Overview of the Maisotsenko cycle – A way towards dew point evaporative cooling

Renewable and Sustainable Energy Reviews

Volumn 66, Issue , 2016, Pages 537-555

  Mahmood, Muhammad H ^a   Sultan, Muhammad ^a,c   Miyazaki, Takahiko ^a   Koyama, Shigeru ^a   Maisotsenko, Valeriy S ^b  

^a KYUSHU UNIVERSITY   (Japan)

^b Idalex Inc   (United States)

^c BAHAUDDIN ZAKARIYA UNIVERSITY   (Pakistan)

Author keywords

Applications; Evaporative cooling; Gas turbine; Heat recovery; Heating, ventilation and air conditioning (HVAC); M Cycle

Indexed keywords

AIR CONDITIONING; COMBUSTION; COOLING; DRIERS (MATERIALS); ENERGY CONSERVATION; EVAPORATION; EVAPORATIVE COOLING SYSTEMS; EXHAUST GASES; WASTE HEAT; WASTE HEAT UTILIZATION;

AC SYSTEMS; CONDITIONING SYSTEMS; DEWPOINT; ENERGY; EVAPORATIVE COOLING; GAS TURBINE POWER CYCLES; HEATING VENTILATION AND AIR CONDITIONING; HEATING, VENTILATION AND AIR-CONDITIONING; HUMID REGIONS; MAISOTSENKO CYCLE;

GAS TURBINES;

EID: 84983480679     PISSN: 13640321     EISSN: 18790690     Source Type: Journal    
DOI: 10.1016/j.rser.2016.08.022     Document Type: Review

References (175)

