[1] |
Dabwan Y N, Mokheimer E M. Optimal integration of linear Fresnel reflector with gas turbine cogeneration power plant. Energy Conversion and Management, 2017 148(Supplement C): 830-843.
|
[2] |
Bellos E, Tzivanidis C, Papadopoulos A. Optical and thermal analysis of a linear Fresnel reflector operating with thermal oil, molten salt and liquid sodium. Applied Thermal Engineering, 2018 133: 70-80.
|
[3] |
Dabwan Y N, Pei G, Gao G, et al. A novel integrated solar tri-generation system for cooling, freshwater and electricity production purpose: Energy, economic and environmental performance analysis. Solar Energy, 2020, 198: 139-150.
|
[4] |
Livshits M, Kribus A. Solar hybrid steam injection gas turbine (STIG) cycle. Solar Energy, 2012, 86(1): 190-199.
|
[5] |
Selwynraj A I, Iniyan S, Polonsky G, et al. Exergy analysis and annual exergetic performance evaluation of solar hybrid STIG (steam injected gas turbine) cycle for Indian conditions. Energy, 2015, 80: 414-427.
|
[6] |
Selwynraj A I, Iniyan S, Polonsky G, et al. An economic analysis of solar hybrid steam injected gas turbine (STIG) plant for Indian conditions. Applied Thermal Engineering, 2015, 75: 1055-1064.
|
[7] |
Selwynraj A I, Iniyan S, Suganthi L, et al. Annual thermodynamic analysis of solar power with steam injection gas turbine (STIG) cycle for indian conditions. Energy Procedia, 2014, 57: 2920-2929.
|
[8] |
PolonskyG, Kribus A. Performance of the solar hybrid STIG cycle with latent heat storage. Applied Energy, 2015, 155: 791-803.
|
[9] |
Ni M, Yang T, Xiao G, et al. Thermodynamic analysis of a gas turbine cycle combined with fuel reforming for solar thermal power generation. Energy, 2017, 137: 20-30.
|
[10] |
He Y, Zheng S, Xiao G. Solar hybrid steam-injected gas turbine system with novel heat and water recovery. Journal of Cleaner Production, 2020, 276: 124268.
|
[11] |
Bianchini A, Pellegrini M, Saccani C. Solar steam reforming of natural gas integrated with a gas turbine power plant. Solar Energy, 2013, 96: 46-55.
|
[12] |
Bianchini A, Pellegrini M, Saccani C. Solar steam reforming of natural gas integrated with a gas turbine power plant: Economic assessment. Solar Energy, 2015, 122: 1342-1353.
|
[13] |
Dabwan Y N, Pei G, Jing L, et al. Development and assessment of integrating parabolic trough collectors with gas turbine trigeneration system for producing electricity, chilled water, and freshwater. Energy, 2018, 162: 364-379.
|
[14] |
DabwanY N, Pei G. A novel integrated solar gas turbine trigeneration system for production of power, heat and cooling: Thermodynamic-economic-environmental analysis. Renewable Energy, 2020, 152: 925-941.
|
[15] |
Mokheimer E M A, Dabwan Y N, Habib M A, et al. Development and assessment of integrating parabolic trough collectors with steam generation side of gas turbine cogeneration systems in Saudi Arabia. Applied Energy, 2015, 141: 131-142.
|
[16] |
Li Y, Yang Y. Impacts of solar multiples on the performance of integrated solar combined cycle systems with two direct steam generation fields. Applied Energy, 2015, 160: 673-680.
|
[17] |
Zhu G, Neises T, Turchi C, et al. Thermodynamic evaluation of solar integration into a natural gas combined cycle power plant. Renewable Energy, 2015, 74: 815-824.
|
[18] |
Adibhatla S, Kaushik S C. Energy, exergy and economic (3E) analysis of integrated solar direct steam generation combined cycle power plant. Sustainable Energy Technologies and Assessments, 2017, 20: 88-97.
