Thermal performance analysis of pool boiling on an enhanced surface modified by the combination of microstructures and wetting properties

Thermal performance analysis of pool boiling on an enhanced surface modified by the combination of microstructures and wetting properties

•Transient simulation of the saturated pool boiling on the surfaces with microstructures was carried out.•Effect of wetting properties on superheat temperature and HTC of saturated pool boiling was connected with microstructures’ size.•The heat transfer performance of saturated pool boiling was enha...

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Veröffentlicht in:Applied thermal engineering 2017-05, Vol.117, p.417-426
Hauptverfasser: Zhao, Zhongchao, Zhang, Jiaojiao, Jia, Dandan, Zhao, Kai, Zhang, Xiao, Jiang, Pengpeng
Format: Artikel
Sprache:eng
Schlagworte:
Bubbles
Computer simulation
Fluid dynamics
Heat flux
Heat transfer
Heat transfer coefficients
Mathematical analysis
Mathematical models
Microstructure
Numerical analysis
Numerical simulation
Pool boiling
Simulation
Studies
Two dimensional models
Volume of fluid
Wetting
Wetting properties
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container_end_page 426
container_issue
container_start_page 417
container_title Applied thermal engineering
container_volume 117
creator Zhao, Zhongchao
Zhang, Jiaojiao
Jia, Dandan
Zhao, Kai
Zhang, Xiao
Jiang, Pengpeng
description •Transient simulation of the saturated pool boiling on the surfaces with microstructures was carried out.•Effect of wetting properties on superheat temperature and HTC of saturated pool boiling was connected with microstructures’ size.•The heat transfer performance of saturated pool boiling was enhanced on the surface modified by the combination of microstructures and wetting properties. Characterized by low temperature difference and high heat flux, pool boiling heat transfer has been widely applied in various engineering technical fields. The aim of this study was to explore the thermal performance of pool boiling heat transfer on an enhanced surface modified by the combination of microstructures and wetting properties. The two-dimensional transient volume of fluid model and numerical simulation were selected to investigate each case which was established. Variation of the vapor bubble behavior, the velocity field of computational domain, the temperature at the liquid/solid interface and heat transfer coefficient (HTC) of each case were analyzed. The heat transfer performances of mixed hydrophilic and hydrophobic microstructures were all superior to those of hydrophilic microstructures only, except the flat. With respect to hydrophilic microstructures, the average growth rates of HTC for mixed hydrophilic and hydrophobic microstructures were 17.59%, 21.59%, 2.74% and 3.81% when the heights of microstructures were 3μm, 5 7, 7μm and 9μm, respectively. Moreover, the average growth rate of HTC for mixed hydrophilic and hydrophobic microstructures decreased by 12.44%, 5.31% and 5.21% with increasing width.
doi_str_mv 10.1016/j.applthermaleng.2017.02.014
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Characterized by low temperature difference and high heat flux, pool boiling heat transfer has been widely applied in various engineering technical fields. The aim of this study was to explore the thermal performance of pool boiling heat transfer on an enhanced surface modified by the combination of microstructures and wetting properties. The two-dimensional transient volume of fluid model and numerical simulation were selected to investigate each case which was established. Variation of the vapor bubble behavior, the velocity field of computational domain, the temperature at the liquid/solid interface and heat transfer coefficient (HTC) of each case were analyzed. The heat transfer performances of mixed hydrophilic and hydrophobic microstructures were all superior to those of hydrophilic microstructures only, except the flat. With respect to hydrophilic microstructures, the average growth rates of HTC for mixed hydrophilic and hydrophobic microstructures were 17.59%, 21.59%, 2.74% and 3.81% when the heights of microstructures were 3μm, 5 7, 7μm and 9μm, respectively. 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Characterized by low temperature difference and high heat flux, pool boiling heat transfer has been widely applied in various engineering technical fields. The aim of this study was to explore the thermal performance of pool boiling heat transfer on an enhanced surface modified by the combination of microstructures and wetting properties. The two-dimensional transient volume of fluid model and numerical simulation were selected to investigate each case which was established. Variation of the vapor bubble behavior, the velocity field of computational domain, the temperature at the liquid/solid interface and heat transfer coefficient (HTC) of each case were analyzed. The heat transfer performances of mixed hydrophilic and hydrophobic microstructures were all superior to those of hydrophilic microstructures only, except the flat. 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Characterized by low temperature difference and high heat flux, pool boiling heat transfer has been widely applied in various engineering technical fields. The aim of this study was to explore the thermal performance of pool boiling heat transfer on an enhanced surface modified by the combination of microstructures and wetting properties. The two-dimensional transient volume of fluid model and numerical simulation were selected to investigate each case which was established. Variation of the vapor bubble behavior, the velocity field of computational domain, the temperature at the liquid/solid interface and heat transfer coefficient (HTC) of each case were analyzed. The heat transfer performances of mixed hydrophilic and hydrophobic microstructures were all superior to those of hydrophilic microstructures only, except the flat. With respect to hydrophilic microstructures, the average growth rates of HTC for mixed hydrophilic and hydrophobic microstructures were 17.59%, 21.59%, 2.74% and 3.81% when the heights of microstructures were 3μm, 5 7, 7μm and 9μm, respectively. Moreover, the average growth rate of HTC for mixed hydrophilic and hydrophobic microstructures decreased by 12.44%, 5.31% and 5.21% with increasing width.</abstract><cop>Oxford</cop><pub>Elsevier Ltd</pub><doi>10.1016/j.applthermaleng.2017.02.014</doi><tpages>10</tpages></addata></record>
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source Elsevier ScienceDirect Journals
subjects Bubbles
Computer simulation
Fluid dynamics
Heat flux
Heat transfer
Heat transfer coefficients
Mathematical analysis
Mathematical models
Microstructure
Numerical analysis
Numerical simulation
Pool boiling
Simulation
Studies
Two dimensional models
Volume of fluid
Wetting
Wetting properties
title Thermal performance analysis of pool boiling on an enhanced surface modified by the combination of microstructures and wetting properties
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