1. [1] Sultan, M., El-Sharkawy II, Miyazaki, T., Saha, B.B., Koyama, S., An overview of solid desiccant dehumidification and air conditioning systems. Renew Sustain Energy Rev 46 (2015), 16–29, 10.1016/j.rser.2015.02.038.
2. [2] Muneer, T., Asif, M., Prospects for secure and sustainable electricity supply for Pakistan. Renew Sustain Energy Rev 11 (2007), 654–671, 10.1016/j.rser.2005.05.001.
3. [3] Asif, M., Sustainable energy options for Pakistan. Renew Sustain Energy Rev 13 (2009), 903–909, 10.1016/j.rser.2008.04.001.
4. [4] Renewables in global energy supply: an IEA Fact Sheet,. International Energy Agency Statistics; 2007.
5. [5] Coolerado Corporation, 4430 Glencoe St. Denver, CO 80216, USA. 〈http://www.coolerado.com/〉; 2015.
6. [6] Coolerado cooler helps to save cooling energy and dollars: new cooling technology targets peak load reduction. United States: U. S. Department of Energy, Energy Efficiency & Renewable Energy, Federal Energy Management Program (FEMP), Report no. DOE/GO-102007-2325, 〈http://www.osti.gov/scitech/biblio/908968〉; 2007.
7. [7] Anisimov, S., Pandelidis, D., Danielewicz, J., Numerical analysis of selected evaporative exchangers with the Maisotsenko cycle. Energy Convers Manag 88 (2014), 426–441, 10.1016/j.enconman.2014.08.055.
8. [8] Pandelidis, D., Anisimov, S., Numerical analysis of the heat and mass transfer processes in selected M-Cycle heat exchangers for the dew point evaporative cooling. Energy Convers Manag 90 (2015), 62–83, 10.1016/j.enconman.2014.11.008.
9. [9] Zhan, C., Zhao, X., Smith, S., Riffat, S.B., Numerical study of a M-cycle cross-flow heat exchanger for indirect evaporative cooling. Build Environ 46 (2011), 657–668, 10.1016/j.buildenv.2010.09.011.
10. [10] Caliskan, H., Dincer, I., Hepbasli, A., A comparative study on energetic, exergetic and environmental performance assessments of novel M-Cycle based air coolers for buildings. Energy Convers Manag 56 (2012), 69–79, 10.1016/j.enconman.2011.11.007.
11. [11] Weerts, B., Coolerado and modeling an application of the Maisotsenko Cycle. Int J Energy Clean Environ 12 (2011), 287–307, 10.1615/InterJEnerCleanEnv.2013005585.
12. [12] Zube, D., Gillan, L., Evaluating Coolerado Corportion's heat-mass exchanger performance through experimental analysis. Int J Energy Clean Environ 12 (2011), 101–116, 10.1615/InterJEnerCleanEnv.2012005839.
13. [13] Buyadgie, D., Buyadgie, O., Drakhnia, O., Brodetsky, P., Maisotsenko, V., Solar low-pressure turbo-ejector Maisotsenko cycle-based power system for electricity, heating, cooling and distillation. Int J Low-Carbon Technol 10 (2015), 157–164, 10.1093/ijlct/ctv012.
14. [14] Worek WM, Khinkis M, Kalensky D, Maisotsenko V. Integrated Desiccant–Indirect Evaporative Cooling System Utilizing the Maisotsenko Cycle. Proc. ASME Summer Heat Transf. Conf., Puerto Rico: ASME; 2012:21–28. doi:10.1115/HT2012-58039.
15. [15] Jenkins, P., Cerza, M., Saaid, M.A., Analysis of using the M-cycle regenerative-humidification process on a gas turbine. J Energy Power Eng 8 (2014), 1824–1837.
16. [16] Saghafifar, M., Gadalla, M., Innovative inlet air cooling technology for gas turbine power plants using integrated solid desiccant and Maisotsenko cooler. Energy 87 (2015), 663–677, 10.1016/j.energy.2015.05.035.
17. [17] Saghafifar, M., Gadalla, M., Analysis of Maisotsenko open gas turbine power cycle with a detailed air saturator model. Appl Energy 149 (2015), 338–353, 10.1016/j.apenergy.2015.03.099.
18. [18] Saghafifar, M., Gadalla, M., Analysis of Maisotsenko open gas turbine bottoming cycle. Appl Therm Eng 82 (2015), 351–359, 10.1016/j.applthermaleng.2015.02.032.
19. [19] Guillet, R., The humid combustion to protect environment and to save the fuel: The water vapor pump and Maisotsenko cycles examples. Int J Energy Clean Environ 12 (2011), 259–271, 10.1615/InterJEnerCleanEnv.2012006092.
20. [20] Maisotsenko, V., Treyger, I., Way to energy abundance can be found through the Maisotsenko cycle. Int J Energy Clean Environ 12 (2011), 319–326, 10.1615/InterJEnerCleanEnv.2012005830.
21. [21] Anisimov, S., Pandelidis, D., Numerical study of the Maisotsenko cycle heat and mass exchanger. Int J Heat Mass Transf 75 (2014), 75–96, 10.1016/j.ijheatmasstransfer.2014.03.050.
22. [22] Bruno, F., On-site experimental testing of a novel dew point evaporative cooler. Energy Build 43 (2011), 3475–3483, 10.1016/j.enbuild.2011.09.013.
23. [23] Cui, X., Chua, K.J., Islam, M.R., Ng, K.C., Performance evaluation of an indirect pre-cooling evaporative heat exchanger operating in hot and humid climate. Energy Convers Manag 102 (2015), 140–150, 10.1016/j.enconman.2015.02.025.
24. [24] Miyazaki, T., Akisawa, A., Nikai, I., The cooling performance of a building integrated evaporative cooling system driven by solar energy. Energy Build 43 (2011), 2211–2218, 10.1016/j.enbuild.2011.05.004.
25. [25] Maisotsenko VS, Gillan LE, Heaton TL, Gillan AD. Power system and method. US Patent No. US7007453 B2; 2006.
26. [26] Maisotsenko V, Gillan L, Heaton T, Gillan A. Power system and method. US Patent No. US20040103637 A1; 2004.
27. [27] Maisotsenko VS, Gillan LE, Heaton TL, Gillan AD. Evaporative duplex counterheat exchanger. US Patent No. US6948558 B2; 2005.
