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Author: Grafiati
Published: 10 December 2022
Last updated: 28 January 2023

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1

Rezaee, Vahid, and Arash Houshmand. "Feasibility Study Of Maisotsenko Indirect Evaporative Air Cooling Cycle In Iran." GeoScience Engineering 61, no. 2 (June 1, 2015): 23–36. http://dx.doi.org/10.1515/gse-2015-0015.

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Abstract This paper presents energy and exergy analysis of air cooling cycle based on novel Maisotsenko indirect evaporative cooling cycle. Maisotsenko cycle (M-cycle) provides desired cooling condition above the dew point and below the wet bulb temperature. In this study, based on average annual temperature, The Iran area is segmented into eleven climates. In energy analysis, wet-bulb and dew point effectiveness, cooling capacity rate and in exergy analysis, exergy input rate, exergy destruction rate, exergy loss, exergy efficiency, exergetic COP and entropy generation rate for Iran's weather conditions in the indicated climates are calculated. Moreover, a feasibility study based on water evaporation rate and Maisotsenko cycle was presented. Energy and exergy analysis results show that the fifth, sixth, seventh and eighth climates are quite compatible and Rasht, Sari, Ramsar and Ardabile cities are irreconcilable with the Maisotsenko cycle.
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2

Gillan, Leland. "MAISOTSENKO CYCLE FOR COOLING PROCESSES." International Journal of Energy for a Clean Environment 9, no. 1-3 (2008): 47–64. http://dx.doi.org/10.1615/interjenercleanenv.v9.i1-3.50.

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3

Levchenko, D., I. Yurko, A. Artyukhov, and V. Baga. "Maisotsenko cycle applications for multistage compressors cooling." IOP Conference Series: Materials Science and Engineering 233 (August 2017): 012023. http://dx.doi.org/10.1088/1757-899x/233/1/012023.

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4

Chow, T. T., Guangya Zhu, and C. K. Lee. "System optimization of innovative tri-generation system for distributed power application." E3S Web of Conferences 111 (2019): 06018. http://dx.doi.org/10.1051/e3sconf/201911106018.

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The building sector is one major primary energy consumer and pollutant emission source. In recent years, the building-related research studies on the potential use of Maisotsenko-cycle in energy systems have been increasing in recent years. The growing interest lies in its expanded applications beyond the air-conditioning systems (the main “energy consumers” in buildings) into the prime movers (the key players in power generation). In order to evaluate its application merits in the practical tri-generation system of the urban districts, an extensive computer simulation platform has been developed. Based on a case study, this paper describes the techniques in the mixed use of numerical tools in performing system optimization studies for distributed power application on a university campus site. The practicality of the methodology is demonstrated through a hypothetical tri-generation system primed with Maisotsenko combustion turbine cycle. The findings are very much interesting.
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5

Reyzin, Ilya. "EVALUATION OF THE MAISOTSENKO POWER CYCLE THERMODYNAMIC EFFICIENCY." International Journal of Energy for a Clean Environment 12, no. 2-4 (2011): 129–39. http://dx.doi.org/10.1615/interjenercleanenv.2012005808.

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6

Gillan, Leland, Alan Gillan, Aleksandr Kozlov, and David Kalensky. "AN ADVANCED EVAPORATIVE CONDENSER THROUGH THE MAISOTSENKO CYCLE." International Journal of Energy for a Clean Environment 12, no. 2-4 (2011): 251–58. http://dx.doi.org/10.1615/interjenercleanenv.2013006619.

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7

Saghafifar, Mohammad, and Mohamed Gadalla. "Analysis of Maisotsenko open gas turbine bottoming cycle." Applied Thermal Engineering 82 (May 2015): 351–59. http://dx.doi.org/10.1016/j.applthermaleng.2015.02.032.

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8

Khalatov, Artem, I. Karp, and B. Isakov. "PROSPECTS OF THE MAISOTSENKO THERMODYNAMIC CYCLE APPLICATION IN UKRAINE." International Journal of Energy for a Clean Environment 12, no. 2-4 (2011): 141–57. http://dx.doi.org/10.1615/interjenercleanenv.2012005916.

