BibTex RIS Cite

CONTROL-ORIENTED MODELLING OF FUEL PROCESSING REACTORS IN FUEL CELL POWER SYSTEMS

Year 2005, Volume: 5 Issue: 1, 1279 - 1286, 28.12.2011

Abstract

  

References

  • www.ballard.com. www.fuelcells.org. J.C. Amphlett, R.M Baumert, R.F. Mann, B.A. Peppley, P.R. Roberge, and A. Rodrigues, “Parametric modelling of the performance of a 5- kw proton exchange membrane fuel cell stack”, Journal of Power Sources 49 349-356,1994.
  • M. Arcak, H. Gorgun, L.M. Pedersen, and S. Varigonda, “An adaptive observer design for fuel cell hydrogen estimation”, Proceedings of the American Control Conference (Denver, Colorado), pp. 2037-2042, 2003.
  • “A nonlinear observer design for fuel cell hydrogen estimation”, IEEE Transactions on Control System Technology 12, no. 1, pp. 101- , 2004.
  • J.J. Baschuk and X. Li, “Modelling of polymer electrolyte membrane fuel cells with variable degrees of water flooding”, Journal of Power Sources 86, pp. 181-196, 2000.
  • D.M. Bernardi and M.W. Verbrugge, “A mathematical model of the solid-polymer electrolyte fuel cell”, Journal of Electrochemical Society, 139, pp. 2477-2491, 1992.
  • L.J. M.J Blomen and M.N. Mugerwa, Fuel cells systems, Plenum Press, New York, 1993.
  • D. Boettner, G. Paganelli, Y. Guezennec, G. Rizzoni, and M. Moran, “Proton exchange membrane fuel cell system model for automotive vehicle simulation and control”, ASME Journal of Energy Resources Technology 124 pp.20-27, L. Carette, K.A. Friedrich, and U. Stimming, “Fuel cells - fundamentals and applications”, Fuel Cells Journal pp. 5-39,1 ,2001.
  • P. Costamagna and S. Srinivasan, “Quantum jumps in the PEMFC science and technology from the 1960s to the year 2000 - part i. fundamental scientificic aspects”, Journal of Power Sources 102 pp. 242-252, 2001.
  • _____, “Quantum jumps in the PEMFC science and technology from the 1960s to the year 2000 - part ii. engineering, technology development and application aspects”, Journal of Power Sources 102 pp. 253-269, 2001.
  • J. Eborn, L.M. Pedersen, C. Haugstetter, and S. Ghosh, “System level dynamic modeling of fuel cell power plants”, Proceedings of the American Control Conference (Denver, Colorado), pp. 2024-2029,2003.
  • T.F. Fuller and J. Newman, “Water and thermal management in solid-polymer- electrolyte fuel cells”, Journal of Electrochemical Society 140 pp. 1218-1225,
  • R.N. Gagnon, Fuel cell fuel control system, United States Patents 4, 098,960, 1978.
  • R.S. Glass, “Sensor needs and requirements for proton-exchange membrane fuel cell systems and direct-injection engines”, Lawrence Livermore National Laboratory, Applied Energy Technologies Program, 2000.
  • H. Gorgun, Nonlinear observer designs for fuel cell power systems, Ph.D. thesis, Rensselaer Polytechnic Institute, Troy, New York, 2003.
  • H. Gorgun, M. Arcak, S. Varigonda, and S.A. Bortof, “Nonlinear observer design for fuel processing reactors in fuel cell power systems”, Proceedings of the American Control Conference (Boston, Massachusetts), pp. 845- , 2004.
  • L. Guzzella, “Control oriented modeling of fuel cell based vehicles”, Presentation in NSF Workshop on The Integration of Modeling and Control for Automotive Systems, 1999.
  • D.Hart and G.Hormandinger, Environmental benefits of transport and stationary fuel cells”, Journal of Power Sources 71, pp. 348-353, 1998.
  • C. Haugstetter, Dynamic modeling and validation of a 75-kw PEM fuel cell stack, M.S. Thesis, Swiss Federal Institute of Technology, Parsen Inc., Fuel cells: A handbook, Elsevier, Business/Technology Books, 2000.
  • A.P Jardine, Hydrogen sensors for hydrogen fuel cell applications, 2000.