28. [28] Alsharif A, Gadalla M, Dincer I. Energy and exergy analyses of Maisotsenko cycle. Proc. ASME 5th Int. Conf. Energy Sustain. ES2011, Washington, DC, USA: 2011:1–7.
29. [29] Riangvilaikul, B., Kumar, S., An experimental study of a novel dew point evaporative cooling system. Energy Build 42 (2010), 637–644, 10.1016/j.enbuild.2009.10.034.
30. [30] Anisimov, S., Pandelidis, D., Danielewicz, J., Numerical study and optimization of the combined indirect evaporative air cooler for air-conditioning systems. Energy 80 (2015), 452–464, 10.1016/j.energy.2014.11.086.
31. [31] Hasan, A., Going below the wet-bulb temperature by indirect evaporative cooling: analysis using a modified ε-NTU method. Appl Energy 89 (2012), 237–245, 10.1016/j.apenergy.2011.07.005.
32. [32] Anisimov, S., Pandelidis, D., Jedlikowski, A., Polushkin, V., Performance investigation of a M (Maisotsenko)-cycle cross-flow heat exchanger used for indirect evaporative cooling. Energy 76 (2014), 593–606, 10.1016/j.energy.2014.08.055.
33. [33] Cui, X., Chua, K.J., Yang, W.M., Numerical simulation of a novel energy-efficient dew-point evaporative air cooler. Appl Energy 136 (2014), 979–988, 10.1016/j.apenergy.2014.04.040.
34. [34] Gillan, L., Maisotsenko Cycle for Cooling Processes. Int J Energy Clean Environ 9 (2008), 47–64, 10.1615/InterJEnerCleanEnv.v9.i1-3.50.
35. [35] Zhan, C., Duan, Z., Zhao, X., Smith, S., Jin, H., Riffat, S., Comparative study of the performance of the M-cycle counter-flow and cross-flow heat exchangers for indirect evaporative cooling – paving the path toward sustainable cooling of buildings. Energy 36 (2011), 6790–6805, 10.1016/j.energy.2011.10.019.
36. [36] Zhao, X., Li, J.M., Riffat, S.B., Numerical study of a novel counter-flow heat and mass exchanger for dew point evaporative cooling. Appl Therm Eng 28 (2008), 1942–1951, 10.1016/j.applthermaleng.2007.12.006.
37. [37] Khalatov, A., Karp, I., Isakov, B., Prospects of the Maisotsenko thermodynamic cycle application in Ukraine. Int J Energy Clean Environ 12 (2011), 141–157, 10.1615/InterJEnerCleanEnv.2012005916.
38. [38] Caliskan, H., Dincer, I., Hepbasli, A., Exergetic and sustainability performance comparison of novel and conventional air cooling systems for building applications. Energy Build 43 (2011), 1461–1472, 10.1016/j.enbuild.2011.02.006.
39. [39] Chua, K.J., Chou, S.K., Yang, W.M., Yan, J., Achieving better energy-efficient air conditioning – A review of technologies and strategies. Appl Energy 104 (2013), 87–104, 10.1016/j.apenergy.2012.10.037.
40. [40] Pandelidis, D., Anisimov, S., Worek, W.M., Performance study of the Maisotsenko Cycle heat exchangers in different air-conditioning applications. Int J Heat Mass Transf 81 (2015), 207–221, 10.1016/j.ijheatmasstransfer.2014.10.033.
41. [41] Rogdakis, E.D., Koronaki, I.P., Tertipis, D.N., Experimental and computational evaluation of a Maisotsenko evaporative cooler at Greek climate. Energy Build 70 (2014), 497–506, 10.1016/j.enbuild.2013.10.013.
42. [42] Cui, X., Chua, K.J., Yang, W.M., Use of indirect evaporative cooling as pre-cooling unit in humid tropical climate: An energy saving technique. Energy Procedia 61 (2014), 176–179, 10.1016/j.egypro.2014.11.933.
43. [43] Riangvilaikul, B., Kumar, S., Numerical study of a novel dew point evaporative cooling system. Energy Build 42 (2010), 2241–2250, 10.1016/j.enbuild.2010.07.020.
44. [44] Itani M, Ghali K, Ghaddar N. Displacement Ventilation System Combined with a Novel Evaporative Cooled Ceiling for a Typical Office in the City of Beirut: Performance Evaluation. Proceeding Int. Conf. Renew. Energ. Power Qual. ICREPQ’15, La Coruña, Spain: Renewable Energy and Power Quality Journal (RE&PQJ); 2015.
45. [45] Weerts BA, Gallaher D, Weaver R, Van Geet O. Green Data Center Cooling: Achieving 90% Reduction: Airside Economization and Unique Indirect Evaporative Cooling. 2012 IEEE Green Technol. Conf., Tulsa, Oklahoma: IEEE; 2012:1–6. 〈doi:10.1109/GREEN.2012.6200950〉.
46. [46] Weerts, B.A., NSIDC green data center project: Coolerado and modeling an application of the Maisotsenko cycle. (M.S. Thesis), 2012, University of Colorado Boulder.
47. [47] NSIDC data center: energy reduction strategies. United States: U. S. Department of Energy, Energy Efficiency & Renewable Energy, Federal Energy Management Program (FEMP), Report no. DOE/GO-102012-3509, 〈http://www.osti.gov/scitech/biblio/1041349〉; 2012.
48. [48] Sultan, M., Study on sorption characteristics of water adsorbents for agricultural air-conditioning systems. 2015, Kyushu University, Japan.
49. [49] Maisotsenko V, Reyzin I. The Maisotsenko Cycle for Electronics Cooling. Proc. IPACK05 Int. Electron. Packag. Tech. Conf. Exhib., California, USA: ASME; 2005:415–424. 〈doi:10.1115/IPACK2005-73283〉.
50. [50] Khazhmuradov, M., Fedorchenko, D., Rudychev, Y., Martynov, S., Zakharchenko, A., Prokhorets, S., et al. Analysis of the Maisotsenko cycle based cooling system for accumulator batteries. Int J Energy Clean Environ 12 (2011), 95–99, 10.1615/InterJEnerCleanEnv.2012005979.
51. [51] Miyazaki T, Oda T, Ito M, Kawasaki N, Nikai I. The possibility of the energy cost savings by the electricity driven desiccant system with a high performance evaporative cooler. Int. Symp. Innov. Mater. Process. Energy Syst.; 2010.
