Hydrogen and fuel cells

Green Energy and Technology

Volumn 201, Issue , 2015, Pages 453-491

  Shabani, Bahman ^a   Andrews, John ^a  

^a RMIT UNIVERSITY   (Australia)

Author keywords

Electricity; Energy storage; Hydrogen; Microgrids

Indexed keywords

ELECTRIC ENERGY STORAGE; ELECTRICITY; EMISSION CONTROL; ENERGY EFFICIENCY; ENERGY POLICY; ENERGY SECURITY; ENERGY STORAGE; FOSSIL FUEL DEPOSITS; FOSSIL FUEL POWER PLANTS; FOSSIL FUELS; FUEL CELLS; GREENHOUSE GASES; HYDROGEN; HYDROGEN PRODUCTION; HYDROGEN STORAGE; MICROGRIDS; MOBILE POWER PLANTS;

AUTOMOTIVE APPLICATIONS; EMISSION REDUCTION TARGETS; FOSSIL FUEL RESOURCES; HYDROGEN ENERGY SYSTEMS; RESEARCH AND DEVELOPMENT; STATIONARY APPLICATIONS; STORAGE REQUIREMENTS; SUSTAINABLE SOLUTION;

RENEWABLE ENERGY RESOURCES;

EID: 84928569171     PISSN: 18653529     EISSN: 18653537     Source Type: Book Series    
DOI: 10.1007/978-81-322-2337-5_17     Document Type: Article

References (99)