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9

Weerts, Benjamin. "COOLERADO AND MODELING AN APPLICATION OF THE MAISOTSENKO CYCLE." International Journal of Energy for a Clean Environment 12, no. 2-4 (2011): 287–307. http://dx.doi.org/10.1615/interjenercleanenv.2013005585.

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10

Zhu, Guangya, Tin-Tai Chow, and Chun-Kwong Lee. "Performance analysis of biogas-fueled maisotsenko combustion turbine cycle." Applied Thermal Engineering 195 (August 2021): 117247. http://dx.doi.org/10.1016/j.applthermaleng.2021.117247.

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11

Zhu, Fuli, Lingen Chen, and Wenhua Wang. "Thermodynamic Analysis of an Irreversible Maisotsenko Reciprocating Brayton Cycle." Entropy 20, no. 3 (March 5, 2018): 167. http://dx.doi.org/10.3390/e20030167.

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12

Zhu, Guangya, Tin-Tai Chow, Valeriy S. Maisotsenko, and Tao Wen. "Maisotsenko power cycle technologies: Research, development and future needs." Applied Thermal Engineering 223 (March 2023): 120023. http://dx.doi.org/10.1016/j.applthermaleng.2023.120023.

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13

Reznikov, Michael. "ELECTROSTATIC ENFORCEMENT OF HEAT EXCHANGE IN THE MAISOTSENKO‐CYCLE SYSTEM." International Journal of Energy for a Clean Environment 12, no. 2-4 (2011): 117–27. http://dx.doi.org/10.1615/interjenercleanenv.2012005850.

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14

Aziz, Mansoor Abdul, Kyaw Thu, and Takahiko Miyazaki. "Thermodynamic analysis of Maisotsenko cycle based humidification dehumidification desalination system." Proceedings of the International Conference on Power Engineering (ICOPE) 2021.15 (2021): 2021–0223. http://dx.doi.org/10.1299/jsmeicope.2021.15.2021-0223.

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15

Anisimov, Sergey, Demis Pandelidis, and Jan Danielewicz. "Numerical analysis of selected evaporative exchangers with the Maisotsenko cycle." Energy Conversion and Management 88 (December 2014): 426–41. http://dx.doi.org/10.1016/j.enconman.2014.08.055.

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16

Khalatov, А. А., І. N. Karp, and B. V. Isakov. "Maisotsenko Thermodynamic Cycle and Prospects of Its Application in Ukraine." Visnik Nacional'noi' akademii' nauk Ukrai'ni, no. 2 (February 20, 2013): 39–49. http://dx.doi.org/10.15407/visn2013.02.039.

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17

Anisimov, Sergey, and Demis Pandelidis. "Numerical study of the Maisotsenko cycle heat and mass exchanger." International Journal of Heat and Mass Transfer 75 (August 2014): 75–96. http://dx.doi.org/10.1016/j.ijheatmasstransfer.2014.03.050.

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18

Zhu, Fuli, Lingen Chen, and Wenhua Wang. "Thermodynamic Analysis and Optimization of an Irreversible Maisotsenko-Diesel Cycle." Journal of Thermal Science 28, no. 4 (July 3, 2019): 659–68. http://dx.doi.org/10.1007/s11630-019-1153-1.

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19

Stupak, O., T. Donik, and A. Khalatov. "THE INFLUENCE OF DIFFERENT FACTORS ON THE MAISOTSENKO CYCLE EFFECTIVENESS." Integrated Technologies and Energy Saving, no. 2 (July 26, 2022): 3–22. http://dx.doi.org/10.20998/2078-5364.2022.2.01.