52. [52] Anisimov, S., Jedlikowski, A., Pandelidis, D., Frost formation in the cross-flow plate heat exchanger for energy recovery. Int J Heat Mass Transf 90 (2015), 201–217, 10.1016/j.ijheatmasstransfer.2015.06.056.
53. [53] Miyazaki, T., Nikai, I., Akisawa, A., Simulation analysis of an open-cycle adsorption air conditioning system −numeral modeling of a fixed bed dehumidification unit and the maisotsenko cycle cooling unit. Int J Energy Clean Environ 12 (2011), 341–354, 10.1615/InterJEnerCleanEnv.2012005977.
54. [54] Anisimov S, Pandelidis D, Maisotsenko V. Numerical analysis of heat and mass transfer processes through the Maisotsenko cycle. Proc 10th Int. Conf. Heat Transf. Fluid Mech. Thermodyn. HEFAT-2014, Orlando, Florida; 2014:634–42.
55. [55] Lee, J., Design, Lee D.-Y., fabrication and testing of a compact regenerative evaporative cooler with finned channels. Int J Energy Clean Environ 12 (2011), 221–237, 10.1615/InterJEnerCleanEnv.2012006393.
56. [56] Duan, Z., Zhan, C., Zhang, X., Mustafa, M., Zhao, X., Alimohammadisagvand, B., et al. Indirect evaporative cooling: Past, present and future potentials. Renew Sustain Energy Rev 16 (2012), 6823–6850, 10.1016/j.rser.2012.07.007.
57. [57] Jaber, S., Ajib, S., Evaporative cooling as an efficient system in Mediterranean region. Appl Therm Eng 31 (2011), 2590–2596, 10.1016/j.applthermaleng.2011.04.026.
58. [58] Anisimov, S., Pandelidis, D., Heat- and mass-transfer procesess in indirect evaporative air conditioners through the Maisotsenko cycle. Int J Energy Clean Environ 12 (2011), 273–286, 10.1615/InterJEnerCleanEnv.2012005770.
59. [59] Tertipis, D., Rogdakis, E., Maisotsenko cycle: technology overview and energy-saving potential in cooling systems. Energy Emiss Control Technol 3 (2015), 15–22, 10.2147/EECT.S62995.
60. [60] Anisimov, S., Pandelidis, D., Numerical study of perforated indirect evaporative air cooler. Int J Energy Clean Environ 12 (2011), 239–250, 10.1615/InterJEnerCleanEnv.2013006668.
61. [61] Reznikov, M., Electrostatic enforcement of heat exchange in the Maisotsenko-cycle system. Int J Energy Clean Environ 12 (2011), 117–127, 10.1615/InterJEnerCleanEnv.2012005850.
62. [62] Sultan, M., Miyazaki, T., Koyama, S., Saha, B.B., Utilization of desiccant air-conditioning system for improvement in greenhouse productivity: a neglected area of research in Pakistan. Int J Environ 04 (2014), 1–10.
63. [63] Lee, J., Lee, D.-Y., Experimental study of a counter flow regenerative evaporative cooler with finned channels. Int J Heat Mass Transf 65 (2013), 173–179, 10.1016/j.ijheatmasstransfer.2013.05.069.
64. [64] Heidarinejad, G., Moshari, S., Novel modeling of an indirect evaporative cooling system with cross-flow configuration. Energy Build 92 (2015), 351–362, 10.1016/j.enbuild.2015.01.034.
65. [65] Alklaibi, A.M., Experimental and theoretical investigation of internal two-stage evaporative cooler. Energy Convers Manag 95 (2015), 140–148, 10.1016/j.enconman.2015.02.035.
66. [66] Xuan, Y.M., Xiao, F., Niu, X.F., Huang, X., Wang, S.W., Research and application of evaporative cooling in China: A review (I) – Research. Renew Sustain Energy Rev 16 (2012), 3535–3546, 10.1016/j.rser.2012.01.052.
67. [67] Pandelidis, D., Anisimov, S., Numerical analysis of the selected operational and geometrical aspects of the M-cycle heat and mass exchanger. Energy Build 87 (2015), 413–424, 10.1016/j.enbuild.2014.11.042.
68. [68] Anisimov, S., Pandelidis, D., Theoretical study of the basic cycles for indirect evaporative air cooling. Int J Heat Mass Transf 84 (2015), 974–989, 10.1016/j.ijheatmasstransfer.2015.01.087.
69. [69] Pandelidis, D., Anisimov, S., Worek, W.M., Comparison study of the counter-flow regenerative evaporative heat exchangers with numerical methods. Appl Therm Eng 84 (2015), 211–224, 10.1016/j.applthermaleng.2015.03.058.
70. [70] Caliskan, H., Hepbasli, A., Dincer, I., Maisotsenko, V., Thermodynamic performance assessment of a novel air cooling cycle: Maisotsenko cycle. Int J Refrig 34 (2011), 980–990, 10.1016/j.ijrefrig.2011.02.001.
71. [71] Caliskan, H., Dincer, I., Hepbasli, A., Exergoeconomic, enviroeconomic and sustainability analyses of a novel air cooler. Energy Build 55 (2012), 747–756, 10.1016/j.enbuild.2012.03.024.
72. [72] Novoselac, A., Srebric, J., A critical review on the performance and design of combined cooled ceiling and displacement ventilation systems. Energy Build 34 (2002), 497–509, 10.1016/S0378-7788(01)00134-7.
73. [73] Hao, X., Zhang, G., Chen, Y., Zou, S., Moschandreas, D.J., A combined system of chilled ceiling, displacement ventilation and desiccant dehumidification. Build Environ 42 (2007), 3298–3308, 10.1016/j.buildenv.2006.08.020.
74. [74] Ghaddar, N., Ghali, K., Chakroun, W., Evaporative cooler improves transient thermal comfort in chilled ceiling displacement ventilation conditioned space. Energy Build 61 (2013), 51–60, 10.1016/j.enbuild.2013.02.010.
75. [75] Rees, S.J., Haves, P., An experimental study of air flow and temperature distribution in a room with displacement ventilation and a chilled ceiling. Build Environ 59 (2013), 358–368, 10.1016/j.buildenv.2012.09.001.
