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http://dx.doi.org/10.7316/khnes.2011.22.1.100

The Study of Steam Reforming for Model Bioigas using 3D-IR Matrix Burner Reformer  

Lim, Mun-Sup (BK21 Team for Hydrogen Production.Department of Environmental Engineering, Chosun University)
Chun, Young-Nam (BK21 Team for Hydrogen Production.Department of Environmental Engineering, Chosun University)
Publication Information
Transactions of the Korean hydrogen and new energy society / v.22, no.1, 2011 , pp. 100-108 More about this Journal
Abstract
The use of biogas as an energy source reduces the chance of possible emission of two greenhouse gases, $CH_4$ and $CO_2$, into the atmosphere at the same time. Its nature of being a reproducible energy source makes its use even more attractive. This research if for the hydrogen production through the steam reforming of the biogas. The biogas utilized 3D-IR matrix burner in which the surface combustion is applied. The nickel catalyst was used inside a reformer. Parametric screening studies were achieved as Steam/Carbon ratio, biogas component ratio, Space velocity and Reformer temperature. When the condition of Steam/Carbon ratio, $CH_4/CO_2$ ratio, Space velocity and Refomer temperature were 3.25, 60%:40%, 19.32L/$g{\cdot}hr$ and $700^{\circ}C$ respectively, the hydrogen concentration and methane conversion rate were showed maximum values. Under the condition mentioned above, $H_2$ concentration was 73.9% and methane conversion rate was 98.9%.
Keywords
3D-IR matrix burner; Biogas; Steam reforming; Ni catalyst; Hydrogen;
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Times Cited By KSCI : 1  (Citation Analysis)
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1 P. Kolbitsch, C. pfeifer, H. Hofbauer, "Catalytic steam reforming of model biogas", Fuel, Vol. 87, 2008, pp. 701-706.   DOI   ScienceOn
2 P. Beckhaus, A. Heinzel, J. Mathiak, and J. Roes, "Dynamic of $H_{2}$ production by steam reforming", J. Power Sources, Vol. 127, 2004, pp. 294-299.   DOI
3 S. G. Wang, Y. W. Li, J. X. Lu, M. Y. He, and H. Jiao, "A detailed mechanism of thermal $CO_{2}$ reforming of $CH_{4}$", J. Molecular Structure, Vol. 673, 2004, pp. 181-189.   DOI
4 A. E. Lutz, R. W. Bradshaw, L. Bromberg, and A. Rabinovich, "Thermodynamic analysis of hydrogen production by partial oxidation reforming", Int. J. Hydrogen Energy, Vol. 29, 2004, pp. 809-816.   DOI   ScienceOn
5 김성천, 전영남, "3상 교류 부채꼴 방전을 이용한 메탄으로부터 수소 생산", 한국수소 및 신에너지학회, Vol. 18, No. 2, 2007, pp. 132-139.
6 T. Takeno, K. Sato, "An excess enthalpy flame theory", Combustion Sience and Technology, Vol. 20, 1979, pp. 73-84.   DOI
7 A. I. Bakry, "Stabilized Premixed Combustion within Atmospheric Gas Porous Inert Medium (PIM) Burner", International Conference on Energy and Environment 2006, 28-30 August2006, pp. 1-9.
8 G. Petitpas, J. D. Rollier, A. Darmon, J. Gonzalez- Aguilar, R. Metkemeijer, L. Fulcheri, "A comparative study of non-thermal plasma assisted reforming technologies," International Journal of Hydrogen Energy, Vol. 32, No. 14, 2007, pp. 2848-2867.   DOI   ScienceOn
9 G. Kolios, A. Gritsch, A. Morillo, U. Tuttlies, J. Bernnat, F. Opferkuch, G. Eigenberger, "Heatintegrated reactor concepts for catalytic refoming and automotive exhaust purification", Applied catalysis B, Vol. 70, 2007, pp. 16-30.   DOI
10 D. G. Avraam, T. I. Halkides, D. K. Liguras, O. A. Bereketidou, M. A. Goula, "An experimental and theoretical approach for the biogas steam reforming reaction", International Journal of Hydrogen Energy, Vol. 35, 2010, pp. 9818-9827.   DOI   ScienceOn
11 Y. N. Chun, Y. C. Yang, K. Yoshikawa, "Hydrogen generation from biogas reforming using a gliding arc plasma-catalyst reformer", Catalysis today, Vol. 148, 2009, pp. 283-289.   DOI
12 M. Ashrafi, T. Pröll, C. Pfeifer, and H. Hofbauer, "Experimental study of model biogas catalytic steam reforming: 1. Thermodynamic optimization", Energy & Fuels, Vol. 22, 2008, pp. 4182-4189.   DOI   ScienceOn