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The combination of electrospray and flow focusing

Published online by Cambridge University Press:  05 October 2006

ALFONSO M. GAÑÁN-CALVO
Affiliation:
E.S.I., Universidad de Sevilla, Camino de los Descubrimientos s/n, 41092 Spain
JOSÉ M. LÓPEZ-HERRERA
Affiliation:
E.S.I., Universidad de Sevilla, Camino de los Descubrimientos s/n, 41092 Spain
PASCUAL RIESCO-CHUECA
Affiliation:
E.S.I., Universidad de Sevilla, Camino de los Descubrimientos s/n, 41092 Spain

Abstract

An ultra-fine liquid atomization procedure combining the advantages of electrospray and flow focusing is presented. Both techniques are known to produce strikingly small and steady liquid micro-jets issuing from menisci held by capillary forces. Such menisci take the form of a cusp-like drop attached to the feeding tube (flow focusing: FF) or a Taylor cone (electrospray: ES). The issuing micro-jets are forced or ‘sucked’ from the parent meniscus either by pressure or electrohydrodynamic forces. Subsequent capillary breakup of the jet leads to fine sprays of remarkable quality. Here we describe the joint effect of pressurization and electrification in a flow focusing device, and the subsequent coupling of both ES and FF phenomena. For any given liquid and flow rate, the combined procedure gives rise to significantly smaller droplet sizes than observed in any of the source techniques. The co-flowing gas stream removes space charges; in addition, the perforated plate facing the feed tube provides an electric barrier, shielding the jet-meniscus or ‘production’ area from the spray or ‘product’ area. As a result, space charges and electrified droplets are removed from the production area, thus avoiding the ambient electric saturation which becomes a limiting factor in ES-spraying: a significantly enhanced spraying stability ensues, with a much wider operation range than FF or ES. Other unexpected outcomes from the combination are also shown. A theoretical model is developed to predict the emitted droplet size: a first integral of the momentum equation yielding a generalized Bernoulli equation, and an explicit approximation for the jet diameter and droplet size, accurate within a broad parametrical band.

Type
Papers
Copyright
© 2006 Cambridge University Press

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