Description of PEM Fuel Cells System

Green Energy and Technology

Volumn 87, Issue , 2012, Pages 49-72

  Feroldi, Diego ^a   Basualdo, Marta ^a,b  

^a UNIVERSIDAD NACIONAL DE ROSARIO   (Argentina)

^b UTN FRRo   (Argentina)

Author keywords

[No Author keywords available]

Indexed keywords

DYNAMIC MODELS; POLYELECTROLYTES;

CONTROL PURPOSE; GENERATION SYSTEMS; GENERIC STRUCTURE; HYDROGEN REDUCTION; MODEL APPROACH; OPTIMAL OPERATION; PEM FUEL CELL; POLYMER ELECTROLYTE MEMBRANES;

PROTON EXCHANGE MEMBRANE FUEL CELLS (PEMFC);

EID: 84883618353     PISSN: 18653529     EISSN: 18653537     Source Type: Book Series    
DOI: 10.1007/978-1-84996-184-4_2     Document Type: Review

References (55)

1. Laughton MA (2002) Fuel cells. Power Eng J 16:37-47
2. Tang H, Peikang S, Jiang SP, Wang F, Pan M (2007) A degradation study of Nafion proton exchange membrane of PEM fuel cells. J Power Sources 170(1):85-92
3. Yao K, Karan K, McAuley K, Oosthuizen P, Peppley B, Xie T (2004) A review ofmathematical models for hydrogen and direct methanol polymer electrolyte membrane fuel cells. Fuel Cells 4(1-2):3-29
4. Pukrushpan JT, Peng AGH (2002) Modeling and control for PEM fuel cell stack system. American Control Conference, Proceedings of the 2002, 4:3117-3122
5. D'Arco S, Ianuzzi D, Pagano M, Tricoli P (2005) Design criteria optimizing the use of fuel cell source in electric power system. In: Proceedings of the 16th IFAC World Congress, Prague
6. Zhang J, Xie Z, Zhang J, Tang Y, Song C, Navessin T, Shi Z, Song D, Wang H, Wilkinson DP, Liu Z-S, Holdcroft S (2006) High temperature pem fuel cells. J Power Sources 160(2):872-891
7. Carrette L, Friedrich K, Stimming U (2001) Fuel cells-fundamentals and applications. Fuel Cells 1(1):5-39
8. Rajashekara K (2000) Propulsion system strategies for fuel cell vehicles. Fuel Cell Technol for Vehicles 1:179-187
9. Jeong K, Oh B (2002) Fuel economic and life-cycle cost analysis of a fuel cell hybrid vehicle. J Power Sources 105:58-65
10. Friedman D, Moore R (1998) PEM fuel cell system optimization. In: Proc Electrochem Soc 27:407-423
11. EG & G Technical Services, Inc. Science Applications International Corporation (2002) IN: U.S. Department of Energy, Fuel Cell Handbook, 6th edition, Morgantown, West Virginia, USA
12. Flipsen S (2006) Power sources compared: the ultimate truth? J Power Sources 162:927-934
13. Larminie J, Dicks A (2003) Fuel Cell Systems Explained, 2nd edn Wiley, New York, USA
14. Amphlett J, Mann R, Peppley B, Roberge P, Rodrigues A (1996) A model predicting transient responses of proton exchange membrane fuel cells. J Power Sources 61:183-188
15. Correa J, Farret F, Canha L, Simoes M (2004) Anelectrochemical-based fuel-cellmodel suitable for electrical engineering automation approach. Ind Electron, IEEE Trans on 51(5):1103-1112
16. Barbir F (2005) PEM fuel cells: theory and practice. Elsevier, Burlington, MA, USA
17. Bossel U (2003) Well-to-wheel studies, heating values, and the energy conservation principle. IN:Ulf Bossel (ed) European Fuel Cell Forum, October 2003, Oberrohrdorf, Switzerland 1:1-5
18. Pukrushpan J (2003) Modelling and control of fuel cell systems and fuel processors. PhD thesis, University of Michigan, Ann Arbor, Michigan, USA. http://www-personal.umich.edu/annastef/FuelCellPdf/pukrushpan_thesis.pdf
19. Wipke K, Cuddy M, Burch S (1999) Advisor 2.1: a user-friendly advanced powertrain simulation using a combined backward/forward approach. IEEE Trans onVehicular Technol 48:1751-1761
20. Markel T, Brooker A, Hendricks T, Johnson V, Kelly K, Kramer B, O'Keefe M, Sprik S, Wipke K (2002) Advisor: a system analysis tool for advanced vehicle modeling. J Power Sources 110:255-266
21. Kim J, Lee SM, Srinivasan S, Chamberlin CE (1995) Modeling of proton exchange membrane fuel cell performance with an empirical equation. J Electrochem Soc 142:2670
22. Squadrito G, Maggio G, Passalacqua E, Lufrano F, Patti A (1999) An empirical equation for polymer electrolyte fuel cell (PEFC) behaviour. J Appl Electrochem 29(12):1449-1455
23. Cheddie D, Munroe N (2005) Review and comparison of approaches to proton exchange membrane fuel cell modeling. J Power Sources 147(1-2):72-84
24. Bernardi DM, Verbrugge MW (1991) Mathematical model of a gas diffusion electrode bonded to a polymer electrolyte. AIChE J 37(8):1151-1163
25. Bernardi DM, Verbrugge MW (1992) A Mathematical model of the solid-polymer-electrolyte fuel cell. J Electrochem Soc 139:2477
26. Springer TE, Zawodzinski TA, Gottesfeld S (1991) Polymer electrolyte fuel cell model. J Electrochem Soc 138(8):2334-2342
