Scientific Reports (Aug 2017)

Atomization characteristics and instabilities in the combustion of multi-component fuel droplets with high volatility differential

  • D. Chaitanya Kumar Rao,
  • Srinibas Karmakar,
  • Saptarshi Basu

DOI
https://doi.org/10.1038/s41598-017-09663-7
Journal volume & issue
Vol. 7, no. 1
pp. 1 – 15

Abstract

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Abstract We delineate and examine the successive stages of ligament-mediated atomization of burning multi-component fuel droplets. Time-resolved high-speed imaging experiments are performed with fuel blends (butanol/Jet A-1 and ethanol/Jet A-1) comprising wide volatility differential, which undergo distinct modes of secondary atomization. Upon the breakup of vapor bubble, depending on the aspect ratio, ligaments grow and break into well-defined (size) droplets for each mode of atomization. The breakup modes either induce mild/intense oscillations on the droplet or completely disintegrate the droplet (micro-explosion). For the blends with a relatively low volatility difference between the components, only bubble expansion contributes to the micro-explosion. In contrast, for blends with high volatility differential, both bubble growth as well as the instability at the interface contribute towards droplet breakup. The wrinkling pattern at the vapor-liquid interface suggests that a Rayleigh-Taylor type of instability triggered at the interface further expedites the droplet breakup.