Fuel cells - the future of electricity generation for portable applications

• Autorzy: Pierozynski B.
• Języki publikacji: EN

Abstrakty

EN

Fossil fuels, including crude oil, coal and natural gas are currently the key resources for world energy supply. Hence, the majority of electrical energy production is realized via combustion of conventional fuels, such as: coal, methane and petroleum. However, increasing emissions of pollutants and greenhouse gases from fossil fuel-based electricity production (especially withrespect to SO2, NOx and CO2 discharge) bring about major environmental concerns. In addition, the status of conventional (fossil) fuel reserves is still uncertain. Thus, production of "clean" electrical energy, especially from renewable resources, such as: biomass, solar, photovoltaic, geothermal, hydro and wind energy sources becomes of significant importance to the world's economy. Fuel cells (FCs) are electrochemical cells, which convert a source fuel (e.g. H2, CH4, alcohols, etc.) into an electric current. They generate electricity inside a cell via electrochemical reactions between a fuel and an oxidant, in the presence of an electrolyte. In general, most of fuel cells can be operated as emission-free devices, based on fuels produced fromrenewable resources. With a variety of possible FC types, fuel cells could potentially serve in stationary, transportation or portable applications. This work is a review of the state-of-the-art in fuel cell technology, with respect to FC employment in portable applications.

Słowa kluczowe

EN

fossil fuel; PEM fuel cells; portable applications; renewable energy

PL

ogniwo paliwowe PEM; przenośne aplikacje; energia odnawialna; paliwo kopalne

• Wydawca: University of Warmia and Mazury in Olsztyn, Poland
• Czasopismo: Environmental Biotechnology
• Rocznik: 2008
• Tom: Vol. 4, No. 2
• Strony: 60--64
• Opis fizyczny: Bibliogr. 24 poz., rys., tab.

Twórcy

autor

Pierozynski B.

• Department of Chemistry, Faculty of Environmental Management and Agriculture, University of Warmia and Mazury in Olsztyn, Plac Lodzki 4, 10-957 Olsztyn, Poland; phone: +48 89 523-4177; fax: +48 89 523-4801,

Bibliografia

• Agnolucci, P. 2007. Economics and market prospects of portable fuel cells. International Journal of Hydrogen Energy 32: 4319-4328.
• Andreadis, G., P. Tsiakaras. 2006. Ethanol crossover and direct ethanol PEM fuel cell performance modeling and experimental validation. Chemical Engineering Science 61: 7497-7508.
• Barbir, F. 2005. PEM Fuel Cells: Theory and Practice. Elsevier Academic Press, San Diego, USA.
• Basu, S., A. Agarwal, H. Pramanik. 2008. Improvement in performance of a direct ethanol fuel cell: Effect of sulfuric acid and Ni-mesh. Electrochemistry Communications 10: 1254-1257.
• Carrette, L.,K.A. Friedrich,U. Stimming. 2001. Fuel cells - fundamentals and applications. Fuel Cells 1: 5-39.
• Cheng, H.M., Q.H. Yang, C. Liu. 2001. Hydrogen storage in carbon nanotubes. Carbon 39: 1447-1454.
• Conway, B.E., B.V. Tilak. 1992. Behavior and characterization of kinetically involved chemisorbed intermediates in electrocatalysis of gas evolution reactions. Advances in Catalysis 38: 1-147.
• Cowey, K., K.J. Green, G.O. Mepsted, R. Reeve. 2004. Portable and military fuel cells. Current Opinion in Solid State and Materials Science 8: 367-371.
• Cropper,M. 2004. Fuel cells for people. Fuel Cells 4: 236-240.
• Demirel, B., P. Scherer, O. Yenigun, T.T. Onay. 2010. Production of methane and hydrogen from biomass through conventional and high-rate anaerobic digestion processes. Critical Reviews in Environmental Science and Technology 40: 116-146.
• Deng, W.Q., X. Xu, W.A. Goddard. 2004. New alkali doped pillared carbon materials designed to achieve practical reversible hydrogen storage for transportation. Physical Review Letters 92: 166103-1-166103-4.
• Dyer, C.K. 2002. Fuel cells for portable applications. Journal of Power Sources 106: 31-34.
• Fujiwara, N., Z. Siroma, S.I. Yamazaki, T. Ioroi, H. Senoh, K. Yasuda. 2008. Direct ethanol fuel cells using an ion exchange membrane. Journal of Power Sources 185: 621-626.
• Li, Y., D. Zhao, Y.Wang, R. Xue, Z. Shen, X. Li. 2006. The mechanism of hydrogen storage in carbon materials. International Journal of Hydrogen Energy 32: 2513-2517.
• Li, Y.S., T.S. Zhao, Z.X. Liang. 2009. Performance of alkaline electrolyte-membrane-based direct ethanol fuel cells. Journal of Power Sources 187: 387-392.
• Liu, C., Y. Chen, C.Z. Wu, S.T. Xu, H.M. Cheng. 2010. Hydrogen storage in carbon nanotubes revisited. Carbon 48: 452-455.
• Matsushita Battery Industrial. 2006. Matsushita Battery develops micro DMFC. Fuel Cells Bulletin 2006: 4.
• Owen, N.A., O.R. Inderwildi, D.A. King. 2010. The status of conventional world oil reserves -Hype or cause for concern? Energy Policy 38: 4743-4749.
• Panella, B., M. Hirscher, S. Roth. 2005. Hydrogen adsorption in different carbon nanostructures. Carbon 43: 2209-2214.
• SFC Smart Fuel Cell AG. 2003. The Smart way to get DMFC products into the market. Fuel Cells Bulletin 2003: 10-12.
• Shafiee, S., E. Topal. 2009.When will fossil fuel reserves be diminished? Energy Policy 37: 181-189.
• Singhal, S.C., K. Kendall (eds.). 2003. High Temperature Solid Oxide Fuel Cells: Fundamentals, Design and Applications. Elsevier, Oxford, UK.
• Toshiba Company. 2003. Toshiba unveils prototype DMFC for portable PCs. Fuel Cells Bulletin 2003: 1.
• Wang, J., W. Wan. 2009. Factors influencing fermentative hydrogen production: A review. International Journal of Hydrogen Energy 34: 799-811.