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Model-based assessment of boiling heat transfer enhanced by coatings

Cao, Zhen LU ; Sundén, Bengt LU and Wu, Zan LU (2022) In International Journal of Heat and Mass Transfer 196.
Abstract

The present study aims to investigate boiling heat transfer enhancement on coated surfaces, based on mechanistic models. An electrochemical deposition method was used to fabricate coatings on copper surfaces which enhance critical heat flux and heat transfer coefficient of deionized water by 35.5% and 40.1%, respectively, compared with a smooth surface. Bubble dynamics indicates that regardless of surfaces, scaling laws of Db*∝t*0.5 and Db*∝t*0.2 are followed in the inertia-controlled growth stage and the heat-diffusion-controlled growth stage, respectively, concerning normalized bubble diameter (Db*) and normalized bubble time (t*). The... (More)

The present study aims to investigate boiling heat transfer enhancement on coated surfaces, based on mechanistic models. An electrochemical deposition method was used to fabricate coatings on copper surfaces which enhance critical heat flux and heat transfer coefficient of deionized water by 35.5% and 40.1%, respectively, compared with a smooth surface. Bubble dynamics indicates that regardless of surfaces, scaling laws of Db*∝t*0.5 and Db*∝t*0.2 are followed in the inertia-controlled growth stage and the heat-diffusion-controlled growth stage, respectively, concerning normalized bubble diameter (Db*) and normalized bubble time (t*). The coating decreases the bubble departure diameter to one-third to half of that on the smooth surface and increases the departure frequency to three times that on the smooth surface. In addition, the coated surface provides more active nucleation sites which are 1, 2 order magnitude higher than the smooth surface. With these insights, a mechanistic heat transfer model was established by quantifying natural convection, transient heat conduction, and microlayer evaporation, which matches well with the measured pool boiling curve. In the end, critical heat flux was explored experimentally and theoretically. Inspired by the coalesced bubble behavior at high heat flux and the Kandlikar force model, a new force-balance model was proposed by incorporating a surface-dependent surface tension force and adding a new capillary wicking force. The present model presents a better prediction of critical heat flux, verified by the current measurement and the literature.

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author
; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
Boiling heat transfer, Bubble dynamics, Coating, Critical heat flux
in
International Journal of Heat and Mass Transfer
volume
196
article number
123272
publisher
Pergamon Press Ltd.
external identifiers
  • scopus:85135062991
ISSN
0017-9310
DOI
10.1016/j.ijheatmasstransfer.2022.123272
language
English
LU publication?
yes
id
f97d08c3-7f08-476b-a3ae-ee51857ae93a
date added to LUP
2022-09-09 15:45:04
date last changed
2023-11-19 21:41:37
@article{f97d08c3-7f08-476b-a3ae-ee51857ae93a,
  abstract     = {{<p>The present study aims to investigate boiling heat transfer enhancement on coated surfaces, based on mechanistic models. An electrochemical deposition method was used to fabricate coatings on copper surfaces which enhance critical heat flux and heat transfer coefficient of deionized water by 35.5% and 40.1%, respectively, compared with a smooth surface. Bubble dynamics indicates that regardless of surfaces, scaling laws of D<sub>b</sub><sup>*</sup>∝t<sup>*</sup><sup>0.5</sup> and D<sub>b</sub><sup>*</sup>∝t<sup>*</sup><sup>0.2</sup> are followed in the inertia-controlled growth stage and the heat-diffusion-controlled growth stage, respectively, concerning normalized bubble diameter (D<sub>b</sub>*) and normalized bubble time (t*). The coating decreases the bubble departure diameter to one-third to half of that on the smooth surface and increases the departure frequency to three times that on the smooth surface. In addition, the coated surface provides more active nucleation sites which are 1, 2 order magnitude higher than the smooth surface. With these insights, a mechanistic heat transfer model was established by quantifying natural convection, transient heat conduction, and microlayer evaporation, which matches well with the measured pool boiling curve. In the end, critical heat flux was explored experimentally and theoretically. Inspired by the coalesced bubble behavior at high heat flux and the Kandlikar force model, a new force-balance model was proposed by incorporating a surface-dependent surface tension force and adding a new capillary wicking force. The present model presents a better prediction of critical heat flux, verified by the current measurement and the literature.</p>}},
  author       = {{Cao, Zhen and Sundén, Bengt and Wu, Zan}},
  issn         = {{0017-9310}},
  keywords     = {{Boiling heat transfer; Bubble dynamics; Coating; Critical heat flux}},
  language     = {{eng}},
  publisher    = {{Pergamon Press Ltd.}},
  series       = {{International Journal of Heat and Mass Transfer}},
  title        = {{Model-based assessment of boiling heat transfer enhanced by coatings}},
  url          = {{http://dx.doi.org/10.1016/j.ijheatmasstransfer.2022.123272}},
  doi          = {{10.1016/j.ijheatmasstransfer.2022.123272}},
  volume       = {{196}},
  year         = {{2022}},
}