Two new high-performance cycles for gas turbine with air bottoming

The objective of this research is to model steam injection in the gas turbine with Air Bottoming Cycle (ABC). Based on an exergy analysis, a computer program has been developed to investigate improving the performance of an ABC cycle by calculating the irreversibility in the corresponding devices of the system. In this study, we suggest two new cycles where an air bottoming cycle along with the steam injection are used. These cycles are: the Evaporating Gas turbine with Air Bottoming Cycle (EGT-ABC), and Steam Injection Gas turbine with Air Bottoming Cycle (STIG-ABC). The results of the model show that in these cycles, more energy recovery and higher air inlet mass flow rate translate into an increase of the efficiency and output turbine work. The EGT-ABC was found to have a lower irreversibility and higher output work when compared to the STIG-ABC. This is due to the fact that more heat recovery in the regenerator in the EGT-ABC cycle results in a lower exhaust temperature. The extensive modeling performed in this study reveals that, at the same up-cycle pressure ratio and turbine inlet temperature (TIT), a higher overall efficiency can be achieved for the EGT-ABC cycle.

[1]  Erik Dick,et al.  RAISING CYCLE EFFICIENCY BY INTERCOOLING IN AIR-COOLED GAS TURBINES , 2006 .

[2]  Yousef S.H. Najjar,et al.  Performance analysis of gas turbine air-bottoming combined system , 1996 .

[3]  J. H. Horlock Heat exchanger performance with water injection (with relevance to evaporative gas turbine (EGT) cycles) , 1998 .

[4]  R. Ganguly,et al.  Energy and exergy analyses of an externally fired gas turbine (EFGT) cycle integrated with biomass gasifier for distributed power generation , 2010 .

[5]  Leonidas M. Th Kambanis Analysis and modeling of power transmitting systems for advanced marine vehicles , 1995 .

[6]  Mohsen Ghazikhani,et al.  Influence of Steam Injection on Thermal Efficiency and Operating Temperature of GE-F5 Gas Turbines Applying VODOLEY System , 2005 .

[7]  T. Srinivas,et al.  Sensitivity analysis of STIG based combined cycle with dual pressure HRSG , 2008 .

[8]  Marco Badami,et al.  Exergetic analysis of an innovative small scale combined cycle cogeneration system , 2010 .

[9]  Mikhail Aleksandrovich Korobitsyn New and Advanced Conversion Technologies: Analysis of Cogeneration, Combined and Integrated Cycles , 1998 .

[10]  Alberto Traverso,et al.  Thermoeconomic analysis of mixed gas–steam cycles , 2002 .

[11]  Andreas Poullikkas,et al.  An overview of current and future sustainable gas turbine technologies , 2005 .

[12]  Olav Bolland,et al.  Air Bottoming Cycle: Use of Gas Turbine Waste Heat for Power Generation , 1996 .

[13]  K. Wark,et al.  Advanced thermodynamics for engineers , 1994 .

[14]  Mikhail Korobitsyn,et al.  Industrial applications of the air bottoming cycle , 2002 .

[15]  Paul Fletcher,et al.  Gas Turbine Performance , 1998 .

[16]  Sergio A. A. G. Cerqueira,et al.  Thermoeconomic Evaluation of a Gas Turbine Cogeneration System , 1998, Advanced Energy Systems.

[17]  George Tsatsaronis,et al.  Optimization of combined cycle power plants using evolutionary algorithms , 2007 .

[18]  Andreas Poullikkas,et al.  Parametric study for the penetration of combined cycle technologies into Cyprus power system , 2004 .