1. Aftabuzzaman M, Mazloumi E (2011) Achieving sustainable urban transport mobility in post peak oil era. Transp Policy 18(5):695-702
2. Ahluwalia RK, Wang X, Kwon J, Rousseau A, Kalinoski J, James B, Marcinkoski J (2011) Performance and cost of automotive fuel cell systems with ultra-low platinum loadings. J Power Sources 196(10):4619-4630
3. Ahluwalia RK, Hua TQ, Peng JK (2012) On-board and Off-board performance of hydrogen storage options for light-duty vehicles. Int J Hydrogen Energy 37(3):2891-2910
4. AltusLift (2014) Hybrid vs. hydrogen fuel cell forklift-possible future. Retrieved Sept 2014, from http://altuslift.com/blog/hybrid-vs-hydrogen-fuel-cell-forklift-possible-future/
5. Amjad S, Neelakrishnan S, Rudramoorthy R (2010) Review of design considerations and technological challenges for successful development and deployment of plug-in hybrid electric vehicles. Renew Sustain Energy Rev 14(3):1104-1110
6. Andrews J, Seif Mohammadi S (2014) Towards a 'proton flow battery': investigation of a reversible PEM fuel cell with integrated metal-hydride hydrogen storage. Int J Hydrogen Energy 39(4):1740-1751
7. Andrews J, Shabani B (2012a) Dimensionless analysis of the global techno-economic feasibility of solar-hydrogen systems. Int J Hydrogen Energy 37(1):16-18
8. Andrews J, Shabani B (2012b) Re-envisioning the role of hydrogen in a sustainable energy economy. Int J Hydrogen Energy 37(2):1184-1203
9. Argumosa MDP, Schucan TH Fuel cell innovative remote energy system for telecom, INTA & IEA Hydrogen implementing Agreement. http://www.ieahia.org/pdfs/FIRST.pdf
10. Ballard (2004) Ballard Fuel Cell. Retrieved Sept 2014, from www.ballard.com
11. BCS (2009) BCS fuel cell, 500 W PEM fuel cell specification. 2009, Retrieved March 2009, from http://www.bcsfuelcells.com/
12. Bezmalinovic D, Barbir F, Tolj I (2013) Techno-economic analysis of PEM fuel cells role in photovoltaic- based systems for the remote base stations. Int J Hydrogen Energy 38(1):417-425
13. Blain L (2007) Honda set to release hydrogen fuel cell car-and home fuelling station. Retrieved Oct. 2014, from http://www.gizmag.com/honda-fuel-cell-fcx/8394/
14. Blanchard J (2007) Site reliability: fuel cells add reliability to telecom sites. Intelec, Rome
15. Bockris JOM (2013) The hydrogen economy: its history. Int J Hydrogen Energy 38(6):2579-2588
16. Braun P (2013) Daimler gets hyped on hydrogen, plans 400 H2 stations in Germany by 2023, from http://www.digitaltrends.com/cars/daimler-goes-big-on-h2-plans-to-bring-400-hydrogenfiling- stations-to-german-in-the-next-decade/
17. Brooks K, Makhmalbaf A, Anderson D, Amaya J, Pilli S, Srivastava V, Upton J (2013) Business case for a micro-combined heat and power fuel-cell system in commercial applications. US Department of Energy, Pacific Northwest National Laboratory, Richland
18. Bubna P, Brunner D, Gangloff JJ Jr, Advani SG, Prasad AK (2010) Analysis, operation and maintenance of a fuel cell/battery series-hybrid bus for urban transit applications. J Power Sources 195(12):3939-3949
19. BusinessWires (2014) Intelligent energy reports highest power densities yet for automotive fuel cells. Retrieved Sept 2014, from http://www.businesswire.com/news/home/20130326005106/ en/Intelligent-Energy-Reports-Highest-Power-Densities-Automotive#.VDY3mfQW18F
20. Carter D Wing J (2013) The fuel cell industry review 2013. Fuel Cell Today, Royston
21. Cockroft C (2008) Perth's fuel cell bus trial 2004-2007, Final operational report to the department for planning and infrastructure. Murdoch University, Perth
22. Cotrell J, Pratt W (2003) Modeling the feasibility of using fuel cells and hydrogen internal combustion engines in remote renewable energy systems. National Renewable Energy Laboratory (NREL), US Department of Energy Laboratory, USA
23. Dantherm (2009a) Benefits of fuel cell solutions for emergency backup power needs in telecom. Retrieved Jan 2012, from www.dantherm-power.com
