Integration of Hydrogen energy technologies in autonomous power systems

Power Systems

Volumn 31, Issue , 2008, Pages 23-81

  Marnellos, G E ^a   Athanasiou, C ^a   Makridis, S S ^a   Kikkinides, E S ^a  

^a NONE

Author keywords

[No Author keywords available]

Indexed keywords

EID: 84883756358     PISSN: 16121287     EISSN: 18604676     Source Type: Book Series    
DOI: 10.1007/978-1-84800-247-0_3     Document Type: Article

References (139)

1. Acres G, (2001). Recent advances in fuel cell technology and its applications. Journal of Power Sources 100: 60-66
2. Agrawal R, Offutt M, Ramage MP, (2005). Hydrogen economy-an opportunity for chemical engineers. AIChE Journal, 51(6): 1582-1589
3. Alanne K, Saari A, Ugursal V, Good J, (2006). The financial viability of an SOFC cogeneration system in single-family dwellings. Journal of Power Sources, 158: 403-416
4. Antolini E, (2007). Platinum-based ternary catalysts for low temperature fuel cells Part II. Electrochemical properties. Applied Catalysis B: Environmental 74: 337-350
5. Athanasiou C, Coutelieris F, Vakouftsi E, Skoulou V, Antonakou E, Marnellos G and Zabaniotou A, (2007). From biomass to electricity through integrated gasification/SOFC system-optimization and energy balance. International Journal of Hydrogen Energy, 32(3): 337-342
6. Ballard, (2005). Fuel Cell Technology "Road Map". Available from www.ballard.com/ be_informed/fuel_cell_technology/roadmap
7. Bar-On I, Kirchain R, Roth R, (2002). Technical Cost Analysis for PEM Fuel Cells. Journal of Power Sources, 109: 71-75
8. Barreto L, Makihira A, Riahi K, (2003). The hydrogen economy in the 21st century: a sustainable development scenario. International Journal of Hydrogen Energy 28: 267-284
9. Barron RF, (1999). Cryogenic Heat Transfer, Taylor & Francis, Philadelphia
10. Berry GD, (2004). Hydrogen production. Encyclopedia of Energy 253-265
11. Berube V, Radtke G, Dresselhaus M, Chen G, (2007). Size effects on the hydrogen storage properties of nanostructured metal hydrides: A review. Int. J. Energy Res. 2007, 31: 637-663
12. Bezerra C, Zhang L, Liu H, Lee K, Marques A, Marques E, Wang H, Zhang J, (2007). A review of heat-treatment effects on activity and stability of PEM fuel cell catalysts for oxygen reduction reaction Journal of Power Sources 173: 891-908
13. Blesl M, Fahl U, Ohl M, (2004). Hochtemperaturbrennstoffzellen und deren Kostenentwicklung. BWK, 56: 72-56
14. Bogdanovic B, Schwickardi M, (1997). Journal of Alloys and Compounds: 253-254, 1-9
15. Boudghene Stambouli A, Traversa E, (2002). Fuel cells, an alternative to standard sources of energy. Renewable and Sustainable Energy Reviews 6: 297-306
16. Bujalski W, Dikwal C, Kendall K, (2007). Cycling of three solid oxide fuel cell types. Journal of Power Sources, 171: 96-100
17. Carrette L, Friedrich KA and Stimming U, (2001). Fuel cells fundamentals and applications. Fuel Cells, 1: 1-35
18. 2adsorption in a microporous metal-organic framework with open metal sites. Angewandte Chemie International Edition.: 44, 4745-4749
19. Cheng X, Shi Z., Glass N, Zhang L, Zhang J, Song D, Liu Z, Wang H, Shen J, (2007). A review of PEM hydrogen fuel cell contamination: Impacts, mechanisms, and mitigation. Journal of Power Sources 165: 739-756
20. Collier A, Wang H, Zi Yuan X, Zhang J, Wilkinson D, (2006). Degradation of polymer electrolyte membranes. International Journal of Hydrogen Energy 31: 1838-1854
21. Costamagna P, Srinivasan S, (2001). Quantum jumps in the PEMFC science and technology from the 1960s to the year 2000. Part I. Fundamental scientific aspects. Journal of Power Sources 102: 242-252
