Open Science Research Excellence

Open Science Index

Commenced in January 2007 Frequency: Monthly Edition: International Publications Count: 29527


Select areas to restrict search in scientific publication database:
10009390
Comparative Exergy Analysis of Ammonia-Water Rankine Cycles and Kalina Cycle
Abstract:
This paper presents a comparative exergy analysis of ammonia-water Rankine cycles with and without regeneration and Kalina cycle for recovery of low-temperature heat source. Special attention is paid to the effect of system parameters such as ammonia mass fraction and turbine inlet pressure on the exergetical performance of the systems. Results show that maximum exergy efficiency can be obtained in the regenerative Rankine cycle for high turbine inlet pressures. However, Kalina cycle shows better exergy efficiency for low turbine inlet pressures, and the optimum ammonia mass fractions of Kalina cycle are lower than Rankine cycles.
Digital Object Identifier (DOI):

References:

[1] S. H. J. Bao and L. Zhao, “A review of working fluid and expander selections for organic Rankine cycle”, Renew. Sustain. Energy Rev., vol. 24, pp. pp.325-342, 2013.
[2] V. A. Prisyazhniuk, “Alternative trends in development of thermal power plant”, Applied Therm. Eng., vol. 28, pp. 190-194, 2008.
[3] K. H. Kim, H. J. Ko, and S. W. Kim, "Performance Analysis of Kalina Cycle using Ammonia-Water Mixture as Working Fluid for Use of Low- Temperature Energy Source", Trans. Korean Hydrogen and New Energy Society, vol. 22, pp. 109-117, 2011.
[4] C. Yu and K. T. Chau, "Thermoelectric automotive waste heat energy recovery using maximum power point tracking", Energy Convers Manage, vol. 50, pp. 1506-1512, 2009.
[5] P. Roy, M. Desilets, N. Galanis, H. Nesreddine H., and E. Cayer, “Thermodynamic analysis of a power cycle using a low-temperature source and a binary NH3 -H2O mixture as working fluid”, Int. J. Thermal Sci., vol. 49, pp. 48-58, 2010.
[6] K. H. Kim and C. H. Han, "Performance Analysis of Ammonia-Water Regenerative Rankine Cycles for Use of Low-Temperature Energy Source", J. Korean Solar Energy Soc., vol. 31, pp. 15-22, 2011.
[7] R. Shankar and T. Srinivas, “Performance investigation of Kalina cooling cogeneration cycles,” Int. J. Refrigeration, vol. 86, pp. 163–185, 2018.
[8] S. Zhang, Y. Chen, J. Wu, and Z. Zhu, “Thermodynamic analysis on a modified Kalina cycle with parallel cogeneration of power and refrigeration,” Energy Conv. Management, vol. 163, pp. 1–127, 2018.
[9] K. H. Kim, C. H. Han, K. Kim, “Effects of Ammonia Concentration on the Thermodynamic Performances of Ammonia-Water Based Power Cycles”, Thermochimica Acta, vol. 530, pp. 7-16, 2012.
[10] K. H. Kim, C. H. Han, and K. Kim, “Comparative exergy analysis of ammonia-water based Rankine cycles with and without regeneration”, Int. J. Exergy, vol. 12, pp. 344-361, 2013.
[11] K. H. Kim, H. J. Ko, and K. Kim, "Assessment of pinch point characteristics in heat exchangers and condensers of ammonia-water based power cycles", Applied Energy, vol. 113, pp. 970-981, 2014.
[12] P. A. Lolos and E. D. Rogdakis, “A Kalina power cycle driven by renewable energy sources”, Energy, vol. 34, pp. 457-464, 2009.
[13] S. Ogriseck, “Integration of Kalina cycle in a combined heat and power plant, a case study”, Applied Ther. Eng., vol. 29, pp. 2843-2848, 2009.
