Until recently the cost of fuel cells for terrestrial applications was prohibitive. Recently, several companies have begun developing high-performance, long-life and cost-effective fuel cell systems, and commercial units are now becoming available for stationary power generation. These systems can often be operated in conjunction with other energy systems to increase overall operational efficiency. A recent technology demonstration project at the University of Louisiana at Lafayette involved the installation, operation and analysis of a fuel cell and a desiccant dehumidification system, which is considered a good combination for the hot, humid climate of the U.S. Gulf coast. The three-year project involved technology assessment, hardware selection and procurement, installation, and operation of the two systems, followed by a performance analysis. The results were reported in a regional symposium. This paper describes the project, focusing on system operation and the results obtained, and predicts future possibilities for integrated energy systems of this type.

Volume Subject Area:
Advanced Energy Systems
Topics:
Fuel cells, Energy / power systems, Climate, Dehumidification, Energy generation, Hardware, Shorelines
1.
1993, “Annual Energy Review - 1993,” U.S. Department of Energy, Report No. USDOE/EIA-0384.
2.
http://energy.cr.usgs.gov/energy/stats_ctry/, U.S. Government Service Website, January 2005.
3.
Lidgate, D., 1990, “Green Energy,” IEE Review, January 1990.
4.
Maycock, P., 1995, “International Photovoltaic Markets, Developments and Trends: Forecast to 2010,” Photovoltaic Energy Systems, Inc., Casanova, VA.
5.
1995, “Renewing Our Energy Future,” Report of the Office of Technology Assessment (OTA), U. S. Congress, Washington, D.C., U.S. Government Printing Office.
6.
http://www.eere.energy.gov/state_energy/images, U.S. Department of Energy (DoE) Website, 2005.
7.
Simon, W.E., Nored, D.L., 1987, “Manned Spacecraft Electrical Power Systems, IEEE Spectrum, 75, No. 3.
8.
Simon
W. E.
,
Cox
J. E.
,
1968
, “
Thermodynamic Analysis of the Transient Response Characteristics of a Fuel Cell System
,”
Journal of Energy Conversion
,
8
, pp.
97
102
.
9.
http://www.ucsusa.org/global_environment/global_warming Union of Concerned Scientists Website, accessed February 2005.
10.
“World Population to 2300,” 2004, United Nations Department of Economic and Social Affairs, Population Division, Report No. ST/ESA/SER_A/236, 2004.
11.
http://www.worldenergy.org/wec-geis/publications/, World Energy Website, accessed February 2005.
12.
http://www.nefl.org/ea/eastats.html, Energy Action Statistics Website, accessed March 2005.
13.
Payne, W.F., 1985, The Cogeneration Sourcebook, Fairmont Press, Atlanta, GA, 1985.
14.
Angelle, J. R., 2002, “Fuel Cell Power Generation for Commercial and Residential Applications with Waste Heat Recovery,” masters thesis, University of Louisiana at Lafayette, Lafayette, LA.
15.
Ventrapragada, V., 2002, “Integration of a Desiccant Dehumidification System with a Fuel Cell for Distributed Power Generation and Waste Heat Recovery,” masters thesis, University of Louisiana at Lafayette, Lafayette, LA.
This content is only available via PDF.
Copyright © 2005
 by ASME
You do not currently have access to this content.