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Proceedings Papers

Proceedings Volume Cover
ASME 2003 1st International Conference on Fuel Cell Science, Engineering and Technology
April 21–23, 2003
Rochester, New York, USA
Conference Sponsors:
  • Electronic and Photonic Packaging Division
ISBN:
0-7918-3668-1
In This Volume
1st International Fuel Cell Science, Engineering and Technology Conference
Design Considerations in the Development of Fuel Cell Power Modules
P. Rivard, J. Cargnelli, T. Simpson, R. DelCore, S. Burany, R. Bazzarella
FUELCELL 2003; 1-8https://doi.org/10.1115/FUELCELL2003-1695
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Topics: Design , Fuel cells
Fuel Cells: What’s Up Next?
Kas Hemmes
FUELCELL 2003; 9-19https://doi.org/10.1115/FUELCELL2003-1696
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Topics: Fuel cells , Fuels , Chemical processes , Fuel cell technology , Molten carbonate fuel cells , Carbon , Chemical energy , Direct carbon fuel cells , Electricity (Physics) , Heat
Overview of Direct Carbonate Fuel Cell Technology and Products Development
Hossein Ghezel-Ayagh, Anthony J. Leo, Hans Maru, Mohammad Farooque
FUELCELL 2003; 21-32https://doi.org/10.1115/FUELCELL2003-1697
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Topics: Coal , Cycles , Electricity (Physics) , Energy generation , Fuel cell power plants , Fuel cell technology , Fuel cells , Fuel gasification , Fuels , Gas turbines
Development of High Efficiency MCFC/GT Hybrid Power Generation System
T. Watanabe, Y. Izaki, Y. Mugikura, M. Yoshikawa, H. Morita, M. Kawase, F. Yoshiba, K. Asano
FUELCELL 2003; 33-40https://doi.org/10.1115/FUELCELL2003-1698
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Topics: Hybrid power systems , Molten carbonate fuel cells , Electrolytes , Power stations , Cycles , Design , Electricity (Physics) , Engineering simulation , Gas turbines , Pressure
Providing and Processing Fuel
Andrew L. Dicks
FUELCELL 2003; 41-54https://doi.org/10.1115/FUELCELL2003-1699
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Topics: Fuels , Hydrogen , Fuel cells , Design , Natural gas , Transportation systems , Biofuel , Chemistry , Coal , Fossil fuels
Fuel Processing for Mobile Fuel Cell Systems
Michael Krumpelt, Theodore R. Krause, John P. Kopasz
FUELCELL 2003; 55-59https://doi.org/10.1115/FUELCELL2003-1700
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Topics: Fuel cells , Fuel processing , Hydrogen , Fuels , Automobiles , Density , Electronics , Engines , Gasoline , Generators
A Review of Hydrogen Production Technologies
D. Yogi Goswami, Samantha T. Mirabal, Nitin Goel, H. A. Ingley
FUELCELL 2003; 61-74https://doi.org/10.1115/FUELCELL2003-1701
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Topics: Hydrogen production , Solar energy , Hydrogen , Economic analysis , Electrolysis , Fossil fuels , Water , Biomass , Cycles , Fuels
Perspectives on the Use of Molten Carbonate Fuel Cells with Renewable Energy Sources
Umberto Desideri
FUELCELL 2003; 75-81https://doi.org/10.1115/FUELCELL2003-1702
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Topics: Molten carbonate fuel cells , Renewable energy sources , Fuels , Anodes , Carbon , Fuel cells , Biogas , Biomass , Carbon dioxide , Damage
Advanced Hydrogen Fuel Systems for Fuel Cell Vehicles
Andris R. Abele
FUELCELL 2003; 83-87https://doi.org/10.1115/FUELCELL2003-1703
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Topics: Fuel cell vehicles , Hydrogen fuels , Hydrogen , Hydrogen storage , Storage , Fuel cells , Vehicles , Safety , Automobiles , Buses
Mechanical Integrity Issues of Fuel Cells
Rowland P. Travis
