Pool boiling of HFE-7200 on nanoparticle-coating surfaces: Experiments and heat transfer analysis

Zhen Cao; Zan Wu; Anh Duc Pham; Yanjie Yang; Sahar Abbood; Peter Falkman; Tautgirdas Ruzgas; Cathrine  Albèr; Bengt Sundén

doi:10.1016/j.ijheatmasstransfer.2018.12.140

Pool boiling of HFE-7200 on nanoparticle-coating surfaces: Experiments and heat transfer analysis

Zhen Cao, Zan Wu, Anh Duc Pham, Yanjie Yang, Sahar Abbood, Peter Falkman, Tautgirdas Ruzgas, Cathrine Albèr, Bengt Sundén

Research output: Contribution to journal › Article › peer-review

Abstract

In the present study, an electrophoretic deposition method was employed to modify copper surfaces with
Cu-Zn (100 nm) nanoparticles. Pool boiling heat transfer of HFE-7200 on the modified surfaces was experimentally studied. The results showed that the heat transfer coefficient on the modified surfaces was significantly enhanced compared with that on a smooth surface, e.g., a maximum 100% enhancement,
while the maximum superheat on the modified surfaces was around 20 K lower than that on the smooth surface. However, the critical heat flux (CHF) was not improved considerably, and supplementary tests indicated that the wickability of HFE-7200 was almost the same on the modified surfaces and the smooth surface. The departure diameters of bubbles were recorded by a high speed camera, which were compared with several models in literature. Active nucleation site sizes were evaluated by the Hsu nucleation theory and active nucleation site densities were estimated by appropriate correlations.
In addition, a heat transfer model, considering natural convection, re-formation of thermal boundary layer and microlayer evaporation, was formulated to predict the heat transfer on the modified surfaces and the smooth surface. A relatively good prediction was achieved.

Original language	English
Pages (from-to)	548-560
Number of pages	12
Journal	International Journal of Heat and Mass Transfer
Volume	133
DOIs	https://doi.org/10.1016/j.ijheatmasstransfer.2018.12.140
Publication status	Published - 2018 Dec 21

Subject classification (UKÄ)

Energy Engineering

Free keywords

Pool boiling
Heat transfer
Nanoparticles
Bubble dynamics

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10.1016/j.ijheatmasstransfer.2018.12.140

1 Doctoral Thesis (compilation)

Pool Boiling on Structured Surfaces: Heat Transfer and Critical Heat Flux: Experiments and Mechanistic Modelling
Cao, Z., 2019 Sept 30, Department of Energy Sciences, Lund University. 63 p.
Research output: Thesis › Doctoral Thesis (compilation)

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title = "Pool boiling of HFE-7200 on nanoparticle-coating surfaces: Experiments and heat transfer analysis",

abstract = "In the present study, an electrophoretic deposition method was employed to modify copper surfaces withCu-Zn (100 nm) nanoparticles. Pool boiling heat transfer of HFE-7200 on the modified surfaces was experimentally studied. The results showed that the heat transfer coefficient on the modified surfaces was significantly enhanced compared with that on a smooth surface, e.g., a maximum 100% enhancement,while the maximum superheat on the modified surfaces was around 20 K lower than that on the smooth surface. However, the critical heat flux (CHF) was not improved considerably, and supplementary tests indicated that the wickability of HFE-7200 was almost the same on the modified surfaces and the smooth surface. The departure diameters of bubbles were recorded by a high speed camera, which were compared with several models in literature. Active nucleation site sizes were evaluated by the Hsu nucleation theory and active nucleation site densities were estimated by appropriate correlations.In addition, a heat transfer model, considering natural convection, re-formation of thermal boundary layer and microlayer evaporation, was formulated to predict the heat transfer on the modified surfaces and the smooth surface. A relatively good prediction was achieved.",

keywords = "Pool boiling, Heat transfer, Nanoparticles, Bubble dynamics",

author = "Zhen Cao and Zan Wu and Pham, {Anh Duc} and Yanjie Yang and Sahar Abbood and Peter Falkman and Tautgirdas Ruzgas and Cathrine Alb{\`e}r and Bengt Sund{\'e}n",

year = "2018",

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doi = "10.1016/j.ijheatmasstransfer.2018.12.140",

language = "English",

volume = "133",

pages = "548--560",

journal = "International Journal of Heat and Mass Transfer",

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T1 - Pool boiling of HFE-7200 on nanoparticle-coating surfaces: Experiments and heat transfer analysis

AU - Cao, Zhen

AU - Wu, Zan

AU - Pham, Anh Duc

AU - Yang, Yanjie

AU - Abbood, Sahar

AU - Falkman, Peter

AU - Ruzgas, Tautgirdas

AU - Albèr, Cathrine

AU - Sundén, Bengt

PY - 2018/12/21

Y1 - 2018/12/21

N2 - In the present study, an electrophoretic deposition method was employed to modify copper surfaces withCu-Zn (100 nm) nanoparticles. Pool boiling heat transfer of HFE-7200 on the modified surfaces was experimentally studied. The results showed that the heat transfer coefficient on the modified surfaces was significantly enhanced compared with that on a smooth surface, e.g., a maximum 100% enhancement,while the maximum superheat on the modified surfaces was around 20 K lower than that on the smooth surface. However, the critical heat flux (CHF) was not improved considerably, and supplementary tests indicated that the wickability of HFE-7200 was almost the same on the modified surfaces and the smooth surface. The departure diameters of bubbles were recorded by a high speed camera, which were compared with several models in literature. Active nucleation site sizes were evaluated by the Hsu nucleation theory and active nucleation site densities were estimated by appropriate correlations.In addition, a heat transfer model, considering natural convection, re-formation of thermal boundary layer and microlayer evaporation, was formulated to predict the heat transfer on the modified surfaces and the smooth surface. A relatively good prediction was achieved.

AB - In the present study, an electrophoretic deposition method was employed to modify copper surfaces withCu-Zn (100 nm) nanoparticles. Pool boiling heat transfer of HFE-7200 on the modified surfaces was experimentally studied. The results showed that the heat transfer coefficient on the modified surfaces was significantly enhanced compared with that on a smooth surface, e.g., a maximum 100% enhancement,while the maximum superheat on the modified surfaces was around 20 K lower than that on the smooth surface. However, the critical heat flux (CHF) was not improved considerably, and supplementary tests indicated that the wickability of HFE-7200 was almost the same on the modified surfaces and the smooth surface. The departure diameters of bubbles were recorded by a high speed camera, which were compared with several models in literature. Active nucleation site sizes were evaluated by the Hsu nucleation theory and active nucleation site densities were estimated by appropriate correlations.In addition, a heat transfer model, considering natural convection, re-formation of thermal boundary layer and microlayer evaporation, was formulated to predict the heat transfer on the modified surfaces and the smooth surface. A relatively good prediction was achieved.

KW - Pool boiling

KW - Heat transfer

KW - Nanoparticles

KW - Bubble dynamics

U2 - 10.1016/j.ijheatmasstransfer.2018.12.140

DO - 10.1016/j.ijheatmasstransfer.2018.12.140

M3 - Article

SN - 0017-9310

VL - 133

SP - 548

EP - 560

JO - International Journal of Heat and Mass Transfer

JF - International Journal of Heat and Mass Transfer

ER -

Pool boiling of HFE-7200 on nanoparticle-coating surfaces: Experiments and heat transfer analysis

Abstract

Subject classification (UKÄ)

Free keywords

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Research output

Pool Boiling on Structured Surfaces: Heat Transfer and Critical Heat Flux: Experiments and Mechanistic Modelling

Cite this