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Proceedings of the Fifth Grove Fuel Cell Symposium - Fuel Cells - Investing in a Clean Future incorporating the First Executive Seminar on Fuel Cells - London, UK, 22-25 September 1997
Lovering DG |
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Proceedings of the Fifth Grove Fuel Cell Symposium - Fuel Cells - Investing in a Clean Future incorporating the First Executive Seminar on Fuel Cells - London, UK, 22-25 September 1997 -Foreword
Acres GJK |
| 4 - 4 |
Investing in the fuel cell business
Rasul F |
| 7 - 11 |
The global and urban environment: the need for clean power systems
Du Melle F |
| 12 - 18 |
Fuel cells - a 21st century power system
Joon K |
| 19 - 25 |
Fuel cells - a new contributor to stationary power
Dufour AU |
| 26 - 35 |
The US Department of Energy - investing in clean transport
Chalk SG, Milliken J, Miller JF, Venkateswaran SR |
| 36 - 38 |
Fuel cells for vehicle applications in cars - bringing the future closer
Panik F |
| 41 - 44 |
Utilities and their investments in fuel cells
Sjunnesson L |
| 45 - 50 |
Fuel cells for hospitals
Damberger TA |
| 51 - 57 |
Long-term commitment of Japanese gas utilities to PAFCs and SOFCs
Matsumoto K, Kasahara K |
| 61 - 64 |
Fuel cell stationary power business development
Weiner SA |
| 65 - 70 |
A consortium approach to commercialized Westinghouse solid oxide fuel cell technology
Casanova A |
| 71 - 74 |
Investment in volume building: the 'virtuous cycle' in PAFC
Whitaker R |
| 75 - 79 |
A new approach to fuel cell investment strategy
Hassmann K, Rippel R |
| 80 - 85 |
Cost reductions of fuel cells for transport applications: fuel processing options
Teagan WP, Bentley J, Barnett B |
| 89 - 94 |
Development of a 1000 kW class MCFC pilot plant in Japan
Yasue H, Kato H, Takasu K |
| 95 - 99 |
The 2 MW Santa Clara Project
Eichenberger PH |
| 100 - 104 |
Utility experience with a 250-kW molten carbonate fuel cell cogeneration power plant at NAS Miramar, San Diego
Figueroa RA, Otahal J |
| 107 - 110 |
Intermediate temperature SOFC - a promise for the 21st century
Huijsmans JPP, van Berkel FPF, Christie GM |
| 111 - 122 |
Advances in catalysts for internal reforming in high temperature fuel cells
Dicks AL |
| 123 - 128 |
On-board hydrogen generation for transport applications: the HotSpot (TM) methanol processor
Edwards N, Ellis SR, Frost JC, Golunski SE, van Keulen ANJ, Lindewald NG, Reinkingh JG |
| 131 - 137 |
Reducing the manufacturing cost of tubular SOFC technology
George RA, Bessette NF |
| 138 - 143 |
Stack networking for system optimisation: an engineering approach
Fellows R, Sloetjes EW, Ottervanger R |
| 144 - 149 |
PEFCs for naval ships and submarines: many tasks, one solution
Sattler G |
| 150 - 155 |
Advanced PEFC development for fuel cell powered vehicles
Kawatsu S |
| 159 - 163 |
Particle growth behaviour of LiAlO2 containing ZrO2 in Li/Na carbonate electrolytes
Yasumoto E, Hatoh K, Gamo T |
| 164 - 168 |
Conductivity of BaPrO3 based perovskite oxides
Fukui T, Ohara S, Kawatsu S |
| 169 - 173 |
Performance of a direct methanol polymer electrolyte fuel cell
Jung DH, Lee CH, Kim CS, Shin DR |
| 174 - 178 |
Performance of a polymer electrolyte membrane fuel cell with thin film catalyst electrodes
Chun YG, Kim CS, Peck DH, Shin DR |
| 179 - 184 |
Simulation of a 250 kW diesel fuel processor PEM fuel cell system
Amphlett JC, Mann RF, Peppley BA, Roberge PR, Rodrigues A, Salvador JP |
| 185 - 189 |
Performance of a solid oxide fuel cell fabricated by co-firing
Ohrui H, Matsushima T, Hirai T |
| 190 - 194 |
New opportunities for fuel cells in the restructured power systems of the United States
Tam KS |
| 195 - 198 |
Electrical and microstructural characteristics of materials in the LaMnO3 +/-delta-LaAlO3-SrMnO3-delta system