FUELCELL 2003; 89-94https://doi.org/10.1115/FUELCELL2003-1704
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Topics: Fuel cells , Temperature , Creep , Residual stresses , Stress , Cooling , Dynamics (Mechanics) , Fluids , High temperature , Operating temperature
Temperature Measurement Technologies and Their Application in the Research of Fuel Cells
Mao Hai Wang, Hang Guo, Chong Fang Ma, Fang Ye, Jian Yu, Xuan Liu, Yan Wang, Chao Yang Wang
FUELCELL 2003; 95-100https://doi.org/10.1115/FUELCELL2003-1705
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Topics: Fuel cells , Hydrogen , Imaging , Proton exchange membrane fuel cells , Temperature measurement
Development of a Comprehensive Simulation Platform to Investigate System Interactions Among Solid-Oxide Fuel Cell, Power-Conditioning Systems, and Application Loads
S. K. Mazumder, R. Burra, K. Acharya, M. R. von Spakovsky, D. Nelson, D. Rancruel, C. Haynes, R. Williams
FUELCELL 2003; 101-109https://doi.org/10.1115/FUELCELL2003-1706
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Topics: Power conditioning , Simulation , Solid oxide fuel cells , Stress , Design methodology , Electrochemistry , Electrodes , Finite element analysis , Modeling , Reliability
Effect of Material and Manufacturing Variations on Membrane Electrode Assembly Pressure Distribution
Andreas Vlahinos, Kenneth Kelly, Jim D’Aleo, Jim Stathopoulos
FUELCELL 2003; 111-120https://doi.org/10.1115/FUELCELL2003-1707
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Topics: Manufacturing , Membrane electrode assemblies , Pressure , Design , Proton exchange membranes , Elastic moduli , Electrical conductivity , Finite element analysis , Flow (Dynamics) , Fuel cells
Fuel Cell Applications of Single Wall Carbon Nanotubes
R. P. Raffaelle, B. Landi, T. Gennett, R. S. Morris, B. Dixon, P. Lamarre
FUELCELL 2003; 121-128https://doi.org/10.1115/FUELCELL2003-1708
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Topics: Fuel cell applications , Single-walled carbon nanotubes , Fuel cells , Single-walled nanotubes , Proton exchange membranes , Electrical conductivity , Polymers , Thermal conductivity , Active materials , Anodes
Fabrication and Performance Evaluation of Miniaturized Proton Exchange Membrane (PEM) Fuel Cells
Tao Zhang, Pei-Wen Li, Qing-Ming Wang, Laura Schaefer, Minking K. Chyu
FUELCELL 2003; 129-136https://doi.org/10.1115/FUELCELL2003-1709
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Topics: Fuel cells , Manufacturing , Performance evaluation , Proton exchange membranes , Brass (Metal) , Current density , Mass transfer , Membranes , Natural convection , Oxygen
A Novel Design and Microfabrication for a Micro PEMFC
Shou-Shing Hsieh, Jenn-Kun Kuo, Ching-Fang Hwang, Hwang-Hsiu Tsai
FUELCELL 2003; 137-142https://doi.org/10.1115/FUELCELL2003-1710
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Topics: Design , Microfabrication , Proton exchange membrane fuel cells , Fuel cells , Proton exchange membranes , Air flow , Flow (Dynamics) , Manufacturing , Polarization (Electricity) , Polarization (Light)
Investigation of Transport Phenomena in Micro Flow Channels for Miniature Fuel Cells
S. W. Cha, S. J. Lee, Y. I. Park, F. B. Prinz
FUELCELL 2003; 143-148https://doi.org/10.1115/FUELCELL2003-1711
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Topics: Flow (Dynamics) , Fuel cells , Transport phenomena , Microchannels , Power density , Design , Engineering prototypes , Gas flow , Metals , Modeling
The Role of Fuel Cells for Consumer Electronic Products and Toys
B. Banazwski, R. K. Shah
FUELCELL 2003; 149-155https://doi.org/10.1115/FUELCELL2003-1712