  • N. Keon, G. Simader, T.I. Oren, and J.C.T. Oliveria, “Modelling and simulation of the proton exchange membrane fuel cell: A state of the art review”, Proceedings of the SCSC'95 (Ottawa, Canada, pp. 659-664, 1995.
  • J. Larminie and A. Dicks, Fuel cell systems explained, John Wiley and Sons, Inc., 2000.
  • J.H. Lee and T.R. Lalk, “Modeling fuel cell stack systems”, Journal of Power Sources 73 pp. 241,1998.
  • D. Mays, W. Campbell, W. Fengler, and S. Rowe, “Control system development for automotive PEM fuel cell vehicles”, SAE Future Transportation Technology Conference and Exposition (Costa Mesa, CA), 2001.
  • K. Mitsuda and T. Murahashi, “Air and fuel starvation of phosphoric acid fuel cells: A study using a single cell with multi-reference electrodes”, Journal of Applied Electrochemistry ,pp. 524-530, 1991.
  • W.E. Mufford and D.G. Strasky, Power control system for a fuel cell powered vehicle, United States Patents 5,991,670, 1999.
  • T.V. Nguyen and R.E. White, “A water and heat management model for proton- exchange membrane fuel cells”, Journal of ElectrochemicalSociety 140, pp.2178-2186,1993.
  • J. Padulles, G.W Ault, C.A. Smith, and J.R. McDonald, “Fuel cell plant dynamic modeling for power systems simulation”, Proceedings of th Universities Power Engineering Conference pp. 21-25. 1999.
  • L. Pino, V. Recupero, S. Beninati, A.K. Shukla, M.S. Hegde, and P. Bera, “Catalytic partial-oxidation of methane on a ceria-supported platinum catalyst for application in fuel cell electric vehicles”, Applied Catalysis 225 no. 1, pp. 63-75,2003.
  • W. Powers and P. Nicastri, “Automotive vehicle control challenges in the 21st century”, Control Engineering Practice 8 pp. 605-618, J. Pukrushpan, Modelling and control of fuel cell systems and fuel processors, Ph.D. thesis, The University of Michigan, Michigan, J. Pukrushpan, A. Stefanopoulou, and H. Peng, “Modeling and control for PEM fuel cell stack system”, Proceedings of the American Control Conference (Anchorage, Alaska), pp. 3122, 2002.
  • J. Pukrushpan, A. Stefanopoulou, S. Varigonda, L.M. Pedersen, S. Ghosh, and H. Peng, “Control of natural gas catalytic partial oxidation for hydrogen generation in fuel cell applications”, Proceedings of the American Control Conference (Denver, Colorado), pp. 2036, 2003.
  • P. Rodatz, G. Paganelli, and L. Guzzella, “Optimization of fuel cell systems through variable pressure control”, Proceedings of the American Control Conference (Denver, Coloradopp).pp. 2043-2048, 2003.
  • A. Rowe and X. Li, “Mathematical modeling of proton exchange membrane fuel cells”, Journal of Power Sources 102), pp. 82- , 2001.
  • A. Sasaki, Reformer reaction control apparatus for fuel cell, United States Patents ,642,273, 1987.
  • C. Song, “Fuel processing for low- temperature and high-temperature fuel cells challenges, and opportunities for sustainable development in the 21st century”, Catalysis Today 77 pp. 17-49,2002
  • R.H. Song, C.S. Kim, and R.S. Dong, “Effects of flow rate and starvation of reactant gases on the performance of phosphoric acid fuel cells”, Journal of Power Sources 86, pp.289-293, T.E. Springer, M.S. Wilson, and S. Gottesfeld, “Modeling and experimental diagnostics in polymer electrolyte fuel cells”, Journal of Electrochemical Society 140), pp. 3526, 1993.
  • T.E. Springer, T.A. Zawodzinski, and S. Gottesfeld, “Polymer electrolyte fuel cell model”, Journal of Electrochemical Society 138 pp. 2334-2342,1991.
  • D.L. Walton, Fuel cell power plant control, United States Patents 5,009,967, 1991.
  • J. Zhu, D. Zhang, and K.D. King, “Reforming of ch4 thermodynamic and kinetic analyses”, Fuel 80 pp. 899-905,2001.
Year 2005, Volume: 5 Issue: 1, 1279 - 1286, 28.12.2011