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An important problem in the heat industry is the significant cost of energy resources for air conditioning. Therefore, energy-efficient refrigeration systems based on renewable energy sources and evaporative air cooling, as well as air-conditioning systems according to the Maisotsenko cycle using psychrometric energy of the environment are of great importance. This paper presents the results of experimental and numerical research of the influence of various factors on the efficiency of indirect evaporative heat and mass transfer apparatus on the M-cycle on the basis of a new unit cell. An experimental stand of a heat and mass transfer apparatus with vertically arranged plate channels was developed for experimental research. Experimental studies of heat and mass transfer in the new unit cell were conducted in a wide range of Reynolds numbers 200…1200, temperature 16… 30 °С, relative humidity 30… 50 %. The calculated study was performed using a modified ε-NTU method. Studies have shown that the thermodynamic efficiency of a wet bulb thermometer at a Reynolds number below 500 exceeded one. According to the results of computational studies, the influence of cell length and surface intensification of dry channels on thermodynamic efficiency was determined. Shown the effect of changes in thermodynamic efficiency in the range of 86…94 % increase in efficiency by 1 % leads to an increase in cell length by 7 %. The value of the enhancement factor increases with increasing air flow regime, so when the heat and mass transfer surface area increases by 50 % and the Reynolds number 200, the thermodynamic efficiency increases by 14 %, and with the Reynolds number 800 – by 28 %. The dependence of the thermodynamic efficiency of the cells at the dew point on the relative humidity of the inlet air have a maximum, which with increasing Reynolds number shifts toward larger values of relative humidity. Unlike traditional air conditioning devices, the M-cycle heat and mass exchanger does not use a steam compression cycle, so energy costs are spent only on the operation of the fan to pump air, which is a more environmentally friendly and energy efficient way of air conditioning.
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20

Aleem, Muhammad, Ghulam Hussain, Muhammad Sultan, Takahiko Miyazaki, Muhammad H. Mahmood, Muhammad I. Sabir, Abdul Nasir, Faizan Shabir, and Zahid M. Khan. "Experimental Investigation of Desiccant Dehumidification Cooling System for Climatic Conditions of Multan (Pakistan)." Energies 13, no. 21 (October 22, 2020): 5530. http://dx.doi.org/10.3390/en13215530.

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In this study, experimental apparatus of desiccant dehumidification was developed at lab-scale, using silica gel as a desiccant material. Experimental data were obtained at various ambient air conditions, while focusing the climatic conditions of Multan (Pakistan). A steady-state analysis approach for the desiccant dehumidification process was used, and thereby the slope of desiccant dehumidification line on psychrometric chart (ϕ*) was determined. It has been found that ϕ* = 0.22 in case of silica gel which is lower than the hydrophilic polymeric sorbent, i.e., ϕ* = 0.31. The study proposed two kinds of systems, i.e., (i) standalone desiccant air-conditioning (DAC) and (ii) Maisotsenko-cycle-assisted desiccant air-conditioning (M-DAC) systems. In addition, two kinds of desiccant material (i.e., silica gel and hydrophilic polymeric sorbent) were investigated from the thermodynamic point of view for both system types, using the experimental data and associated results. The study aimed to determine the optimum air-conditioning (AC) system type, as well as adsorbent material for building AC application. In this regard, perspectives of dehumidification capacity, cooling capacity, and thermal coefficient of performance (COP) are taken into consideration. According to the results, hydrophilic polymeric sorbent gave a higher performance, as compared to silica gel. In case of both systems, the performance was improved with the addition of Maisotsenko cycle evaporative cooling unit. The maximum thermal COP was achieved by using a polymer-based M-DAC system, i.e., 0.47 at 70 °C regeneration temperature.
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21

Pacak, Anna, Aleksandra Cichoń, Demis Pandelidis, and Sergey Anisimov. "Impact of indirect evaporative air cooler type on the performance of desiccant systems." E3S Web of Conferences 44 (2018): 00134. http://dx.doi.org/10.1051/e3sconf/20184400134.

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In this study, two different indirect evaporative coolers operating with a desiccant wheel are compared theoretically: System A with the regenerative Maisotsenko Cycle (M-Cycle) unit and System B with the cross-flow M-cycle unit. Each system component performance was simulated using the original ε-NTU model. The influence of selected operational factors, such as inlet air temperature, humidity and regeneration air temperature for two system configurations was analysed and compared. It was established, that System B obtains higher cooling capacities and is more sensitive on ambient air humidity changes than System A.
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22

Maisotsenko, Valeriy, and Ilya Treyger. "WAY TO ENERGY ABUNDANCE CAN BE FOUND THROUGH THE MAISOTSENKO CYCLE." International Journal of Energy for a Clean Environment 12, no. 2-4 (2011): 319–26. http://dx.doi.org/10.1615/interjenercleanenv.2012005830.

