A combined thermal power and cooling cycle is proposed which combines the Rankine and absorption refrigeration cycles. It can provide power output as well as refrigeration with power generation as a primary goal. Ammonia-water mixture is used as a working fluid. The boiling temperature of the ammonia-water mixture increases as the boiling process proceeds until all liquid is vaporized, so that a better thermal match is obtained in the boiler. The proposed cycle takes advantage of the low boiling temperature of ammonia vapor so that it can be expanded to a low temperature while it is still in a vapor state or a high quality two phase state. This cycle is ideally suited for solar thermal power using low cost concentrating collectors, with the potential to reduce the capital cost of a solar thermal power plant. The cycle can also be used as a bottoming cycle for any thermal power plant. This paper presents a parametric analysis of the proposed cycle.

Issue Section:
Research Papers
Topics:
Cooling, Solar collectors, Temperature, Thermodynamic cycles, Cycles, Boiling, Solar thermal power, Vapors, Water, Absorption, Boilers, Energy generation, Fluids, Low temperature, Refrigeration, Refrigeration cycles, Thermal energy, Thermal power stations
1.
Avery, K. A., 1980, “An Evaluation of the Use of the Binary Mixture ’Ammonia Water’ as the Heat Exchange Medium for Power Generation in the Ocean Thermal Energy Conversion Power Plant,” Master Thesis, University of Rhode Island.
2.
Bohn, M. S., Williams, T. A., and Price, H. W., 1995, “Combined Cycle Power Tower,” Solar Engineering 1995, Proceedings of the 1995 ASME/JSME/JSES International Solar Energy Conference, pp. 597–606.
3.
DeLaquil, P., Kearney, D., Geyer, M., and Diver, R., 1993,“Solar Thermal ElectricTechnology,” Chapter 5 in Renewable Energy Sources for Fuel and Electricity (Editors), Island Press, Washington, D.C.
4.
El-Sayed
Y. M.
, and
Tribus
M.
,
1985
a,“
A Theoretical Comparison of the Rankine and Kalina Cycles
,”
ASME Special Publication
, AES-Vol.
1
, pp.
97
102
.
5.
E`l-Sayed
Y. M.
, and
Tribus
M.
,
1985
b,“
Thermodynamic Properties of Water Ammonia Mixtures: Theoretical Implementation for Use in Power Cycle Analysis
,”
ASME Special Publication
, AES-Vol.
1
, pp.
89
95
.
6.
Gillespie, P. C, Wilding, W. V., and Wilson, G. M., 1987,“Vapor-Liquid Equilibrium Measurements on the Ammonia-Water System from 313K to 589K,” AICHE Symposium Series, Vol. 83, No. 256, pp. 97–127.
7.
Goswami, D. Y., 1994,“Solar Energy—The Natural Solution for Energy and Environmental Problems,” Heat and Mass Transfer 94, Proceedings of the First ISHMT-ASME Heat and Mass Transfer Conference, Tata-McGraw Hill Publishers, New Delhi, India, pp. 41–46.
8.
Goswami, D. Y., 1995,“Solar Thermal Power: Status of Technologies and Opportunities for Research,” Heat and Mass Transfer 95, Proceedings of the 2nd ASME-ISHMT Heat and Mass Transfer Conference, Tata-McGraw Hill Publishers, New Delhi, India, pp. 57–60.
9.
Goswami, D. Y., 1996,“Solar Thermal Power Technology: Present Status and Ideas for the Future,” Plenary Lecture at the ENERGEX ’ 96, Beijing, China, June 1996. To appear in Energy Sources: Journal of Extraction, Conversion and Environment.
10.
Haar
L.
, and
Gallagher
J. S.
,
1978
,“
Thermodynamic Properties of Ammonia
,”
Journal of Physical and Chemical Reference Data
, Vol.
7
. pp.
635
792
.
11.
Herold, K. E., Han, K., and Moran, M. J., 1988, “AMMWAT: A Computer Program for Calculating the Thermodynamic Properties of Ammonia and Water Mixtures Using a Gibbs Free Energy Formulation,” Proceedings of the ASME Winter Annual Meeting, AES-Vol. 4, pp. 65–75.
