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CLC number: TM911.4

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Received: 2005-04-04

Revision Accepted: 2005-10-11

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Journal of Zhejiang University SCIENCE A 2006 Vol.7 No.3 P.450~457

http://doi.org/10.1631/jzus.2006.A0450


Research on a simulated 60 kW PEMFC cogeneration system for domestic application


Author(s):  Zhang Ying-ying, Yu Qing-chun, Cao Guang-yi, Zhu Xin-jian

Affiliation(s):  Fuel Cell Institute, Shanghai Jiao Tong University, Shanghai 200030, China

Corresponding email(s):   tricia@sjtu.edu.cn

Key Words:  Proton Exchange Membrane Fuel Cell (PEMFC), Cogeneration, Coordination strategy, Power response, Heat management


Zhang Ying-ying, Yu Qing-chun, Cao Guang-yi, Zhu Xin-jian. Research on a simulated 60 kW PEMFC cogeneration system for domestic application[J]. Journal of Zhejiang University Science A, 2006, 7(3): 450~457.

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author="Zhang Ying-ying, Yu Qing-chun, Cao Guang-yi, Zhu Xin-jian",
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%A Yu Qing-chun
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%A Zhu Xin-jian
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%DOI 10.1631/jzus.2006.A0450

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T1 - Research on a simulated 60 kW PEMFC cogeneration system for domestic application
A1 - Zhang Ying-ying
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A1 - Zhu Xin-jian
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PB - Zhejiang University Press & Springer
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DOI - 10.1631/jzus.2006.A0450


Abstract: 
The electrical and thermal performances of a simulated 60 kW proton Exchange Membrane Fuel Cell (PEMFC) cogeneration system are first analyzed and then strategies to make the system operation stable and efficient are developed. The system configuration is described first, and then the power response and coordination strategy are presented on the basis of the electricity model. Two different thermal models are used to estimate the thermal performance of this cogeneration system, and heat management is discussed. Based on these system designs, the 60 kW PEMFC cogeneration system is analyzed in detail. The analysis results will be useful for further study and development of the system.

Darkslateblue:Affiliate; Royal Blue:Author; Turquoise:Article

Reference

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[2] Amphlett, J.C., Baumert, R.M., Harris, T.J., Mann, R.F., Peppley, B.A., Roberge, P.R., 1995b. Performance modeling of the Ballard Mark IV solid polymer electrolyte fuel cell II. Empirical model development. J. Electrochem. Soc., 142(1):9-15.

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[4] DOE NETL (US Department of Energy, National Energy Technology Laboratory), 2002. Grid-independent, Residential Fuel-cell Conceptual Design and Cost Estimate. Final Report for DOE NETL in Subcontract to Parsons Infrastructure & Technology Group, Inc.

[5] Ferguson, A., Ugursal, V.I., 2004. Fuel cell modeling for building cogeneration applications. Journal of Power Sources, 137(1):30-42.

[6] Ferguson, A., Beausoleil-Morrison, I., Ugursal, V.I., 2003. A Comparative Assessment of Fuel Cell Cogeneration Heat Recovery Models. Proceedings of Building Simulation 2003, The Eighth International IBPSA Conference.

[7] Gunes, M.B., 2001. Investigation of a Fuel Cell Based Total Energy System for Residential Applications. Virginia Polytechnic Institute and State University.

[8] Hawkes, A., Leach, M., 2005. Impacts of temporal precision in optimisation modelling of micro-combined heat and power. Energy, 30(10):1759-1779.

[9] Kim, J., Lee, S., Srinivasan, S., Chamberlin, C.E., 1995. Modeling of proton exchange membrane fuel cell performance with an empirical equation. J. Elelctrochem. Soc., 142(8):2670-2674.

[10] Pukrushpan, J.T., Peng, H., Stefanopoulou, A.G., 2004. Control-oriented modeling and analysis for automotive fuel cell systems. Journal of Dynamic Systems Measurement, and Control, 126(1):14-25.

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