Wind-generated electricity can be fundamentally transformed from an intermittent resource to a baseload power supply. For the case of long distance transmission of wind electricity, this change can be achieved at a negligible increase or even a decrease in per unit cost of electricity. The economic and technical feasibility of this process can be illustrated by studying the example of a wind farm located in central Kansas and a 2000 km, 2000 megawatt transmission line to southern California. Such a system can have capacity factor of 60 percent, with no economic penalty and without storage. With compressed air energy storage (CAES) (and with a negligible economic penalty), capacity factors of 70–95 percent can be achieved. This strategy has important implications for the development of wind energy throughout the world since good wind resources are usually located far from major demand centers.

Issue Section:
Research Papers
Topics:
Compressed air, Energy storage, Storage, Transmission lines, Wind, Wind energy, Wind energy systems, Wind farms
1.
Brower, M., Tennis, M., Denzler, E., and Kaplan, M., 1993, “Powering the Midwest,” Union of Concerned Scientists, Cambridge, MA.
2.
Cavallo, A., 1992, “The Economics of the Exploitation of Wind Generated Electricity in the Great Plains,” Proceedings of Windpower 92, American Wind Energy Association, Washington, DC.
3.
Cavallo
A.
,
1993
, “
Wind Energy: Current Status, Future Prospects
,”
Science and Global Security
, Vol.
4
, pp.
65
109
.
4.
Cavallo, A., 1994, “High Capacity Factor Wind Turbine-Transmission Systems,” Proceedings of the 13th Wind Energy Symposium, Energy Sources Technology Conference, New Orleans, Solar Energy Division, Vol. 15, pp. 87–94, ASME, New York.
5.
Elliott, D. L., Holladay, C. G., Barchet, W. R., Foote, H. P., and Sandusky, W. F., 1987, “Wind Energy Resource Atlas of the United States,” Pacific Northwest Laboratories, Richland, WA, DOE/CH10094-4.
6.
Elliott, D. L., Wendell, L. L., and Gower, G. L., 1991, “An Assessment of the Available Windy Land Area and Wind Energy Potential in the Contiguous United States,” PNL-7789, Pacific Northwest Laboratories, Richland, WA.
7.
Elliott, D. T., 1994, private communication, Pacific Northwest Laboratories, Richland, WA, Jan.
8.
EIA (Energy Information Agency), 1994, “Annual Energy Outlook 1994,” DOE/EIA-0383(94),” U.S. Department of Energy, Washington, DC.
9.
EPRI (Electric Power Research Institute), 1989, Technical Assessment Guide, Vol. 1, Electricity Supply, Palo Alto, CA, EPRI Report P-6587-L.
10.
Enercon, 1993, Dreekamp 5, D-2960, Aurich, Germany.
11.
Friis, P., and Mogens, H., 1993, “Commercial and Experimental Wind Power in Elsam Utility Area, Denmark,” Proceedings, Windpower 93, San Francisco, July 12-16, American Wind Energy Association, Washington, DC.
12.
Grubb
M.
,
1991
, “
The Value of Variable Sources on Power Systems
,”
IEE Proceedings C
, Vol.
138
, p.
2
2
.
13.
Grubb, M., and Meyer, H., 1992, “Wind Energy: Resources, Systems and Regional Strategies,” Renewable Energy: Sources for Fuels and Electricity, T. B. Johannson, H. Kelly, A. K. N. Reddy, and R. Williams, eds., Island Press, Washington, DC.
14.
Harrison
L.
,
1993
, “
Juggling With New Balls
,”
Windpower Monthly
, Vol.
9
, pp.
33
36
.
15.
Haslett
J.
, and
Diesendorf
M.
,
1981
, “
The Capacity Credit of Wind Power: A Theoretical Analysis
,”
Solar Energy
, Vol.
26
, pp.
391
401
.
16.
Jenkins, A., 1991, Technology Characterization, Final Report, November 1991, California Energy Commission, Sacramento, CA.
17.
Johnson, G., 1985, “Wind Energy Systems,” Prentice-Hall, Englewood Cliffs, NJ.
18.
Jourolman, L., 1992, “PURPA Handbook for Independent Electric Power Producers,” American Wind Energy Association, Washington, DC.
19.
Long, W., 1987, “Comparison of Cost and Benefits for AC and DC Transmission,” ORNL-6204, Oak Ridge National Laboratory, Oak Ridge, TN.
20.
Lynette, R., 1989, “Assessment of Wind Power Station Performance and Reliability,” EPRI Report GS-6256, Electric Power Research Institute, Box 50490, Palo Alto, CA.
21.
Miller, E., 1993, U.S. Windpower (Kenetech) letter to Lloyd Wright, U.S. EPA, May 27.
22.
Northwest Power and Conservation Plan, 1991, Volume II, Part 1, Northwest Power Planning Council, 851 S.W. Sixth Ave., Portland, Oregon 97204.
23.
Reason
J.
,
1990
, “
HVDC Line Brings Canadian Hydropower to New England
,”
Electrical World
, Vol.
3
, pp.
27
32
.
24.
SERI (Solar Energy Research Institute, now NREL), 1990, “The Potential of Renewable Energy: An Interlaboratory White Paper,” SERI/TP-260-3674, National Renewable Energy Laboratory, Golden, CO.
25.
Schainker, R. B., Mehta, B., and Pollak, R., 1993, “Overview of CAES Technology,” Proceedings of the American Power Conference, Chicago, Illinois Institute of Technology, Chicago, IL, pp. 992–997.
26.
Vestas, 1993, Smed Hansens Vej 27, DK-6940, Lem, Denmark.
27.
Watkins, K., 1991, “Blackfeet Area Wind Integration Study,” PNUCC, One Main Place, 101 S.W. Main, Suite 810, Portland, OR.
28.
Wen, H., 1991, personal communication, Fossil Technology Group, Bechtel Power Corporation, Gaithersberg, MD.
29.
Wu
C. T.
, eds.,
1990
, “
AC-DC Economics and Alternatives
,”
IEEE Transactions on Power Delivery
, Vol.
5
, pp.
1956
1969
.
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