22. Cotrell J, Pratt W, (2003). "Modeling the Feasibility of Using Fuel Cells and Hydrogen Internal Combustion Engines in Remote Renewable Energy Systems" NREL Technical Review
23. Crabtree GW, Dresselhaus MS, Buchanan MV, (2004). The hydrogen economy. Physics Today 57: 39-44
24. 2capture and storage. Part A: Review and selection of promising conversion and capture technologies. Progress in Energy and Combustion Science 32(2): 2514-2529
25. 2capture and storage. Part B: Chain analysis of promising CCS options. Progress in Energy and Combustion Science 33(6): 580-609
26. Darkrim FL, Malbrunot P, Tartaglia GP, (2002). Review of hydrogen storage by adsorption in carbon nanotubes. Int. J. Hydrogen Energy 27: 193-202
27. De Castro E, Tsou Y, Cao L, Hou C (2004). Approaches for low-cost components and MEAs for PEFCs: Current and future directions" 2004 Fuel Cell Seminar, San Antonio, Texas. Available from http://www.fuelcellseminar.com/pdf/2004/82%20 De%20Castro.pdf
28. Doran P, Robeson S, Wright D, Craven J, (2003). Finance and the fuel cell industry: a review of the current financing climate. International Journal of Hydrogen Energy 28: 713-715
29. Dornheim M, Eigen N, Barkhordarian G, Klassen T, Bormann R, (2006). Tailoring hydrogen storage materials towards application. Advanced Engineering Materials 8(5): 377-385
30. Dreier T and Wagner U, (2000). Perspektiven einer wasserstoff-energiewirtschaft. Teil 1: Techniken und Systeme zur Wasserstofferzeugung. BWK Bd. 52: 41-46
31. Dunn S, (2002). Hydrogen futures: toward a sustainable energy system. International Journal of Hydrogen Energy, 27: 235-264
32. Eddaoudi M, Kim J, Rosi N, Vodak D, Wachter J, O'Keeffe M, Yaghi OM, (2002). Systematic design of pore size and functionality in isoreticular MOFs and their application in methane storage. Science 295: 469-472
33. Eddaoudi M, Li H, Yaghi OM, (2000). Highly porous and stable metal-organic frameworks: Structure design and sorption properties. Journal of the American Chemical Society 122: 1391-1397
34. Edwards PP, Kuznetsov VL, David WIF, (2007). Hydrogen energy. Philosophical Transactions of the Royal Society 365, 1043-1056.
35. Ernst W, (2000). PEM technology development at Plug Power. 2000 Fuel Cell Seminar Program and Abstracts, Portland Oregon
36. European Commission's High Level Group (HLG) on Hydrogen and Fuel Cells, (2002). Hydrogen energy and fuel cells-a vision of our future, Report.
37. Fang HHP, Liu H, (2002). Effect of pH on hydrogen production from glucose by a mixed culture. Bioresources Technology 82: 87-93.
38. Farooque M, Maru H, (2006). Carbonate fuel cells: Milliwatts to megawatts. Journal of Power Sources 160 827-834
39. Felderhoff M, Weidenthaler C, von Helmolt R, Eberle U, (2007). Hydrogen storage: the remaining scientific and technological challenges. Physical Chemistry Chemical Physics 9: 2643-2653
40. Fergus J, (2006). Oxide anode materials for solid oxide fuel cells. Solid State Ionics 177: 1529-1541
41. Floch P-H, Gabriel S, Mansilla C, Werkoff F, (2007). On the production of hydrogen via alkaline electrolysis during off-peak periods. International Journal of Hydrogen Energy 32(18): 4641-4647
42. Fuel Cells (2000). How much do fuel cells cost? Available from http://www.fuelcells.org /fcfaqs.htm#cost
43. Gasteiger H, Kocha S, Sompalli B, Wagner F, (2005). Activity benchmarks and requirements for Pt, Pt-alloy and non-Pt oxygen reduction catalysts for PEMFCs", Applied Catalysis B: Environmental, 56: 9-35
44. Ghouse M, Abaoud H, Al-Boeiz A, (2000). Operational experience of a 1 kW PAFC stack. Applied Energy 65: 303-314
45. Gouérec P, Poletto L, Denizot J, Sanchez-Cortezon E, Miners J, (2004). The evolution of the performance of alkaline fuel cells with circulating electrolyte. Journal of Power Sources, 129: 193-204.
