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ID 205

Liquid Fuel Aerosols with Submicron Droplets

Maksim Mezhericher
Princeton University
United States

Nikolay Razorenov
Shamoon College of Engineering
Israel

Natalya Dvoskin
Shamoon College of Engineering
Israel

Mazor Gedalya
Shamoon College of Engineering
Israel

Yiguang Ju
Princeton University
United States

Howard A. Stone
Princeton University
United States

 

Abstract:

We describe a methodology for producing aerosols of submicron-sized droplets for liquid fuels. The meth-od of droplet formation is based on disintegration, by gas jets, of thin liquid films formed as bubbles on a liquid surface. Using compressed air and CO2, we atomized gasoline (95 RON), diesel, and 0.1-2 wt.% aqueous solu-tions of sodium alginate with dynamic viscosities up to 210 mPa·s as a model of a highly viscous fuel. The ob-served droplet volume distributions were bi-modal with two peaks between the droplet diameters 0.1-1 µm and 1-10 µm, and the respective volume and Sauter mean droplet diameters were substantially smaller than typically produced by other atomization methods. For most of the studied cases, 99% of droplets in the aerosols by num-ber were smaller than 1 µm, and the arithmetic mean diameters were ~200 nm. The liquid flow rates were meas-ured between a few hundreds of mg/min (for 2 wt.% sodium alginate solution) and O(10) g/min (for gasoline). The minimum air-to-liquid mass ratio was smaller (for gasoline) and near (for diesel) than the respective stoi-chiometric air-fuel ratios. Finally, we established the empirical dependence of the droplet diameter on the di-mensionless number relating between the four process-governing forces: atomizing gas pressure, droplet inertia, and liquid viscosity and surface tension.