[1]
Nyberg B., Thern M., Thermodynamic studies of a HAT cycle and its components. Applied Energy, 2012, 89(1): 315–321.
[2]
Wang Y.Z., Zhang Q., Li Y.X., et al., Research on the effectiveness of the key components in the HAT cycle. Applied Energy, 2022, 306: 118066.
[3]
Guillet R., The humid combustion to protect environment and to save the fuel: The water vapor pump and Maisotsenko cycles examples. International Journal of Energy for a Clean Environment, 2013, 12(2–4): 259–271.
[4]
Serrano J., Jimenez-Espadafor F.J., Lora A., et al., Experimental analysis of NO
x reduction through water addition and comparison with exhaust gas recycling. Energy, 2019, 168: 737–752.
[5]
Saghafifar M., Gadalla M., Analysis of Maisotsenko open gas turbine power cycle with a detailed air saturator model. Applied Energy, 2015, 149: 338–353.
[6]
Dizaji F.S., Hu E.J., Chen L., A comprehensive review of the Maisotsenko-cycle based air conditioning systems. Energy, 2018, 156: 725–749.
[7]
Sajjad U., Abbas N., Hamid K., et al., A review of recent advances in indirect evaporative cooling technology. International Communications in Heat and Mass Transfer, 2021, 122(2): 105140.
[8]
Ma X., Zhao X., Zhang Y., et al., Combined Rankine Cycle and dew point cooler for energy efficient power generation of the power plants-A review and perspective study. Energy, 2022, 238: 121688.
[9]
Saghafifar M., Gadalla M., Innovative inlet air cooling technology for gas turbine power plants using integrated solid desiccant and Maisotsenko cooler. Energy, 2015, 87: 663–677.
[10]
Caliskan H., Dincer I., Hepbasli A., Assessment of Maisotsenko combustion turbine cycle with compressor inlet cooler. Progress in Clean Energy, 2015, 1: 41–55.
[11]
Lai L.B., Wang X.L., Kefayati G., et al., Evaporative cooling integrated with solid desiccant systems: A review. Energies, 2021, 14(18): 5982.
[12]
Gillan L., Maisotsenko V., Maisotsenko open cycle used for gas turbine power generation. ASME Turbo Expo 2003: International Joint Power Generation, Atlanta, Georgia, USA, 2003, Paper No: GT2003-38080.
https://doi.org/10.1115/GT2003-38080.
[13]
Wicker K., Life below the wet bulb: The Maisotsenko cycle. Tunnelling and Underground Space Technology, 2003, 14: 40.
[14]
Reyzin I., Evaluation of the Maisotsenko power cycle thermodynamic efficiency. International Journal of Energy for a Clean Environment, 2013, 12(2–4): 129–139.
[15]
Jenkins P.E., Carty J., The effects of the M-cycle on the performance of a gas turbine. 9th International Conference on Heat Transfer, Fluid Mechanics and Thermodynamic, Malta, 2012, Paper No: GT2014-25178.
[16]
Jenkins P.E., Cerza M., Al Saaid M.M., Analysis of using the m-cycle regenerative-humidification process on a gas turbine. ASME Turbo Expo 2014: Turbine Technical Conference and Exposition, Düsseldorf, Germany, 2014, Paper No: GT2014-25178.
[17]
Zhu G.Y., Chow T.T., Fong K.F., et al., Comparative study on humidified gas turbine cycles with different air saturator designs. Applied Energy, 2019, 254: 113592.
[18]
Zhu G.Y., Chow T.T., Lee C.K., Performance analysis of biogas-fueled maisotsenko combustion turbine cycle. Applied Thermal Engineering. 2021, 195: 117247.
[19]
Zhu F.L., Chen L.G., Wang W.H., Thermodynamic Analysis of an Irreversible Maisotsenko Reciprocating Brayton Cycle. Entropy, 2018, 20(3): 167.
[20]
Khalatov A., Severin S.D., Brodetsky P.I., et al., Brayton’s subatmospheric inverse cycle with regeneration of output heat by Maisotsenko’s cicle. Reports of the National Academy of Sciences of Ukraine, 2015, pp: 72–79.
[21]
Buyadgie D., Buyadgie O., Drakhnia O., et al, Solar low-pressure turbo-ejector Maisotsenko cycle-based power system for electricity, heating, cooling and distillation. International Journal of Low-Carbon Technologies, 2015, 10(2): 157–164.
[22]
Saghafifar M., Gadalla M., Analysis of Maisotsenko open gas turbine bottoming cycle. Applied Thermal Engineering, 2015, 82: 351–359.