76. [76] Taki, A.H., Jalil, L., Loveday, D.L., Experimental and computational investigation into suppressing natural convection in chilled ceiling/displacement ventilation environments. Energy Build 43 (2011), 3082–3089, 10.1016/j.enbuild.2011.08.002.
77. [77] Miyazaki T, Akisawa A, Nikai I. Study on the Maisotsenko cycle evaporative cooler driven by the solar chimney. Proc. Renew. Energy 2010 Conf. O-Th-2-4, Yokohama, Japan;2010.
78. [78] Kozubal, E., Slayzak, S., Coolerado 5 t RTU Performance: Western Cooling Challenge Results (revised). Colorado. 2010, National Renewable Energy Laboratory (NREL), USA.
79. [79] Anderson, E., Antkowiak, M., Butt, R., Davis, J., Dean, J., Hillesheim, M., et al. A Broad Overview of Energy Efficiency and Renewable Energy Opportunities for Department of Defense Installations. Colorado. 2011, National Renewable Energy Laboratory (NREL), USA.
80. [80] Duan, Z., Investigation of a novel dew point indirect evaporative air conditioning system for buildings. (PhD thesis), 2011, University of Nottingham.
81. [81] Dirkes, J.V. II, Energy simulation results for indirect evaporative-assisted DX cooling systems. Int J Energy Clean Environ 12 (2011), 209–220, 10.1615/InterJEnerCleanEnv.2012005806.
82. [82] Buyadgie, D., Buyadgie, O., Drakhnia, O., Sladkovskyi, Y., Artemenko, S., Chamchine, A., Theoretical study of the combined M-Cycle/Ejector air-conditioning system. Int J Energy Clean Environ 12 (2011), 309–318, 10.1615/InterJEnerCleanEnv.2013005893.
83. [83] Abdulateef, J.M., Sopian, K., Alghoul, M.A., Sulaiman, M.Y., Review on solar-driven ejector refrigeration technologies. Renew Sustain Energy Rev 13 (2009), 1338–1349, 10.1016/j.rser.2008.08.012.
84. [84] Chen, J., Havtun, H., Palm, B., Screening of working fluids for the ejector refrigeration system. Int J Refrig 47 (2014), 1–14, 10.1016/j.ijrefrig.2014.07.016.
85. [85] Sarkar, J., Ejector enhanced vapor compression refrigeration and heat pump systems—A review. Renew Sustain Energy Rev 16 (2012), 6647–6659, 10.1016/j.rser.2012.08.007.
86. [86] Chen, X., Omer, S., Worall, M., Riffat, S., Recent developments in ejector refrigeration technologies. Renew Sustain Energy Rev 19 (2013), 629–651, 10.1016/j.rser.2012.11.028.
87. [87] Al-Zubaydi, A.Y.T., Solar air conditioning and refrigeration with absorption chillers technology in australia – an overview on researches and applications. J Adv Sci Eng Res 1 (2011), 23–41.
88. [88] Aphornratana, S., Eames, I.W., Experimental investigation of a combined ejector-absorption refrigerator. Int J Energy Res 22 (1998), 195–207, 10.1002/(SICI)1099-114X(19980310)22:3<195::AID-ER346>3.0.CO;2-A.
89. [89] Sun, D.-W., Solar powered combined ejector-vapour compression cycle for air conditioning and refrigeration. Energy Convers Manag 38 (1997), 479–491, 10.1016/S0196-8904(96)00063-5.
90. [90] Buyadgie, D., Buyadgie, O., Artemenko, S., Chamchine, A., Drakhnia, O., Conceptual design of binary/multicomponent fluid ejector refrigeration systems. Int J Low-Carbon Technol 7 (2012), 120–127, 10.1093/ijlct/cts038.
91. [91] Buyadgie, D., Buyadgie, O., Drakhnia, O., Artemenko, S., Chamchine, A., Solar cooling technologies using ejector refrigeration system. Energy Procedia 30 (2012), 912–920, 10.1016/j.egypro.2012.11.103.
92. [92] Artemenko SV, Buyadgie DI, Buyadgie OD, Drakhnia OY, Sladkovsky EN, Chamchine AV. Analysis of refrigerants properties for the ejector refrigeration systems. Proc 4th IIR Conf. Thermophys. Prop. Transf. Process. Refrig., Delft, The Netherlands: 2013;1–10.
93. [93] Gao WZ, Cheng YP, Jiang AG, Liu T, Anderson K. Experimental investigation on integrated liquid desiccant – Indirect evaporative air cooling system utilizing the Maisotesenko – Cycle. Appl Therm Eng n.d. 〈doi:10.1016/j.applthermaleng.2014.08.066〉.
94. [94] Amer, O., Boukhanouf, R., Ibrahim, H.G., A review of evaporative cooling technologies. Int J Environ Sci Dev 6 (2015), 111–117, 10.7763/IJESD.2015.V6.571.
95. [95] Daou, K., Wang, R.Z., Xia, Z.Z., Desiccant cooling air conditioning: a review. Renew Sustain Energy Rev 10 (2006), 55–77, 10.1016/j.rser.2004.09.010.
96. [96] La, D., Dai, Y.J., Li, Y., Wang, R.Z., Ge, T.S., Technical development of rotary desiccant dehumidification and air conditioning: A review. Renew Sustain Energy Rev 14 (2010), 130–147, 10.1016/j.rser.2009.07.016.
97. [97] Mei, L., Dai, Y.J., A technical review on use of liquid-desiccant dehumidification for air-conditioning application. Renew Sustain Energy Rev 12 (2008), 662–689, 10.1016/j.rser.2006.10.006.
98. [98] Maisotsenko VS, Gillan LE, Heaton TL, Gillan AD. Method and apparatus of indirect-evaporation cooling. US Patent No. US6497107 B2; 2002.
99. [99] Enteria, N., Yoshino, H., Mochida, A., Takaki, R., Satake, A., Yoshie, R., et al. Construction and initial operation of the combined solar thermal and electric desiccant cooling system. Sol Energy 83 (2009), 1300–1311, 10.1016/j.solener.2009.03.008.
100. [100] Enteria, N., Yoshino, H., Satake, A., Mochida, A., Takaki, R., Yoshie, R., et al. Development and construction of the novel solar thermal desiccant cooling system incorporating hot water production. Appl Energy 87 (2010), 478–486, 10.1016/j.apenergy.2009.08.026.
