2020
DOI: 10.1016/j.jfoodeng.2019.109742
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Theoretical prediction of atomization performance of fibre suspensions and the effect of feed temperature and air velocity

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Cited by 3 publications
(3 citation statements)
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“…Particle size can also be affected by material temperature in two different ways. When material temperature increases, viscosity and surface tension of material decrease thereby enable easier breakup to form finer atomized powder 59,60 . For material melts, viscosity has a Tk dependence while surface tension has a kT dependence where k is a positive arbitrary constant 49 .…”
Section: Working Principles Of Atomizationmentioning
confidence: 99%
See 1 more Smart Citation
“…Particle size can also be affected by material temperature in two different ways. When material temperature increases, viscosity and surface tension of material decrease thereby enable easier breakup to form finer atomized powder 59,60 . For material melts, viscosity has a Tk dependence while surface tension has a kT dependence where k is a positive arbitrary constant 49 .…”
Section: Working Principles Of Atomizationmentioning
confidence: 99%
“…When material temperature increases, viscosity and surface tension of material decrease thereby enable easier breakup to form finer atomized powder. 59,60 For material melts, viscosity has a T Àk dependence while surface tension has a ÀkT dependence where k is a positive arbitrary constant. 49 This indicates that further extent of material temperature increase will have diminishing improvement of droplet breakup as the heating utility cost increases significantly.…”
Section: Materials Feed Temperaturementioning
confidence: 99%
“…1) is the disintegration of a liquid film that comes out on a solid surface subjected to a sufficient surface disturbance in the normal direction. The competition between disruptive (like kinetic energy, friction, gravity, interface shearing, and pressure fluctuation) and cohesive (like shear resistance, the surface tension of liquids, and extensional resistance) forces on the liquid surface induce fluctuations and disturbances in the liquid, separating it from the surface and splits into small droplets like a mist in the gas phase [1][2][3]. The initial process of disintegration or break-up is defined as primary atomization, while the second atomization occurs when numerous larger droplets produced in the primary atomization can be unstable, thus reducing to smaller sizes [2,4].…”
Section: Introductionmentioning
confidence: 99%