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Topics: Electronic products , Fuel cells , Direct methanol fuel cells , Proton exchange membrane fuel cells , Density , Electronics , Fuel cell technology , Fuels , Laptop computers , Packaging
Modeling of Reformers for Fuel Cell Applications
William A. Rogers, Shaoping Shi, David A. Berry, Todd H. Gardner, Dushyant Shekhawat
FUELCELL 2003; 157-165https://doi.org/10.1115/FUELCELL2003-1713
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Topics: Boiling , Carbon , Chemical reactions , Chemistry , Computational fluid dynamics , Diesel , Eddies (Fluid dynamics) , Energy dissipation , Engineering simulation , Evaporation
Development of Natural Gas Reformer in ITRI
C. H. Lee, C. H. Huang, C. T. Lin, Y. C. Liu, R. J. Shyu
FUELCELL 2003; 167-170https://doi.org/10.1115/FUELCELL2003-1714
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Topics: Natural gas , Catalysts , Electrolytes , Fuel cells , Hydrogen , Polymers , Water , Flow (Dynamics) , High temperature , Low temperature
Structured Catalysts for Autothermal Reforming of Hydrocarbon Fuels
J.-M. Bae, S. Ahmed, R. Kumar, E. Doss
FUELCELL 2003; 171-174https://doi.org/10.1115/FUELCELL2003-1715
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Topics: Catalysts , Fuels , Microchannels , Diffusion (Physics) , Electricity (Physics) , Fuel cells , Fuel processing , Gasoline , Honeycomb structures , Natural gas
GlidArc-Assisted Production of Synthesis Gas Through Propane Partial Oxidation
Albin Czernichowski, Mieczyslaw Czernichowski, Krystyna Wesolowska
FUELCELL 2003; 175-179https://doi.org/10.1115/FUELCELL2003-1716
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Topics: Oxidation , Syngas , Catalysts , Fuel cells , Sulfur , Atmospheric pressure , Electricity (Physics) , Plasmas (Ionized gases) , Recycling , Solid oxide fuel cells
GlidArc-Assisted Production of Synthesis Gas Through Partial Oxidation of Natural Gas
Albin Czernichowski, Krystyna Wesolowska
FUELCELL 2003; 181-185https://doi.org/10.1115/FUELCELL2003-1717
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Topics: Natural gas , Oxidation , Syngas , Plasmas (Ionized gases) , Atmospheric pressure , Catalysts , Electricity (Physics) , Fuel cells , Recycling , Soot
Parametric Study of Transport Phenomena in PEM Fuel Cells Using a 3D Computational Model
T. Berning, N. Djilali
FUELCELL 2003; 187-194https://doi.org/10.1115/FUELCELL2003-1718
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Topics: Proton exchange membrane fuel cells , Transport phenomena , Contact resistance , Design , Diffusion (Physics) , Fuel cells , Modeling , Optimization , Porosity , Pressure
3D Modeling of Polymer Electrolyte Membrane Fuel Cells
Sacheverel Eldrid, Mehrdad Shahnam, Michael T. Prinkey, Zhirui Dong
FUELCELL 2003; 195-202https://doi.org/10.1115/FUELCELL2003-1719
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Topics: Proton exchange membrane fuel cells , Three-dimensional modeling , Anodes , Diffusion (Physics) , Hydrogen , Catalysts , Fuel cells , Computational fluid dynamics , Electrochemical reactions , Electrons
A Simplified Three-Dimensional CFD Approach for PEMFC and DMFC Design
C. W. Hong, C. H. Cheng, K. Fei
FUELCELL 2003; 203-208https://doi.org/10.1115/FUELCELL2003-1720
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Topics: Computational fluid dynamics , Design , Direct methanol fuel cells , Proton exchange membrane fuel cells , Fuel cells , Flow (Dynamics) , Transport phenomena , Algorithms , Anodes , Computation
Gas Flow and Heat Transfer Analysis for an Anode Duct in Reduced Temperature SOFCs
