Open AccessTurbulent Liquid−Liquid Dispersion in Sulzer SMX Mixer
Author(s) -
Félicie Theron,
Nathalie Le Sauze,
A. Ricard
Publication year - 2009
Publication title -
industrial and engineering chemistry research
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.878
H-Index - 221
eISSN - 1520-5045
pISSN - 0888-5885
DOI - 10.1021/ie900090d
Subject(s) - reynolds number , turbulence , sauter mean diameter , mechanics , pressure drop , mixing (physics) , liquid liquid , coalescence (physics) , drop (telecommunication) , dispersion (optics) , static mixer , thermodynamics , chemistry , materials science , chromatography , physics , optics , mechanical engineering , engineering , quantum mechanics , nozzle , astrobiology
This paper presents an experimental study of pressure drop of single-phase flow and liquid−liquid dispersion through a Sulzer SMX mixer in the turbulent flow regime. Emulsification experiments are performed with various numbers of mixing elements from 2 to 20 and different flow rates ranging from 204 to 600 L/h. Pressure drop in single phase flow when Re is greater than 800 is modeled using a correlation based on the Blasius approach. The pressure drop is quantified at high Reynolds numbers for a liquid−liquid system. The droplet size distribution evolves along the mixer, and 10 mixing elements are required to reach break-up coalescence equilibrium in the case of emulsification experiments. Finally, assuming Kolmogorov’s theory of isotropic turbulence, a new correlation is established to predict the Sauter mean diameter in this mixing device as a function of the Reynolds and Weber numbers as well as the number of mixing elements
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