Vibration-Enhanced Droplet Motion Modes: Simulations of Rocking, Ratcheting, Ratcheting With Breakup, and Ejection

dc.citationHuber, R. A., Campbell, M., Doughramaji, N., & Derby, M. M. (2019). Vibration-Enhanced Droplet Motion Modes: Simulations of Rocking, Ratcheting, Ratcheting With Breakup, and Ejection. Journal of Fluids Engineering, 141(7), 071105-071105–071113. https://doi.org/10.1115/1.4042037
dc.citation.doi10.1115/1.4042037
dc.citation.issn0098-2202
dc.citation.issue7
dc.citation.jtitleJournal of Fluids Engineering
dc.citation.spage71105
dc.citation.volume141
dc.contributor.authorHuber, Ryan A.
dc.contributor.authorCampbell, Matthew
dc.contributor.authorDoughramaji, Nicole
dc.contributor.authorDerby, Melanie M.
dc.date.accessioned2019-03-01T23:30:44Z
dc.date.available2019-03-01T23:30:44Z
dc.date.issued2019-01-07
dc.date.published2019
dc.descriptionCitation: Huber, R. A., Campbell, M., Doughramaji, N., & Derby, M. M. (2019). Vibration-Enhanced Droplet Motion Modes: Simulations of Rocking, Ratcheting, Ratcheting With Breakup, and Ejection. Journal of Fluids Engineering, 141(7), 071105-071105–071113. https://doi.org/10.1115/1.4042037
dc.description.abstractPower plant water usage is a coupling of the energy–water nexus; this research investigates water droplet motion, with implications for water recovery in cooling towers. Simulations of a 2.6 mm-diameter droplet motion on a hydrophobic, vertical surface were conducted in XFLOW using the lattice Boltzmann method (LBM). Results were compared to two experimental cases; in the first case, experimental and simulated droplets experi-enced 30 Hz vibrations (i.e.,60.1 mm x-direction amplitude,60.2 mm y-direction amplitude) and the droplet ratcheted down the surface. In the second case, 100 Hz vibrations(i.e.,60.8 mm x-direction amplitude,60.2 mm y-direction amplitude) caused dropletejection. Simulations were then conducted for a wide range of frequencies (i.e., 10–100Hz) and amplitudes (i.e.,60.018–50 mm), resulting in maximum accelerations of 0.197–1970 m/s2. Under low maximum accelerations (e.g.,<7 m/s2), droplets rocked upward and downward in rocking mode, but did not overcome the contact angle hysteresis and, therefore, did not move. As acceleration increased, droplets overcame the contact angle hysteresis and entered ratcheting mode. For vibrations that prompted droplet motion, droplet velocities varied between 10–1000 mm/s. At capillary numbers above approximately 0.0044 and Weber numbers above 3.6, liquid breakup was observed in ratcheting droplets (e.g., the formation of smaller child droplets from the parent droplet). It was noted that both x- and y-direction vibrations were required for droplet ejection
dc.description.embargo2020-01-07
dc.description.versionArticle: Accepted Manuscript (AM)
dc.identifier.urihttp://hdl.handle.net/2097/39440
dc.language.isoen_US
dc.relation.urihttps://doi.org/10.1115/1.4042037
dc.rightsThis manuscript version is made available under the CC-BY 4.0 license https://creativecommons.org/licenses/by/4.0/
dc.rights.urihttps://creativecommons.org/licenses/by/4.0/
dc.rights.urihttps://www.asme.org/shop/journals/information-for-authors/journal-guidelines/rights-and-permissions
dc.subjectSimulation
dc.subjectDrops
dc.subjectWater
dc.subjectVibration
dc.titleVibration-Enhanced Droplet Motion Modes: Simulations of Rocking, Ratcheting, Ratcheting With Breakup, and Ejection
dc.typeText

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