46. Grigoriev SA, Porembsky VI, Fateev VN, (2006). Pure hydrogen production by PEM electrolysis for hydrogen energy. International Journal of Hydrogen Energy 31(2): 171-175
47. 2containing gases. Journal of Power Sources, 127: 243-251
48. Haile S, (2003). Fuel cell materials and components. Acta Materialia 51: 5981-6000
49. Haland A, (2000). High-pressure conformable hydrogen storage for fuel cell vehicles, US DOE Hydrogen Program review, NREL/CP-570-28890, San Ramon California USA
50. Harris R, Book D, Anderson PA, Edwards PP, (2004). Hydrogen storage: the grand challenge. The Fuel Cell Review 1: 17-23
51. Hart D (1997). Hydrogen Power: The commercial future of the ultimate fuel. London, UK: Financial Times Energy Publishing
52. Hawkes A, Leach M, (2005). Solid oxide fuel cell systems for residential micro-combined heat and power in the UK: Key economic drivers. Journal of Power Sources, 149: 72-83
53. Hellmana H, van den Hoed R, (2007). Characterising fuel cell technology: Challenges of the commercialisation process. International Journal of Hydrogen Energy 32: 305-315
54. Hermann A, Chaudhuri T, Spagnol P, (2005). Bipolar plates for PEM fuel cells: A review. International Journal of Hydrogen Energy 30: 1297-1302
55. Herring JS, O'Brien JE, Stoots CM, Hawkes GL, Hartrigsen JJ, Shahnan M, (2007). Progress in high temperature electrolysis for hydrogen production using planar SOFC technology. International Journal of Hydrogen Energy 32(4): 440-450
56. Hirscher M, Becher M, (2003). Hydrogen storage in carbon nanotubes. Journal of Nanoscience and Nanotechnology 3: 3-17
57. Hogarth W, Diniz da Costa J, Lu G, (2005). Solid acid membranes for high temperature (>140C) proton exchange membrane fuel cells. Journal of Power Sources 142: 223-237
58. Hufton J, Waldron W, Weigel S, Rao M, Nataraj S, Sircar S, (2000). Sorption enhanced reaction process for the production of hydrogen. Proceedings of the 2000 US Department of Energy Hydrogen Program Review, NREL/CP-570-28890
59. Hummel G, (2001). Hydrogen burner technology. The benefits of on-site reforming of natural gas to hydrogen for early alternative fuelling systems. In: National Hydrogen Association (NHA). Hydrogen: The common thread, 12th Annual US Hydrogen Meeting, Washington, DC, 6-8 March 2001, Proceedings: 121-127
60. IEA, (2005). Prospects for hydrogen and fuel cells. IEA Publications
61. Kandiyoti R, Herod AA, Bartle KD, (2006). Pyrolysis: Thermal breakdown of solid fuels in a gaseous environment. Solid Fuels and Heavy Hydrocarbons Liquids: 36-90
62. Kendall K, Singhal S, (2003). High Temperature Solid Oxide Fuel Cells: Fundamentals, Design and Applications. Elsevier Ltd
63. Knights S, Colbow K, St-Pierre J, Wilkinson D, (2004). Aging mechanisms and lifetime of PEFC and DMFC. Journal of Power Sources, 127: 127-134.
