Publication:
Spreading behavior of droplets impacting over substrates with varying surface topographies

dc.contributor.authorCetiner, A.
dc.contributor.authorEvren, B.
dc.contributor.authorBudakli, M.
dc.contributor.authorArık, Mehmet
dc.contributor.authorOzbek, A.
dc.contributor.departmentMechanical Engineering
dc.contributor.ozuauthorARIK, Mehmet
dc.date.accessioned2021-02-12T10:09:30Z
dc.date.available2021-02-12T10:09:30Z
dc.date.issued2020-12-05
dc.description.abstractDroplet interaction with solid surface plays an important role in a number of practical applications such as thermal management systems, steel production, painting, prevention of impurit deposition, and formation of corrosion. In this study, droplet impact on different surface topographies was experimentally investigated. A major part of this work was to devoted to developing supherhydrophobic surfaces using a combination of two conventional manufacturing techniques in order to study the droplet dynamics with the aim of preventing liquid attachement at the wall. Five surfaces were manufactured for which the methods such as mechanical polishing, Ylaser-ablation, anodization, superhydrophobic spray-coating, and combination of laser-ablation and anodization were applied. Deionized water was used as the working liquid. The effects of velocity and surface temperature on spreading dynamics were investigated by impacting single droplets for Weber numbers between 67 and 565. Experiments are performed at 25 degrees C ambient temperature with a constant droplet temperature of 25 degrees C, while the effect of surface temperature has been studied for 25 degrees C and 2 degrees C. Maximum spreading factor data was obtained and compared with theoretical models and experimental data found in the literature. Through the combination of laser-ablation and anodization methods, superhydrophobicty is obtained with static contact angles similar to that measured on the superhydrophobic coating. Experiments at 25 degrees C surface temperature show that the droplet impacting on the combined surface had greater maximum spreading factor values than only laser-ablated and anodized surfaces and lower than those determined at the cotaed surface. At low surface temperature, the smallest maximum spreading factor was measured at the substrate with its surface treated by the combined method. The mathematical models found in literature show a good agreement concerning the maximum spreading factor values determined at the polished, anodized and laser-ablated surfaces. However, the maximum spreading factor at both spray-coated and combined surfaces is larger than the model predictions.en_US
dc.description.versionPublisher versionen_US
dc.identifier.doi10.1016/j.colsurfa.2020.125385en_US
dc.identifier.issn0927-7757en_US
dc.identifier.scopus2-s2.0-85089495164
dc.identifier.urihttp://hdl.handle.net/10679/7306
dc.identifier.urihttps://doi.org/10.1016/j.colsurfa.2020.125385
dc.identifier.volume606en_US
dc.identifier.wos000580858600012
dc.language.isoengen_US
dc.peerreviewedyesen_US
dc.publicationstatusPublisheden_US
dc.publisherElsevieren_US
dc.relation.ispartofColloids and Surfaces A: Physicochemical and Engineering Aspects
dc.relation.publicationcategoryInternational Refereed Journal
dc.rightsrestrictedAccess
dc.subject.keywordsDrop impacten_US
dc.subject.keywordsSurface wettabilityen_US
dc.subject.keywordsSuperhydrophobicityen_US
dc.subject.keywordsLaser machiningen_US
dc.subject.keywordsMaximum spreading factoren_US
dc.titleSpreading behavior of droplets impacting over substrates with varying surface topographiesen_US
dc.typearticleen_US
dspace.entity.typePublication
relation.isOrgUnitOfPublicationdaa77406-1417-4308-b110-2625bf3b3dd7
relation.isOrgUnitOfPublication.latestForDiscoverydaa77406-1417-4308-b110-2625bf3b3dd7

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