Pool boiling performance of water and self-rewetting fluids on hybrid functionalized aluminum surfaces
Povzetek
The boiling performance of functionalized hybrid aluminum surfaces was experimentally investigated for water and self-rewetting mixtures of water and 1-butanol. Firstly, microstructured surfaces were produced via chemical etching in hydrochloric acid and the effect of the etching time on the surface morphology was evaluated. An etching time of 5 min was found to result in pitting corrosion and produced weakly hydrophilic microstructured surfaces with many microcavities. Observed cavity-mouth diameters between 3.6 and 32 µm are optimal for efficient nucleation and provided a superior boiling performance. Longer etching times of 10 and 15 min resulted in uniform corrosion and produced superhydrophilic surfaces with a micropeak structure, which lacked microcavities for efficient nucleation. In the second stage, hybrid surfaces combining lower surface energy and a modified surface microstructure were created by hydrophobization of etched aluminum surfaces using a silane agent. Hydrophobized surfaces were found to improve boiling heat transfer and their boiling curves exhibited a significantly lower superheat. Significant heat transfer enhancement was observed for hybrid microcavity surfaces with a low surface energy. These surfaces provided an early transition into nucleate boiling and promoted bubble nucleation. For a hydrophobized microcavity surface, heat transfer coefficients of up to 305 kW m$^{−2}$ K$^{−1}$ were recorded and an enhancement of 488% relative to the untreated reference surface was observed. The boiling of self-rewetting fluids on functionalized surfaces was also investigated, but a synergistic effect of developed surfaces and a selfrewetting working fluid was not observed. An improved critical heat flux was only obtained for the untreated surface, while a lower critical heat flux and lower heat transfer coefficients were measured on functionalized surfaces, whose properties were already tailored to promote nucleate boiling.
Ključne besede
pool boiling;nucleate boiling;surface modification;functionalized surfaces;heat transfer enhancement;self-rewetting fluids;
Podatki
| Jezik: | Angleški jezik |
|---|---|
| Leto izida: | 2021 |
| Tipologija: | 1.01 - Izvirni znanstveni članek |
| Organizacija: | UL FS - Fakulteta za strojništvo |
| UDK: | 536.242:66.046.7 |
| COBISS: |
67560707
|
| ISSN: | 2227-9717 |
| Št. ogledov: | 679 |
| Št. prenosov: | 186 |
| Ocena: | 0 (0 glasov) |
| Metapodatki: |
|
Ostali podatki
| Sekundarni jezik: | Slovenski jezik |
|---|---|
| Sekundarne ključne besede: | vrenje v bazenu;mehurčkasto vrenje;površinska modifikacija;funkcionalizirane površine;izboljšan prenos toplote;samoomočljivi fluidi; |
| Vrsta dela (COBISS): | Članek v reviji |
| Strani: | Str. 1-27 |
| Letnik: | ǂVol. ǂ9 |
| Zvezek: | ǂno. ǂ6 |
| Čas izdaje: | Jun. 2021 |
| DOI: | 10.3390/pr9061058 |
| ID: | 13040637 |
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