24. Dantherm (2009b) Economics of fuel cell solutions for emergency backup power needs in telecom. Retrieved Jan 2012, from www.dantherm-power.com
25. Doddathimmaiah A, Andrews J (2009) Theory, modelling and performance measurement of unitised regenerative fuel cells. Int J Hydrogen Energy 34(19):8157-8170
26. DoE (2010) Early markets: fuel cells for backup power, US Department of energy, energy efficiency and renewable energy. Fuel cell technologies program
27. DoE (2011) Technical plans fuel cells. US department of energy, hydrogen and fuel cell program
28. DoE FY (2011) Progress report for the DOE hydrogen program. Department of Energy, Washington DC
29. DoE (2012) Progress report for the DOE hydrogen program. US Department of Energy
30. DoE (2013) US department of energy, hydrogen and fuel cell program: annual progress review. Retrieved Oct 2014, from http://www.hydrogen.energy.gov/annual_progress13.html
31. DoE (2014) DOE H2A delivery analysis. Retrieved Oct 2014, from http://www.hydrogen.energy. gov/h2a_delivery.html
32. DoE (2014) Fuel cells for backup power in telecommunications facilities, providing a constant, reliable electric power supply. DOE hydrogen program
33. Dougherty WS, Kartha C, Rajan M, Lazarus A, Bailie BR, Fencl A (2009) Greenhouse gas reduction benefits and costs of a large-scale transition to hydrogen in the USA. Energy Policy 37(1): 56-67
34. DSEWPC (2009) Hydrogen fuel cell bus trial. Department of sustainability, environment, water, population and communities. Retrieved Sept 2013, from http://www.environment.gov.au/ atmosphere/fuelquality/emerging/alternative/hydrogen.html
35. DW (2014) German fuel cell plane makes maiden flight. Retrieved Sept 2014, from http://www.dw.de/german-fuel-cell-plane-makes-maiden-flight/a-4463354
36. Farrell AE, Keith DW, Corbett JJ (2003) A strategy for introducing hydrogen into transportation. Energy Policy 31(13):1357-1367
37. Folkesson A, Andersson C, Alvfors P, Alaküla M, Overgaard L (2003) Real life testing of a Hybrid PEM Fuel Cell Bus. J Power Sources 118(1-2):349-357
38. Fosberg K (2011) Fuel cell systems provide backup power in telecom application. IdaTech LLC, Oregon
39. Fuelcells2000 (2014) Fuel cell vehicles. Retrieved Sept 2014, from http://www.fuelcells.org/info/ charts/carchart.pdf
40. FuelCellToday (2012) Two-wheelers and the demand for fuel cells. Retrieved Sept 2014, from http://www.fuelcelltoday.com/analysis/analyst-views/2012/12-08-01-two-wheelers-and-thedemand- for-fuel-cells
41. Gao D, Jin Z, Lu Q (2008) Energy management strategy based on fuzzy logic for a fuel cell hybrid bus. J Power Sources 185(1):311-317
42. Gigliucci G, Petruzzi L, Cerelli E, Garzisi A, La Mendola A (2004) Demonstration of a residential CHP system based on PEM fuel cells. J Power Sources 131(1-2):62-68
43. GM (2013) GM, Honda to collaborate on next-generation fuel cell technologies. Retrieved Oct 2014, from http://media.gm.com/media/us/en/gm/news.detail.html/content/Pages/news/us/ en/2013/Jul/0702-gm-honda.html
44. Gómez G, Martínez G, Gálvez JL, Gila R, Cuevas R, Maellas J, Bueno E (2009) Optimization of the photovoltaic-hydrogen supply system of a stand-alone remote-telecom application. Int J Hydrogen Energy 34(13):5304-5310
45. Haraldsson K, Folkesson A, Alvfors P (2005) Fuel cell buses in the Stockholm CUTE project- first experiences from a climate perspective. J Power Sources 145(2):620-631
46. Hoffman P (2012) Tomorrow's energy: hydrogen, fuel cells, and the prospects for a clear planet. MIT Press, Cambridge
47. HONDA (2014a) FCX Clarity. Retrieved Sep. 2014, from http://automobiles. honda.com/fcx-clarity/
48. HONDA (2014b) Future models + concepts. Retrieved Sep. 2014, from http://automobiles. honda.com/honda-fcev/
49. Horizon (2014) Horizon fuel cell technologies. Retrieved Oct 2014, from http://www.horizonfuel cell.com/#!h-series-stacks/c52t
