Numerical and Experimental Study on the Heat Dissipation Performance of a Novel System

Numerical and Experimental Study on the Heat Dissipation Performance of a Novel System

In order to better release the heat generated by the electronic components, a novel heat dissipation system is proposed, which combines a microchannel heat pipe (MHP) with a high thermal conductivity and a radiative plate with a high emissivity at nighttime. First, a simple testing rig was made with...

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Main Authors: Cairui Yu, Dongmei Shen, Qingyang Jiang, Wei He, Hancheng Yu, Zhongting Hu, Hongbing Chen, Pengkun Yu, Sheng Zhang
Format: Article
Language:English
Published: MDPI AG 2019-12-01
Series:Energies
Subjects:
electronic cooling
microchannel pipe
radiative cooling
numerical study
Online Access:https://www.mdpi.com/1996-1073/13/1/106
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spelling doaj-c4c51774429944e7a7398158358d20032020-11-25T02:18:06ZengMDPI AGEnergies1996-10732019-12-0113110610.3390/en13010106en13010106Numerical and Experimental Study on the Heat Dissipation Performance of a Novel SystemCairui Yu0Dongmei Shen1Qingyang Jiang2Wei He3Hancheng Yu4Zhongting Hu5Hongbing Chen6Pengkun Yu7Sheng Zhang8Department of Building Environment and Equipment, Hefei University of Technology, Hefei 230009, ChinaDepartment of Architecture and Civil Engineering, West Anhui University, Lu’an 237012, ChinaCollege of Civil Engineering and Architecture, Jiaxing University, Jiaxing 314001, ChinaDepartment of Building Environment and Equipment, Hefei University of Technology, Hefei 230009, ChinaQinghai College of Architectural Technology, Xining 810002, ChinaDepartment of Building Environment and Equipment, Hefei University of Technology, Hefei 230009, ChinaSchool of Environment and Energy Engineering, Beijing University of Civil Engineering and Architecture, Beijing 100044, ChinaDepartment of Building Environment and Equipment, Hefei University of Technology, Hefei 230009, ChinaDepartment of Building Environment and Equipment, Hefei University of Technology, Hefei 230009, ChinaIn order to better release the heat generated by the electronic components, a novel heat dissipation system is proposed, which combines a microchannel heat pipe (MHP) with a high thermal conductivity and a radiative plate with a high emissivity at nighttime. First, a simple testing rig was made with an MHP and a radiative plate, where the radiative plate was made of acrylic resin, a curing agent, thinner, and aluminum plate, and had strong radiative cooling at nighttime. Second, the mathematical model was initially established and verified using experiments, where it was shown that the agreement between numerical and experimental data was well within experimental uncertainties. Comprehensive simulation investigations were conducted by varying wind speed, relative humidity, the cloudiness coefficient, dimension of the radiative plate, and tilted angle. The results show that: (1) the emissivity of the radiative plate was about 0.311 in the daytime and about 0.908 in the nighttime; (2) the influence of wind speed on reducing the component surface temperature was greater than the cloudiness coefficient and relative humidity; (3) the width of the radiative plate had a greater effect on heat dissipation than on its length, and the maximum size of radiative plate was recommended to be 400 mm × 400−500 mm (length × width), which was equipped with a single MHP (width: 60 mm). Additionally, the tilted angle of the radiative plate should be kept within 30° of the horizontal level. In conclusion, the novel heat dissipation system had a superior application value for providing assisted electronic component cooling in the nighttime.https://www.mdpi.com/1996-1073/13/1/106electronic coolingmicrochannel piperadiative coolingnumerical study
collection DOAJ
language English
format Article
sources DOAJ
author Cairui Yu
Dongmei Shen
Qingyang Jiang
Wei He
Hancheng Yu
Zhongting Hu
Hongbing Chen
Pengkun Yu
Sheng Zhang
spellingShingle Cairui Yu
Dongmei Shen
Qingyang Jiang
Wei He
Hancheng Yu
Zhongting Hu
Hongbing Chen
Pengkun Yu
Sheng Zhang
Numerical and Experimental Study on the Heat Dissipation Performance of a Novel System
Energies
electronic cooling
microchannel pipe
radiative cooling
numerical study
author_facet Cairui Yu
Dongmei Shen
Qingyang Jiang
Wei He
Hancheng Yu
Zhongting Hu
Hongbing Chen
Pengkun Yu
Sheng Zhang
author_sort Cairui Yu
title Numerical and Experimental Study on the Heat Dissipation Performance of a Novel System
title_short Numerical and Experimental Study on the Heat Dissipation Performance of a Novel System
title_full Numerical and Experimental Study on the Heat Dissipation Performance of a Novel System
title_fullStr Numerical and Experimental Study on the Heat Dissipation Performance of a Novel System
title_full_unstemmed Numerical and Experimental Study on the Heat Dissipation Performance of a Novel System
title_sort numerical and experimental study on the heat dissipation performance of a novel system
publisher MDPI AG
series Energies
issn 1996-1073
publishDate 2019-12-01
description In order to better release the heat generated by the electronic components, a novel heat dissipation system is proposed, which combines a microchannel heat pipe (MHP) with a high thermal conductivity and a radiative plate with a high emissivity at nighttime. First, a simple testing rig was made with an MHP and a radiative plate, where the radiative plate was made of acrylic resin, a curing agent, thinner, and aluminum plate, and had strong radiative cooling at nighttime. Second, the mathematical model was initially established and verified using experiments, where it was shown that the agreement between numerical and experimental data was well within experimental uncertainties. Comprehensive simulation investigations were conducted by varying wind speed, relative humidity, the cloudiness coefficient, dimension of the radiative plate, and tilted angle. The results show that: (1) the emissivity of the radiative plate was about 0.311 in the daytime and about 0.908 in the nighttime; (2) the influence of wind speed on reducing the component surface temperature was greater than the cloudiness coefficient and relative humidity; (3) the width of the radiative plate had a greater effect on heat dissipation than on its length, and the maximum size of radiative plate was recommended to be 400 mm × 400−500 mm (length × width), which was equipped with a single MHP (width: 60 mm). Additionally, the tilted angle of the radiative plate should be kept within 30° of the horizontal level. In conclusion, the novel heat dissipation system had a superior application value for providing assisted electronic component cooling in the nighttime.
topic electronic cooling
microchannel pipe
radiative cooling
numerical study
url https://www.mdpi.com/1996-1073/13/1/106
work_keys_str_mv AT cairuiyu numericalandexperimentalstudyontheheatdissipationperformanceofanovelsystem
AT dongmeishen numericalandexperimentalstudyontheheatdissipationperformanceofanovelsystem
AT qingyangjiang numericalandexperimentalstudyontheheatdissipationperformanceofanovelsystem
AT weihe numericalandexperimentalstudyontheheatdissipationperformanceofanovelsystem
AT hanchengyu numericalandexperimentalstudyontheheatdissipationperformanceofanovelsystem
AT zhongtinghu numericalandexperimentalstudyontheheatdissipationperformanceofanovelsystem
AT hongbingchen numericalandexperimentalstudyontheheatdissipationperformanceofanovelsystem
AT pengkunyu numericalandexperimentalstudyontheheatdissipationperformanceofanovelsystem
AT shengzhang numericalandexperimentalstudyontheheatdissipationperformanceofanovelsystem
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