|
[19] |
Wang J, Yang Y. A hybrid operating strategy of combined cooling, heating and power system for multiple demands considering domestic hot water preferentially: A case study. Energy, 2017, 122: 444-457.
|
[20] |
Bellos E, Tzivanidis C, Torosian K. Energetic, exergetic and financial evaluation of a solar driven trigeneration system. Thermal Science and Engineering Progress, 2018, 7: 99-106.
|
[21] |
Popov D. Innovative solar augmentation of gas turbine combined cycle plants. Applied Thermal Engineering, 2014, 64(1): 40-50.
|
[22] |
Matjanov E. Gas turbine efficiency enhancement using absorption chiller: Case study for Tashkent CHP. Energy, 2020, 192: 116625.
|
[23] |
Behar O. A novel hybrid solar preheating gas turbine. Energy Conversion and Management, 2018, 158: 120-132.
|
[24] |
Wang J, Lu Z, Li M, et al. Energy, exergy, exergoeconomic and environmental (4E) analysis of a distributed generation solar-assisted CCHP (combined cooling, heating and power) gas turbine system. Energy, 2019, 175: 1246-1258.
|
[25] |
Power G. Proprietary G E. Fim Proposal. [2021-03-15] , http://www.centralesdelacosta.com.ar/ciclo_combinado/PARTE%20II/PARTE%20II%20-%20%20%20ANEXO%20II%20-%20TURBINA%20GE%20FRAME%20%206FA%20EXISTENTE.pdf, 2012.
|
[26] |
Marin G, Osipov B, Mendeleev D. Research on the influence of fuel gas on energy characteristics of a gas turbine. in E3S Web of Conferences. EDP Sciences, 2019, 124: 05063.
|
[27] |
Abudu K, Igie U, Roumeliotis I, et al. Aeroderivative gas turbine back-up capability with compressed air injection. Applied Thermal Engineering, 2020, 180: 115844.
|
[28] |
Ol'khovskii G G, Radin Y A, Ageev A V, et al. Thermal tests of LMS100 gas-turbine units at the Dzhubga thermal power plant. Power Technology and Engineering, 2016 50(3): 294-302.
|
[29] |
Power G. LMS100* gas turbine (50 Hz). 2015
|
[30] |
Walsh P P, Fletcher P. Gas Turbine Performance. John Wiley & Sons, 2004.
|
[31] |
Saravanamuttoo H I, Rogers G F C, Cohen H. Gas Turbine Theory. Pearson Education, 2001.
|
[32] |
Canière H, Willockx A, Dick E, et al. Raising cycle efficiency by intercooling in air-cooled gas turbines. Applied Thermal Engineering, 2006, 26(16): 1780-1787.
|
[33] |
Lefebvre A H, Ballal D R. Gas Turbine Combustion: Alternative Fuels and Emissions. CRC press, 2010.
|
[34] |
Reale M J, Prochaska J K. New high efficiency simple cycle gas turbine–GE's LMS100. GER-4222A, GE Energy, 2004.
|
[35] |
Power G. LMS100 power plants. General Electric Company, 2019.
|
[36] |
Bejan A. Advanced Engineering Thermodynamics. John Wiley & Sons, 2016.
|
[37] |
Ellingwood K, Mohammadi K, Powell K. Dynamic optimization and economic evaluation of flexible heat integration in a hybrid concentrated solar power plant. Applied Energy, 2020, 276: 115513.
|
[38] |
MishraS, Sanjay Y H. Energy and exergy analysis of air-film cooled gas turbine cycle: Effect of radiative heat transfer on blade coolant requirement. Applied Thermal Engineering, 2018, 129: 1403-1413.
|
[39] |
Mishra S, Sharma A, Kumari A, et al. Response surface methodology based optimization of air-film blade cooled gas turbine cycle for thermal performance prediction. Applied Thermal Engineering, 2020, 164: 114425.
