universidad Del Zulia, 11(29), 60-78. https://doi.org/10.46925//rdluz.29.05
Número
Vol. 11 Núm. 29 (2020): Revista de la Universidad del Zulia, Número 29, Ciencias del Agro, Ingeniería y Tecnología
Sección
Artículos

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