A numerical and experimental study on the energy efficiency of a regenerative Heat and Mass Exchanger utilizing the counter-flow Maisotsenko cycle
نویسنده:
, , , , , , , , , , ,سال
: 2020
چکیده: In this work, a numerical and experimental study is performed to evaluate the affecting variables on
energy efficiency of a novel regenerative evaporative cooler utilizing dew-point indirect evaporative
cooling. For first time, an investigation is experimentally and numerically carried out to study the
effects of the channel number on important parameters such as product temperature and humidity
ratio. Investigations are carried out for five configurations with various channel numbers. The comparison of the numerical and experimental results is obtained and well accuracy observed. For the
five studied configurations, the results show that with an increase in the number of channels, the
outlet temperature decreases. For an inlet air flow rate of 100–600 m3/h, the cooled outlet flow temperature changes to the range of 23.4–30.7°C, 19.7–28.3°C, 18–26.4°C, 17.2–25°C and 16.6–23.8°C.
For the configurations with finned channels, the percentage of increase in produced air temperature
reaches 11.5% for HMX B, 18.6% for HMX C, 23.4% for HMX D and 26.9% for HMX E, as compared with
HMX A.
energy efficiency of a novel regenerative evaporative cooler utilizing dew-point indirect evaporative
cooling. For first time, an investigation is experimentally and numerically carried out to study the
effects of the channel number on important parameters such as product temperature and humidity
ratio. Investigations are carried out for five configurations with various channel numbers. The comparison of the numerical and experimental results is obtained and well accuracy observed. For the
five studied configurations, the results show that with an increase in the number of channels, the
outlet temperature decreases. For an inlet air flow rate of 100–600 m3/h, the cooled outlet flow temperature changes to the range of 23.4–30.7°C, 19.7–28.3°C, 18–26.4°C, 17.2–25°C and 16.6–23.8°C.
For the configurations with finned channels, the percentage of increase in produced air temperature
reaches 11.5% for HMX B, 18.6% for HMX C, 23.4% for HMX D and 26.9% for HMX E, as compared with
HMX A.
شناسه الکترونیک: 10.1080/19942060.2019.1617193
کلیدواژه(گان): ounter-flow configuration,
heat and mass transfer
modeling,Maisotsenko cycle,
regenerative evaporative
cooling,number of channels
کالکشن
:
-
آمار بازدید
A numerical and experimental study on the energy efficiency of a regenerative Heat and Mass Exchanger utilizing the counter-flow Maisotsenko cycle
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| contributor author | Ali Mohammad Ez Abadi | en |
| contributor author | Meisam Sadi | en |
| contributor author | محمود فرزانه گرد | en |
| contributor author | Mohammad Hossein Ahmadi | en |
| contributor author | RavinderKumar | en |
| contributor author | Kwok-wing Chau | en |
| contributor author | Ali Mohammad Ez Abadi | fa |
| contributor author | Meisam Sadi | fa |
| contributor author | Mahmood Farzaneh-Gord | fa |
| contributor author | Mohammad Hossein Ahmadi | fa |
| contributor author | RavinderKumar | fa |
| contributor author | Kwok-wing Chau | fa |
| date accessioned | 2020-06-06T13:47:37Z | |
| date available | 2020-06-06T13:47:37Z | |
| date issued | 2020 | |
| identifier uri | http://libsearch.um.ac.ir:80/fum/handle/fum/3369246?locale-attribute=fa | |
| description abstract | In this work, a numerical and experimental study is performed to evaluate the affecting variables on energy efficiency of a novel regenerative evaporative cooler utilizing dew-point indirect evaporative cooling. For first time, an investigation is experimentally and numerically carried out to study the effects of the channel number on important parameters such as product temperature and humidity ratio. Investigations are carried out for five configurations with various channel numbers. The comparison of the numerical and experimental results is obtained and well accuracy observed. For the five studied configurations, the results show that with an increase in the number of channels, the outlet temperature decreases. For an inlet air flow rate of 100–600 m3/h, the cooled outlet flow temperature changes to the range of 23.4–30.7°C, 19.7–28.3°C, 18–26.4°C, 17.2–25°C and 16.6–23.8°C. For the configurations with finned channels, the percentage of increase in produced air temperature reaches 11.5% for HMX B, 18.6% for HMX C, 23.4% for HMX D and 26.9% for HMX E, as compared with HMX A. | en |
| language | English | |
| title | A numerical and experimental study on the energy efficiency of a regenerative Heat and Mass Exchanger utilizing the counter-flow Maisotsenko cycle | en |
| type | Journal Paper | |
| contenttype | External Fulltext | |
| subject keywords | ounter-flow configuration | en |
| subject keywords | heat and mass transfer modeling | en |
| subject keywords | Maisotsenko cycle | en |
| subject keywords | regenerative evaporative cooling | en |
| subject keywords | number of channels | en |
| identifier doi | 10.1080/19942060.2019.1617193 | |
| journal title | Engineering Applications of Computational Fluid Mechanics | fa |
| pages | 12-Jan | |
| journal volume | 14 | |
| journal issue | 1 | |
| identifier link | https://profdoc.um.ac.ir/paper-abstract-1076999.html | |
| identifier articleid | 1076999 |