Authors:Bushra S. Younis,Karima E. 𝐀𝐦𝐨𝐫𝐢 ,
Keywords:Heat Recovery Steam Generator,Solar Energy,Integrated Solar Combined Power Plant,
AbstractThis paper study the effect of Heat Recovery Steam Generator (HRSG) type on the thermal effeicncy of Integrated Solar Combined Power Plant. The aim of this work is to improve thermal effeicncy of Integrated Solar Combined Cycle System (ISCCS). In this plant, recovery the largest possible amount of thermal energy in flue gases of gas power plants, to produce steam, and adopting solar energy to produce hot water. The efficiency of Solar Integrated Steam Power Plant can be increased from 40% for case A to 50% for case B, due to increased the aviable heat of HRSG from 168.27 MW to306 MW. Also, thermal environmental pollution can reduced from 148.36 ℃ to 68.97 ℃.
I. AL-Zafaraniyah Gas Power Plant / Baghdad, Iraq.
II. Cavalcanti E. J. C.,” Exergoeconomic and exergoenvironmental analyses of an integrated solar combined cycle system” renewable and sustainable energy reviews, V.67, PP.507-519, 2017.
III. E.Kabalci ,” Design and analysis of a hybrid renewable energy plant with solar and wind power”, energy conversion and management, V.xxx, PP.xxx-xxx, 2013.
IV. F. Calise , Accadia M. D., Libertini L. and Vicidomini M. ,” Thermoeconomic analysis of an integrated solar combined cycle power plant”, energy conversion and management, V.171, PP.1038-1051, 2018.
V. G .Khankari, and Karmakar S., ” power generation from flue gas waste heat in a 500 MW subcritical coal-fired thermal power plant using solar-assisted Kalina cycle system 11“, applied thermal engineering, V.xxx, PP.xxx-xxx, 2018.
VI. G. Bonforte, Buchgeister J., Manfrida G. and Petela K., ” Exergoeconomic and Exergoenvironmental analysis of an integrated solar gas turbine/combined cycle power plant “, energy, V.152, PP.xxx-xxx, 2018.
VII. G. Manente, Rech S., and Lazzaretto A.,” optimum choice and placement of concentrating solar power technologies in integrated solar combined cycle systems “renewable energy, V.96, PP.172-189, 2016.
VIII. H .Nezammahalleh, F. Farhadi, and Tanhaemami M., ” conceptual design and techno-economic assessment of integrated solar combined cycle system with DSG technology “, solar energy, V.84, PP.1696-1705, 2010.
IX. H.Nezammahalleh, Farhadi F., and Tanhaemami M.,” conceptual design and techno-economic assessment of integrated solar combined cycle system with DSG technology “, solar energy, V.84, PP.1696-1705, 2010.
X. J .Potter ,”Power plant , Theory and design “, John wiley pub,1956.
XI. N. Khan M,and Tlili I., “ Innovative thermodynamic parametric investigation of gas and steam bottoming cycles with heat exchanger and heat recovery steam generator: Energy and exergy analysis”, Energy Reports, V4, PP. 497-506, 2018.
XII. Q .Yan, Hu E., Yang Y. and Zhai R., ” Evaluation of solar aided thermal power generation with various power plants”, International journal of energy research, V.35, PP.909-922, 2011.
XIII. S .Jamel M., Shamsuddin A.H., and Abd- Rahman A.,” advances in the integration of solar thermal energy with conventional and non-conventional power plants”, renewable and sustainable energy reviews, V20, PP.71-81, 2013.
XIV. Y. Li and Xiong Y., ” Thermo-economic analysis of a novel cascade integrated solar combined cycle system”, energy, V145, PP.116-127,2018.
XV. Y.Li and Xiong Y.,” Thermo-economic analysis of a novel cascade integrated solar combined cycle system”, energy, V145, PP.116-127, 2018.