Bio-fuel reforming for solid oxide fuel cell applications. Part 2: Biodiesel

International Journal of Hydrogen Energy

Volumn 39, Issue 1, 2014, Pages 183-195

  Lin, Jiefeng ^a   Trabold, Thomas A ^a   Walluk, Mark R ^a   Smith, Daniel F ^a  

^a ROCHESTER INSTITUTE OF TECHNOLOGY   (United States)

Author keywords

Autothermal reforming; Biodiesel; Carbon formation; Diesel; Solid oxide fuel cells; Thermodynamic analysis

Indexed keywords

AUTOTHERMAL REFORMING; CARBON FORMATION; DIESEL; DIFFERENT OPERATING CONDITIONS; GAS HOURLY SPACE VELOCITIES; GIBBS FREE ENERGY MINIMIZATION; SOLID OXIDE FUEL CELLS (SOFCS); THERMO DYNAMIC ANALYSIS;

CARBON; HYDROGEN PRODUCTION; SOLID OXIDE FUEL CELLS (SOFC); THERMOANALYSIS; THERMODYNAMIC PROPERTIES;

BIODIESEL;

EID: 84890437517     PISSN: 03603199     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijhydene.2013.10.058     Document Type: Article

References (38)

1. Argonne National Laboratory Reducing vehicle idling 2007 [cited on 2012 Dec. 10]. Available from: http://www.transportation.anl.gov/engines/idling.html
2. Y.S. Seo, A. Shirley, and S.T. Kolaczkowski Evaluation of thermodynamically favourable operating conditions for production of hydrogen in three different reforming technologies J Power Sources 108 2002 213 225
3. K. Faungnawakij, R. Kikuchi, and K. Eguchi Thermodynamic analysis of carbon formation boundary and reforming performance for steam reforming of dimethyl ether J Power Sources 164 2007 73 79
4. Q. Zhang, X. Li, K. Fujimoto, and K. Asami Hydrogen production by partial oxidation and reforming of DME Appl Catal A Gen 288 2005 169 174
5. I. Kang, H. Carstensen, and A.M. Dean Impact of gas-phase reactions in the mixing region upstream of a diesel fuel autothermal reformer J Power Sources 196 2011 2020 2026
6. N. Laosiripojana, and S. Assabumrungrat Catalytic dry reforming of methane over high surface area ceria Appl Catal B Environ 60 2005 107 116
7. R.D. Parmar, A. Kundu, and K. Karan Thermodynamic analysis of diesel reforming process: mapping of carbon formation boundary and representative independent reactions J Power Sources 194 2009 1007 1020
8. P.K. Cheekatamarla, and A.M. Lane Catalytic autothermal reforming of diesel fuel for hydrogen generation in fuel cells I. Activity tests and sulfur poisoning J Power Sources 152 2005 256 263
9. R.L. Borup, M.A. Inbody, J.I. Tafoya, D. Guidry, and W.J. Parkinson Diesel reforming for SOFC auxiliary power units 2004 Los Alamos National Laboratory LA-UR-04-5370
10. W. Wang, and Y. Cao Hydrogen-rich gas production for solid oxide fuel cell (SOFC) via partial oxidation of butanol: thermodynamic analysis Int J Hydrogen Energy 35 2010 13280 13289
11. T.A. Trabold, J.S. Lylak, M.R. Walluk, J.F. Lin, and D.R. Troiani Measurement and analysis of carbon formation during diesel reforming for solid oxide fuel cells Int J Hydrogen Energy 37 2012 5190 5201
12. J.F. Lin, T.A. Trabold, M.R. Walluk, and D.F. Smith Autothermal reforming of biodiesel-ethanol-diesel blends for solid oxide fuel cell applications Energy Fuels 27 2013 4371 4385
13. B.D. Gould, X. Chen, and J.W. Schwank n-Dodecane reforming over nickel-based monolith catalysts: deactivation and carbon deposition Appl Catal A Gen 334 2008 277 290
14. B.J. Dreyer, I.C. Lee, J.J. Krummenacher, and L.D. Schmidt Autothermal steam reforming of higher hydrocarbons: n-decane, n-hexadecane, and JP-8 Appl Catal A Gen 307 2006 184 194
15. A.V. Gonzalez, X. Karatzas, and L.J. Pettersson Autothermal reforming of Fischer-Tropsh diesel over alumina and ceria-zirconia supported catalysts Fuel 107 2013 162 169
16. C. Yu, D. Lee, S. Park, K. Lee, and K. Lee Study on a catalytic membrane reactor for hydrogen production from ethanol steam reforming Int J Hydrogen Energy 34 2009 2947 2954
17. I. Kang, J. Bae, and G. Bae Performance comparison of autothermal reforming for liquid hydrocarbons, gasoline and diesel for fuel cell application J Power Sources 163 2006 538 546