[23]
Saghafifar M., Gadalla M., Thermo-economic optimization of hybrid solar Maisotsenko bottoming cycles using heliostat field collector: Comparative analysis. Applied Energy, 2017, 190: 686–702.
[24]
Saghafifar M., Omar A., Erfanmoghaddam S., et al., Thermo-economic analysis of recuperated Maisotsenko bottoming cycle using triplex air saturator: Comparative analyses. Applied Thermal Engineering, 2017, 111: 431–444.
[25]
Tariq R., Sheikh N.A., Numerical heat transfer analysis of Maisotsenko humid air bottoming cycle—A study towards the optimization of the air-water mixture at bottoming turbine inlet. Applied Thermal Engineering, 2018, 133: 49–60.
[26]
Omar A., Saghafifar M., Gadalla M., Thermo-economic analysis of air saturator integration in conventional combined power cycles. Applied Thermal Engineering, 2016, 107: 1104–1122.
[27]
Kumar P., Choudhary T., Ansari M.Z., Thermodynamic assessment of a novel SOFC and intercooled GT integration with ORC: Energy and exergy analysis. Thermal Science and Engineering Progress, 2022, 34: 101411.
[28]
Kose O., Koc Y., Yagli H., Performance improvement of the bottoming steam Rankine cycle (SRC) and organic Rankine cycle (ORC) systems for a triple combined system using gas turbine (GT) as topping cycle. Energy Conversion and Management, 2020, 211: 112745.
[29]
Chacartegui R., Sánchez D., Muñoz J.M., et al., Alternative ORC bottoming cycles for combined cycle power plants. Applied Energy, 2009, 86: 2162–2170.
[30]
Zare V., Mahmoudi S.M.S., A thermodynamic comparison between organic Rankine and Kalina cycles for waste heat recovery from the gas turbine-modular helium reactor. Energy, 2015, 79: 398–406.
[31]
Nami H., Akrami E., Analysis of a gas turbine based hybrid system by utilizing energy, exergy and exergoeconomic methodologies for steam, power and hydrogen production. Energy Conversion and Management, 2017, 143: 326–337.
[32]
Cao Y., Gao Y.K., Zheng Y., et al., Optimum design and thermodynamic analysis of a gas turbine and ORC combined cycle with recuperators. Energy Conversion and Management, 2016, 116: 32–41.
[33]
Zhu G.Y., Chow T.T., Maisotsenko V., et al., Maisotsenko power cycle technologies: Research, development and future needs. Applied Thermal Engineering, 2023, 223: 120023.
[34]
De Paepe M., Dick E., Technological and economical analysis of water recovery in steam injected gas turbines. Applied Thermal Engineering, 2001, 21(2): 135–156.
[35]
Feng Y.Q., Zhang F.Y., Xu J.W., et al., Parametric analysis and multi-objective optimization of biomass-fired organic Rankine cycle system combined heat and power under three operation strategies. Renewable Energy, 2023, 208: 431–449.
[36]
Sahu M.K., Sanjay, Thermoeconomic investigation of power utilities: Intercooled recuperated gas turbine cycle featuring cooled turbine blades. Energy, 2017, 138: 490–499.
[37]
Cao Y., Mihardj L.W.W., Dahari M., et al., Waste heat from a biomass fueled gas turbine for power generation via an ORC or compressor inlet cooling via an absorption refrigeration cycle: A thermoeconomic comparison. Applied Thermal Engineering, 2021, 182: 116117.
[38]
Wang J.F., Yan Z.Q., Zhao P., et al., Off-design performance analysis of a solar-powered organic Rankine cycle. Energy Conversion Management, 2014, 80: 150–157.
[39]
Zhao S.J., Zhao D.F., Song Q.B., Comparative lifecycle greenhouse gas emissions and their reduction potential for typical petrochemical enterprises in China. Journal of Environmental Sciences, 2022, 116: 125–138.
[40]
Mosaffa A.H., Mokarram N.H., Farshi L.G., Thermo-economic analysis of combined different ORCs geothermal power plants and LNG cold energy. Geothermics, 2017, 65: 113–125.
[41]
Tian Z., Qi Z., Gan W.L., et al., A novel negative carbon-emission, cooling, and power generation system based on combined LNG regasification and waste heat recovery: Energy, exergy, economic, environmental (4E) evaluations. Energy, 2022, 257: 124528.
[42]
Abido M.A., Multiobjective evolutionary algorithms for electric power dispatch problem. IEEE Transactions on Evolutionary Computation, 2006, 10(3): 315–329.
[43]
International Energy Agency & Nuclear Energy Agency. Projected costs of generating electricity 2020. Paris: International Energy Agency, 2020.
https://www.iea.org/reports/projected-costs-of-generating-electricity-2020.