Jinliang Yuan, Masoud Rokni, Bengt Sunde´n
FUELCELL 2003; 209-216https://doi.org/10.1115/FUELCELL2003-1721
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Topics: Anodes , Ducts , Gas flow , Heat transfer , Solid oxide fuel cells , Temperature , Electrochemical reactions , Fuel cells , Boundary-value problems , Composite materials
Influence of Radiative Heat Transfer on Variation of Cell Voltage Within a Stack
A. C. Burt, I. B. Celik, R. S. Gemmen, A. V. Smirnov
FUELCELL 2003; 217-223https://doi.org/10.1115/FUELCELL2003-1722
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Topics: Radiative heat transfer , Flow (Dynamics) , Electrodes , Heat transfer , Temperature , Electrolytes , Engineering simulation , Flux (Metallurgy) , Fuel cells , Geometry
Fuel Cells vs. Competing Technologies
Supramanian Srinivasan, Lakshmi Krishnan, Andrew B. Bocarsly, Kan-Lin Hsueh, Chiou-Chu Lai, Alex Peng
FUELCELL 2003; 225-232https://doi.org/10.1115/FUELCELL2003-1723
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Topics: Fuel cells , Direct methanol fuel cells , Proton exchange membrane fuel cells , Solid oxide fuel cells , Carbon , Energy conversion , Heating , Military systems , Molten carbonate fuel cells , Phosphoric acid fuel cells
Performance Modeling of PEM Fuel Cell Operated on Reformate
Tianhong Zhou, Hongtan Liu
FUELCELL 2003; 233-240https://doi.org/10.1115/FUELCELL2003-1724
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Topics: Modeling , Proton exchange membrane fuel cells , Anodes , Hydrogen , Design , Diffusers , Oxidation , Platinum , Equations , Flow (Dynamics)
Study on Morphological Properties and Mass Transport Parameters of ORR in Recast Ion-Exchange Polymer Electrolyte Membranes
Kunchan Lee, Akimitsu Ishihara, Shigenori Mitsushima, Nobuyuki Kamiya, Ken-Ichiro Ota
FUELCELL 2003; 241-243https://doi.org/10.1115/FUELCELL2003-1725
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Topics: Ion exchange , Proton exchange membranes , Temperature , Diffusion (Physics) , Electrolytes , Membranes , Oxygen , Water , Heat treating (Metalworking) , Polymers
Development of PEMFC Systems for Space Power Applications
Kerri McCurdy, Arturo Vasquez, Karla Bradley
FUELCELL 2003; 245-251https://doi.org/10.1115/FUELCELL2003-1726
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Topics: Proton exchange membrane fuel cells , Fuel cells , Oxygen , Water , Ejectors , Fluids , NASA , Density , Design , Energy storage
PEM Fuel Cell Bipolar Plate Reliability and Material Selection
Michael J. Ajersch, Michael W. Fowler, Kunal Karan, Brant A. Peppley
FUELCELL 2003; 253-260https://doi.org/10.1115/FUELCELL2003-1727
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Topics: Proton exchange membrane fuel cells , Reliability , Fuel cells , Design , Durability , Plates (structures) , Cycles , Failure mechanisms , Fuels , Manufacturing
Membraneless Fuel Cell Based on Laminar Flow
Eric R. Choban, Piotr Waszczuk, Larry J. Markoski, Andrzej Wieckowski, Paul J. A. Kenis
FUELCELL 2003; 261-265https://doi.org/10.1115/FUELCELL2003-1728
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Topics: Fuel cells , Laminar flow , Flow (Dynamics) , Fuels , Proton exchange membranes , Reynolds number , Diffusion (Physics) , Electrodes , Fluid dynamics , Fuel cell technology
A Silicon Microfabricated Direct Formic Acid Fuel Cell
J. Yeom, G. Z. Mozsgai, A. Asthana, B. R. Flachsbart, P. Waszczuk, E. R. Choban, P. J. A. Kenis, M. A. Shannon
FUELCELL 2003; 267-272https://doi.org/10.1115/FUELCELL2003-1729
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Topics: Fuel cells , Silicon , Catalysts , Electrodes , Fuel cell applications , Membranes , Power density , Proton exchange membrane fuel cells , Water