|
[40] |
Montes M, Abánades A, Martinez-Val J, et al. Solar multiple optimization for a solar-only thermal power plant, using oil as heat transfer fluid in the parabolic trough collectors. Solar Energy, vol. 83, no. 12: 2165-2176, 2009.
|
[41] |
Dabwan Y N, G. Pei, G. Gao, J. Li, and J. Feng. Performance analysis of integrated linear fresnel reflector with a conventional cooling, heat, and power tri-generation plant. Renewable Energy, 2019, 138: 639-650.
|
[42] |
Mokheimer E M A, Dabwan Y N, Habib M A. Optimal integration of solar energy with fossil fuel gas turbine cogeneration plants using three different CSP technologies in Saudi Arabia. Applied Energy, 2017, 185: 1268-1280.
|
[43] |
Dersch J, Geyer M, Herrmann U, et al. Trough integration into power plants: A study on the performance and economy of integrated solar combined cycle systems. Energy, 2004, 29(5): 947-959.
|
[44] |
Energy Information Administration. Levelized Cost and Levelized Avoided Cost of New Generation Resources in the Annual Energy Outlook 2018. US, 2018.
|
[45] |
Nezammahalleh H, Farhadi F, Tanhaemami M. Conceptual design and techno-economic assessment of integrated solar combined cycle system with DSG technology. Solar Energy, 2010, 84(9): 1696-1705.
|
[46] |
Cau G, Cocco D, Tola V. Performance and cost assessment of integrated solar combined cycle systems (ISCCSs) using CO2 as heat transfer fluid. Solar Energy, 2012 86(10): 2975-2985.
|
[47] |
Horn M, Führing H, Rheinländer J. Economic analysis of integrated solar combined cycle power plants: A sample case: The economic feasibility of an ISCCS power plant in Egypt. Energy, 2004, 29(5): 935-945.
|
[48] |
Power G. Aeroderivative Gas Turbine LMS100. [2021-03-15] , https://www.ge.com/gas-power/products/gas-turbines/lms100.
|
[1] |
Dabwan Y N, Mokheimer E M. Optimal integration of linear Fresnel reflector with gas turbine cogeneration power plant. Energy Conversion and Management, 2017 148(Supplement C): 830-843.
|
[2] |
Bellos E, Tzivanidis C, Papadopoulos A. Optical and thermal analysis of a linear Fresnel reflector operating with thermal oil, molten salt and liquid sodium. Applied Thermal Engineering, 2018 133: 70-80.
|
[3] |
Dabwan Y N, Pei G, Gao G, et al. A novel integrated solar tri-generation system for cooling, freshwater and electricity production purpose: Energy, economic and environmental performance analysis. Solar Energy, 2020, 198: 139-150.
|
[4] |
Livshits M, Kribus A. Solar hybrid steam injection gas turbine (STIG) cycle. Solar Energy, 2012, 86(1): 190-199.
|
[5] |
Selwynraj A I, Iniyan S, Polonsky G, et al. Exergy analysis and annual exergetic performance evaluation of solar hybrid STIG (steam injected gas turbine) cycle for Indian conditions. Energy, 2015, 80: 414-427.
|
[6] |
Selwynraj A I, Iniyan S, Polonsky G, et al. An economic analysis of solar hybrid steam injected gas turbine (STIG) plant for Indian conditions. Applied Thermal Engineering, 2015, 75: 1055-1064.
|
[7] |
Selwynraj A I, Iniyan S, Suganthi L, et al. Annual thermodynamic analysis of solar power with steam injection gas turbine (STIG) cycle for indian conditions. Energy Procedia, 2014, 57: 2920-2929.
|
[8] |
PolonskyG, Kribus A. Performance of the solar hybrid STIG cycle with latent heat storage. Applied Energy, 2015, 155: 791-803.
|
[9] |
Ni M, Yang T, Xiao G, et al. Thermodynamic analysis of a gas turbine cycle combined with fuel reforming for solar thermal power generation. Energy, 2017, 137: 20-30.