64. Larminie J, Dicks A, (2003). Fuel cell systems explained 2nd edn. John Wiley & Sons Ltd. West Sussex, UK.
65. Levin DB, Pitt L, Love M, (2004). Biohydrogen production: Prospects and limitations to practical application. International Journal of Hydrogen Energy 29(2): 173-185
66. Li H, Eddaoudi M, O'Keeffe M, Yaghi OM, (1999). Design and synthesis of an exceptionally stable and highly porous metal-organic framework. Nature 402: 276-279
67. Li X, Sabir I, (2005). Reviewof bipolar plates in PEMfuel cells: Flow-field designs. International Journal of Hydrogen Energy 30: 359-371
68. Li YW, Yang RT, (2007). Hydrogen storage on platinum nanoparticles doped on superactivated carbon. Journal of Physical Chemistry C 111: 11086-11094
69. Lipman T, Edwards J, Kammen D, (2004). Fuel cell system economics: comparing the costs of generating power with stationary and motor vehicle PEM fuel cell systems. Energy Policy 32: 101-125
70. Litster S, G. McLean G, (2004). PEM fuel cell electrodes. Journal of Power Sources 130: 61-76
71. Ma Y, Wainright J, Savinell R, (2004). Conductivity of PBI Membranes for hightemperature polymer electrolyte fuel cells. Journal of Electrochemical Society, 151: 8-16
72. Mahadevan K, Judd K, Stone H, Zewatsky J, Thomas A, Mahy H, Paul D, (2007). Identification and characterization of near-term direct hydrogen proton exchange fuel cell markets. US DOE, DOE Contract No. DE-FC36-03GO13110
73. Marban G and Valdes-Solis T, (2007). Towards the hydrogen economy? International Journal of Hydrogen Energy, 32: 1625-1637
74. McLean G, Niet T, Prince-Richard S, Djilali N, (2001). An assessment of alkaline fuel cell technology. International Journal of Hydrogen Energy 27: 507-526
75. Mehta V, Cooper J, (2003). Review and analysis of PEM fuel cell design and manufacturing. Journal of Power Sources 114: 32-53
76. Melis A, (2002). Green algae hydrogen production: progress, challenges and prospects. International Journal of Hydrogen Energy 27(11-12): 1217-1228
77. Moller S, Kaucic D, Sattler S, (2004). Hydrogen production by solar reforming of natural gas: a cost study. Proceedings of 2004 Solar Conference, July 11-14, Portland, Oregon, USA
78. Momirlan M and Veziroglu TN, (2002). Current status of hydrogen energy. Renewable and Sustainable Energy Reviews, 6: 141-179
79. Ni M, Leung DYC, Leung MKH and Sumathy K, (2006). An overview of hydrogen production from biomass. Fuel Process Technology 87: 461-472
80. Niel EWJV, Claassen PAM, Stams AJM, (2003). Substrate and product inhibition of hydrogen production by the extreme thermophile Caldicellulosiruptor saccharolyticus. Biotechnololy Bioengineering 81: 255-262.
81. Nowotny J, Sorrell CC, Bak T, Sheppard LR, (2005). Solar-hydrogen: Unresolved problems in solid-state science. Solar Energy 78(5): 593-602
82. Panella B, Hirscher M, Püttner H, Müller U, (2006). Hydrogen adsorption in metal-organic frameworks: Cu-MOFs and Zn-MOFs compared. Advanced Functional Materials 16: 520-524
83. Pehnt M, Ramesohl S, (2004). Fuel cells for distributed power: benefits, barriers and perspectives. An Activity of World Fuel Cell Council, http://assets.panda.org/ downloads/stationaryfuelcellsreport.pdf
84. 2filling station. International Journal of Hydrogen Energy 26: 777-782
85. Price Waterhouse Coopers (2006). New energy for world markets: 2006 fuel cell industry survey. Available from: http://www.fuelcelltoday.com/media/pdf/financials/fcis_06.pdf
86. PriceWaterhouse Coopers (2007). New energy for world markets: 2007 fuel cell industry survey. Available from: http://www.pwc.com/extweb/ pwcpublications. nsf/DocID/ 25582836BD5E736 A852570CA00178BC7.
