Contribution of fuel cell systems to CO2 emission reduction in their application fields

Renewable and Sustainable Energy Reviews

Volumn 14, Issue 2, 2010, Pages 735-744

  Wee, Jung Ho ^a  

^a The Catholic University of Korea   (South Korea)

Author keywords

Carbon capture and sequestration; Carbon dioxide emission; Climate change; Fuel cells; Greenhouse gas

Indexed keywords

APPLICATION FIELDS; CARBON CAPTURE; CARBON CAPTURE AND SEQUESTRATIONS; CARBON DIOXIDE EMISSION; CARBON DIOXIDE EMISSIONS; COMBUSTION CYCLE; DIRECT METHANOL; DISTRIBUTED GENERATIONS; ELECTRICITY EFFICIENCIES; EMISSION REDUCTION; FUEL CELL SYSTEM; MOBILE APPLICATIONS; PRE-COMBUSTIONS; PRODUCTION METHODS; SOLID OXIDE; STATIONARY APPLICATIONS;

CARBON DIOXIDE; COMBUSTION; ELECTRIC GROUNDING; FUEL CELLS; GALERKIN METHODS; GLOBAL WARMING; GREENHOUSES; HYBRID COMPUTERS; HYBRID SYSTEMS; LEAKAGE (FLUID); METHANOL;

CARBON MONOXIDE;

EID: 72049101437     PISSN: 13640321     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.rser.2009.10.013     Document Type: Review

References (61)