|
[10] |
He Y, Zheng S, Xiao G. Solar hybrid steam-injected gas turbine system with novel heat and water recovery. Journal of Cleaner Production, 2020, 276: 124268.
|
[11] |
Bianchini A, Pellegrini M, Saccani C. Solar steam reforming of natural gas integrated with a gas turbine power plant. Solar Energy, 2013, 96: 46-55.
|
[12] |
Bianchini A, Pellegrini M, Saccani C. Solar steam reforming of natural gas integrated with a gas turbine power plant: Economic assessment. Solar Energy, 2015, 122: 1342-1353.
|
[13] |
Dabwan Y N, Pei G, Jing L, et al. Development and assessment of integrating parabolic trough collectors with gas turbine trigeneration system for producing electricity, chilled water, and freshwater. Energy, 2018, 162: 364-379.
|
[14] |
DabwanY N, Pei G. A novel integrated solar gas turbine trigeneration system for production of power, heat and cooling: Thermodynamic-economic-environmental analysis. Renewable Energy, 2020, 152: 925-941.
|
[15] |
Mokheimer E M A, Dabwan Y N, Habib M A, et al. Development and assessment of integrating parabolic trough collectors with steam generation side of gas turbine cogeneration systems in Saudi Arabia. Applied Energy, 2015, 141: 131-142.
|
[16] |
Li Y, Yang Y. Impacts of solar multiples on the performance of integrated solar combined cycle systems with two direct steam generation fields. Applied Energy, 2015, 160: 673-680.
|
[17] |
Zhu G, Neises T, Turchi C, et al. Thermodynamic evaluation of solar integration into a natural gas combined cycle power plant. Renewable Energy, 2015, 74: 815-824.
|
[18] |
Adibhatla S, Kaushik S C. Energy, exergy and economic (3E) analysis of integrated solar direct steam generation combined cycle power plant. Sustainable Energy Technologies and Assessments, 2017, 20: 88-97.
|
[19] |
Wang J, Yang Y. A hybrid operating strategy of combined cooling, heating and power system for multiple demands considering domestic hot water preferentially: A case study. Energy, 2017, 122: 444-457.
|
[20] |
Bellos E, Tzivanidis C, Torosian K. Energetic, exergetic and financial evaluation of a solar driven trigeneration system. Thermal Science and Engineering Progress, 2018, 7: 99-106.
|
[21] |
Popov D. Innovative solar augmentation of gas turbine combined cycle plants. Applied Thermal Engineering, 2014, 64(1): 40-50.
|
[22] |
Matjanov E. Gas turbine efficiency enhancement using absorption chiller: Case study for Tashkent CHP. Energy, 2020, 192: 116625.
|
[23] |
Behar O. A novel hybrid solar preheating gas turbine. Energy Conversion and Management, 2018, 158: 120-132.
|
[24] |
Wang J, Lu Z, Li M, et al. Energy, exergy, exergoeconomic and environmental (4E) analysis of a distributed generation solar-assisted CCHP (combined cooling, heating and power) gas turbine system. Energy, 2019, 175: 1246-1258.
|
[25] |
Power G. Proprietary G E. Fim Proposal. [2021-03-15] , http://www.centralesdelacosta.com.ar/ciclo_combinado/PARTE%20II/PARTE%20II%20-%20%20%20ANEXO%20II%20-%20TURBINA%20GE%20FRAME%20%206FA%20EXISTENTE.pdf, 2012.
|
[26] |
Marin G, Osipov B, Mendeleev D. Research on the influence of fuel gas on energy characteristics of a gas turbine. in E3S Web of Conferences. EDP Sciences, 2019, 124: 05063.
|
[27] |
Abudu K, Igie U, Roumeliotis I, et al. Aeroderivative gas turbine back-up capability with compressed air injection. Applied Thermal Engineering, 2020, 180: 115844.