87. Ralph T, (1997). Proton exchange membrane fuel cells: Progress in cost reduction of the key components. Platinum Metals Review, 41: 102-113
88. Reijers HTJ, Roskam-Bakker DF, Dijkastra JW, de Smidt RP, de Groot A, van den Brink RW, (2003). Hydrogen production through sorption enhanced reforming. 1st European Hydrogen Energy Conference, Grenoble
89. Rowsell JLC, Yaghi OM, (2005). Strategies for hydrogen storage in metal-organic frameworks. Angewandte Chemie International Edition 44: 4670-4679
90. Sakintun B, Lamari-Darkrim F, Hirscher M, (2007). Metal hydride materials for solid hydrogen storage: A review. International Journal of Hydrogen Energy 32: 1121-1140
91. Sammes N, Bove R, Stahl K, (2004). Phosphoric acid fuel cells: Fundamentals and applications. Current opinion in solid state and materials. Science 8: 372-378
92. Sandrock G, (1999). A panoramic overview of hydrogen storage alloys from a gas reaction point of view. Journal of Alloys and Compounds 293-295: 877-888
93. Saxena RC, Seal D, Kumar S, Goyal HB, (2007). Thermo-chemical routes for hydrogen rich gas from biomass: A review, in press
94. Schlapbach L, Züttel A, (2001). Hydrogen-storage materials for mobile applications. Nature 414: 353-358
95. Schuckert M, (2005). CUTE-a major step towards cleaner urban transport. Hydrogen and Fuel Cell Expert Workshop, IEA
96. Seayad, AM, Antonelli M, (2004). Recent advances in hydrogen storage in metal containing inorganic nanostructures and related materials. Advanced Materials 16: 765-777
97. Shoko E, McLellan B, Dicks AL, Diniz da Costa JC, (2006). Hydrogen from coal: Production and utilisation technologies. International. Journal of Coal Geology, 65(3-4): 213-222
98. Smith B, Sridhar S, Khan A, (2005). Solid polymer electrolyte membranes for fuel cell applications-a review. Journal of Membrane Science 259: 10-26
99. Sopian K, Wan Daud W, (2006). Challenges and future developments in proton exchange membrane fuel cells. Renewable Energy 31: 719-727
100. Srinivasan S, (2006). Fuel cells: From fundamentals to applications. Springer Science and Business Media LLC, New York
101. Staffell I, (2007a). Review of Alkaline Fuel Cell performance. Available from: http://www.form-eng.bham.ac.uk/fuelcells/staffell.htm.
102. Staffell I, (2007b). Review of PEM fuel cell performance. Available from: http://www.form-eng.bham.ac.uk/fuelcells/staffell.htm.
103. Staffell I, (2007c). Review of Solid Oxide Fuel Cell performance. Available from: http://www.form-eng.bham.ac.uk/fuelcells/staffell.htm.
104. Staffell I, Green R, Kendall K, (2007). Cost targets for domestic fuel cell CHP. Journal of Power Sources, doi:10.1016/j.jpowsour.2007.11.068
105. Stone HBJ, Veldhuis I, Richardson RN, (2005). An investigation into large-scale hydrogen storage in the UK. Proceedings International Hydrogen Energy Congress and Exhibition IHEC, Istanbul, Turkey, 13-15 July 2005
106. Stoukides M, (2000). Solid electrolyte membrane reactors: current experience and future outlook. Catalysis Reviews Science & Engineering, 42: 1-70
107. Sun C, Stimming U, (2007). Recent anode advances in solid oxide fuel cells. Journal of Power Sources 171: 247-260
108. Sunandana CS, (2007). Nanomaterials for hydrogen storage-The van't Hoff connection. Springer Resonance, 12(5): 31-36(6)
109. Tawfik H, Hung Y, Mahajan D, (2007). Metal bipolar plates for PEM fuel cell-A review. Journal of Power Sources 163: 755-767
110. Taylor JB, Alderson JEA, Kalyanam KM, Lyle AB and Phillips LA, (1986). Technical and economic assessment of methods for the storage of large quantities of hydrogen, International Journal of Hydrogen Energy 11: 5-22
111. Thomas KM, (2007). Hydrogen adsorption and storage on porous materials. Catalysis Today 120: 389-398
112. Timmerhaus KD, Flynn TM, (1989). Cryogenic process engineering, Plenum Press, New York
113. Tsuchiya H, Kobayashi O, (2004). Mass production cost of PEM fuel cell by learning curve. International Journal of Hydrogen Energy, 29: 985-990
114. Turner J, (2003). Photo electrochemical water splitting. http://www.eere.energy.gov/ hydrogenandfuelcells/hydrogen/pdfs/15_nrel_john_turner.pdf
115. US DOE, (2002). Fuel cell handbook (Sixth edn). EG&G Technical Services, Inc. Science Applications International Corporation. DOE/NETL-2002/1179