1. IPCC. The fourth assessment report on climate change. http://www.ipcc.ch/pdf/assessment-report/ar4/syr/ar4_syr.pdf; 2007.
2. Barbir F., and Gómez T. Efficiency and economics of proton exchange membrane (PEM) fuel cells. Int J Hydrogen Energy 22 (1997) 1027-1037
3. Appleby A.J., and Foulkes F.R. Fuel cell handbook (1989), Van Nostrand Reinhold, New York
4. Holman F.P. Thermodynamics. 2nd ed. (1974), McGraw-Hill, New York
5. 2 from gas turbine exhaust gases. Energy 29 (2004) 1279-1284
6. Fuel cell today. UN approves CDM methodology by POSCO Power for DMFCs. http://www.fuelcelltoday.com/online/news/articles/2009-07/Posco-CDM-approval; 2009.
7. Campanari S. Carbon dioxide separation from high temperature fuel cell power plants. J Power Sources 112 (2002) 273-289
8. Varbanov P., and Klemeš J. Analysis and integration of fuel cell combined cycles for development of low-carbon energy technologies. Energy 33 (2008) 1508-1517
9. Orecchini F., Bocci E., and Di Carlo A. MCFC and microturbine power plant simulation. J Power Sources 160 (2006) 835-841
10. Ghezel-Ayagh H., Walzak J., Patel D., Daly J., Maru H., Sanderson R., et al. State of direct fuel cell/turbine systems development. J Power Sources 152 (2005) 219-225
11. Singhal S.C. Advances in solid oxide fuel cell technology. Solid State Ionics 135 (2000) 305-313
12. 2 capturing solid oxide fuel cell. J Power Sources 106 (2002) 377-380
13. 2 capture. Energy 29 (2004) 1249-1257
14. 2 separation. Energy 33 (2008) 311-320
15. Perdikaris N., Panopoulos K.D., Fryda L., and Kakaras E. Design and optimization of carbon-free power generation based on coal hydrogasification integrated with SOFC. Fuel 88 (2009) 1365-1375
16. Haseli Y., Naterer G.F., and Dincer I. Comparative assessment of greenhouse gas mitigation of hydrogen passenger trains. Int J Hydrogen Energy 33 (2008) 1788-1796
17. Chapman L. Transport and climate change: a review. J Transport Geogr 15 (2007) 354-367
18. 2 segregation using molten carbonate fuel cells. J Power Sources 131 (2004) 351-360
19. Wee J.H. A feasibility study on direct methanol fuel cells for laptop computers based on a cost comparison with lithium-ion batteries. J Power Sources 173 (2007) 424-436
20. Korea Energy Economics Institute. The nation's total GHG emission (2009). http://www.keei.re.kr/main.nsf/index.html http://www.keei.re.kr/main.nsf/index.html
21. NREL. Cost by solar cell and wind turbine (2008). http://www.nrel.gov/ http://www.nrel.gov
22. Gregorio M., and Teresa V.S. Towards the hydrogen economy?. Int J Hydrogen Energy 32 (2007) 1625-1637
23. Buhre B.J.P., Elliott L.K., Sheng C.D., Gupta R.P., and Wall T.F. Oxy-fuel combustion technology for coal-fired power generation. Prog Energy Combust 31 (2005) 283-307
24. Damen K., Van Troost M., Faaij A., and Turkenburg W. A comparison of electricity and hydrogen production systems with CO2 capture and storage. Part A. Review and selection of promising conversion and capture technologies. Prog Energy Combust 32 (2006) 215-246
25. Bossel U., Eliasson B., and Taylor G. The future of the hydrogen economy: bright or bleak? European fuel cell forum (2005). http://www.efcf.com/reports/E08.pdf http://www.efcf.com/reports/E08.pdf
26. Edwards P.P., Kuznetsov V.L., David W.I.F., and Brandon N.P. Hydrogen and fuel cells: towards a sustainable energy future. Energy Policy 36 (2008) 4356-4362
27. 2 capture and the sustainable carbon economy. Energy Convers Manage 49 (2008) 1674-1683
28. Marbán G., and Valdés-Solís T. Towards the hydrogen economy?. Int J Hydrogen Energy 32 (2007) 1625-1637
29. Hammerschlag R., and Mazza P. Questioning hydrogen. Energy Policy 33 (2005) 2039-2043
30. Lattin W.C., and Utgikar V.P. Transition to hydrogen economy in the United States: A 2006 status report. Int J Hydrogen Energy 32 (2007) 3230-3237
31. McDowall W., and Eames M. Towards a sustainable hydrogen economy: a multi-criteria sustainability appraisal of competing hydrogen futures. Int J Hydrogen Energy 32 (2007) 4611-4626
32. Winter C.J. Into the hydrogen energy economy-milestones. Int J Hydrogen Energy 30 (2005) 681-685
33. Sacramento Municipal Utility District. Smud open hydrogen vehicle fueling station powered by the sun (2008). http://www.smud.org/en/news/Documents/08archive/04_02_08_fuelcell.pdf http://www.smud.org/en/news/Documents/08archive/04_02_08_fuelcell.pdf
34. DOE. Vehicle technology program (2008). http://www1.eere.energy.gov/vehiclesandfuels/facts/2008_fotw523.html http://www1.eere.energy.gov/vehiclesandfuels/facts/2008_fotw523.html
35. Dougherty W., Kartha S., Rajan C., Lazarus M., Bailie A., Runkle B., et al. Greenhouse gas reduction benefits and costs of a large-scale transition to hydrogen in the USA. Energy Policy 37 (2009) 56-67
36. Möller B.F., Arriagada J., Assadi M., and Potts I. Optimisation of an SOFC/GT system with CO2-capture. J Power Sources 131 (2004) 320-326
37. Williams M.C., and Maru H.C. Distributed generation-molten carbonate fuel cells. J Power Sources 160 (2006) 863-867
38. Pilavachi P. Mini- and micro-gas turbines for combined heat and power. Appl Therm Eng 22 (2002) 2003-2014
39. Winkler W., Nehter P., Williams M.C., Tucker D., and Gemmen R. General fuel cell hybrid synergies and hybrid system testing status. J Power Sources 159 (2006) 656-666
40. EG&G Technical Services Inc. Fuel cells: a handbook. 7th ed. (2004), DOE, Morgantown, West Virginia
41. Varbanov P., Klemeš J., Shah R.K., and Shihn H. Power cycle integration and efficiency increase of molten carbonate fuel cell systems. J Fuel Cell Sci Technol 3 (2006) 375-383
42. Siemens Power Generation. http://www.powergeneration.siemens.com; 2006.
43. Larminie J., and Dicks A. Fuel cell systems explained (2003), John Wiley & Sons Ltd., Chichester, West Sussex
44. Uechi H., Kimijima S., and Kasagi N. Cycle analysis of gas turbine-fuel cell cycle hybrid micro generation system. J Eng Gas Turb Power 126 (2004) 755-762
45. POSCO Power. http://poscofuelcell.com; 2009.
46. Karvountzi G.C., Price C.M., and Duby P.F. Comparison of molten carbonate and solid oxide fuel cells for integration in a hybrid system for cogeneration or tri-generation, ASME 2004 International Mechanical Engineering Congress and Exposition. Anaheim, USA, November (2004)
47. Lunghi P., and Ubertini S. Efficiency upgrading of an ambient pressure molten carbonate fuel cell plant through the introduction of an indirect heated gas turbine. J Eng Gas Turb Power 124 (2002) 858-866
48. Bedont P., Grillo O., and Massardo A.F. Off-design performance analysis of a hybrid system based on an existing molten fuel cell stack. J Eng Gas Turb Power 125 (2003) 986-993
49. Massardo A.L., and Bosio B. Assessment of molten carbonate fuel cell models and integration with gas and steam cycles. J Eng Gas Turb Power 124 (2002) 103-109
50. IEA. Greenhouse gas R&D programme, fuel cells with carbon dioxide removal (1998)
51. George R.A. Status of tubular SOFC field unit demonstrations. J Power Sources 86 (2000) 134-139
52. DOE. Report to Congress, FutureGen Integrated Hydrogen, Electric Power Production and Carbon Sequestration Research Initiative; 2004.
53. Beér J.M. High efficiency electric power generation: the environmental role. Prog Energy Combust 33 (2007) 107-134
54. Arsalis A. Thermoeconomic modeling and parametric study of hybrid SOFC-gas turbine-steam turbine power plants ranging from 1.5 to 10 MWe. J Power Sources 181 (2008) 313-326
55. Campanari S. Full load and part-load performance prediction for integrated SOFC and microturbine systems. J Eng Gas Turb Power 122 (2000) 239-246
56. 2. Energy 32 (2007) 10-24
57. Lisbona P., and Romeo L.M. Enhanced coal gasification heated by unmixed combustion integrated with an hybrid system of SOFC/GT. Int J Hydrogen Energy 33 (2008) 5755-5764
58. 2 capture, separation and R&D options. In: Eliasson B., Riemer P., and Wokaun A. (Eds). International conference on greenhouse gas control technologies (1999), Pergamon, Interlaken, Switzerland, Amsterdam 119-124
59. Parsons E.L., Shelton W.W., and Lyons J.L. Advanced fossil power systems comparison study, final report (2002), NETL, Morgantown. http://www.netl.doe.gov/publications/others/techrpts/AdvFossilPowerSysCompStudy.pdf http://www.netl.doe.gov/publications/others/techrpts/AdvFossilPowerSysCompStudy.pdf
60. Nawaz M., and Ruby J. Zero emission coal alliance project. Conceptual design and economics. The 26th international technical conference on coal utilization & fuel systems. FL, USA, March (2001)
61. IPCC. Special report on carbon dioxide capture and storage (2005). http://www.climatescience.gov/workshop2005/presentations/breakout_2ARubin.pdf http://www.climatescience.gov/workshop2005/presentations/breakout_2ARubin.pdf