超疏水表面微通道内水的传热特性被引量：16

Heat transfer characteristics of water flowing in microchannels with super-hydrophobic inner surface

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摘要 Liquid convective heat transfer in microchannels exhibits high efficiency.However,the large pressure drop causes much concern for practical application.Water flowing in hydrophobic tubes shows low pressure drop owing to the slippage on the tube walls.Super-hydrophobic/hydrophilic micro aluminum tubes of 0.68mm inner diameter were fabricated with a two step procedure of chemical etching and then surface chemical modification.A kind of micro-nanometric hierarchical structure was formed on the surface,which could trap air serving as the slip agent.Heat transfer and fluid flow of deioned water flowing laminary in the super-hydrophobic/hydrophilic microchannels were studied experimentally.The results showed that the air-layer existing in the micro-nano hierarchical structures of the super-hydrophobic surface decreased flow resistance evidently but decreased heat transfer coefficient only a little,which was still higher than the superficial heat transfer coefficient while considering the heat conduction of stationary nanolayer of air.It was supposed that eddy flow was generated in the micro-nano bubbles by the slip flow of water on the tube wall,which enhanced the heat transfer. Liquid convective heat transfer in microchannels exhibits high efficiency. However, the large pressure drop causes much concern for practical application. Water flowing in hydrophobic tubes shows low pressure drop owing to the slippage on the tube walls. Super-hydrophobic/hydrophilic micro aluminum tubes of 0.68mm inner diameter were fabricated with a two step procedure of chemical etching and then surface chemical modification. A kind of micro-nanometric hierarchical structure was formed on the surface, which could trap air serving as the slip agent. Heat transfer and fluid flow of deioned water flowing laminary in the super-hydrophobic/hydrophilic microchannels were studied experimentally. The results showed that the air-layer existing in the micro-nano hierarchical structures of the super-hydrophobic surface decreased flow resistance evidently but decreased heat transfer coefficient only a little, which was still higher than the superficial heat transfer coefficient while considering the heat conduction of stationary nanolayer of air. It was supposed that eddy flow was generated in the micro-nano bubbles by the slip flow of water on the tube wall, which enhanced the heat transfer.

作者宋善鹏于志家刘兴华秦福涛方薪晖孙相彧

机构地区大连理工大学化工学院

出处《化工学报》 EI CAS CSCD 北大核心 2008年第10期2465-2469,共5页 CIESC Journal

基金国家自然科学基金项目(20476014)~~

关键词超疏水微通道流动阻力表面传热系数滑移 super-hydrophobic microchannel flow resistance surface heat transfer coefficient slip

分类号 TQ021.3 [化学工程]

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超疏水表面微通道内水的传热特性被引量：16

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超疏水表面微通道内水的传热特性 被引量：16

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超疏水表面微通道内水的传热特性被引量：16