PDF-Download zu https://doi.org/10.53192/ITSC2026564
Enhanced nucleate pool boiling performance of aluminum alloy coatings fabricated by cold spray additive manufacturing
Artikel-Nr.: SW11165
Versandkostenfreie Lieferung!
Als Sofortdownload (nur für Windowsgeräte, nicht für ios Geräte geeignet) verfügbar - der Lizenzschlüssel wird nach der Bezahlung in Ihrem Kundenkonto unter "Meine Sofortdownloads" hinterlegt. Bitte installieren Sie vor dem Download das "File open" plugin (https://plugin.fileopen.com/) - Bitte "MSI Installer for 64-bit systems" verwenden - und beachten die Hinweise zum Digital Rights Management (https://www.dvs-media.eu/de/drm-digitales-rechte-management). Für den Download der E-Book Datei empfehlen wir "Mozilla Firefox", zum Öffnen der Datei "Adobe Acrobat Reader DC.
Preise gelten für Versand nach Deutschland inkl. gesetzlicher MwSt. zzgl. Versandkosten
Produktinformationen
Prof. Rocco Lupoir, lupoir@tcd.ie, Trinity College Dublin; Yan Cheny, chen21@tcd.ie, Trinity College Dublin; Prof. Anthony Robins, AROBINS@tcd.ie, Trinity College Dublin; Prof. Shuo Yin, yins@tcd.ie, Trinity College Dublin; Research Fellow Prasad Kangude, kangudep@tcd.ie, Trinity College Dublin;
https://doi.org/10.53192/ITSC2026564
Roughened surfaces hold great potential for enhancing boiling heat transfer. This study demonstrates the effectiveness of using cold spray additive manufacturing (CSAM) to fabricate enhanced boiling surfaces, specifically focusing on the deposition of aluminum coatings on Al6082 substrates. The method offers a fast and low-cost approach for producing enhanced boiling surfaces.
Typically, CSAM deposition of aluminum powder results in dense Al coatings. However, in this work, porous aluminum coatings with a honeycomb surface structure were successfully produced by pre-marking the substrate prior to spraying. Key CSAM parameters and surface pre-treatment conditions, such as the size and distribution of surface cavities, were identified to enable the reproducible formation of porous structures.
Following deposition, all samples underwent systematic pool boiling experiments using a dedicated test apparatus. Boiling curves were generated for the CSAM-enhanced surfaces and compared to the untreated bare substrate to assess heat transfer enhancement. Initial data analysis showed that all tested surfaces exhibited significant improvements in Critical Heat Flux (CHF). This enhancement is likely attributed to increased surface area, higher nucleation site density, enhanced capillary wicking, and suppression of lateral bubble coalescence.
In summary, the honeycomb-structured aluminum surfaces fabricated via the CSAM process show strong potential for industrial applications where high-performance boiling heat transfer is essential. Importantly, the process is industrially scalable and offers a cost-effective and rapid way to coat large surface areas compared to conventional subtractive and other metal additive manufacturing techniques.
- Reihe
- PDF-Download zu https://doi.org/10.53192/ITSC2026564
- Erscheinungsdatum
- März 2026
- Bindung
- PDF Download
- Seiten
- 6