Abstract

References

  • www.ballard.com. www.fuelcells.org. J.C. Amphlett, R.M Baumert, R.F. Mann, B.A. Peppley, P.R. Roberge, and A. Rodrigues, “Parametric modelling of the performance of a 5- kw proton exchange membrane fuel cell stack”, Journal of Power Sources 49 349-356,1994.
  • M. Arcak, H. Gorgun, L.M. Pedersen, and S. Varigonda, “An adaptive observer design for fuel cell hydrogen estimation”, Proceedings of the American Control Conference (Denver, Colorado), pp. 2037-2042, 2003.
  • “A nonlinear observer design for fuel cell hydrogen estimation”, IEEE Transactions on Control System Technology 12, no. 1, pp. 101- , 2004.
  • J.J. Baschuk and X. Li, “Modelling of polymer electrolyte membrane fuel cells with variable degrees of water flooding”, Journal of Power Sources 86, pp. 181-196, 2000.
  • D.M. Bernardi and M.W. Verbrugge, “A mathematical model of the solid-polymer electrolyte fuel cell”, Journal of Electrochemical Society, 139, pp. 2477-2491, 1992.
  • L.J. M.J Blomen and M.N. Mugerwa, Fuel cells systems, Plenum Press, New York, 1993.
  • D. Boettner, G. Paganelli, Y. Guezennec, G. Rizzoni, and M. Moran, “Proton exchange membrane fuel cell system model for automotive vehicle simulation and control”, ASME Journal of Energy Resources Technology 124 pp.20-27, L. Carette, K.A. Friedrich, and U. Stimming, “Fuel cells - fundamentals and applications”, Fuel Cells Journal pp. 5-39,1 ,2001.
  • P. Costamagna and S. Srinivasan, “Quantum jumps in the PEMFC science and technology from the 1960s to the year 2000 - part i. fundamental scientificic aspects”, Journal of Power Sources 102 pp. 242-252, 2001.
  • _____, “Quantum jumps in the PEMFC science and technology from the 1960s to the year 2000 - part ii. engineering, technology development and application aspects”, Journal of Power Sources 102 pp. 253-269, 2001.
  • J. Eborn, L.M. Pedersen, C. Haugstetter, and S. Ghosh, “System level dynamic modeling of fuel cell power plants”, Proceedings of the American Control Conference (Denver, Colorado), pp. 2024-2029,2003.
  • T.F. Fuller and J. Newman, “Water and thermal management in solid-polymer- electrolyte fuel cells”, Journal of Electrochemical Society 140 pp. 1218-1225,
  • R.N. Gagnon, Fuel cell fuel control system, United States Patents 4, 098,960, 1978.
  • R.S. Glass, “Sensor needs and requirements for proton-exchange membrane fuel cell systems and direct-injection engines”, Lawrence Livermore National Laboratory, Applied Energy Technologies Program, 2000.
  • H. Gorgun, Nonlinear observer designs for fuel cell power systems, Ph.D. thesis, Rensselaer Polytechnic Institute, Troy, New York, 2003.
  • H. Gorgun, M. Arcak, S. Varigonda, and S.A. Bortof, “Nonlinear observer design for fuel processing reactors in fuel cell power systems”, Proceedings of the American Control Conference (Boston, Massachusetts), pp. 845- , 2004.
  • L. Guzzella, “Control oriented modeling of fuel cell based vehicles”, Presentation in NSF Workshop on The Integration of Modeling and Control for Automotive Systems, 1999.
  • D.Hart and G.Hormandinger, Environmental benefits of transport and stationary fuel cells”, Journal of Power Sources 71, pp. 348-353, 1998.
  • C. Haugstetter, Dynamic modeling and validation of a 75-kw PEM fuel cell stack, M.S. Thesis, Swiss Federal Institute of Technology, Parsen Inc., Fuel cells: A handbook, Elsevier, Business/Technology Books, 2000.
  • A.P Jardine, Hydrogen sensors for hydrogen fuel cell applications, 2000.