|
[28] |
Ol'khovskii G G, Radin Y A, Ageev A V, et al. Thermal tests of LMS100 gas-turbine units at the Dzhubga thermal power plant. Power Technology and Engineering, 2016 50(3): 294-302.
|
[29] |
Power G. LMS100* gas turbine (50 Hz). 2015
|
[30] |
Walsh P P, Fletcher P. Gas Turbine Performance. John Wiley & Sons, 2004.
|
[31] |
Saravanamuttoo H I, Rogers G F C, Cohen H. Gas Turbine Theory. Pearson Education, 2001.
|
[32] |
Canière H, Willockx A, Dick E, et al. Raising cycle efficiency by intercooling in air-cooled gas turbines. Applied Thermal Engineering, 2006, 26(16): 1780-1787.
|
[33] |
Lefebvre A H, Ballal D R. Gas Turbine Combustion: Alternative Fuels and Emissions. CRC press, 2010.
|
[34] |
Reale M J, Prochaska J K. New high efficiency simple cycle gas turbine–GE's LMS100. GER-4222A, GE Energy, 2004.
|
[35] |
Power G. LMS100 power plants. General Electric Company, 2019.
|
[36] |
Bejan A. Advanced Engineering Thermodynamics. John Wiley & Sons, 2016.
|
[37] |
Ellingwood K, Mohammadi K, Powell K. Dynamic optimization and economic evaluation of flexible heat integration in a hybrid concentrated solar power plant. Applied Energy, 2020, 276: 115513.
|
[38] |
MishraS, Sanjay Y H. Energy and exergy analysis of air-film cooled gas turbine cycle: Effect of radiative heat transfer on blade coolant requirement. Applied Thermal Engineering, 2018, 129: 1403-1413.
|
[39] |
Mishra S, Sharma A, Kumari A, et al. Response surface methodology based optimization of air-film blade cooled gas turbine cycle for thermal performance prediction. Applied Thermal Engineering, 2020, 164: 114425.
|
[40] |
Montes M, Abánades A, Martinez-Val J, et al. Solar multiple optimization for a solar-only thermal power plant, using oil as heat transfer fluid in the parabolic trough collectors. Solar Energy, vol. 83, no. 12: 2165-2176, 2009.
|
[41] |
Dabwan Y N, G. Pei, G. Gao, J. Li, and J. Feng. Performance analysis of integrated linear fresnel reflector with a conventional cooling, heat, and power tri-generation plant. Renewable Energy, 2019, 138: 639-650.
|
[42] |
Mokheimer E M A, Dabwan Y N, Habib M A. Optimal integration of solar energy with fossil fuel gas turbine cogeneration plants using three different CSP technologies in Saudi Arabia. Applied Energy, 2017, 185: 1268-1280.
|
[43] |
Dersch J, Geyer M, Herrmann U, et al. Trough integration into power plants: A study on the performance and economy of integrated solar combined cycle systems. Energy, 2004, 29(5): 947-959.
|
[44] |
Energy Information Administration. Levelized Cost and Levelized Avoided Cost of New Generation Resources in the Annual Energy Outlook 2018. US, 2018.
|
[45] |
Nezammahalleh H, Farhadi F, Tanhaemami M. Conceptual design and techno-economic assessment of integrated solar combined cycle system with DSG technology. Solar Energy, 2010, 84(9): 1696-1705.
|
[46] |
Cau G, Cocco D, Tola V. Performance and cost assessment of integrated solar combined cycle systems (ISCCSs) using CO2 as heat transfer fluid. Solar Energy, 2012 86(10): 2975-2985.
|
[47] |
Horn M, Führing H, Rheinländer J. Economic analysis of integrated solar combined cycle power plants: A sample case: The economic feasibility of an ISCCS power plant in Egypt. Energy, 2004, 29(5): 935-945.
|
[48] |
Power G. Aeroderivative Gas Turbine LMS100. [2021-03-15] , https://www.ge.com/gas-power/products/gas-turbines/lms100.
|