On surface area coverage by an electrostatic rotating bell atomizer

An electrostatic rotating bell atomizer was used to produce a spray of a 20 wt% aqueous glycerol solution. Droplet size distributions were measured by photographing droplets in-flight and using image analysis software to measure their diameters. Increasing the rotational speed of the bell-cup result...

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Veröffentlicht in:	JCT research 2021-05, Vol.18 (3), p.649-663
Hauptverfasser:	Sidawi, K., Moroz, P., Chandra, S.
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Sprache:	eng
Schlagworte:	Atomizing Chemistry and Materials Science Corrosion and Coatings Diameters Droplets Film thickness Flow velocity Fluid flow Glass substrates High speed cameras Image analysis Industrial Chemistry/Chemical Engineering Materials Science Polymer Sciences Probabilistic models Probability theory Rotation Statistical analysis Surfaces and Interfaces Thin Films Tribology Vertical orientation
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creator	Sidawi, K. Moroz, P. Chandra, S.
description	An electrostatic rotating bell atomizer was used to produce a spray of a 20 wt% aqueous glycerol solution. Droplet size distributions were measured by photographing droplets in-flight and using image analysis software to measure their diameters. Increasing the rotational speed of the bell-cup resulted in a decrease in the average droplet diameter. The fraction of area covered by spray droplets was measured for various bell-cup speeds using a high-speed camera positioned behind a vertical glass substrate on which the liquid was sprayed. An analytical model, based on probability theory, was used to predict the fraction of surface covered solely using the droplet flux and the droplet size. Results from the model were compared to experimentally measured fractions of surface coverage and showed good agreement. The minimum theoretical film thickness assuming full coverage was derived from the probabilistic model. When the minimum theoretical film thickness was divided by the droplet diameter, it was found to be only dependent on the spread factor. Experiments to measure the fraction of area covered were also conducted using an automotive paint. Increasing the paint flow rate increased the fraction of area covered. Increasing rotational speed reduced splat size but had little effect on coverage. Increasing shaping air 1 flow rate reduced splat size and increased surface coverage significantly. Application of an electrostatic potential increased splat diameter but enhanced surface coverage only slightly.
doi_str_mv	10.1007/s11998-020-00430-4
format	Article
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Experiments to measure the fraction of area covered were also conducted using an automotive paint. Increasing the paint flow rate increased the fraction of area covered. Increasing rotational speed reduced splat size but had little effect on coverage. Increasing shaping air 1 flow rate reduced splat size and increased surface coverage significantly. 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Droplet size distributions were measured by photographing droplets in-flight and using image analysis software to measure their diameters. Increasing the rotational speed of the bell-cup resulted in a decrease in the average droplet diameter. The fraction of area covered by spray droplets was measured for various bell-cup speeds using a high-speed camera positioned behind a vertical glass substrate on which the liquid was sprayed. An analytical model, based on probability theory, was used to predict the fraction of surface covered solely using the droplet flux and the droplet size. Results from the model were compared to experimentally measured fractions of surface coverage and showed good agreement. The minimum theoretical film thickness assuming full coverage was derived from the probabilistic model. When the minimum theoretical film thickness was divided by the droplet diameter, it was found to be only dependent on the spread factor. Experiments to measure the fraction of area covered were also conducted using an automotive paint. Increasing the paint flow rate increased the fraction of area covered. Increasing rotational speed reduced splat size but had little effect on coverage. Increasing shaping air 1 flow rate reduced splat size and increased surface coverage significantly. 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Experiments to measure the fraction of area covered were also conducted using an automotive paint. Increasing the paint flow rate increased the fraction of area covered. Increasing rotational speed reduced splat size but had little effect on coverage. Increasing shaping air 1 flow rate reduced splat size and increased surface coverage significantly. Application of an electrostatic potential increased splat diameter but enhanced surface coverage only slightly.</abstract><cop>New York</cop><pub>Springer US</pub><doi>10.1007/s11998-020-00430-4</doi><tpages>15</tpages><orcidid>https://orcid.org/0000-0001-7564-815X</orcidid></addata></record>
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subjects	Atomizing Chemistry and Materials Science Corrosion and Coatings Diameters Droplets Film thickness Flow velocity Fluid flow Glass substrates High speed cameras Image analysis Industrial Chemistry/Chemical Engineering Materials Science Polymer Sciences Probabilistic models Probability theory Rotation Statistical analysis Surfaces and Interfaces Thin Films Tribology Vertical orientation
title	On surface area coverage by an electrostatic rotating bell atomizer
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