Diesel autothermal reforming with hydrogen peroxide for low-oxygen environments

Applied Energy

Volumn 156, Issue , 2015, Pages 99-106

  Han, Gwangwoo ^a   Lee, Sangho ^a   Bae, Joongmyeon ^a  

^a Korea Advanced Institute of Science and Technology (KAIST)   (South Korea)

Author keywords

Autothermal reforming; Diesel; Hydrogen; Hydrogen peroxide; Low oxygen environments

Indexed keywords

AUTONOMOUS UNDERWATER VEHICLES; CARBON; CATALYST ACTIVITY; DEGRADATION; DIESEL FUELS; ETHYLENE; FUEL CELLS; FUEL STORAGE; HYDRIDES; HYDROGEN; HYDROGEN PEROXIDE; HYDROGEN PRODUCTION; OXIDANTS; OXIDATION; OXYGEN; PEROXIDES; RUBIDIUM COMPOUNDS; STEAM REFORMING; SUBMARINES;

AUTOTHERMAL REFORMING; DIESEL; HYDROGEN PRODUCTION METHOD; LOW OXYGEN; OXYGEN-TO-CARBON RATIO; STEAM-TO-CARBON RATIO; SUBMARINE APPLICATIONS; UNMANNED UNDERWATER VEHICLES;

HYDROGEN STORAGE;

CATALYSIS; DIESEL; ETHYLENE; FUEL CELL; HYDROGEN PEROXIDE; OXYGEN; SUBMARINE; TEMPERATURE EFFECT; THERMODYNAMICS;

KOREA;

EID: 84936854618     PISSN: 03062619     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.apenergy.2015.06.036     Document Type: Article

References (41)

