Residential combined heat and power (CHP) systems using fuel cell technology can provide both electricity and heat and can substantially reduce the energy and environmental impact associated with residential applications. The energy, environmental, and economic characteristics of fuel cell CHP systems are investigated for single-family residential applications. Hourly energy use profiles for electricity and thermal energy are determined for typical residential applications. A mathematical model of a residential fuel cell based CHP system is developed. The CHP system incorporates a fuel cell system to supply electricity and thermal energy, a vapor compression heat pump to provide cooling in the summer and heating in the winter, and a thermal storage tank to help match the available thermal energy to the thermal energy needs. The performance of the system is evaluated for different climates. Results from the study include an evaluation of the major design parameters of the system, load duration curves, an evaluation of the effect of climate on energy use characteristics, an assessment of the reduction in emissions, and a comparison of the life cycle cost of the fuel cell based CHP system to the life cycle costs of conventional residential energy systems. The results suggest that the fuel cell CHP system provides substantial energy and environmental benefits but that the cost of the fuel cell sub-system must be reduced to roughly $500/kWe before the system can be economically justified.

Issue Section:
Technical Papers
Keywords:
fuel cell power plants, fuel cells, cogeneration, environmental factors, thermal analysis, life cycle costing, power generation economics, Fuel cell, PEMFC, Cogeneration, heat, power, residential, energy
Topics:
Cogeneration systems, Energy consumption, Fuel cells, Heat pumps, Heating, Thermal energy storage, Combined heat and power, Heat, Design, Stress
1.
Energy Information Administration, 2001, “1997 Residential Energy Consumption Survey: Housing Characteristics,” http://www.eia.doe.gov/emeu/recs/recs97_hc/97tblhp.html (accessed: June, 2002).
2.
Ellis, M. W., 2002, Fuel Cells for Building Applications, ASHRAE, Atlanta, GA.
3.
Hoven, J. A., 1993, “Residential Cogeneration System Development,” GRI-94/0029, Gas Reseach Institute.
4.
Darrow, K. G., and Smit, K. L., 1993, “Analysis of Residential and Small Commercial Cogeneration Technology,” GRI-93/0168, Gas Research Institute.
5.
Krist, K., and Gleason, K. J., 1999, “SOFC-based Residential Cogeneration Systems,” Electrochemical Society Proceedings, 99(19), pp. 107–115.
6.
Teagan, W. P., Wilson, R. P., Mathias, S., and Frantzis, L., 1986, “System and Technology Concept Generation for Small Commercial/Residential Cogeneration Applications,” GRI-Report # 86/0224, Gas Research Institute.
7.
Becker
,
B. R.
, and
Stogsdill
,
K. E.
,
1990
, “
Domestic Hot Water Use Database
,”
ASHRAE J.
,
32
(
9
), pp.
21
25
.
8.
Labs, K., 1981, Regional Analysis of Ground and Above-Ground Climate, US-Department of Energy, Oak Ridge National Laboratory.
9.
Hirsch, James, J., and Associates, 1999, “PowerDOE, Version 1.18a.”
10.
Kulp, G., 2001, “Issues in PEM Fuel Cell Air Management,” Masters Thesis, Virginia Polytechnic Institute and State University, Blacksburg, Virginia.
11.
Little, Arthur D., 1994, “Multi-Fuel Reformers for Fuel Cells Used in Transportation,” Department of Energy: DOE/CE/50343-2, Arthur D. Little, Cambridge, MA.
12.
ASHRAE, 1999, HVAC Applications Handbook, American Society of Heating, Refrigerating, and Air Conditioning Engineers, Atlanta, GA.
13.
Pontikakis
,
N.
, and
Ruth Douglas
,
W.
,
1994
, “
Electrical Residential Water Heating: A Consumption and Conservation Survey
,”
ASHRAE Trans.
,
100
(
2
), pp.
74
91
.
14.
Gunes, M. B., 2001, “Investigation of a Fuel Cell Based Total Energy System for Residential Applications,” Masters Thesis, Virginia Polytechnic Institute and State University, Blacksburg, VA.
15.
Energy Information Administration, 2001, “Annual Energy Review,” DOE/EIA-0384(2000), Department of Energy, Washington, DC.
16.
Energy Information Administration, 2001, “Emissions of Greenhouse Gases in the United States 2000,” DOE/EIA-0573(2000), Department of Energy, Washington, DC.
17.
R. S. Means Company Inc., 1998, Mechanical Cost Data, R. S. Means Company, Inc., Kingston, MA.
18.
W. W. Grainger Inc., 1999, Industrial and Commercial Equipment and Supplies, W. W. Grainger, Inc., Lake Forest, IL.
19.
McMaster-Carr, 2000, McMaster-Carr Supply Company Catalog, McMaster-Carr, Atlanta, GA.
20.
Energy Information Administration, “Annual Energy Outlook Supplement Reference Case Forecast (1999–2020),” http://www.eia.doe.gov/oiaf/aeo/supplement/supref.html, (accessed: March 2000, 2000).
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