12.
Ibrahim, O. M., and Klein, S. A., 1993,“Thermodynamic Properties of Ammonia Water Mixtures,” ASHRAE Transactions: Symposia, pp. 1495–1502.
13.
Ibrahim
O. M.
, and
Klein
S. A.
,
1996
,“
Absorption Power Cycles
,”
Energy
, Vol.
21
, No.
1
, pp.
21
27
.
14.
Kalina. A. I., 1983,“Combined Cycle and Waste-Heat Recovery Power Systems Based on a Novel Thermodynamic Energy Cycle Utilizing Low-Temperature Heat for Power Generation,” ASME Paper 83-JPGC-GT-3, ASME, New York.
15.
Kalina
A. I.
,
1984
a,“
Combined Cycle System with Novel Bottoming Cycle
,”
ASME Journal of Engineering for Gas Turbines and Power
, Vol.
106
, pp.
737
742
.
16.
Kalina
A. I.
,
1984
b,“
Gas Turbines and Power
,”
ASME Journal of Engineering for Gas Turbines and Power
, Vol.
106
, p.
737
737
.
17.
Kalina, A. I., and Tribus, M., 1990a, “Advances in Kalina Cycle Technology (1980–1991): Part I, Development of a Practical Cycle,” Energy for the Transition Age, Proceedings of the Florence World Energy Research Symposium, Firenze, Italy, Vol. 97, pp. 111–124.
18.
Kalina, A. I., and Tribus, M., 1990b ,“Advances in Kalina Cycle Technology (1980–1991): Part II, Iterative Improvements,” Energy for the Transition Age, Proceedings of the Florence World Energy Research Symposium, Firenze, Italy, Vol. 97, pp. 111–124.
19.
Kalina, A. I., Tribus, M., and El-Sayed, Y. M., 1986, “A Theoretical Approach to the Thermophysical Properties of Two-Miscible-Component Mixtures for the Purpose of Power-Cycle Analysis,” ASME Paper 86-WA/HT-54.
20.
Koremenos, D. A., Rogdakis, E. D., and Antonopoulos, K. A., 1994,“Cogeneration with Combined Gas and Aqua-Ammonia Absorption Cycles,” in Thermodynamics and The Design. Analysis, and Improvement of Energy Systems (R. J. Drane, Ed.), AES Vol. 33, pp. 231–238.
21.
Macriss, R. A., Eakine, B. E., Ellington, R. T., and Huebler, J., 1964,“Physical and Thermodynamic Properties of Ammonia-Water Mixtures,” Institute of Gas Technology, Chicago, IL, Research Bulletin No. 34.
22.
Maloney, J. D., and Robertson, R. C, 1953,“Thermodynamic Study of Ammonia Water Heat Power Cycles,” ORNL Report CF-53–8-43, Oak Ridge, TN.
23.
Marston
C. H.
,
1990
,“
Parametric Analysis of the Kalina Cycle
,”
ASME Journal of Engineering for Gas Turbines and Power
, Vol.
112
, pp.
107
116
.
24.
Park
Y. M.
, and
Sonntag
R. E.
,
1990
,“
A Preliminary Study of the Kalina Power Cycle in Connection with a Combined Cycle System
,”
International Journal of Energy Research
, Vol.
14
, pp.
153
162
.
25.
Rogdakis
E. D.
, and
Antonopoulos
K. A.
,
1991
, “
A High Efficiency NH3/H2O Absorption Power Cycle
,”
Heat Recovery Systems
, Vol.
II
, pp.
263
275
.
26.
Washam, B., Willrich, M., Schaefer, J. C., and Kearney, D., 1994,“Integrated Solar Combined Cycle Systems (ISCCS) Utilizing Solar Parabolic Trough Technology— Golden Opportunities for the ’ 90s,” presented at the 1994 Annual Meeting of the American Solar Energy Society. Paper available from Spencer Management Associates, Diablo, California.
27.
Xu, F., 1997, “Analysis of a Novel Combined Thermal Power and Cooling Cycle Using Ammonia-Water Mixture as a Working Fluid,” Ph.D. Dissertation, University of Florida, Gainesville FL.
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