116. UNEP (2002). Fuel Cell Market Prospects and Intervention Strategies, United Nations Environment Programme, Imperial College Centre for Energy Policy and Technology
117. Varner K, Warren S, Turner JA, (2002). Photoelectrochemical systems for hydrogen production. Proceedings of the 2002 US DOE Hydrogen Program Review. NREL/CP-610-32405
118. Venter RD and Pucher G, (1997). Modelling of stationary bulk hydrogen storage systems. International Journal of Hydrogen Energy 22: 791-798
119. Vitart X, Le Duigou A, Carles P, (2006). Hydrogen production using the sulphur-iodine cycle coupled to a VHTR: An overview. Energy Conversion and Management 47(17): 2740-2747
120. Von Helmolt R, Eberle U, (2007). Fuel cell vehicles: Status 2007. Journal of Power Sources 165: 833-843
121. Wang B, (2005). Recent development of non-platinum catalysts for oxygen reduction reaction: Review. Journal of Power Sources 152: 1-15
122. Wee J, Lee K, (2006). Overview of the development of CO-tolerant anode electrocatalysts for proton-exchange membrane fuel cells. Journal of Power Sources 157: 128-135
123. Wetzel FJ, (1998). Improved handling of liquid hydrogen at filling stations: Review of six years' experience. International Journal of Hydrogen Energy 23(5): 339-348
124. Wilkinson D, Steck A, (1997). General progress in the research of solid polymer fuel cell technology at Ballard. Second international symposium on new materials for fuel cell and modern battery systems, Montreal, Quebec, Canada
125. Williams M, Strakey J, Singhal S, (2004). US distributed generation fuel cell program. Journal of Power Sources 131: 79-85
126. 2saturation uptake in microporous metal-organic frameworks. Journal of the American Chemical Society 128: 3494-3495
127. Worldwide Fuel Cell Industry Survey (2006). Available from: http://www.usfcc.com /download_a_file/download_a_file/Nov27-PGWG-2006WorldwideFuelCellIndustry Survey-06-209.pdf
128. Yaman S, (2004). Pyrolysis of biomass to produce fuels and chemical feedstocks. Energy Conversion and Management 45(5): 651-671
129. Yamashita and Barreto, (2003). Integrated energy systems for the 21st century: Coal gasification for co-producing hydrogen, electricity and liquid fuels. Interim report IR-03-039, International Institute for Applied System Analysis, Laxenburg
130. Yang J, Park Y, Seo S, Lee H, Noh J, (2002). Development of a 50 kW PAFC power generation system. Journal of Power Sources. 106: 68-75
131. Yu X, Ye S, (2007). Recent advances in activity and durability enhancement of Pt/C catalytic cathode in PEMFC. Part I. Physico-chemical and electronic interaction between Pt and carbon support, and activity enhancement of Pt/C catalyst. Journal of Power Sources 172: 133-144
132. Yu X, Ye S, (2007). Recent advances in activity and durability enhancement of Pt/C catalytic cathode in PEMFC. Part II: Degradation mechanism and durability enhancement of carbon supported platinum catalyst. Journal of Power Sources 172: 145-154
133. Yuh A, Farooque M, (2002). Carbonate fuel cell materials. Advanced Materials and Processes, 160: 31
134. Zaluska A, Zaluski L, Ström-Olsen JO (2001). Structure, catalysis and atomic reactions on the nano-scale: a systematic approach to metal hydrides for hydrogen storage. Applied Physics A: Materials Science & Processing 72(2): 157-165
135. Zhang J, Fisher TS, Ramachandran PV, Gore JG, Mudawar I, (2005). A review of heat transfer issues in hydrogen storage technologies. Journal of Heat Transfer 127: 1391-1399
136. Zhang J, Xie Z, Zhang J, Tang Y, Song C, Navessin T, Shi Z, Song D, Wang H, Wilkinson D, Liu Z, Holdcroft S, (2006). High temperature PEM fuel cells: Review. Journal of Power Sources 160: 872-891
137. Zhang L, Zhang J, Wilkinson D, Wang H, (2006). Progress in preparation of non-noble electrocatalysts for PEM fuel cell reactions. Journal of Power Sources 156: 171-182
138. Zink F, Lu Y, Schaefer L, (2007). A solid oxide fuel cell system for buildings. Energy Conversion and Management 48: 809-818
139. Zoulias EI, Glockner R, Lymberopoulos N, Tsoutsos T, Vosseler I, Gavalda O, Mydske HJ, Taylor P, (2006). Integration of hydrogen energy technologies in stand-alone power systems. Analysis of the current potential for application. Renewable and Sustainable Energy Reviews 10(5): 432-462