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Abstract

The conventional desert cooler is effective for dry seasons and the regenerative evaporative cooler (REC) is an effective device for humid seasons in composite climate zones. Hence, the dual-mode evaporative cooler (a two-in-one device) is an intelligent choice for air conditioning, which can operate in both direct and regenerative modes depending on the seasonal climatic condition. The exergy and economic analyses of this novel device for global climatic conditions are performed to check the suitability in different regions of the world. An experimental prototype of a dual-mode evaporative cooler is developed and tested to validate the simulation model. The effectiveness, coefficient of performance, exergy destruction, exergy efficiency, operating cost, and specific total cost (STC) are evaluated for both (direct and regenerative) modes of operation. The annual and month-wise performances of dual-mode evaporative cooler have been assessed for five cities of international climate zones. The operating cost of both modes is compared by considering electricity charges in different countries. The dual-mode device is compared with the single-mode device as well. The specific cost is similar for both modes in most of the ASHRAE climatic zones. The present study reveals that significant energy and cost savings are possible by using the dual-mode evaporative cooler.

Practical application: This article considers the application of a dual-mode evaporative cooler (direct as well as regenerative mode) in different climate zones and, through investigating the exergy and economic performances, allows designers and operators to understand the potential benefits of employing various operating modes in particular climates.

Keywords

Dual-mode evaporative cooler experimentation coefficient of performance wet bulb effectiveness exergy destruction specific total cost

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References

Al-Juwayhel

El-Dessouky

Ettouney

, et al. Experimental evaluation of one, two, and three stage evaporative cooling systems. Heat Transfer Eng 2004; 25: 72–86.

Yan

Chen

Zhang

. Year-round-based optimization of high‐low control in the regenerative indirect evaporative cooler (RIEC). Sci Tech Built Environ 2019; 25: 1394–1405.

Kashyap

Sarkar

Kumar

. Proposal and month-wise performance evaluation of a novel dual-mode evaporative cooler. Heat Mass Transfer 2019; 55: 3523–3536.

Chengqin

Nianping

Guangfa

. Principles of exergy analysis in HVAC and evaluation of evaporative cooling schemes. Build Environ 2002; 37: 1045–1055.

Farmahini-Farahani

Delfani

Esmaeelian

. Exergy analysis of evaporative cooling to select the optimum system in diverse climates. Energy 2012; 40: 250–257.

Caliskan

Dincer

Hepbasli

. Exergoeconomic, enviroeconomic and sustainability analyses of a novel air cooler. Energy Build 2012; 55: 747–756.

Duan

Zhao

Zhan

, et al. Energy saving potential of a counter-flow regenerative evaporative cooler for various climates of China: experiment-based evaluation. Energy Build 2017; 148: 199–210.

Jafarian

Sayyaadi

Torabi

. A numerical model for a dew-point counter-flow indirect evaporative cooler using a modified boundary condition and considering effects of entrance regions. Int J Refrig 2017; 84: 36–51.

Lin

Bui

Wang

, et al. On the exergy analysis of the counter-flow dew point evaporative cooler. Energy 2018; 165: 958–971.

10.

Sohani

Sayyaadi

. Thermal comfort based resources consumption and economic analysis of a two-stage direct-indirect evaporative cooler with diverse water to electricity tariff conditions. Energ Convers Manag 2018; 172: 248–264.

11.

Baakeem

Orfi

Bessadok-Jemai

. Thermodynamic and economic analysis of the performance of a direct evaporative cooler working under extreme summer weather conditions. J Mech Sci Tech 2018; 32: 1815–1825.

12.

Arun

Mariappan

. Experimental study of an ultrasonic regenerative evaporative cooler for a desiccant cooling system. Build Serv Eng Res Tech 2018; 40: 151–175.

13.

Pakari

Ghani

. Comparison of 1D and 3D heat and mass transfer models of a counter flow dew point evaporative cooling system: numerical and experimental study. Int J Refrig 2019; 99: 114–125.

14.

Cui

Yang

Kong

, et al. Performance evaluation and comparison of multistage indirect evaporative cooling systems in two operation modes. Int J Energ Res 2020; 44: 9298–9308.

15.

Wang

Zhan

Zhang

, et al. The energy and exergy analysis on the performance of counter-flow heat and mass exchanger for M-cycle indirect evaporative cooling. Therm Sci 2019; 23: 613–623.

16.

Kashyap

Sarkar

Kumar

. Exergy, economic, environmental and sustainability analyses of possible regenerative evaporative cooling device topologies. Build Environ 2020; 180: 107033.

17.

ASHRAE handbook: fundamentals American Society of Heating. Atlanta: Refrigerating and Air-Conditioning Engineers, 2009.

18.

Lin

Thu

Bui

, et al. Unsteady-state analysis of a counter-flow dew point evaporative cooling system. Energy 2016; 113: 172–185.

19.

Moshari

Heidarinejad

. Numerical study of regenerative evaporative coolers for sub-wet bulb cooling with cross- and counter-flow configuration. Appl Therm Eng 2015; 89: 669–683.

20.

Duan

Zhan

Zhao

, et al. Experimental study of a counter-flow regenerative evaporative cooler. Build Environ 2016; 104: 47–58.

21.

Ren

Yang

. An analytical model for the heat and mass transfer processes in indirect evaporative cooling with parallel/counter flow configurations. Int J Heat Mass Transfer 2006; 49: 617–627.

22.

Klein

. Engineering equation solver professional. Version V10.215. Madison, WI: F-Chart Software, 2017.

23.

Duan

. Investigation of a novel dew point indirect evaporative air conditioning system for buildings. PhD thesis, Nottingham, UK: University of Nottingham, 2011.

24.

Zhao

Riffat

. Numerical study of a novel counter-flow heat and mass exchanger for dew point evaporative cooling. Appl Therm Eng 2008; 28: 1942–1951.

25.

Kashyap

Sarkar

Kumar

. Development and experimental analysis of a novel dual-mode counter-flow evaporative cooling device. Build Environ 2021; 205: 108176.

26.

Riangvilaikul

Kumar

. An experimental study of a novel dew point evaporative cooling system. Energy Build 2010; 42: 637–644.

27.

Zhu

Chow

T-T

Lee

. Performance analysis of counter-flow regenerative heat and mass exchanger for indirect evaporative cooling based on data-driven model. Energy Build 2017; 155: 503–512.

Energy,exergy and economic assessments of the dual-mode evaporative cooler for various international climate zones

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