References
- Appels , L. , Baeyens , J. , Degréve , J. and Dewil , R. 2008 . Principles and potential of the anaerobic digestion of waste-activated sludge . Progr. Energy & Combus. Sci. , 34 : 755 – 781 .
- Ashrafi , M. , Proll , T. , Pfeifer , C. and Hofbauer , H. 2008 . Experimental study of model biogas catalytic steam reforming: 1. Thermodynamic optimization . Energy & Fuels , 22 : 4182 – 4189 .
- Balat , M. 2009 . Possible methods for hydrogen production . Energy Sources, Part A , 31 : 39 – 50 .
- Benito , M. , García , S. , Ferreira-Aparicio , P. , García Serrano , L. and Daza , L. 2007 . Development of biogas reforming Ni-La-Al catalysts for fuel cells . J. Power Sources , 169 : 177 – 183 .
- Bensaid , S. , Russo , N. and Fino , D. 2010 . Power and hydrogen co-generation from biogas . Energy Fuels , 24 : 4743 – 4747 .
- Bove , R. and Lunghi , P. 2005 . Experimental comparison of MCFC performance using three different biogas types and methane . J. Power Sources , 145 : 588 – 593 .
- Bove , R. and Lunghi , P. 2006 . Electric power generation from landfill gas using traditional and innovative technologies . Energy Convers. Manage. , 47 : 1391 – 1401 .
- De Lorenzo , G. and Fragiacomo , P. 2010 . Technical analysis of an eco-friendly hybrid plant with a microgas turbine and an MCFC system . Fuel Cells , 10 : 194 – 208 .
- Demirbas , A. 2008 . Biohydrogen generation from organic waste . Energy Sources, Part A , 30 : 475 – 482 .
- Dokmaingam , P. , Assabumrungrat , S. , Soottitantawat , A. and Laosiripojana , N. 2010 . Modelling of tubular-designed solid oxide fuel cell with indirect internal reforming operation fed by different primary fuels . J. Power Sources , 195 : 69 – 78 .
- Dong , L. , Zhenhong , Y. , Yongming , S. and Longlong , M. 2011 . Anaerobic fermentative co-production of hydrogen and methane from an organic fraction of municipal solid waste . Energy Sources, Part A , 33 : 575 – 585 .
- Effendi , A. , Hellgardt , K. , Zhang , Z. G. and Yoshida , T. 2005 . Optimising H$_2$ production from model biogas via combined steam reforming and CO shift reactions . Fuel , 84 : 869 – 874 .
- Farhad , S. , Hamdullahpur , F. and Yoo , Y. 2010 . Performance evaluation of different configurations of biogas-fuelled SOFC micro-CHP systems for residential applications . Int. J. Hydrogen Energy , 35 : 3758 – 3768 .
- Gadde , B. 2007 . Economic utilisation of biogas as a renewable fuel for fuel cell . Asian J. Energy & Environ. , 8 : 573 – 582 .
- Herle , J. V. and Membrez , Y. Biogas exploitation in SOFC . Proc. 5th European Solid Oxide Fuel Cell Forum . Lucerne , Switzerland. Edited by: Bossel , U. pp. 1003 – 1011 .
- Herle , J. V. , Maréchal , F. , Leuenberger , S. and Favrat , D. 2003 . Energy balance model of a SOFC cogenerator operated with biogas . J. Power Sources , 118 : 375 – 383 .
- Kolbitsch , P. , Pfeifer , C. and Hofbauer , H. 2008 . Catalytic steam reforming of model biogas . Fuel , 87 : 701 – 706 .
- Lanzini , A. and Leone , P. 2010 . Experimental investigation of direct internal reforming of biogas in solid oxide fuel cells . Int. J. Hydrogen Energy , 35 : 2463 – 2476 .
- Larminie , J. and Dicks , A. 2000 . Fuel Cell Systems Explained Chichester : John Wiley & Sons Ltd. .
- Massardo , A. F. and Lubelli , F. 2000 . Internal reforming solid oxide fuel cell-gas turbine combined cycles (IRSOFC-GT): Part A—Cell model and cycle thermodynamic analysis . ASME , 122 : 27 – 35 .
- Mata-Alvarez , J. , Macé , S. and Llabrés , P. 2000 . Anaerobic digestion of organic solid wastes. An overview of research achievements and perspectives . Bioresour. Technol. , 74 : 3 – 16 .
- Pekridis , G. , Kalimeri , K. , Kaklidis , N. , Vakouftsi , E. , Iliopoulou , E. F. , Athanasiou , C. and Marnellos , G. E. 2007 . Study of the reverse water gas shift (RWGS) reaction over Pt in a solid oxide fuel cell (SOFC) operating under open and closed-circuit conditions . Catal. Today , 127 : 337 – 346 .
- Piroonlerkgul , P. , Laosiripojana , N. , Adesina , A. A. and Assabumrungrat , S. 2009a . Performance of biogas-fed solid oxide fuel cell systems integrated with membrane module for CO$_2$ removal . Chem. Eng. Process. , 48 : 672 – 682 .
- Piroonlerkgul , P. , Wiyaratn , W. , Soottitantawat , A. , Kiatkittipong , W. , Arpornwichanop , A. , Laosiripojana , N. and Assabumrungrat , S. 2009b . Operation viability and performance of solid oxide fuel cell fuelled by different feeds . Chem. Eng. J. , 155 : 411 – 418 .
- Pöschl , M. , Ward , S. and Owende , P. 2010 . Evaluation of energy efficiency of various biogas production and utilization pathways . Appl. Energy , 87 : 3305 – 3321 .
- San , B. , Zhou , P. and Clealand , D. 2010 . Dynamic modeling of tubular SOFC for marine power system . J. Marine Sci. Appl. , 9 : 231 – 240 .
- Verda , V. and Nicolin , F. Design of a biogas fuelled MCFC system integrated with an anaerobic digester . ASME 2010 4th International Conference on Energy Sustainability . May 17–22 , Phoenix , Arizona. pp. 225 – 232 .
- Williams , M. C. , Strakey , J. P. and Singhal , S. C. 2004 . U.S. distributed generation fuel cell program . J. Power Sources , 131 : 79 – 85 .
- Yi , Y. , Rao , A. D. , Brouwer , J. and Samuelsen , G. S. 2005 . Fuel flexibility study of an integrated 25kW SOFC reformer system . J. Power Sources , 144 : 67 – 76 .