50. Huétink FJ, van der Vooren A, Alkemade F (2010) Initial infrastructure development strategies for the transition to sustainable mobility. Technol Forecast Soc Change 77(8): 1270-1281
51. HydrogenCarsNow (2014a) Hydrogen cars now. Retrieved Sept 2014, from http://www.hydrogencarsnow.com/
52. HydrogenCarsNow (2014b) Vision Tyrano truck. Retrieved Sept 2014, from http://www.hydrogencarsnow.com/vision-tyrano.htm
53. HydrogenMotor (2007) BMW hydrogen 7. Retrieved Sept 2014, from http://www.hydrogenmotors. com/bmw-hydrogen-7.html
54. Hyundai (2007) Tucson fuel cell car. Retrieved Sept 2014, from https://www.hyundaiusa.com/tu csonfuelcell/
55. IAHE (2014) International association for hydrogen energy news letter. 6(2). http://www.iahe.org/
56. IEA (2013) Key world energy outlook. International Energy Agency, Paris
57. IEA (2014) IEA statistics, CO2 emissions from fuel combustion highlights. International Energy Agency, Paris
58. INTECH (2014) The application of electric drive technologies in city buses. Retrieved Sept 2014, from http://www.intechopen.com/books/new-generation-of-electric-vehicles/the-applicationof- electric-drive-technologies-in-city-buses
59. IPCC (2014) Climate change 2014, mitigation of climate change
60. Jacobson MZ, Delucchi MA (2011) Providing all global energy with wind, water, and solar power, part I: technologies, energy resources, quantities and areas of infrastructure, and materials. Energy Policy 39(3):1154-1169
61. Jiménez-Fernández S, Salcedo-Sanz S, Gallo-Marazuela D, Gómez-Prada G, Maellas J, Portilla-Figueras A (2014) Sizing and maintenance visits optimization of a hybrid photovoltaichydrogen stand-alone facility using evolutionary algorithms. Renew Energy 66:402-413
62. Kim J, Moon I (2008) The role of hydrogen in the road transportation sector for a sustainable energy system: a case study of Korea. Int J Hydrogen Energy 33(24):7326-7337
63. Kleijn R, van der Voet E (2010) Resource constraints in a hydrogen economy based on renewable energy sources: an exploration. Renew Sustain Energy Rev 14(9):2784-2795
64. Larminie J, Dicks A (2003) Fuel cell explained, 2nd edn. Wiley, New York
65. Lee K, Chung D, Park M, Chu C (2013) The development of a cylindrical proton exchange membrane fuel cell with an integrated metal-hydride container. Int J Precis Eng Manufact 14(6):1065-1070
66. Li X, Li J, Xu L, Yang F, Hua J, Ouyang M (2010) Performance analysis of proton-exchange membrane fuel cell stacks used in Beijing urban-route buses trial project. Int J Hydrogen Energy 35(8):3841-3847
67. McDowall W, Eames M (2007) Towards a sustainable hydrogen economy: A multi-criteria sustainability appraisal of competing hydrogen futures. Int J Hydrogen Energy 32(18):4611-4626
68. Melaina MW, Antonia O, Penev M (2013) Blending hydrogen into natural gas pipeline networks: a review of key issues. National Renewable Energy Laboratory (NREL), Colorado
69. Mock P, Schmid SA (2009) Fuel cells for automotive powertrains-a techno-economic assessment. J Power Sources 190(1):133-140
70. NREL (2014) Hydrogen and fuel cell research. Retrieved Sept 2014, from http://www.nrel.gov/ hydrogen/proj_fc_bus_eval.html
71. Ouyang M, Xu L, Li J, Lu L, Gao D, Xie Q (2006) Performance comparison of two fuel cell hybrid buses with different powertrain and energy management strategies. J Power Sources 163(1):467-479
72. Panasonic (2011) Tokyo gas and Panasonic to launch new improved "Ene-Farm" home fuel cell with world-highest power generation efficiency at more affordable price. Retrieved Sept 2014, from http://panasonic.co.jp/corp/news/official.data/data.dir/en110209-2/en110209-2.html
73. Paolo A (2007) Hydrogen infrastructure for the transport sector. Int J Hydrogen Energy 32(15):3526-3544
74. Rifkin J (2002) The hydrogen economy: the creation of the worldwide energy web and the redistribution of power on earth. Refocus 4(3):12
75. Saathoff S (2004) Fuel cells as backup power for state government communications sites. Avista Labs, Washington