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23

Khazhmuradov, Manap, Dmitrij Fedorchenko, Yegor Rudychev, Sergej Martynov, Alexander Zakharchenko, Svetlana Prokhorets, Anna Skrypnyk, et al. "ANALYSIS OF THE MAISOTSENKO CYCLE BASED COOLING SYSTEM FOR ACCUMULATOR BATTERIES." International Journal of Energy for a Clean Environment 12, no. 2-4 (2011): 95–99. http://dx.doi.org/10.1615/interjenercleanenv.2012005979.

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24

Khan, Mohammad S., Sami Tahan, Mohamad Toufic El-Achkar, and Saleh Abou Jamus. "The study of operating an air conditioning system using Maisotsenko-Cycle." IOP Conference Series: Materials Science and Engineering 323 (March 2018): 012014. http://dx.doi.org/10.1088/1757-899x/323/1/012014.

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25

Caliskan, Hakan, Arif Hepbasli, Ibrahim Dincer, and Valeriy Maisotsenko. "Thermodynamic performance assessment of a novel air cooling cycle: Maisotsenko cycle." International Journal of Refrigeration 34, no. 4 (June 2011): 980–90. http://dx.doi.org/10.1016/j.ijrefrig.2011.02.001.

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26

Sadighi Dizaji, Hamed, Eric Jing Hu, and Lei Chen. "A comprehensive review of the Maisotsenko-cycle based air conditioning systems." Energy 156 (August 2018): 725–49. http://dx.doi.org/10.1016/j.energy.2018.05.086.

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27

Pandelidis, Demis. "Numerical study and performance evaluation of the Maisotsenko cycle cooling tower." Energy Conversion and Management 210 (April 2020): 112735. http://dx.doi.org/10.1016/j.enconman.2020.112735.

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28

Morozyuk, Tatjana, and George Tsatsaronis. "ADVANCED COOLING TOWER CONCEPT BASED ON THE MAISOTSENKO‐CYCLE - AN EXERGETIC EVALUATION." International Journal of Energy for a Clean Environment 12, no. 2-4 (2011): 159–73. http://dx.doi.org/10.1615/interjenercleanenv.2012006013.

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29

Wani, Chandrakant, and Satyashree Ghodke. "PERFORMANCE ANALYSIS OF A MAISOTSENKO CYCLE-BASED ENERGY-EFFICIENT EVAPORATIVE AIR CONDITIONER." International Journal of Energy for a Clean Environment 12, no. 2-4 (2011): 327–40. http://dx.doi.org/10.1615/interjenercleanenv.2013006192.

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30

Mahmood, Muhammad H., Muhammad Sultan, Takahiko Miyazaki, Shigeru Koyama, and Valeriy S. Maisotsenko. "Overview of the Maisotsenko cycle – A way towards dew point evaporative cooling." Renewable and Sustainable Energy Reviews 66 (December 2016): 537–55. http://dx.doi.org/10.1016/j.rser.2016.08.022.

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31

Sadighi Dizaji, Hamed, Eric Jing Hu, Lei Chen, and Samira Pourhedayat. "Comprehensive exergetic study of regenerative Maisotsenko air cooler; formulation and sensitivity analysis." Applied Thermal Engineering 152 (April 2019): 455–67. http://dx.doi.org/10.1016/j.applthermaleng.2019.02.067.

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32

Guangya, Zhu, T. T. Chow, K. F. Fong, and C. K. Lee. "Investigation on humidified gas turbine cycles with Maisotsenko-cycle-based air saturator." Energy Procedia 158 (February 2019): 5195–200. http://dx.doi.org/10.1016/j.egypro.2019.01.676.

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33

Tariq, Rasikh, Nadeem Ahmed Sheikh, A. Bassam, and J. Xamán. "Analysis of Maisotsenko humid air bottoming cycle employing mixed flow air saturator." Heat and Mass Transfer 55, no. 5 (November 27, 2018): 1477–89. http://dx.doi.org/10.1007/s00231-018-2531-z.