1. Hayre R.O., Cha S.W., Colella W., Prinz F.B. Fuel Cell fundamentals 2006, John Wiley & Sons, New York.
2. Larmine J., Dicks A. Fuel cell systems explained 2003, Wiley, New York. 2nd ed.
3. Mendez A., Leo T., Herreros M. Current state of technology of fuel cell power systems for autonomous underwater vehicles. Energies 2014, 7:4676-4693.
4. Wang X., Shang J., Luo Z., Tang L., Zhang X., Li J. Reviews of power systems and environmental energy conversion for unmanned underwater vehicles. Renew Sustain Energy Rev 2012, 16:1958-1970.
5. Davies Kevin L., Moore Robert M. Unmanned underwater vehicle fuel cell energy/power system technology assessment. IEEE J Oceanic Eng 2007, 32:365-372.
6. Lee C.-H., Yang J.-T. Modeling of the Ballard-Mark-V proton exchange membrane fuel cell with power converters for applications in autonomous underwater vehicles. J Power Sources 2011, 196:3810-3823.
7. Gizmag. Fuel cell submarines offer underwater stealth. Victoria, Australia; 2004. http://wwwgizmagcom/go/3434/.
8. Hauschildt P. PEM fuel cell systems-an attractive energy source for submarines. Naval Forces 2003, 30-33.
9. Goodenough L.R.H., Greig A. Hybrid nuclear/fuel-cell submarine. J Naval Eng 2008, 44:455-471.
10. Reese M.A., Turn S.Q., Cui H. High pressure autothermal reforming in low oxygen environments. J Power Sources 2009, 187:544-554.
11. Baumert R, Epp D. Hydrogen storage for fuel cell powered underwater vehicles. In: Proceedings of engineering in harmony with Ocean, Victoria, BC, Canada, 18-21 October 1993. p. 166-71.
12. Kang I., Bae J. Autothermal reforming study of diesel for fuel cell application. J Power Sources 2006, 159:1283-1290.
13. Shamsi A., Baltrus J.R., Spivey J.J. Characterization of coke deposited on Pt/alumina catalyst during reforming of liquid hydrocarbons. Appl Catal A-Gen 2005, 293:145-152.
14. Cheekatamarla P.K., Lane A.M. Catalytic autothermal reforming of diesel fuel for hydrogen generation in fuel cells: I. Activity tests and sulfur poisoning. J Power Sources 2005, 152:256-263.
15. Kopasz J.P., Applegate D., Miller L., Liao H.K., Ahmed S. Unraveling the maze: understanding of diesel reforming through the use of simplified fuel blends. Int J Hydrogen Energy 2005, 30:1243-1250.
16. Granlund M.Z., Jansson K., Nilsson M., Dawody J., Pettersson L.J. Evaluation of Co, La, and Mn promoted Rh catalysts for autothermal reforming of commercial diesel. Appl Catal B 2014, 154-155:386-394.
17. Kang I., Yoon S., Bae G., Kim J.H., Bae J., Lee D., et al. The micro-reactor testing of catalysts and fuel delivery apparatuses for diesel autothermal reforming. Catal Today 2008, 136:249-257.
18. Pasel J., Samsun R.C., Peters R., Stolten D. Fuel processing of diesel and kerosene for auxiliary power unit applications. Energy Fuels 2013, 27:4386-4394.
19. Xu X.H., Li P.W., Shen Y.S. Small-scale reforming of diesel and jet fuels to make hydrogen and syngas for fuel cells: a review. Appl Energy 2013, 108:202-217.
20. Ahmed S., Krumpelt M. Hydrogen from hydrocarbon fuels for fuel cells. Int J Hydrogen Energy 2001, 26:291-301.
21. Shekhawat D., Berry D.A., Gardner T.H., Spivey J.J. Catalytic reforming of liquid hydrocarbon fuels for fuel cell applications. Catal Today 2006, 19:184-253.
22. Samsun R.C., Pasel J., Janßen H., Lehnert W., Peters R., Stolten D. Design and test of a 5kWe high-temperature polymer electrolyte fuel cell system operated with diesel and kerosene. Appl Energy 2014, 114:238-249.
23. Pasel J., Samsun R.C., Tschauder A., Peters R., Stolten D. A novel reactor type for autothermal reforming of diesel fuel and kerosene. Appl Energy 2015, 150:176-184.
24. Takeguchi T., Kani Y., Yano T., Kikuchi R., Eguchi K., Tsujimoto K., et al. Study on steam reforming of CH4 and C2 hydrocarbons and carbon deposition on Ni-YSZ cermets. J Power Sources 2002, 112:588-595.
25. Kaila R.K., Gutiérrez A., Krause A.O.I. Autothermal reforming of simulated and commercial diesel: the performance of zirconia-supported RhPt catalyst in the presence of sulfur. Appl Catal B 2008, 84:324-331.
26. Pasel J., Meisner J., Pors Z., Samsun R., Tschauder A., Peters R. Autothermal reforming of commercial Jet A-1 on a 5kWe scale. Int J Hydrogen Energy 2007, 32:4847-4858.
27. x catalyst generated from metallo-organic network for autothermal reforming of diesel surrogate. Appl Catal A 2013, 459:89-96.
28. Martinez A.S., Brouwer J., Samuelsen G.S. Comparative analysis of SOFC-GT freight locomotive fueled by natural gas and diesel with onboard reformation. Appl Energy 2015, 148:421-438.
29. Walluk M.R., Lin J., Waller M.G., Smith D.F., Trabold T.A. Diesel auto-thermal reforming for solid oxide fuel cell systems: anode off-gas recycle simulation. Appl Energy 2014, 130:94-102.
30. Yoon S., Kang I., Bae J. Effects of ethylene on carbon formation in diesel autothermal reforming. Int J Hydrogen Energy 2008, 33:4780-4788.
31. Yoon S., Kang I., Bae J. Suppression of ethylene-induced carbon deposition in diesel autothermal reforming. Int J Hydrogen Energy 2009, 34:1844-1851.
32. Kwon H. A study of catalytic decomposition for hydrogen gas generator. MS thesis, KAIST, Daejon, December 2004.
33. 2-x (Me: Rh, Pt and Ru) catalysts for diesel pre-reforming. Int J Hydrogen Energy 2015, 40:3207-3216.
34. 2 mixed oxides as water-gas shift catalysts. Catal Today 2005, 99:257-262.
35. Yoon S. Development of the self-sustaining integrated diesel fuel processor for hydrogen production and solid oxide fuel cell operation. PhD dissertation, KAIST, Daejon, September 2011.
36. Opalka S.M., Vanderspurt T.H., Radhakrishnan R., She Y., Willigan R.R. Design of water gas shift catalysts for hydrogen production in fuel processors. J Phys Condens Matter: Inst Phys J 2008, 20:064237.
37. Kang I., Bae J., Bae G. Performance comparison of autothermal reforming for liquid hydrocarbons, gasoline and diesel for fuel cell applications. J Power Sources 2006, 163:538-546.
38. Kwan W.P., Voelker B.M. Decomposition of hydrogen peroxide and organic compounds in the presence of dissolved iron and ferrihydrite. Environ Sci Technol 2002, 36:1467-1476.
39. 2 solutions in UV). Anal Biochem 1972, 49:474.
40. Bae M, Han G, Jang H, Bae J. Investigation of possibilities for pure-oxygen diesel reforming using hydrogen peroxide as an oxidant. Jeju, South Korea, KSME; 2014.
41. Yoon S., Bae J., Lee S., Pham T.V., Katikaneni S.P. A diesel fuel processor for stable operation of solid oxide fuel cells system: II. Integrated diesel fuel processor for the operation of solid oxide fuel cells. Int J Hydrogen Energy 2012, 37:9228-9236.