18. S.R. Yenumala, and S.K. Maity Reforming of vegetable oil for production of hydrogen: a thermodynamic analysis Int J Hydrogen Energy 36 2011 11666 11675
19. J.F. Lin, C.W. Babbitt, and T.A. Trabold Life cycle assessment integrated with thermodynamic analysis of bio-fuel options for solid oxide fuel cells Bioresour Technol 128 2013 495 504
20. J.F. Lin, T.A. Trabold, M.R. Walluk, and D.F. Smith Bio-fuel reforming for solid oxide fuel cell applications. Part 1: fuel vaporization and reactant mixing Int J Hydrogen Energy 38 2013 12024 12034
21. C.N. Avila-Neto, S.C. Dantas, F.A. Silva, T.V. Franco, L.L. Romanielo, and C.E. Hori Hydrogen production from methane reforming: thermodynamic assessment and autothermal reactor design J Nat Gas Sci Eng 1 2009 205 215
22. S. Yoon, J. Bae, S. Kim, and Y. Yoo Self-sustained operation of a kWe-class kerosene-reforming processor for solid oxide fuel cells J Power Sources 192 2009 360 366
23. D. Tarlet, J. Bellettre, M. Tazerout, and C. Rahmouni Prediction of micro-explosion delay of emulsified fuel droplets Int J Therm Sci 48 2009 449 460
24. T. Kadota, H. Tanaka, D. Segawa, S. Nakaya, and H. Yamasaki Microexplosion of an emulsion droplet during Leidenfrost burning Proc Combust Inst 31 2007 2125 2131
25. W. Schindler, C. Haisch, H.A. Beck, R. Niessner, E. Jacob, and D. Rothe A photoacoustic sensor system for time resolved quantification of diesel soot emissions 2004 SAE Paper 2004-01-0968
26. D. Shekhawat, J.J. Spivey, and D.A. Berry Fuel cells: technologies for fuel processing 1st ed. 2011 Elsevier Science 540 544
27. G. Rabenstein, and V. Hacker Hydrogen for fuel cells from ethanol by steam-reforming, partial oxidation and combined auto-thermal reforming: a thermodynamic analysis J Power Sources 185 2008 1293 1304
28. K. Faungnawakij, N. Viriya-empikal, and W. Tanthapanichakoon Evaluation of the thermodynamic equilibrium of the autothermal reforming of dimethyl ether Int J Hydrogen Energy 36 2011 5865 5874
29. X. Wang, M. Li, M. Wang, H. Wang, S. Li, and S. Wang Thermodynamic analysis of glycerol dry reforming for hydrogen and synthesis gas production Fuel 88 2009 2148 2153
30. J.F. Lin, M.R. Walluk, D.F. Smith, and T.A. Trabold Mitigation of carbon formation during autothermal reforming of biodiesel for solid oxide fuel cell applications Proceedings of the ASME 2012 6th international conference on energy sustainability & 10th fuel cell science, ESFuelCell2012-91092 July 23-26, 2012 San Diego, CA, USA
31. B.F. Hagh Optimization of autothermal reactor for maximum hydrogen production Int J Hydrogen Energy 28 2003 1369 1377
32. D. Shekhawat, D.A. Berry, T.H. Gardner, D.J. Haynes, and J.J. Spivey Effects of fuel cell anode recycle on catalytic fuel reforming J Power Sources 168 2007 477 483
33. G. Kolb Fuel processing for fuel cells 2008 Wiley-VCH Verlag GmbH & Co. KGaA Weinheim 30 38
34. D.A. Berry, D. Shekhawat, and T.H. Gardner Development of reaction kinetics for diesel-based fuel cell reformers 2003 Hydrogen, Fuel Cells, and Infrastructure Technologies, FY Progress Report [cited on 2012 Oct 10]. Available from: http://www1.eere.energy.gov/hydrogenandfuelcells/pdfs/ivd15- berry.pdf
35. I. Aartun, H.J. Venvik, A. Holmen, P. Pfeifer, O. Görke, and K. Schubert Temperature profiles and residence time effects during catalytic partial oxidation and oxidative steam reforming of propane in metallic microchannel reactors Catal Today 110 2005 98 107
36. M. Ni, Y.C. Leung, and M.K.H. Leung A review on reforming bio-ethanol for hydrogen production Int J Hydrogen Energy 32 2007 3238 3247
37. K. Ahmed, and K. Foger Fuel processing for high-temperature high-efficiency fuel cells Ind Eng Chem Res 49 2010 7239 7256
38. A. Lanzini, P. Leone, C. Guerra, F. Smeacetto, N.P. Brandon, and M. Santarelli Durability of anode supported solid oxide fuel cells (SOFC) under direct dry-reforming of methane Chem Eng J 220 2013 254 263