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34

Levchenko, D. O., A. E. Artyukhov, and I. V. Yurko. "Maisotsenko cycle applications in multi-stage ejector recycling module for chemical production." IOP Conference Series: Materials Science and Engineering 233 (August 2017): 012024. http://dx.doi.org/10.1088/1757-899x/233/1/012024.

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35

Khalid, Omar, Muzaffar Ali, Nadeem Ahmed Sheikh, Hafiz M. Ali, and M. Shehryar. "Experimental analysis of an improved Maisotsenko cycle design under low velocity conditions." Applied Thermal Engineering 95 (February 2016): 288–95. http://dx.doi.org/10.1016/j.applthermaleng.2015.11.030.

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36

Pandelidis, Demis, Aleksandra Cichoń, Anna Pacak, Paweł Drąg, Marlena Drąg, William Worek, and Sabri Cetin. "Performance study of the cross-flow Maisotsenko cycle in humid climate conditions." International Communications in Heat and Mass Transfer 115 (June 2020): 104581. http://dx.doi.org/10.1016/j.icheatmasstransfer.2020.104581.

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37

Rogdakis, Emmanuel D., Irene P. Koronaki, and Dimitrios Nik Tertipis. "Experimental and computational evaluation of a Maisotsenko evaporative cooler at Greek climate." Energy and Buildings 70 (February 2014): 497–506. http://dx.doi.org/10.1016/j.enbuild.2013.10.013.

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38

Pandelidis, Demis, Sergey Anisimov, and William M. Worek. "Performance study of the Maisotsenko Cycle heat exchangers in different air-conditioning applications." International Journal of Heat and Mass Transfer 81 (February 2015): 207–21. http://dx.doi.org/10.1016/j.ijheatmasstransfer.2014.10.033.

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39

Pacak, Anna, Demis Pandelidis, and Sergey Anisimov. "Mathematical modelling of solid desiccant systems." ITM Web of Conferences 23 (2018): 00029. http://dx.doi.org/10.1051/itmconf/20182300029.

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In this study, the mathematical model equations for solid desiccant system integrated with indirect evaporative coolers with Maisotsenko - Cycle are presented. The authors chose the modified ε–NTU method to describe heat and mass transfer processes in regenerative indirect evaporative cooler and desiccant wheel. The models based on the ε–NTU method show satisfactory agreement with experimental results. That is why this method allows to analyze and develop the performance of solid desiccant systems. In this study, the models allowed to prove that solid desiccant system with an additional heat exchanger before the desiccant wheel (System 1) obtains higher thermal COP values, higher humidity ratio drop and lower supply airflow temperatures in comparison to system with only one heat exchanger after the desiccant wheel (System 2).
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40

Fang, Ranran, Zhonglin Pan, Jiangen Zheng, Xiaofa Wang, Rui Li, Chen Yang, Lianrui Deng, and Anatoliy Y. Vorobyev. "Evaporative and Wicking Functionalities at Hot Airflows of Laser Nano-/Microstructured Ti-6Al-4V Material." Nanomaterials 13, no. 1 (January 3, 2023): 218. http://dx.doi.org/10.3390/nano13010218.

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A novel multifunctional material with efficient wicking and evaporative functionalities was fabricated using hierarchical surface nano-/microstructuring by femtosecond laser micromachining. The created material exhibits excellent multifunctional performance. Our experiments in a wind tunnel demonstrate its good wicking and evaporative functionalities under the conditions of high-temperature airflows. An important finding of this work is the significantly enhanced evaporation rate of the created material compared with the free water surface. The obtained results provide a platform for the practical implementation of Maisotsenko-cycle cooling technologies for substantially increasing efficiency in power generation, thermal management, and other evaporation-based technologies. The developed multifunctional material demonstrates long-lasting wicking and evaporative functionalities that are resistant to degradation under high-temperature airflows, indicating its suitability for practical applications.
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41

Ali, Muzaffar, Nadeem Sheikh, Omar Khalid, Shehryar Manzoor, and Hafiz Ali. "Parametric investigation of a counter-flow heat and mass exchanger based on Maisotsenko cycle." Thermal Science 22, no. 6 Part B (2018): 3099–106. http://dx.doi.org/10.2298/tsci160808296a.

