Xiulan Huai scite author profile

Xiulan Huai

3Publications

0Citation Statements Received

29Citation Statements Given

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Affiliations

Institute of Engineering Thermophysics, Chinese Academy of Sciences, Nanjing Institute of Technology

Publications

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Enhancing pool boiling heat transfer of modified surface by 3-D Lattice Boltzmann method

et al. 2024

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In this study, pool boiling from micro-pillar modified surface has been simulated numerically by a 3D Lattice Boltzmann method(LBM). Effects of geometries and wettability of micro-pillaron boiling heat transfer performance were also systematically evaluated. Result showed that compared with in micro-pillar surface, heat flux of cubic micro-pillar surface was the highest with the lowest wall temperature. In addition, compared to hydrophilic condition, Heat flux of cubic micro-pillar surface with hydrophobic wettability increased by 98.3%. This is because hydrophobic wettability influenced nucleation site density, vapor-liquid flow field and heat transfer performance much more than cubic shaped geometry. Finally, heat flux of cubic micro-pillar surface with hybrid wettability increased by 430.7% compared to pure hydrophilic wettability. That is due to optimal hybrid wettability surface could control nucleate site location, restrict bubble growth, and increase obviously heat transfer performance.

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Studying the effect of geometry of micro-cavity on pool boiling by LBM

Huang

Zhou²,

Huai³

et al. 2023

J. Phys.: Conf. Ser.

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Pool boiling heat transfer from structured surface is simulated numerically with a 3D OTRT (optimal two relaxation time) Lattice Boltzmann method. This work shows in detail that multiple bubbles grow and coalesce over hydrophilic (θ = 50°) surfaces in 3D view, heat flux transfers from heater surface to fluid, and temperature of heater surface varies with time. Specifically, four types of geometry in microstructure surfaces are examined and compared. It is found that heat flux of S5 is the highest and its wall temperature is the lowest. When compared with S0, the heat flux of S5~S7 increased a lot due to the easier formation of vapor blanket, and cubic shaped cavity alleviates largely this deterioration. Next, the large quantity of heat from the three phase contact line in the vicinity of side wall accounts for bubble nucleation and energy from the evaporation of thin liquid between bubbles and superheated wall helps bubbles to grow further. Besides, it is found that S5 increases nucleate site density, reduces boiling incipience superheat, and enhances remarkably heat transfer performance.

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Saturated pool boiling heat transfer of HFE-7100 on sintered copper powder and wire mesh microporous surfaces: A comparison study

Jiang

Zhou

et al. 2022

Applied Thermal Engineering

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Xiulan Huai

Enhancing pool boiling heat transfer of modified surface by 3-D Lattice Boltzmann method

Studying the effect of geometry of micro-cavity on pool boiling by LBM

Saturated pool boiling heat transfer of HFE-7100 on sintered copper powder and wire mesh microporous surfaces: A comparison study

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