27. He W, Yi JS, Van Nguyen T (2000) Two-phase flow model of the cathode of PEM fuel cells using interdigitated flow fields. AIChE J 46(10):2053-2064
28. Natarajan D, Van Nguyen T (2001) A two-dimensional, two-phase, multicomponent, transient model for the cathode of a proton exchange membrane fuel cell using conventional gas distributors. J Electrochem Soc 148:A1324
29. Nguyen TV, White RE (1993) A water and heat management model for proton-exchangemembrane fuel cells. J Electrochem Soc 140:2178
30. Wang ZH, Wang CY, Chen KS (2001) Two-phase flowand transport in the air cathode of proton exchange membrane fuel cells. J Power Sources 94(1):40-50
31. Nguyen PT, Berning T, Djilali N (2004) Computational model of a PEM fuel cell with serpentine gas flow channels. J Power Sources 130(1-2):149-157
32. Natarajan D, Van Nguyen T (2003) Three-dimensional effects of liquid water flooding in the cathode of a PEM fuel cell. J Power Sources 115(1):66-80
33. Bernardi DM (1990) Water-balance calculations for solid-polymer-electrolyte fuel cells. J Electrochem Soc 137:3344
34. Fuller TF, Newman J (1993) Water and thermal management in solid-polymer-electrolyte fuel cells. J Electrochem Soc 140:1218
35. Wohr M, Bolwin K, Schnurnberger W, Fischer M, Neubrand W, Eigenberger G (1998) Dynamic modelling and simulation of a polymer membrane fuel cell including mass transport limitation. Int J Hydrogen Energy 23(3):213-218
36. Barsoukov En, Macdonald JR (2005) Impedance spectroscopy: theory, experiment, and applications. Wiley, Hoboken, New Jersey, USA
37. Andreaus B, McEvoy AJ, Scherer GG (2002) Analysis of performance losses in polymer electrolyte fuel cells at high current densities by impedance spectroscopy. Electrochimica Acta 47(13-14):2223-2229
38. Ciureanu M, Mikhailenko SD, Kaliaguine S (2003) PEM fuel cells as membrane reactors: kinetic analysis by impedance spectroscopy. Catal Today 82(1-4):195-206
39. Macdonald DD (2006) Reflections on the history of electrochemical impedance spectroscopy. Electrochimica Acta 51(8-9):1376-1388
40. Primucci M, Ferrer L, Serra M, Riera J (2008) Characterisation of fuel cell state using Electrochemical Impedance Spectroscopy analysis. Simposium Ibérico de Hidrógeno, Pilas de Combustible y Baterías Avanzadas (HYCELTEC)
41. Alejandro J, Real D, Arce A, Bordons C (2007) Development and experimental validation of a pem fuel cell dynamic model. J Power Sources 173(1):310-324
42. Pathapati PR, Xue X, Tang J (2005) A new dynamic model for predicting transient phenomena in a pem fuel cell system. Renew Energy 30(1):1-22
43. El-Sharkh M, Rahman A, Alam M, Byrne P, Sakla A, Thomas T (2004) A dynamic model for a stand-alone PEM fuel cell power plant for residential applications. J Power Sources 138:199-204
44. An improved dynamic voltage model of pem fuel cell stack (2010) Int J Hydrogen Energy 35(20):11154-11160 Hyceltec 2009 Conference
45. Grujicic M, Chittajallu KM, Law EH, Pukrushpan JT (2004) Model-based control strategies in the dynamic interaction of air supply and fuel cell. Proc Inst Mech Eng, Part A: J Power Energy 218(7):487-499
46. Vahidi A, Peng A (2004) Model predictive control for starvation prevention in a hybrid fuel cell system. Am Control Conf, Proc 2004 1:834-839
47. Varigonda S, Pukrushpan JT, Stefanopoulou AG (2003) American Institute of Chemical Engineers. Challenges in fuel cell power plant control: the role of system level dynamic models. Am Inst Chem Eng 1:101-110
48. Gelfi S, Stefanopoulou AG, Pukrushpan JT, Huei Peng (2003) Dynamics of low-pressure and high-pressure fuel cell air supply systems. In: AmControl Conf, 2003 Proceedings of the 2003 3:2049-2054
49. Caux S, Lachaize J, Fadel M, Shott P, Nicod L (2005) Energy management of fuel cell system and supercaps elements. In: Proceedings of the 16th IFAC World Congress, Prague
50. Serra M, Aguado J, Ansade X, Riera J (2005) Controllability analysis of decentralized linear controllers for polymeric fuel cells. J Power Sources 151:93-102
51. Feroldi D, Serra M, Riera J (2007) Performance improvement of a pemfc system controlling the cathode outlet air flow. J Power Sources 169(1):205-212
52. Zenith F, Skogestad S (2007) Control of fuel cell power output. J Process Control 17(4):333-347
53. Ceraolo M, Miulli C, Pozio A (2003) Modelling static and dynamic behaviour of proton exchange membrane fuel cells on the basis of electro-chemical description. J Power Sources 113(1):131-144
54. Yang W, Bates B, Fletcher N, Pow R (1998) Control challenges and methodologies in fuel cell vehicles development. Fuel Cell Technol for Vehicles 1:249-256
55. Friedman D (1999) Maximizing direct-hydrogen PEM fuel cell vehicle efficiency-is hybridization necessary? SAE Int 1:265-272