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42

Anisimov, Sergey, and Demis Pandelidis. "HEAT- AND MASS-TRANSFER PROCESESS IN INDIRECT EVAPORATIVE AIR CONDITIONERS THROUGH THE MAISOTSENKO CYCLE." International Journal of Energy for a Clean Environment 12, no. 2-4 (2011): 273–86. http://dx.doi.org/10.1615/interjenercleanenv.2012005770.

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43

Dizaji, Hamed Sadighi, Eric Hu, Lei Chen, Samira Pourhedayat, and Makatar Wae-hayee. "Proposing the concept of mini Maisotsenko cycle cooler for electronic cooling purposes; experimental study." Case Studies in Thermal Engineering 27 (October 2021): 101325. http://dx.doi.org/10.1016/j.csite.2021.101325.

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44

Saghafifar, Mohammad, and Mohamed Gadalla. "Analysis of Maisotsenko open gas turbine power cycle with a detailed air saturator model." Applied Energy 149 (July 2015): 338–53. http://dx.doi.org/10.1016/j.apenergy.2015.03.099.

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45

Saghafifar, Mohammad, Amr Omar, Sepehr Erfanmoghaddam, and Mohamed Gadalla. "Thermo-economic analysis of recuperated Maisotsenko bottoming cycle using triplex air saturator: Comparative analyses." Applied Thermal Engineering 111 (January 2017): 431–44. http://dx.doi.org/10.1016/j.applthermaleng.2016.09.100.

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46

Pandelidis, Demis, and Sergey Anisimov. "Numerical study and optimization of the cross-flow Maisotsenko cycle indirect evaporative air cooler." International Journal of Heat and Mass Transfer 103 (December 2016): 1029–41. http://dx.doi.org/10.1016/j.ijheatmasstransfer.2016.08.014.

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47

Zhu, Guangya, Weiwei Chen, and Shihua Lu. "Modelling of a dew-point effectiveness correlation for Maisotsenko cycle heat and mass exchanger." Chemical Engineering and Processing - Process Intensification 145 (November 2019): 107655. http://dx.doi.org/10.1016/j.cep.2019.107655.

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48

Fang, Ranran, Hongbo Zhu, Zekai Li, Xiaohui Zhu, Xianhang Zhang, Zhiyu Huang, Ke Li, et al. "Temperature Effect on Capillary Flow Dynamics in 1D Array of Open Nanotextured Microchannels Produced by Femtosecond Laser on Silicon." Nanomaterials 10, no. 4 (April 21, 2020): 796. http://dx.doi.org/10.3390/nano10040796.

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Capillary flow of water in an array of open nanotextured microgrooves fabricated by femtosecond laser processing of silicon is studied as a function of temperature using high-speed video recording. In a temperature range of 23–80 °C, the produced wicking material provides extremely fast liquid flow with a maximum velocity of 37 cm/s in the initial spreading stage prior to visco-inertial regime. The capillary performance of the material enhances with increasing temperature in the inertial, visco-inertial, and partially in Washburn flow regimes. The classic universal Washburn’s regime is observed at all studied temperatures, giving the evidence of its universality at high temperatures as well. The obtained results are of great significance for creating capillary materials for applications in cooling of electronics, energy harvesting, enhancing the critical heat flux of industrial boilers, and Maisotsenko cycle technologies.
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49

Sverdlin, Boris, Alexey Tikhonov, and Ritta Gelfand. "THEORETICAL POSSIBILITY OF THE MAISOTSENKO CYCLE APPLICATION TO DECREASE COLD WATER TEMPERATURE IN COOLING TOWERS." International Journal of Energy for a Clean Environment 12, no. 2-4 (2011): 175–85. http://dx.doi.org/10.1615/interjenercleanenv.2012005876.

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50

Stupak, Oleh, Artem Khalatov, Tetiana Donyk, and Oksana Shikhabutinova. "A study of new local heating and air conditioning schemes based on the Maisotsenko cycle." Eastern-European Journal of Enterprise Technologies 3, no. 8 (105) (June 30, 2020): 6–14. http://dx.doi.org/10.15587/1729-4061.2020.205047.

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