Oxygen: Aluminum Fuel Cells and Most Practical Fields of Their Applications
A. A. Farmakovskaya, V. V. Popov, S. D. Sevruk, B. I. Tumanov, V. G. Udaltsov
FUELCELL 2003; 273-277https://doi.org/10.1115/FUELCELL2003-1730
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Topics: Aluminum , Fuel cells , Oxygen , Anodes , Power stations , Storage , Alloys , Electrolytes , Emergencies , Hydrogen
Fabrication of Micro-Actuated Galvanic Cells as Power on Demand for Lab on a Chip Applications by Means of Novel PCB/MEMS Technology
A. M. Cardenas-Valencia, D. P. Fries, G. Steimle, H. Broadbent, L. C. Langebrake, R. F. Benson
FUELCELL 2003; 279-286https://doi.org/10.1115/FUELCELL2003-1731
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Topics: Actuators , Aluminum , Batteries , Circuits , Construction , Copper , Industrial research , Liquid crystalline polymers , Manufacturing , Metals
Fabrication of Miniature Silicon Wafer Fuel Cells Using Micro Fabrication Technologies
Jingrong Yu, Ping Cheng, Zhiqi Ma, Baolian Yi
FUELCELL 2003; 287-291https://doi.org/10.1115/FUELCELL2003-1732
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Topics: Fuel cells , Manufacturing , Microfabrication , Semiconductor wafers , Fuels , Membranes , Silicon , Water , Anodes , Electrolytes
Some Aspects of Mass Transfer Within the Passages of Fuel Cells
S. B. Beale
FUELCELL 2003; 293-299https://doi.org/10.1115/FUELCELL2003-1733
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Topics: Fuel cells , Mass transfer , Heat , Ducts , Electrical conductance , Scalars
Exergy Analysis of Polymer Electrolyte Fuel Cell Systems Using Methanol
Akimitsu Ishihara, Shigenori Mitsushima, Nobuyuki Kamiya, Ken-Ichiro Ota
FUELCELL 2003; 301-306https://doi.org/10.1115/FUELCELL2003-1734
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Topics: Electrolytes , Exergy analysis , Fuel cells , Methanol , Polymers , Exergy , Direct methanol fuel cells , Enthalpy , Steam reforming , Current density
Thermodynamic Modeling and Performance Analysis of a Power Generation System Based on the Solid Oxide Fuel Cell
Bong-Hyang Bae, Jeong L. Sohn, Sung Tack Ro
FUELCELL 2003; 307-314https://doi.org/10.1115/FUELCELL2003-1735
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Topics: Energy / power systems , Modeling , Solid oxide fuel cells , Exhaust systems , Steam , Fuels , High pressure (Physics) , Hydrogen , Methane , Natural gas
Analogies Between Fuel Cells and Heat Exchangers: From Phenomena to Design Principles
Comas Haynes, William Rooker, Vaughn Melbourne, Jeffery Jones
FUELCELL 2003; 315-332https://doi.org/10.1115/FUELCELL2003-1736
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Topics: Design , Fuel cells , Heat exchangers , Electrodes , Bridges (Structures) , Electric potential , Engineering design processes , Engineering simulation , Fins , Heat
An Analysis of Water Management for a PEM Fuel Cell System in Automotive Drive Cycles
Kristina Haraldsson, Tony Markel, Keith Wipke
FUELCELL 2003; 333-338https://doi.org/10.1115/FUELCELL2003-1737
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Topics: Cycles , Proton exchange membrane fuel cells , Water resource management , Fuel cells , Vehicles , Water , Condensers (steam plant) , Proton exchange membranes , Automotive design , Design
Simulation of a 25 kW Steam-Methanol Fuel Processor/PEM Fuel Cell System
I. R. Wheeldon, J. C. Amphlett, M. Fowler, M. Hooper, R. F. Mann, B. A. Peppley, C. P. Thurgood
FUELCELL 2003; 339-345https://doi.org/10.1115/FUELCELL2003-1738