101. [101] Baniyounes, A.M., Rasul, M.G., Khan, M.M.K., Experimental assessment of a solar desiccant cooling system for an institutional building in subtropical Queensland, Australia. Energy Build 62 (2013), 78–86, 10.1016/j.enbuild.2013.02.062.
102. [102] La, D., Dai, Y., Li, Y., Ge, T., Wang, R., Case study and theoretical analysis of a solar driven two-stage rotary desiccant cooling system assisted by vapor compression air-conditioning. Sol Energy 85 (2011), 2997–3009, 10.1016/j.solener.2011.08.039.
103. [103] Nagaya, K., Senbongi, T., Li, Y., Zheng, J., Murakami, I., High energy efficiency desiccant assisted automobile air-conditioner and its temperature and humidity control system. Appl Therm Eng 26 (2006), 1545–1551, 10.1016/j.applthermaleng.2005.12.005.
104. [104] Lee, S.H., Lee, W.L., Site verification and modeling of desiccant-based system as an alternative to conventional air-conditioning systems for wet markets. Energy 55 (2013), 1076–1083, 10.1016/j.energy.2013.04.029.
105. [105] Ismail, M.Z., Angus, D.E., Thorpe, G.R., The performance of a solar-regenerated open-cycle desiccant bed grain cooling system. Sol Energy 46 (1991), 63–70, 10.1016/0038-092X(91)90017-Q.
106. [106] Guojie, Z., Chaoyu, Z., Guanghai, Y., Wu, C., Development of a new marine rotary desiccant airconditioning system and its energy consumption analysis. Energy Procedia 16:Part B (2012), 1095–1101, 10.1016/j.egypro.2012.01.175.
107. [107] Zhu, J., Chen, W., Energy and exergy performance analysis of a marine rotary desiccant air-conditioning system based on orthogonal experiment. Energy 77 (2014), 953–962, 10.1016/j.energy.2014.10.014.
108. [108] Ascione, F., Bellia, L., Capozzoli, A., A coupled numerical approach on museum air conditioning: Energy and fluid-dynamic analysis. Appl Energy 103 (2013), 416–427, 10.1016/j.apenergy.2012.10.007.
109. [109] Ascione, F., Bellia, L., Capozzoli, A., Minichiello, F., Energy saving strategies in air-conditioning for museums. Appl Therm. Eng. 29 (2009), 676–686, 10.1016/j.applthermaleng.2008.03.040.
110. [110] Gao, W., Worek, W., Konduru, V., Adensin, K., Numerical study on performance of a desiccant cooling system with indirect evaporative cooler. Energy Build 86 (2015), 16–24, 10.1016/j.enbuild.2014.09.049.
111. [111] Qi, R., Lu, L., Huang, Y., Energy performance of solar-assisted liquid desiccant air-conditioning system for commercial building in main climate zones. Energy Convers Manag 88 (2014), 749–757, 10.1016/j.enconman.2014.09.006.
112. [112] Mohammad, A.T., Bin Mat, S., Sulaiman, M.Y., Sopian, K., Al-abidi, A.A., Survey of hybrid liquid desiccant air conditioning systems. Renew Sustain Energy Rev 20 (2013), 186–200, 10.1016/j.rser.2012.11.065.
113. [113] Mohammad, A.T., Mat, S.B., Sulaiman, M.Y., Sopian, K., Al-abidi, A.A., Artificial neural network analysis of liquid desiccant regenerator performance in a solar hybrid air-conditioning system. Sustain Energy Technol Assess 4 (2013), 11–19, 10.1016/j.seta.2013.08.001.
114. [114] Qi, R., Lu, L., Energy consumption and optimization of internally cooled/heated liquid desiccant air-conditioning system: A case study in Hong Kong. Energy 73 (2014), 801–808, 10.1016/j.energy.2014.06.086.
115. [115] Mohammad, A.T., Mat, S.B., Sulaiman, M.Y., Sopian, K., Al-abidi, A.A., Artificial neural network analysis of liquid desiccant dehumidifier performance in a solar hybrid air-conditioning system. Appl Therm Eng 59 (2013), 389–397, 10.1016/j.applthermaleng.2013.06.006.
116. [116] Buker, M.S., Riffat, S.B., Recent developments in solar assisted liquid desiccant evaporative cooling technology—A review. Energy Build 96 (2015), 95–108, 10.1016/j.enbuild.2015.03.020.
117. [117] Woods, J., Kozubal, E., A desiccant-enhanced evaporative air conditioner: Numerical model and experiments. Energy Convers Manag 65 (2013), 208–220, 10.1016/j.enconman.2012.08.007.
118. [118] Burch, J., Woods, J., Kozubal, E., Boranian, A., Zero energy communities with central solar plants using liquid desiccants and local storage. Energy Procedia 30 (2012), 55–64, 10.1016/j.egypro.2012.11.008.
119. [119] Woods J, Kozubal E. Desiccant enhanced evaporative air conditioning: parametric analysis and design. Proc Second Int. Conf. Build. Energy Environ. COBEE-2012, (Boulder, Colorado), USA;2012.
120. [120] Kozubal, E., Woods, J., Burch, J., Boranian, A., Merrigan, T., Desiccant enhanced evaporative air-conditioning (DEVap): evaluation of a new concept in ultra efficient air conditioning. Golden, Colorado 80401. Technical report: NREL/TP-5500-49722, 2011, National Renewable Energy Laboratory (NREL), USA 〈http://www.nrel.gov/docs/fy11osti/49722.pdf〉.
121. [121] Kozubal, E., Woods, J., Judkoff, R., Development and analysis of desiccant enhanced evaporative air conditioner prototype. Golden, Colorado 80401. Technical report: NREL/TP-5500-54755, 2012, National Renewable Energy Laboratory (NREL), USA 〈http://www.nrel.gov/docs/fy12osti/54755.pdf〉.
122. [122] El-Dessouky, H.T., Ettouney, H.M., Bouhamra, W., A novel air conditioning system: Membrane air drying and evaporative cooling. Chem Eng Res Des 78 (2000), 999–1009, 10.1205/026387600528111.
123. [123] Yang, B., Yuan, W., Gao, F., Guo, B., A review of membrane-based air dehumidification. Indoor Built Environ 24 (2015), 11–26, 10.1177/1420326×13500294.