76. Saathoff S (2010) Fuel cell basics for communications industry professionals. ReliOn, USA
77. ScienceDaily (2013) Metal-free catalyst outperforms platinum in fuel cell. Retrieved Oct 2013, from http://www.sciencedaily.com/releases/2013/06/130605111518.htm
78. Shabani B, Andrews J (2011) An experimental investigation of a PEM fuel cell to supply both heat and power in a solar-hydrogen RAPS system. Int J Hydrogen Energy 36(9):5442-5452
79. Shabani B, Andrews J (2015) Standalone solar-hydrogen systems powering fire contingency networks. Int J Hydrogen Energy. Available online 25 February 2015 (in press)
80. Shabani B, Andrews J, Badwal S (2010a) Fuel cell heat recovery, electrical load management, and the economics of solar-hydrogen systems. Int J Power Energy Syst 30(4):256-263
81. Shabani B, Andrews J, Watkins S (2010b) Energy and cost analysis of a solar-hydrogen combined heat and power system for remote power supply using a computer simulation. Sol Energy 84(1):144-155
82. Shabani B, Andrews J, Subic A (2012) Hydrogen fuel keep on trucking. Retrieved Sept 2014, from http://ecogeneration.com.au/news/hydrogen_fuel_keeps_on_trucking/077017/
83. Singh T (2012) UK's first hydrogen-powered locomotive built by University of Birmingham Students. Retrieved Sept 2014, from http://inhabitat.com/university-of-birmingham-studentsbuild- uks-first-hydrogen-powered-locomotive/
84. Sorensen B (2005) Hydrogen and fuel cells-emerging technologies and applications. Elsevier Academic Press, London
85. Sossan F, Bindner H, Madsen H, Torregrossa D, Chamorro LR, Paolone M (2014) A model predictive control strategy for the space heating of a smart building including cogeneration of a fuel cell-electrolyzer system. Int J Electr Power Energy Syst 62:879-889
86. Sterling S (2012) Hydrogen: the 'never say die' industry surges again. Retrieved Sept 2014, from http://www.renewableenergyfocus.com/view/27884/hydrogen-the-never-say-die-industrysurges- again/
87. TeslaMotor (2014) Tesla motor electric car model S. Retrieved Oct. 2014, from http://www.teslamotors.com/en_AU
88. TMR (2007) BMW hydrogen 7. Retrieved Oct 2014, from http://www.themotorreport.com. au/483/bmw-hydrogen-7
89. Toyota (2014) Toyota fuel cell vehicle. Retrieved Sept 2014, from http://www.toyota-global.com/ innovation/environmental_technology/fuelcell_vehicle/
90. van Vliet O, Brouwer AS, Kuramochi T, van den Broek M, Faaij A (2011) Energy use, cost and CO2 emissions of electric cars. J Power Sources 196(4):2298-2310
91. Vancoillie J, Demuynck J, Sileghem L, Van De Ginste M, Verhelst S (2012) Comparison of the renewable transportation fuels, hydrogen and methanol formed from hydrogen, with gasoline- engine efficiency study. Int J Hydrogen Energy 37(12):9914-9924
92. Varkaraki E, Lymberopoulos N, Zachariou A (2003) Hydrogen based emergency back-up system for telecommunication applications. J Power Sources 118(1-2):14-22
93. Verhelst S, Wallner T (2009) Hydrogen-fueled internal combustion engines. Prog Energy Combust Sci 35(6):490-527
94. Vision (2014) Vision Tyrano. Retrieved Sep. 2014, from http://www.visionmotorcorp.com/tyr ano.asp
95. Wang J, Chen Y, Chen Q (2006) A fuel cell city bus with three drivetrain configurations. J Power Sources 159(2):1205-1213
96. Wilkinson DP, Zhang J, Hui R, Fergus J, Li X (2009) Proton exchange membrane fuel cells; materials properties and performance. CRC Press, Florida
97. WNA (2014) World nuclear association update: Fukushima accident, from http://www. world-nuclear.org/info/Safety-and-Security/Safety-of-Plants/Fukushima-Accident/
98. Yang B, Hoober-Burkhardt L, Wang F. Prakash GKS, Narayanan SR (2014) An inexpensive aqueous flow battery for large-scale electrical energy storage based on water-soluble organic Redox couples. J Electrochem Soc 161(9):1371-1380
99. Zapata C, Nieuwenhuis P (2010) Exploring innovation in the automotive industry: new technologies for cleaner cars. J Clean Prod 18(1):14-20