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Topics: Fuels , Methanol , Proton exchange membrane fuel cells , Simulation , Steam , Hydrogen , Membranes , Pressure , Carbon , System efficiency
State of the Art About the Effects of Impurities on MCFCs and Pointing Out of Additional Research for Alternative Fuel Utilization
U. Desideri, P. Lunghi, R. Burzacca
FUELCELL 2003; 347-353https://doi.org/10.1115/FUELCELL2003-1739
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Topics: Fuels , Molten carbonate fuel cells , Fuel cells , Gases , Energy generation , Sulfur , Anodes , Carbon , Coal , Design
Gasification and Fuel Cell Integration With Bottoming Turbine Cycle: Performances of a Hybrid Plant for Electricity Production
P. Lunghi, R. Burzacca
FUELCELL 2003; 355-362https://doi.org/10.1115/FUELCELL2003-1740
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Topics: Cycles , Fuel cells , Fuel gasification , Turbines , Energy generation , Biomass , Fuels , Carbon , Combustion , Compression
Process Integration and Optimization of Molten Carbonate Fuel Cell System
Harmanjeet Shihn, Ramesh K. Shah
FUELCELL 2003; 363-371https://doi.org/10.1115/FUELCELL2003-1741
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Topics: Molten carbonate fuel cells , Optimization , Fuel cells , Combined cycles , Steam turbines , Electric power generation , Heat exchangers , Cycles , Natural gas , Steady state
An Investigation of DIR-MCFC Based Cooling, Heating and Power System
Indraneel Samanta, Ramesh K. Shah, Ali Ogut
FUELCELL 2003; 373-379https://doi.org/10.1115/FUELCELL2003-1742
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Topics: Cooling , Heating , Molten carbonate fuel cells , Power systems (Machinery) , Combined heat and power , Absorption , Fuel cells , Fuels , Heat , Hot water
Analysis and Optimization of a Hybrid MCFC-Steam Turbine Plant
P. Lunghi, R. Bove
FUELCELL 2003; 381-384https://doi.org/10.1115/FUELCELL2003-1743
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Topics: Molten carbonate fuel cells , Optimization , Steam , Turbines , Cycles , Fuel cells , Exhaust systems , Gas turbines , Steam turbines , Temperature
Assessing the Impact of Inverter Current-Ripple on SOFC Performance
Randall S. Gemmen, Parviz Famouri, Christopher Johnson
FUELCELL 2003; 385-393https://doi.org/10.1115/FUELCELL2003-1744
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Topics: Solid oxide fuel cells , Fuel cells , Electrodes , Stress , Boundary-value problems , Dynamics (Mechanics) , Electrolytes , Steady state , Transients (Dynamics)
Innovative Thermal Management of Fuel Cell Power Electronics
Kenneth Kelly, Andreas Vlahinos, Pablo Rodriguez, Desikan Bharathan
FUELCELL 2003; 395-401https://doi.org/10.1115/FUELCELL2003-1745
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Topics: Electronics , Fuel cells , Thermal management , Design , Computational fluid dynamics , Modeling , Aluminum extrusions , Bone , Computer-aided design , Convection
Investigation of a Novel Reciprocating Compression Reformer for Use in Solid Oxide Fuel Cell Systems
Anthony N. Zinn, Todd H. Gardner, David A. Berry, Robert E. James, Dushyant Shekhawat
FUELCELL 2003; 403-409https://doi.org/10.1115/FUELCELL2003-1746
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Topics: Compression , Solid oxide fuel cells , Fuels , Fuel cells , Carbon , Equilibrium (Physics) , System efficiency , Heat , Modeling , Natural gas
The Role of High Performance Foil Bearings in Advanced, Oil-Free, High-Speed Motor Driven Compressors
James F. Walton, II, Michael J. Tomaszewski, H. Heshmat
FUELCELL 2003; 411-417https://doi.org/10.1115/FUELCELL2003-1747