  • N. Keon, G. Simader, T.I. Oren, and J.C.T. Oliveria, “Modelling and simulation of the proton exchange membrane fuel cell: A state of the art review”, Proceedings of the SCSC'95 (Ottawa, Canada, pp. 659-664, 1995.
  • J. Larminie and A. Dicks, Fuel cell systems explained, John Wiley and Sons, Inc., 2000.
  • J.H. Lee and T.R. Lalk, “Modeling fuel cell stack systems”, Journal of Power Sources 73 pp. 241,1998.
  • D. Mays, W. Campbell, W. Fengler, and S. Rowe, “Control system development for automotive PEM fuel cell vehicles”, SAE Future Transportation Technology Conference and Exposition (Costa Mesa, CA), 2001.
  • K. Mitsuda and T. Murahashi, “Air and fuel starvation of phosphoric acid fuel cells: A study using a single cell with multi-reference electrodes”, Journal of Applied Electrochemistry ,pp. 524-530, 1991.
  • W.E. Mufford and D.G. Strasky, Power control system for a fuel cell powered vehicle, United States Patents 5,991,670, 1999.
  • T.V. Nguyen and R.E. White, “A water and heat management model for proton- exchange membrane fuel cells”, Journal of ElectrochemicalSociety 140, pp.2178-2186,1993.
  • J. Padulles, G.W Ault, C.A. Smith, and J.R. McDonald, “Fuel cell plant dynamic modeling for power systems simulation”, Proceedings of th Universities Power Engineering Conference pp. 21-25. 1999.
  • L. Pino, V. Recupero, S. Beninati, A.K. Shukla, M.S. Hegde, and P. Bera, “Catalytic partial-oxidation of methane on a ceria-supported platinum catalyst for application in fuel cell electric vehicles”, Applied Catalysis 225 no. 1, pp. 63-75,2003.
  • W. Powers and P. Nicastri, “Automotive vehicle control challenges in the 21st century”, Control Engineering Practice 8 pp. 605-618, J. Pukrushpan, Modelling and control of fuel cell systems and fuel processors, Ph.D. thesis, The University of Michigan, Michigan, J. Pukrushpan, A. Stefanopoulou, and H. Peng, “Modeling and control for PEM fuel cell stack system”, Proceedings of the American Control Conference (Anchorage, Alaska), pp. 3122, 2002.
  • J. Pukrushpan, A. Stefanopoulou, S. Varigonda, L.M. Pedersen, S. Ghosh, and H. Peng, “Control of natural gas catalytic partial oxidation for hydrogen generation in fuel cell applications”, Proceedings of the American Control Conference (Denver, Colorado), pp. 2036, 2003.
  • P. Rodatz, G. Paganelli, and L. Guzzella, “Optimization of fuel cell systems through variable pressure control”, Proceedings of the American Control Conference (Denver, Coloradopp).pp. 2043-2048, 2003.
  • A. Rowe and X. Li, “Mathematical modeling of proton exchange membrane fuel cells”, Journal of Power Sources 102), pp. 82- , 2001.
  • A. Sasaki, Reformer reaction control apparatus for fuel cell, United States Patents ,642,273, 1987.
  • C. Song, “Fuel processing for low- temperature and high-temperature fuel cells challenges, and opportunities for sustainable development in the 21st century”, Catalysis Today 77 pp. 17-49,2002
  • R.H. Song, C.S. Kim, and R.S. Dong, “Effects of flow rate and starvation of reactant gases on the performance of phosphoric acid fuel cells”, Journal of Power Sources 86, pp.289-293, T.E. Springer, M.S. Wilson, and S. Gottesfeld, “Modeling and experimental diagnostics in polymer electrolyte fuel cells”, Journal of Electrochemical Society 140), pp. 3526, 1993.
  • T.E. Springer, T.A. Zawodzinski, and S. Gottesfeld, “Polymer electrolyte fuel cell model”, Journal of Electrochemical Society 138 pp. 2334-2342,1991.
  • D.L. Walton, Fuel cell power plant control, United States Patents 5,009,967, 1991.
  • J. Zhu, D. Zhang, and K.D. King, “Reforming of ch4 thermodynamic and kinetic analyses”, Fuel 80 pp. 899-905,2001.
There are 38 citations in total.

