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Hydrogen from Waste Tyres
Authors: Ibrahim F. Elbaba, Paul T. Williams
Abstract:
Hydrogen is regarded to play an important role in future energy systems because it can be produced from abundant resources and its combustion only generates water. The disposal of waste tyres is a major problem in environmental management throughout the world. The use of waste materials as a source of hydrogen is particularly of interest in that it would also solve a waste treatment problem. There is much interest in the use of alternative feedstocks for the production of hydrogen since more than 95% of current production is from fossil fuels. The pyrolysis of waste tyres for the production of liquid fuels, activated carbons and gases has been extensively researched. However, combining pyrolysis with gasification is a novel process that can gasify the gaseous products from pyrolysis. In this paper, an experimental investigation into the production of hydrogen and other gases from the bench scale pyrolysis-gasification of tyres has been investigated. Experiments were carried using a two stage system consisting of pyrolysis of the waste tyres followed by catalytic steam gasification of the evolved gases and vapours in a second reactor. Experiments were conducted at a pyrolysis temperature of 500 °C using Ni/Al2O3 as a catalyst. The results showed that there was a dramatic increase in gas yield and the potential H2 production when the gasification temperature was increased from 600 to 900 oC. Overall, the process showed that high yields of hydrogen can be produced from waste tyres.Keywords: Catalyst, Hydrogen, Pyrolysis, Gasification, Tyre, Waste
Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1055994
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[1] European Tyre& Rubber Manufacturers' Association, ELTs treatment data in 2007, ETRMA, 2008.
[2] US Rubber Manufacturers Association, Scrap Tire Markets in the United States: 2007, Rubber Manufacturers AssociationWashington, US, 2009.
[3] The Japan automobile tyre manufacturers association. Inc, Tyre Industry of Japan 2007, The Japan automobile tyre manufacturers association. Inc,2007.
[4] H Wang, H Xu, X. Xuan,Review of Waste Tire Reuse& Recycling in China-current situation, problems and countermeasures. Advances in Natural Science,2(1), pp. 31-39, 2009.
[5] Sharma, V.K., Fortuna, F., Mincarini, M., Berillo, M., Cornacchia, G.,Disposal of waste tyres for energy recovery and safe environment. Applied Energy, 65(1-4), pp. 381-394, 2000.
[6] Heermann C., Schwager F. J., Whiting K. J., Pyrolysis and Gasification of waste: A Worldwide Technology and Business Review, Juniper Consultancy Services Ltd,2001.
[7] Williams, P.T., Brindle, A.J.,Catalytic pyrolysis of tyres: influence of catalyst temperature. Fuel, 81(18), pp. 2425-2434, 2002.
[8] Williams, P.T., Besler, S., Taylor, D.T.,The pyrolysis of scrap automotive tyres: The influence of temperature and heating rate on product composition. Fuel, 69(12), pp. 1474-1482, 1990.
[9] Diez, C., Martinez, O., Calvo, L.F., Cara, J., Morán, A.,Pyrolysis of tyres. Influence of the final temperature of the process on emissions and the calorific value of the products recovered. Waste Management, 24(5), pp. 463-469, 2004.
[10] Tanksale, A., Beltramini, J.N., Lu, G.M.,A review of catalytic hydrogen production processes from biomass. Renewable and Sustainable Energy Reviews, 14(1), pp. 166-182, 2010.
[11] Pattabhi Raman, K., Walawender, W.P., Fan, L.T.,Gasification of waste tires in a fluid bed reactor. Conservation & Recycling, 4(2), pp. 79-88, 1981.
[12] Leung, D.Y.C., Wang, C.L.,Fluidized-bed gasification of waste tire powders. Fuel Processing Technology, 84(1-3), pp. 175-196, 2003.
[13] Wu, C., Williams, P.T.,Hydrogen production by steam gasification of polypropylene with various nickel catalysts. Applied Catalysis B: Environmental, 87(3-4), pp. 152-161, 2009.