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The wall heat flux partitioning during the pool boiling of water on thin metallic foils
ID
Zupančič, Matevž
(
Author
),
ID
Gregorčič, Peter
(
Author
),
ID
Bucci, Mattia
(
Author
),
ID
Wang, Chi
(
Author
),
ID
Aguiar, Gustavo Matana
(
Author
),
ID
Bucci, Matteo
(
Author
)
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MD5: 71854AAE1C3EB759A5C931A3C426C9D4
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https://www.sciencedirect.com/science/article/pii/S1359431121010644
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Abstract
In this work, we studied the wall heat flux partitioning during the pool boiling of water on thin metallic surfaces. We conducted boiling experiments on surfaces where we engineered nucleation sites by nanosecond-fiber-laser texturing. These nucleation sites form triangular lattice patterns with different pitches. We measured the time-dependent temperature and heat flux distributions on the boiling surface using an infrared camera. We developed post-processing algorithms to measure, based on these distributions, all the fundamental boiling parameters used in heat flux partitioning models (e.g., nucleation site density, bubble wait and growth time, and bubble footprint radius) and the actual partitioning of the heat flux, i.e., how much heat is transferred by evaporation of the microlayer, rewetting of the surface, and convective effects. This work reveals that the mechanisms of heat transfer on substrates of small thermal capacity are very different compared to substrates of large thermal capacity. With water, the bubble microlayer typically does not dry out and the surface temperature at rewetting is practically the same as the rewetting fluid temperature. These effects limit the efficiency of microlayer evaporation and rewetting heat transfer. Instead, convective effects generated by the bubble growth process remove most of the energy from the heated surface. This behavior is captured by a heat flux partitioning model that we re-derived from first principles to describe the heat transfer mechanisms on substrate of small thermal capacity.
Language:
English
Keywords:
nucleate boiling
,
thin metallic foils
,
surface laser micro-engineering
,
infrared thermometry
,
heat flux partitioning
Work type:
Article
Typology:
1.01 - Original Scientific Article
Organization:
FS - Faculty of Mechanical Engineering
Publication status:
Published
Publication version:
Version of Record
Year:
2022
Number of pages:
16 str.
Numbering:
Vol. 200, art. 117638
PID:
20.500.12556/RUL-132089
UDC:
536:66.02(045)
ISSN on article:
1359-4311
DOI:
10.1016/j.applthermaleng.2021.117638
COBISS.SI-ID:
80131843
Publication date in RUL:
12.10.2021
Views:
774
Downloads:
223
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Record is a part of a journal
Title:
Applied thermal engineering
Shortened title:
Appl. therm. eng.
Publisher:
Elsevier Science
ISSN:
1359-4311
COBISS.SI-ID:
1861910
Licences
License:
CC BY-NC-ND 4.0, Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International
Link:
http://creativecommons.org/licenses/by-nc-nd/4.0/
Description:
The most restrictive Creative Commons license. This only allows people to download and share the work for no commercial gain and for no other purposes.
Secondary language
Language:
Slovenian
Keywords:
mehurčkasto vrenje
,
tanke kovinske folije
,
laserska mikroobdelava površin
,
infrardeča termografija
,
delitev toplotnega toka
Projects
Funder:
ARRS - Slovenian Research Agency
Project number:
P2-0223
Name:
Prenos toplote in snovi
Funder:
ARRS - Slovenian Research Agency
Project number:
J2-2486
Name:
Izboljšan prenos toplote pri vrenju z uporabo hierarhičnih funkcionaliziranih površin (eHEATs)
Funder:
ARRS - Slovenian Research Agency
Project number:
J2-1741
Name:
Lasersko mikro- in nanostrukturiranje za razvoj biomimetičnih kovinskih površin z edinstvenimi lastnostmi (LaMiNaS)
Funder:
ARRS - Slovenian Research Agency
Funding programme:
BIL – SLO-ZDA 2019-2021
Funder:
Other - Other funder or multiple funders
Funding programme:
US Nuclear Regulatory Commission
Funder:
NSF - National Science Foundation
Project number:
2019245
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