Thermal dissipation performance of metal-polymer composite heat exchanger with V-shape microgrooves: A numerical and experimental study

•A metal-polymer composite heat exchanger with V-shape microgrooves was proposed.•The relationship between thermal conduction flux and thickness of single layer polymer was discussed.•The governing equations of heat exchanger were established and solved by iterative solution.•Four basic design crite...

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Published inApplied thermal engineering Vol. 121; pp. 492 - 500
Main Authors Sun, Jingyao, Zhuang, Jian, Jiang, Hui, Huang, Yao, Zheng, Xiuting, Liu, Ying, Wu, Daming
Format Journal Article
LanguageEnglish
Published Oxford Elsevier Ltd 05.07.2017
Elsevier BV
Subjects
Aluminum
Apex angle
Dissipation
Emissivity
Energy dissipation
Heat exchangers
Heat transfer
Integrated circuits
Low cost
Mathematical analysis
Mathematical models
Metal-polymer composite
Microstructure
Microstructure heat exchanger
Numerical analysis
Power consumption
Shape
Thermal conductivity
Thermal dissipation performance
V-shape microgroove
V-shape microgroove
Thermal dissipation performance
Metal-polymer composite
Microstructure heat exchanger
Online AccessGet full text
ISSN1359-4311
1873-5606
DOI10.1016/j.applthermaleng.2017.04.104

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Abstract •A metal-polymer composite heat exchanger with V-shape microgrooves was proposed.•The relationship between thermal conduction flux and thickness of single layer polymer was discussed.•The governing equations of heat exchanger were established and solved by iterative solution.•Four basic design criterions were proposed based on numerical analysis results.•A self-made testing platform was established to obtain real time data in experimental study. Nowadays, power consumption and heat output problems are becoming more and more serious with the rapid development of multi-functional and high integration density systems. The installation space for heat exchangers is also getting smaller and smaller. Thus, the need for efficient thermal dissipation performance within limited space becomes one of the major topics in this field. In this paper, a new kind of metal-polymer composite heat exchanger with V-shape microgrooves is proposed. The physical model and governing equation of it are established under several suitable assumptions. The influences of some key factors (half apex angle, thermal conductivity coefficient, radiant emissivity, etc.) on thermal dissipation performance of metal-polymer composite heat exchanger are investigated by numerical computation method. Furthermore, a comparison of the thermal dissipation performances between commercial aluminum heat exchanger and metal-polymer composite heat exchanger with V-shape microgrooves is performed. Results show that although the spatial volume of metal-polymer composite heat exchanger is only one-fifth of that of aluminum heat exchanger, their thermal dissipation performance is almost the same. As metal-polymer composite heat exchanger has the advantages of high processing efficiency, low cost, light weighted and space saving, it will play an important role in the field of heat exchanger undoubtedly in the near future.
AbstractList •A metal-polymer composite heat exchanger with V-shape microgrooves was proposed.•The relationship between thermal conduction flux and thickness of single layer polymer was discussed.•The governing equations of heat exchanger were established and solved by iterative solution.•Four basic design criterions were proposed based on numerical analysis results.•A self-made testing platform was established to obtain real time data in experimental study. Nowadays, power consumption and heat output problems are becoming more and more serious with the rapid development of multi-functional and high integration density systems. The installation space for heat exchangers is also getting smaller and smaller. Thus, the need for efficient thermal dissipation performance within limited space becomes one of the major topics in this field. In this paper, a new kind of metal-polymer composite heat exchanger with V-shape microgrooves is proposed. The physical model and governing equation of it are established under several suitable assumptions. The influences of some key factors (half apex angle, thermal conductivity coefficient, radiant emissivity, etc.) on thermal dissipation performance of metal-polymer composite heat exchanger are investigated by numerical computation method. Furthermore, a comparison of the thermal dissipation performances between commercial aluminum heat exchanger and metal-polymer composite heat exchanger with V-shape microgrooves is performed. Results show that although the spatial volume of metal-polymer composite heat exchanger is only one-fifth of that of aluminum heat exchanger, their thermal dissipation performance is almost the same. As metal-polymer composite heat exchanger has the advantages of high processing efficiency, low cost, light weighted and space saving, it will play an important role in the field of heat exchanger undoubtedly in the near future.
Nowadays, power consumption and heat output problems are becoming more and more serious with the rapid development of multi-functional and high integration density systems. The installation space for heat exchangers is also getting smaller and smaller. Thus, the need for efficient thermal dissipation performance within limited space becomes one of the major topics in this field. In this paper, a new kind of metal-polymer composite heat exchanger with V-shape microgrooves is proposed. The physical model and governing equation of it are established under several suitable assumptions. The influences of some key factors (half apex angle, thermal conductivity coefficient, radiant emissivity, etc.) on thermal dissipation performance of metal-polymer composite heat exchanger are investigated by numerical computation method. Furthermore, a comparison of the thermal dissipation performances between commercial aluminum heat exchanger and metal-polymer composite heat exchanger with V-shape microgrooves is performed. Results show that although the spatial volume of metal-polymer composite heat exchanger is only one-fifth of that of aluminum heat exchanger, their thermal dissipation performance is almost the same. As metal-polymer composite heat exchanger has the advantages of high processing efficiency, low cost, light weighted and space saving, it will play an important role in the field of heat exchanger undoubtedly in the near future.
Author Sun, Jingyao
Zheng, Xiuting
Liu, Ying
Jiang, Hui
Zhuang, Jian
Huang, Yao
Wu, Daming
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  organization: College of Mechanical and Electrical Engineering, Beijing University of Chemical Technology, Beijing 100029, China
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Keywords V-shape microgroove
Thermal dissipation performance
Metal-polymer composite
Microstructure heat exchanger
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Snippet •A metal-polymer composite heat exchanger with V-shape microgrooves was proposed.•The relationship between thermal conduction flux and thickness of single...
Nowadays, power consumption and heat output problems are becoming more and more serious with the rapid development of multi-functional and high integration...
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StartPage 492
SubjectTerms Aluminum
Apex angle
Dissipation
Emissivity
Energy dissipation
Heat exchangers
Heat transfer
Integrated circuits
Low cost
Mathematical analysis
Mathematical models
Metal-polymer composite
Microstructure
Microstructure heat exchanger
Numerical analysis
Power consumption
Shape
Thermal conductivity
Thermal dissipation performance
V-shape microgroove
Title Thermal dissipation performance of metal-polymer composite heat exchanger with V-shape microgrooves: A numerical and experimental study
URI https://dx.doi.org/10.1016/j.applthermaleng.2017.04.104
https://www.proquest.com/docview/1932400225
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