[14] C. Yue, D. Han, W. Pu, and W. He, "Comparative analysis of a bottoming transcritical ORC and a Kalina cycle for engine exhaust heat recovery", Energy Convers Manage., vol. 89, pp. 764–774, 2015.
[15] A. Modi, F. Haglind, “Thermodynamic optimisation and analysis of four Kalina cycle layouts for high temperature applications,” App. Therm. Eng., vol. 76, pp. 196-205, 2015
[16] F. Sun, W. Zhou, Y. Ikegami, K. Nakagami, and X. Su, “Energy-exergy analysis and optimization of the solar-boosted Kalina cycle of the solar-boosted Kalina cycle system 11 (KCS-11),” Renewable Energy, vol. 66, pp. 268-279, 2014.
[17] A. Bejan, Advanced Engineering Thermodynamics, 3rd ed. New York, NY, USA: John Wiley & Sons, 2006
[18] K. H. Kim, C.H. Han, K. Kim, “Comparative exergy analysis of ammonia-water based Rankine cycles with and without regeneration,” Int. J. Exergy, Vol. 12, pp. 344-361, 2013.
[19] F. Xu and D. Y. Goswami, “Thermodynamic properties of ammonia-water mixtures for power cycle,” Energy, vol. 24, pp. 525-536, 1999.
Vol:13 No:04 2019Vol:13 No:03 2019Vol:13 No:02 2019Vol:13 No:01 2019
Vol:12 No:12 2018Vol:12 No:11 2018Vol:12 No:10 2018Vol:12 No:09 2018Vol:12 No:08 2018Vol:12 No:07 2018Vol:12 No:06 2018Vol:12 No:05 2018Vol:12 No:04 2018Vol:12 No:03 2018Vol:12 No:02 2018Vol:12 No:01 2018
Vol:11 No:12 2017Vol:11 No:11 2017Vol:11 No:10 2017Vol:11 No:09 2017Vol:11 No:08 2017Vol:11 No:07 2017Vol:11 No:06 2017Vol:11 No:05 2017Vol:11 No:04 2017Vol:11 No:03 2017Vol:11 No:02 2017Vol:11 No:01 2017
Vol:10 No:12 2016Vol:10 No:11 2016Vol:10 No:10 2016Vol:10 No:09 2016Vol:10 No:08 2016Vol:10 No:07 2016Vol:10 No:06 2016Vol:10 No:05 2016Vol:10 No:04 2016Vol:10 No:03 2016Vol:10 No:02 2016Vol:10 No:01 2016
Vol:9 No:12 2015Vol:9 No:11 2015Vol:9 No:10 2015Vol:9 No:09 2015Vol:9 No:08 2015Vol:9 No:07 2015Vol:9 No:06 2015Vol:9 No:05 2015Vol:9 No:04 2015Vol:9 No:03 2015Vol:9 No:02 2015Vol:9 No:01 2015
Vol:8 No:12 2014Vol:8 No:11 2014Vol:8 No:10 2014Vol:8 No:09 2014Vol:8 No:08 2014Vol:8 No:07 2014Vol:8 No:06 2014Vol:8 No:05 2014Vol:8 No:04 2014Vol:8 No:03 2014Vol:8 No:02 2014Vol:8 No:01 2014
Vol:7 No:12 2013Vol:7 No:11 2013Vol:7 No:10 2013Vol:7 No:09 2013Vol:7 No:08 2013Vol:7 No:07 2013Vol:7 No:06 2013Vol:7 No:05 2013Vol:7 No:04 2013Vol:7 No:03 2013Vol:7 No:02 2013Vol:7 No:01 2013
Vol:6 No:12 2012Vol:6 No:11 2012Vol:6 No:10 2012Vol:6 No:09 2012Vol:6 No:08 2012Vol:6 No:07 2012Vol:6 No:06 2012Vol:6 No:05 2012Vol:6 No:04 2012Vol:6 No:03 2012Vol:6 No:02 2012Vol:6 No:01 2012
Vol:5 No:12 2011Vol:5 No:11 2011Vol:5 No:10 2011Vol:5 No:09 2011Vol:5 No:08 2011Vol:5 No:07 2011Vol:5 No:06 2011Vol:5 No:05 2011Vol:5 No:04 2011Vol:5 No:03 2011Vol:5 No:02 2011Vol:5 No:01 2011
Vol:4 No:12 2010Vol:4 No:11 2010Vol:4 No:10 2010Vol:4 No:09 2010Vol:4 No:08 2010Vol:4 No:07 2010Vol:4 No:06 2010Vol:4 No:05 2010Vol:4 No:04 2010Vol:4 No:03 2010Vol:4 No:02 2010Vol:4 No:01 2010
Vol:3 No:12 2009Vol:3 No:11 2009Vol:3 No:10 2009Vol:3 No:09 2009Vol:3 No:08 2009Vol:3 No:07 2009Vol:3 No:06 2009Vol:3 No:05 2009Vol:3 No:04 2009Vol:3 No:03 2009Vol:3 No:02 2009Vol:3 No:01 2009
Vol:2 No:12 2008Vol:2 No:11 2008Vol:2 No:10 2008Vol:2 No:09 2008Vol:2 No:08 2008Vol:2 No:07 2008Vol:2 No:06 2008Vol:2 No:05 2008Vol:2 No:04 2008Vol:2 No:03 2008Vol:2 No:02 2008Vol:2 No:01 2008
Vol:1 No:12 2007Vol:1 No:11 2007Vol:1 No:10 2007Vol:1 No:09 2007Vol:1 No:08 2007Vol:1 No:07 2007Vol:1 No:06 2007Vol:1 No:05 2007Vol:1 No:04 2007Vol:1 No:03 2007Vol:1 No:02 2007Vol:1 No:01 2007