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Daniel Czaja, Tadeusz Chmielnak and Sebastian Lepszy

References [1] Chmielniak T., Czaja D., Lepszy S.: A thermodynamic and economic comparative analysis of combined gas-steam and gas turbine air bottoming cycle. In: Proc. 25th Int. Conf. Efficiency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems, ECOS 2012, Jun 26-29, 2012, Perugia. [2] Intecteam, JV-Team for Planning, Construciton, Service, Trading in the Energy Business. Budget offer Combined Cycle Power Plant. Würzburg; website: www.intecteam.eu. [3] Czaja D., Chmielniak T., Lepszy S

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Tadeusz Chmielniak, Daniel Czaja and Sebastian Lepszy

References [1] Zander L., Zander Z.: Plate heat exchange designing. Instalacje sanitarne 2(2003), 7, 27-30 (in Polish). [2] Chmielniak T., Czaja D., Lepszy S.: A thermodynamic and economic comparative analysis of combined gas-steam and gas turbine air bottoming cycle. In: Proc.ECOS 2012 - 25th Int. Conf. on Efficiency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems, Perugia, June 26-29, 2012, 34-53. [3] Gut J. A.W, Pinto Jose M.: Modeling of plate heat exchangers with

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Tadeusz Chmielniak, Sebastian Lepszy and Daniel Czaja

-and-steam power station on the characteristics of efficiency. In: Proc. 4th International Science and Technology Conference, Expo-Ship 2006. Research papers number 10(82) of the Marine University in Szczecin. Korobitsyn M.: Industrial applications of the air bottoming cycle systems assessment department. Netherlands Energy Research Foundation, Energy Conversion and Management 43 (2002), 1311-1322. Yousef S, Najjar H., Zaamout M.S.: Performance analysis of gas turbine air-bottoming combined system. Energy Conversion and

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Janusz Kotowicz and Marcin Job

References [1] K otowicz J.: Combined Cycle Power Plants. Kaprint, Lublin 2008 (in Polish). [2] K otowicz J., J anusz K.: Manners of the reduction of the emission CO 2 from energetic processes. Rynek Energii 68 (2007), 1, 10–18 (in Polish). [3] L iu C.Y., C hen G., S ipöcz N., A ssadi M., B ai X.S.: Characteristics of oxy-fuel combustion in gas turbines. Appl. Energ. 89 (2012), 387–394. [4] Z hanga N., L ior N.: Two novel oxy-fuel power cycles integrated with natural gas reforming and CO 2 capture. Energy 33 (2008

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Maris Klavins, Valdis Bisters and Juris Burlakovs

] Klimantos P., Koukouzas N., Katsiadakis A., Kakaras E. Air-blown biomass gasification combined cycles (BGCC): system analysis and economic assessment. Energy 2009:34(5):708-714. doi:10.1016/j.energy.2008.04.009 [48] Chaiwat W., Hasegawa I., Mae K. Examination of the low-temperature region in a downdraft gasifier for the pyrolysis product analysis of biomass air gasification. Industrial Engineering and Chemistry Research 2009:48:8934-8943. [49] Sheth P. N., Babu B. V. Experimental studies on producer gas generation from wood waste in a

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Ginta Cimdina, Lelde Timma, Ivars Veidenbergs and Dagnija Blumberga

of gas turbine with air bottoming cycle. Energy 2014:72:599-607. doi:10.1016/j.energy.2014.05.085 [23] Kecebas A. Energetic, exergetic, economic and environmental evaluations of geothermal district heating systems: an application. Energy Conversion and Management 2013:65:546-556. [24] Kaska O. Energy and exergy analysis of organic Rankine for power generation from heat recovery in steel industry. Energy Conversion and Management 2014:77:108-117. doi:10.1016/j.enconman.2013.09.026 [25] Ertesvag I. Exergetic comparison