124. [124] Woods, J., Pellegrino, J., Kozubal, E., Slayzak, S., Burch, J., Modeling of a membrane-based absorption heat pump. J Membr Sci 337 (2009), 113–124, 10.1016/j.memsci.2009.03.039.
125. [125] Woods, J., Pellegrino, J., Kozubal, E., Burch, J., Design and experimental characterization of a membrane-based absorption heat pump. J Membr Sci 378 (2011), 85–94, 10.1016/j.memsci.2010.11.012.
126. [126] Woods, J., Kozubal, E., Heat transfer and pressure drop in spacer-filled channels for membrane energy recovery ventilators. Appl Therm Eng 50 (2013), 868–876, 10.1016/j.applthermaleng.2012.06.052.
127. [127] Tyagi, S.K., Wang, S., Park, S.R., Sharma, A., Economic considerations and cost comparisons between the heat pumps and solar collectors for the application of plume control from wet cooling towers of commercial buildings. Renew Sustain Energy Rev 12 (2008), 2194–2210, 10.1016/j.rser.2007.03.012.
128. [128] Tyagi, S.K., Pandey, A.K., Pant, P.C., Tyagi, V.V., Formation, potential and abatement of plume from wet cooling towers: A review. Renew Sustain Energy Rev 16 (2012), 3409–3429, 10.1016/j.rser.2012.01.059.
129. [129] He, S., Gurgenci, H., Guan, Z., Huang, X., Lucas, M., A review of wetted media with potential application in the pre-cooling of natural draft dry cooling towers. Renew Sustain Energy Rev 44 (2015), 407–422, 10.1016/j.rser.2014.12.037.
130. [130] Anisimov S, Kozlov A, Glanville P, Khinkis M, Maisotsenko V, Shi J. Advanced Cooling Tower Concept for Commercial and Industrial Applications. Proc ASME 2014 Power Conf., vol. 2, Maryland, USA: ASME; 2014, p. V002T10A001 (7pages). 〈doi:10.1115/POWER2014-32020〉.
131. [131] Morosuk, T., Tsatsaronis, G., Maisotsenko, V., Kozlov, A., Exergetic Analysis of a Maisotsenko-Process-Enhanced Cooling Tower, 6, 2012, ASME, Texas, USA, 189–194, 10.1115/IMECE2012-87581.
132. [132] Gillan L, Glanville P, Kozlov A. Maisotsenko-Cycle Enhanced Cooling Towers. Proc 2011 Cool. Technol. Inst. Annu. Conf., Texas, USA: Cooling Technology Institute; (paper no. TP11–3).
133. [133] Qureshi, B.A., Zubair, S.M., A complete model of wet cooling towers with fouling in fills. Appl Therm Eng 26 (2006), 1982–1989, 10.1016/j.applthermaleng.2006.01.010.
134. [134] Maisotsenko V, Gillan LE, Heaton TL, Gillan AD. Method of evaporative cooling of a fluid and apparatus therefor. US Patent No. US6854278 B2; 2005.
135. [135] Morozyuk, T., Tsatsaronis, G., Advanced cooling tower concept based on the Maisotsenko-cycle - an exergetic evaluation. Int J Energy Clean Environ 12 (2011), 159–173, 10.1615/InterJEnerCleanEnv.2012006013.
136. [136] Wicker, K., Life below the wet bulb: The Maisotsenko cycle. Power 147 (2003), 29–31.
137. [137] Sverdlin, B., Tikhonov, A., Gelfand, R., Theoretical possibility of the Maisotsenko cycle application to decrease cold water temperature in cooling towers. Int J Energy Clean Environ 12 (2011), 175–185, 10.1615/InterJEnerCleanEnv.2012005876.
138. [138] Hosoz, M., Kilicarslan, A., Performance evaluations of refrigeration systems with air-cooled, water-cooled and evaporative condensers. Int J Energy Res 28 (2004), 683–696, 10.1002/er.990.
139. [139] Hwang, Y., Radermacher, R., Kopko, W., An experimental evaluation of a residential-sized evaporatively cooled condenser. Int J Refrig 24 (2001), 238–249, 10.1016/S0140-7007(00)00022-0.
140. [140] Hajidavalloo, E., Eghtedari, H., Performance improvement of air-cooled refrigeration system by using evaporatively cooled air condenser. Int J Refrig 33 (2010), 982–988, 10.1016/j.ijrefrig.2010.02.001.
141. [141] Li, Y., Wu, J., Shiochi, S., Modeling and energy simulation of the variable refrigerant flow air conditioning system with water-cooled condenser under cooling conditions. Energy Build 41 (2009), 949–957, 10.1016/j.enbuild.2009.04.002.
142. [142] Maisotsenko V, Gillan LE, Heaton TL, Gillan AD. Method and plate apparatus for dew point evaporative cooler. US Patent No. US6581402 B2;2003.
143. [143] Maisotsenko V, Gillan LE, Heaton TL, Gillan AD. Method and plate apparatus for dew point evaporative cooler. US Patent No. US7197887 B2;2007.
144. [144] Wani, C., Ghodke, S., Shrivastava, C., A review on potential of Maisotsenko cycle in energy saving applications using evaporative cooling. Int J Adv Res Sci Eng Technol 1 (2012), 15–20.
145. [145] Gorshkov, V., Systems based on Maisotsenko cycle: Coolerado coolers. (Bachelor's Thesis), 2012, Mikkeli University of Applied Sciences.
146. [146] The Idalex evaporative condenser: Harnessing the power of nature to redefine energy efficiency. Business opportunity report, Idalex Technologies, Inc. Arvada, CO 80003, USA; 2006.
147. [147] Maisotsenko, V.S., Evaporative cooled micro-channel condenser project through the Maisotsenko cycle. 80207, 2006, Idalex Inc., Denver, CO, USA.
148. [148] Wani, C., Ghodke, S., Performance analysis of a Maisotsenko cycle-based energy-efficient evaporative air conditioner. Int J Energy Clean Environ 12 (2011), 327–340, 10.1615/InterJEnerCleanEnv.2013006192.
149. [149] Gillan, L., Gillan, A., Kozlov, A., Kalensky, D., An advanced evaporative condenser through the Maisotsenko cycle. Int J Energy Clean Environ 12 (2011), 251–258, 10.1615/InterJEnerCleanEnv.2013006619.
150. [150] Cengel, Y.A., Boles, M.A., Thermodynamics: An Engineering Approach, 1994, McGraw-Hill, New York.
