SCI和EI收录∣中国化工学会会刊

中国化学工程学报 ›› 2020, Vol. 28 ›› Issue (4): 980-994.DOI: 10.1016/j.cjche.2020.01.007

• Fluid Dynamics and Transport Phenomena • 上一篇    下一篇

CFD investigation of the feasibility of polymer-based microchannel heat sink as thermal solution

Yue Seong Ong, KuZilati KuShaari   

  1. Department of Chemical Engineering, University Teknologi PETRONAS, Seri Iskandar, Malaysia
  • 收稿日期:2019-12-16 修回日期:2020-01-14 出版日期:2020-04-28 发布日期:2020-07-27
  • 通讯作者: Yue Seong Ong, KuZilati KuShaari
  • 基金资助:
    This work was supported by The Murata Science Foundation [grant numbers 015ME0-031].

CFD investigation of the feasibility of polymer-based microchannel heat sink as thermal solution

Yue Seong Ong, KuZilati KuShaari   

  1. Department of Chemical Engineering, University Teknologi PETRONAS, Seri Iskandar, Malaysia
  • Received:2019-12-16 Revised:2020-01-14 Online:2020-04-28 Published:2020-07-27
  • Contact: Yue Seong Ong, KuZilati KuShaari
  • Supported by:
    This work was supported by The Murata Science Foundation [grant numbers 015ME0-031].

摘要: Microchannel heat sinks (MCHSs) are promising thermal solutions in miniaturized or compact devices. Lightweight aspect has been given huge emphasis in recent years. Metal-based materials are commonly used to fabricate MCHSs due to their high thermal conductivity. Consequently, MCHSs are heavy due to the high density of these materials albeit the small footprint of MCHSs. Polymer-based materials are interesting alternatives. Despite their poor thermal conductivity, lightweight feature attracts the interest of researchers. Heat transfer is a conjugate process of heat conduction and heat convection. Poor heat conductions aspect may be compensated through enhancement of heat convection aspects. Although polymer-based materials have been used in microscale heat transfer studies, their focus was not on their feasibility. The present study aims to evaluate the feasibility of polymer-based MCHSs as thermal solutions. The effect of thermal conductivity of fabrication materials, including polymer-based PDMS, PTFE, PDMS/MWCNT, and metal-based aluminum, on the thermal performance of MCHSs was investigated and compared at various inlet flow rate, fluid thermal conductivity, and microchannel ratio at different constant heat fluxes using three-dimensional CFD approach. Results showed that the thermal performance of MCHSs was greatly affected by the heat conduction aspect in which poor heat conduction limited the thermal performance improvement due to enhanced heat convection aspects. This suggests polymer-based materials have the potential for heat transfer applications through thermal conductivity enhancement. This was confirmed in the further analysis using a recently proposed high thermal conductivity polymer-based graphite/epoxy MCHS and a hybrid-based PDMS/aluminum MCHS.

关键词: Microchannel heat sink, Thermal performance, Thermal conductivity, Microchannel ratio, Computational fluid dynamic

Abstract: Microchannel heat sinks (MCHSs) are promising thermal solutions in miniaturized or compact devices. Lightweight aspect has been given huge emphasis in recent years. Metal-based materials are commonly used to fabricate MCHSs due to their high thermal conductivity. Consequently, MCHSs are heavy due to the high density of these materials albeit the small footprint of MCHSs. Polymer-based materials are interesting alternatives. Despite their poor thermal conductivity, lightweight feature attracts the interest of researchers. Heat transfer is a conjugate process of heat conduction and heat convection. Poor heat conductions aspect may be compensated through enhancement of heat convection aspects. Although polymer-based materials have been used in microscale heat transfer studies, their focus was not on their feasibility. The present study aims to evaluate the feasibility of polymer-based MCHSs as thermal solutions. The effect of thermal conductivity of fabrication materials, including polymer-based PDMS, PTFE, PDMS/MWCNT, and metal-based aluminum, on the thermal performance of MCHSs was investigated and compared at various inlet flow rate, fluid thermal conductivity, and microchannel ratio at different constant heat fluxes using three-dimensional CFD approach. Results showed that the thermal performance of MCHSs was greatly affected by the heat conduction aspect in which poor heat conduction limited the thermal performance improvement due to enhanced heat convection aspects. This suggests polymer-based materials have the potential for heat transfer applications through thermal conductivity enhancement. This was confirmed in the further analysis using a recently proposed high thermal conductivity polymer-based graphite/epoxy MCHS and a hybrid-based PDMS/aluminum MCHS.

Key words: Microchannel heat sink, Thermal performance, Thermal conductivity, Microchannel ratio, Computational fluid dynamic