Drop formation from rapidly moving liquid sheets

Fraser, R. P.; Eisenklam, P.; Dombrowski, N.; Hasson, David

doi:10.1002/aic.690080522

Cited by 203 publications

(104 citation statements)

References 14 publications

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“…As the liquid moves farther away from the nozzle, the cone expands and the sheet thins. The breakup of sheets occurs by a wavy mechanism (Figure 2.3), as opposed to the dilational, symmetric disturbances that govern jet breakup (Fraser et al, 1962). In the sheet, asymmetric disturbances grow, and waves form.…”

Section: Sheet Breakupmentioning

confidence: 99%

Liquid‐phase mass transfer in spray contactors

Yeh

Rochelle

2003

AIChE Journal

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The liquid‐phase mass transfer in sprays has been measured with carbon dioxide desorption by collecting and analyzing samples of the spray. Experiments were conducted with laboratory‐ (0.009 to 0.13 L/s) and pilot‐scale (6.4 to 12.8 L/s) centrifugal hollow‐cone spray nozzles at pressure drops from 34 kPa to 138 kPa. Significant mass transfer occurred during sample collection, and a quench sampling method was developed to minimize this effect. The number of liquid‐phase transfer units (NL) due to spray impact onto walls and liquid pools was often as much as the spray NL. Approximately 60% of the spray NL occurs in the liquid sheet before droplet formation, and the droplet region can account for less than half of the total NL of the spray.

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Section: Sheet Breakupmentioning

confidence: 99%

Liquid‐phase mass transfer in spray contactors

Yeh

Rochelle

2003

AIChE Journal

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“…The linear temporal analyses predict that an optimum frequency exists where growth rate is a maximum. Fraser et al [90] extended the analysis on the aerodynamic instability of liquid sheets of uniform thickness to the flow of attenuating liquid sheets as observed in the flow in a fan spray sheet.…”

Section: Planar Liquid Sheetsmentioning

confidence: 99%

Trends in Comprehensive Modeling of Spray Formation

Tharakan

Mukhopadhyay

Datta

et al. 2013

International Journal of Spray and Combustion Dynamics

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Comprehensive modeling of spray formation in liquid fuel injectors involves modeling of (i) internal hydrodynamics of fuel injector (ii) break up of liquid sheet leading to primary and secondary atomization and (iii) prediction of size and velocity distributions of droplets in the spray. Comprehensive models addressing all the three aspects are rare though some work has been reported that incorporate two of the three aspects. However, significant volume of literature exists on the individual modules. In the present work, progress and current trends in the individual modules have been extensively reviewed and their implications on development of comprehensive models have been discussed. The unresolved issues and future research directions are also indicated.

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“…For the fan nozzles, with an aspect ratio of approximately 2 (actually from 1.8 to 2.2, Fraser et al, 1962), used by Hasson & Mizrahi and Fraser, et al, the spray angle was 1 1S0, which gives a K value of about 0.583A using Equation (6). For a given nozzle, K can be determined experimentally (sheet thickness times radial distance from orifice, especially at time of break up into ligaments).…”

Section: At-7mentioning

confidence: 99%

Analysis of Waste Leak and Toxic Chemical Release Accidents from Waste Feed Delivery (WFD) Diluent System

Williams¹

2000

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Drop formation from rapidly moving liquid sheets

Cited by 203 publications

References 14 publications

Liquid‐phase mass transfer in spray contactors

Liquid‐phase mass transfer in spray contactors

Trends in Comprehensive Modeling of Spray Formation

Analysis of Waste Leak and Toxic Chemical Release Accidents from Waste Feed Delivery (WFD) Diluent System

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