151. [151] Cohen, H., Rogers, G.F.C., Saravanamuttoo, H.I.H., Gas Turbine Theory - 4th Edition. Reading MA, 1996, Addison Wesley Longman.
152. [152] Yee, S.K., Milanovic, J.V., Hughes, F.M., Overview and comparative analysis of gas turbine models for system stability studies. IEEE Trans Power Syst 23 (2008), 108–118, 10.1109/TPWRS.2007.907384.
153. [153] Jonsson, M., Yan, J., Humidified gas turbines—a review of proposed and implemented cycles. Energy 30 (2005), 1013–1078, 10.1016/j.energy.2004.08.005.
154. [154] Poullikkas, A., An overview of current and future sustainable gas turbine technologies. Renew Sustain Energy Rev 9 (2005), 409–443, 10.1016/j.rser.2004.05.009.
155. [155] Gillan L, Maisotsenko V. Maisotsenko Open Cycle Used for Gas Turbine Power Generation. ASME Turbo Expo 2003 Collocated Int. Jt. Power Gener. Conf., vol. 3, Georgia, USA: 2003:75–84. 〈doi:10.1115/GT2003-38080〉.
156. [156] Gallo, W.L.R., A comparison between the hat cycle and other gas-turbine based cycles: Efficiency, specific power and water consumption. Energy Convers Manag 38 (1997), 1595–1604, 10.1016/S0196-8904(96)00220-8.
157. [157] Lazzaretto, A., Segato, F., A thermodynamic approach to the definition of the HAT cycle plant structure. Energy Convers Manag 43 (2002), 1377–1391, 10.1016/S0196-8904(02)00022-5.
158. [158] Jenkins PE, Cerza M, Saaid MM Al. Analysis of Using the M-Cycle Regenerative-Humidification Process on a Gas Turbine. ASME Turbo Expo 2014 Turbine Tech. Conf. Expo., vol. 3A, Düsseldorf, Germany:2014:1–11. doi:10.1115/GT2014-25178.
159. [159] Reyzin, I., Evaluation of the Maisotsenko power cycle thermodynamic efficiency. Int J Energy Clean Environ 12 (2011), 129–139, 10.1615/InterJEnerCleanEnv.2012005808.
160. [160] Clemente, S., Micheli, D., Reini, M., Taccani, R., Bottoming organic Rankine cycle for a small scale gas turbine: A comparison of different solutions. Appl Energy 106 (2013), 355–364, 10.1016/j.apenergy.2013.02.004.
161. [161] Bianchi, M., De Pascale, A., Bottoming cycles for electric energy generation: Parametric investigation of available and innovative solutions for the exploitation of low and medium temperature heat sources. Appl Energy 88 (2011), 1500–1509, 10.1016/j.apenergy.2010.11.013.
162. [162] Chacartegui, R., Sánchez, D., Muñoz, J.M., Sánchez, T., Alternative ORC bottoming cycles FOR combined cycle power plants. Appl Energy 86 (2009), 2162–2170, 10.1016/j.apenergy.2009.02.016.
163. [163] Kaikko J, Hunyadi L, Reunanen A, Larjola J. Comparison between air bottoming cycle and organic rankine cycle as bottoming cycles. Proc. Second Int. Heat Powered Cycles Conf. HPC, vol. 1; 2001:195.
164. [164] Pierobon, L., Haglind, F., Design and optimization of air bottoming cycles for waste heat recovery in off-shore platforms. Appl Energy 118 (2014), 156–165, 10.1016/j.apenergy.2013.12.026.
165. [165] Ghazikhani, M., Khazaee, I., Abdekhodaie, E., Exergy analysis of gas turbine with air bottoming cycle. Energy 72 (2014), 599–607, 10.1016/j.energy.2014.05.085.
166. [166] Saghafifar, M., Poullikkas, A., Comparative analysis of power augmentation in air bottoming cycles. Int J Sustain Energy, 2014, 1–14.
167. [167] Korobitsyn, M., Industrial applications of the air bottoming cycle. Energy Convers Manag 43 (2002), 1311–1322, 10.1016/S0196-8904(02)00017-1.
168. [168] Khalatov АА, Severin SD, Brodetsky PI, Maisotsenko VS. Brayton's subatmospheric inverse cycle with regeneration of output heat by Maisotsenko's cicle. Dopovidi Natsional'noi akademii nauk Ukrainy (Reports of the National Academy of Sciences of Ukraine) January 2015; 1:72-79, ISSN: 1025–6415 (in Russian language), 〈http://dopovidi-nanu.org.ua/en/archive/2015/1/11〉 n.d.
169. [169] Wilson, D.G., Korakianitis, T., The design of high-efficiency turbomachinery and gas turbines. 1984, MIT Press Cambridge, London, England.
170. [170] Besarati, S.M., Atashkari, K., Jamali, A., Hajiloo, A., Nariman-zadeh, N., Multi-objective thermodynamic optimization of combined Brayton and inverse Brayton cycles using genetic algorithms. Energy Convers Manag 51 (2010), 212–217, 10.1016/j.enconman.2009.09.015.
171. [171] Zhang, W., Chen, L., Sun, F., Power and efficiency optimization for combined Brayton and inverse Brayton cycles. Appl Therm Eng 29 (2009), 2885–2894, 10.1016/j.applthermaleng.2009.02.011.
172. [172] Alabdoadaim, M.A., Agnew, B., Potts, I., Performance analysis of combined Brayton and inverse Brayton cycles and developed configurations. Appl Therm Eng 26 (2006), 1448–1454, 10.1016/j.applthermaleng.2006.01.003.
173. [173] Agnew, B., Anderson, A., Potts, I., Frost, T.H., Alabdoadaim, M.A., Simulation of combined Brayton and inverse Brayton cycles. Appl Therm Eng 23 (2003), 953–963, 10.1016/S1359-4311(03)00019-X.
174. [174] Zhang, W., Chen, L., Sun, F., Thermodynamic optimization principle for open inverse Brayton cycle (refrigeration/heat pump cycle). Sci Iran 19 (2012), 1638–1652, 10.1016/j.scient.2012.09.007.
175. [175] Zhang, Z., Chen, L., Sun, F., Energy performance optimization of combined Brayton and two parallel inverse Brayton cycles with regeneration before the inverse cycles. Sci Iran 19 (2012), 1279–1287, 10.1016/j.scient.2012.07.009.