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Topics: Compressors , Engines , Foil bearings , Motors , Bearings , Maintenance , Rotors , Torque , Damping , Design
“Floating Scroll” Technology for Fuel Cell Air Management System
Sam Ni
FUELCELL 2003; 419-423https://doi.org/10.1115/FUELCELL2003-1748
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Topics: Fuel cells , Compressors , Centrifugal force , Compression , Coolants , Cooling , Lubricants , Lubrication , Pressure , Proton exchange membrane fuel cells
Systems Analysis of Diesel Based Fuel Cells for Auxiliary Power Units
David A. Berry, Robert James, Todd H. Gardner, Dushyant Shekhawat
FUELCELL 2003; 425-431https://doi.org/10.1115/FUELCELL2003-1749
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Topics: Diesel , Fuel cells , Systems analysis , Fuels , Carbon , Carbon dioxide , Catalysts , Combustion chambers , Fuel cell technology , Heat
Regulations Governing Transportation of Portable Fuel Cell Devices and Systems in Aircrafts
Etim U. Ubong, K. J. Berry
FUELCELL 2003; 433-441https://doi.org/10.1115/FUELCELL2003-1750
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Topics: Aircraft , Fuel cells , Regulations , Transportation systems , Hazardous substances , Fuels , Buses , Fuel storage , Hydrogen , Laptop computers
Circumventing the Challenges of Fuel Cell Powered Automobiles
James E. Gover
FUELCELL 2003; 443-448https://doi.org/10.1115/FUELCELL2003-1751
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Topics: Automobiles , Fuel cells , Vehicles , Electricity (Physics) , Public policy , Combustion , Design , Energy consumption , Engines , Fuel cell applications
An Engineering System for Automated Design and Optimization of Fuel Cell Powered Vehicles
Keith Wipke, Prashant Chintawar, Rick Weller, Gordon Willis
FUELCELL 2003; 449-454https://doi.org/10.1115/FUELCELL2003-1752
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Topics: Design , Engineering systems and industry applications , Fuel cells , Optimization , Vehicles , Fuels , Engineering prototypes , Automobiles , Computer-aided engineering , Databases
An Evaluation of Cooling Systems for PEMFCs in Transport Applications
K. M. Oseen-Senda, J. Pauchet, M. Feidt, O. Lottin
FUELCELL 2003; 455-462https://doi.org/10.1115/FUELCELL2003-1753
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Topics: Cooling systems , Proton exchange membrane fuel cells , Fuel cells , Automobiles , Condensation , Density , Electrolytes , Engines , Freezing , Heat
Modeling of Two-Phase Flow in a Cathode Duct of PEM Fuel Cells
Jinliang Yuan, Masoud Rokni, Bengt Sunde´n
FUELCELL 2003; 463-470https://doi.org/10.1115/FUELCELL2003-1754
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Topics: Ducts , Modeling , Proton exchange membrane fuel cells , Two-phase flow , Heat , Water , Pressure , Temperature , Condensation , Convection
Heat and Mass Transfer and Two Phase Flow in Hydrogen Proton Exchange Membrane Fuel Cells and Direct Methanol Fuel Cells
Hang Guo, Chong Fang Ma, Mao Hai Wang, Jian Yu, Xuan Liu, Fang Ye, Chao Yang Wang
FUELCELL 2003; 471-476https://doi.org/10.1115/FUELCELL2003-1755
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Topics: Direct methanol fuel cells , Heat , Hydrogen , Mass transfer , Microchannels , Proton exchange membrane fuel cells , Two-phase flow
Water and Thermal Balance in PEM Fuel Cells
Michael G. Izenson, Roger W. Hill
FUELCELL 2003; 477-486https://doi.org/10.1115/FUELCELL2003-1756
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Topics: Proton exchange membrane fuel cells , Water , Proton exchange membranes , Thermal management , Cooling , Cooling systems , Density , Design , Direct methanol fuel cells , Evaporation