Kuscer D, Hrovat M, Holc J, Bernik S, Kolar D |
| 199 - 207 |
Compact hydrogen production systems for solid polymer fuel cells
Ledjeff-Hey K, Formanski V, Kalk T, Roes J |
| 208 - 214 |
Hydrogen generator, via catalytic partial oxidation of methane for fuel cells
Recupero V, Pino L, Di Leonardo R, Lagana M, Maggio G |
| 215 - 217 |
Development of second generation direct internal reforming molten carbonate fuel cell stack technology for cogeneration application
Kraaij GJ, Rietveld G, Makkus RC, Huijsmans JPP |
| 218 - 222 |
Dynamic model of solid polymer fuel cell water management
van Bussel HPLH, Koene FGH, Mallant RKAM |
| 223 - 225 |
The 'advanced DIR-MCFC development' project, an overview
Kortbeek PJ, Ottervanger R |
| 226 - 230 |
Usage of biomass gas for fuel cells by the SIR process
Hacker V, Faleschini G, Fuchs H, Fankhauser R, Simader G, Ghaemi M, Spreitz B, Friedrich K |
| 231 - 238 |
Estimation of the lifetime of Al/Ni-plated material for wet-seal area in molten carbonate fuel cells
Fujimoto N, Yamamoto M, Nagoya T |
| 239 - 243 |
Solubility and deposition of LiCoO2 in a molten carbonate
Fukui T, Okawa H, Tsunooka T |
| 244 - 248 |
Design and manufacturing of a tabular solid oxide fuel cell combustion system
Winkler W, Kruger J |
| 249 - 255 |
Performance and endurance of a PEMFC operated with synthetic reformate fuel feed
Sishtla C, Koncar G, Platon R, Gamburzev S, Appleby AJ, Velev OA |
| 256 - 263 |
Fuel cell adventures. Dynamics of a technological community in a quasi-market of technological options
Schaeffer GJ, Uyterlinde MA |
| 264 - 267 |
Energy saving system using by-product hydrogen
Miki H, Yamarnoto H, Ganke T, Satake I, Nogi T, Yoshioka H |
| 268 - 270 |
A small solid oxide fuel cell demonstrator for microelectronic applications
Kendall K, Palin M |
| 271 - 274 |
A 1000-cell SOFC reactor for domestic cogeneration
Alston T, Kendall K, Palin M, Prica M, Windibank P |
| 275 - 277 |
Biogas powering a small tubular solid oxide fuel cell
Staniforth J, Kendall K |
| 278 - 280 |
A dynamic simulator for a 250 kW class ER-MCFC system
Kortbeek PJ, de Ruijter JAF, van der Laag PC, Hagg F, Barten H |
| 281 - 287 |
A novel configuration for direct internal reforming stacks
Fellows R |
| 288 - 293 |
Compact methanol reformer test for fuel-cell powered light-duty vehicles
Emonts B, Hansen JB, Jorgensen SL, Hohlein B, Peters R |
| 294 - 301 |
Analysis of energy and water management in terms of fuel-cell electricity generation
Menzer R, Hohlein B |
| 302 - 305 |
Operation of anode-supported thin electrolyte film solid oxide fuel cells at 800 degrees C and below
de Haart LGJ, Mayer K, Stimming U, Vinke IC |
| 306 - 314 |
Optimization of a 200 kW SOFC cogeneration power plant. Part II: variation of the flowsheet
Riensche E, Meusinger J, Stimming U, Unverzagt G |
| 315 - 320 |
Reforming of natural gas in solid oxide fuel cell systems
Meusinger J, Riensche E, Stimming U |
| 321 - 327 |
A fuel cell balance of plant test facility
Dicks AL, Martin PA |
| 328 - 336 |
Numerical analyses of the internal conditions of a molten carbonate fuel cell stack: comparison of stack performances for various gas flow types
Yoshiba F, Ono N, Izaki Y, Watanabe T, Abe T |
| 337 - 347 |
Effect of operating pressure on the system efficiency of a methane-fuelled solid polymer fuel cell power source
Virji MBV, Adcock PL, Mitchell PJ, Cooley G |
| 348 - 353 |
Environmental benefits of transport and stationary fuel cells
Hart D, Hormandinger G |
| 354 - 360 |
Planar solid oxide fuel cell integrated system technology development
Elangovan S, Hartvigsen J, Khandkar A, Privette RM, Kneidel KE, Perna MA, Rowley DR |
| 361 - 369 |
The development of intermediate-temperature solid oxide fuel cells for the next millennium
Choy K, Bai W, Clarojrochkul S, Steele BCH |