Details

Primary Language English
Journal Section Articles
Authors

Haluk Gorgun This is me

Publication Date December 28, 2011
Published in Issue Year 2005 Volume: 5 Issue: 1

Cite

APA Gorgun, H. (2011). CONTROL-ORIENTED MODELLING OF FUEL PROCESSING REACTORS IN FUEL CELL POWER SYSTEMS. IU-Journal of Electrical & Electronics Engineering, 5(1), 1279-1286.
AMA Gorgun H. CONTROL-ORIENTED MODELLING OF FUEL PROCESSING REACTORS IN FUEL CELL POWER SYSTEMS. IU-Journal of Electrical & Electronics Engineering. December 2011;5(1):1279-1286.
Chicago Gorgun, Haluk. “CONTROL-ORIENTED MODELLING OF FUEL PROCESSING REACTORS IN FUEL CELL POWER SYSTEMS”. IU-Journal of Electrical & Electronics Engineering 5, no. 1 (December 2011): 1279-86.
EndNote Gorgun H (December 1, 2011) CONTROL-ORIENTED MODELLING OF FUEL PROCESSING REACTORS IN FUEL CELL POWER SYSTEMS. IU-Journal of Electrical & Electronics Engineering 5 1 1279–1286.
IEEE H. Gorgun, “CONTROL-ORIENTED MODELLING OF FUEL PROCESSING REACTORS IN FUEL CELL POWER SYSTEMS”, IU-Journal of Electrical & Electronics Engineering, vol. 5, no. 1, pp. 1279–1286, 2011.
ISNAD Gorgun, Haluk. “CONTROL-ORIENTED MODELLING OF FUEL PROCESSING REACTORS IN FUEL CELL POWER SYSTEMS”. IU-Journal of Electrical & Electronics Engineering 5/1 (December 2011), 1279-1286.
JAMA Gorgun H. CONTROL-ORIENTED MODELLING OF FUEL PROCESSING REACTORS IN FUEL CELL POWER SYSTEMS. IU-Journal of Electrical & Electronics Engineering. 2011;5:1279–1286.
MLA Gorgun, Haluk. “CONTROL-ORIENTED MODELLING OF FUEL PROCESSING REACTORS IN FUEL CELL POWER SYSTEMS”. IU-Journal of Electrical & Electronics Engineering, vol. 5, no. 1, 2011, pp. 1279-86.
Vancouver Gorgun H. CONTROL-ORIENTED MODELLING OF FUEL PROCESSING REACTORS IN FUEL CELL POWER SYSTEMS. IU-Journal of Electrical & Electronics Engineering. 2011;5(1):1279-86.