The Influence of Water and Thermal Conditions on the Performance of PEM Fuel Cell
Y. Y. Yan, L. Y. Sung, H. S. Chu, K. C. Tsay, F. S. Tsu, F. Chen, R. J. Shyu
FUELCELL 2003; 487-492https://doi.org/10.1115/FUELCELL2003-1757
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Topics: Proton exchange membrane fuel cells , Water , Catalysts , Floods , Fuel cells , Anodes , Electrochemical reactions , Flow (Dynamics) , Heat , Hydrogen
System Integration for PEM Fuel Cell With Water and Heat Recovered
Y. Y. Yan, G. S. Chen, S. C. Chiang, H. S. Chu, F. S. Tsu, K. C. Tsay, F. Chen, R. J. Shyu
FUELCELL 2003; 493-497https://doi.org/10.1115/FUELCELL2003-1758
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Topics: Heat , Proton exchange membrane fuel cells , Water , Fuel cells , Energy / power systems , Hot water , Proton exchange membranes , Electrical efficiency , Energy efficiency , Fittings
Metal-Supported Solid Oxide Fuel Cells for Operation at Temperatures of 500–650°C
A. Atkinson, S. Baron, N. P. Brandon, A. Esquirol, J. A. Kilner, N. Oishi, R. Rudkin, B. C. H. Steele
FUELCELL 2003; 499-506https://doi.org/10.1115/FUELCELL2003-1759
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Topics: Metals , Solid oxide fuel cells , Temperature , Electrolytes , Anodes , Stainless steel , Thick films , Manufacturing , Membranes , Sintering
The Vision for Solid Oxide Fuel Cells: Development of a SOFC APU for the Transportation Industry
S. Mukerjee, C. De Minco
FUELCELL 2003; 507-509https://doi.org/10.1115/FUELCELL2003-1760
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Topics: Solid oxide fuel cells , Transportation systems , Air conditioning , Engines , Stress
Improved Multi-Functionality of Ni/YSZ Cermet Anode by Optimizing Fabrication Processes
H. Song, J.-H. Lee, J. Kim, S.-W. Kim, H.-W. Lee
FUELCELL 2003; 511-516https://doi.org/10.1115/FUELCELL2003-1761
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Topics: Anodes , Cermets , Manufacturing , Ceramics , Electrical conductivity , Performance evaluation , Permeability , Raw materials , Solid oxide fuel cells
Validation and Application of a CFD-Based Model for Solid Oxide Fuel Cells and Stacks
William A. Rogers, Randall S. Gemmen, Christopher Johnson, Michael Prinkey, Mehrdad Shahnam
FUELCELL 2003; 517-520https://doi.org/10.1115/FUELCELL2003-1762
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Topics: Computational fluid dynamics , Solid oxide fuel cells , Flow (Dynamics) , Fuel cells , Electrodes , Electrolytes , Anodes , Chemistry , Collaboration , Computer software
Development of a Comprehensive Numerical Model for Analyzing a Tubular-Type Indirect Internal Reforming SOFC
Takafumi Nishino, Hajime Komori, Hiroshi Iwai, Kenjiro Suzuki
FUELCELL 2003; 521-528https://doi.org/10.1115/FUELCELL2003-1763
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Topics: Computer simulation , Solid oxide fuel cells , Electric current , Energy generation , Overvoltage , Temperature , Catalysts , Circuits , Fuels , Gas flow
Techno-Economic Challenges for PEMFCs and DMFCs Entering Energy Sector
S. Srinivasan, R. Dillon, L. Krishnan, A. S. Arico, V. Antonucci, A. B. Bocarsly, W. J. Lee, K.-L. Hsueh, C.-C. Lai, A. Peng
FUELCELL 2003; 529-536https://doi.org/10.1115/FUELCELL2003-1764
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Topics: Direct methanol fuel cells , Proton exchange membrane fuel cells , Fuel cells , Membranes , Electrodes , Fuel cell technology , Industrial research , Manufacturing , Optimization , Protons
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