posted on 2021-11-15, 15:46authored byAbhijeet H. Thaker, Vivek V. Ranade
Liquid–liquid emulsions are used in many sectors such as personal care, home care,
and food products. There is an increasing need for developing compact and modular
devices for producing emulsions with desired droplet size distribution (DSD). In this
work, we have experimentally and computationally investigated an application of
vortex-based hydrodynamic cavitation (HC) device for producing emulsions. The
focus is on understanding drop breakage occurring in a single-pass through the con sidered HC device. The experiments were performed for generating oil-in-water
emulsion containing 1%–20% rapeseed oil. The effect of pressure drop across the
HC device in the range of 50–250 kPa on drop breakage was examined. DSD of
emulsions produced through a single pass was measured using the focussed beam
reflectance measurements. Comprehensive computational fluid dynamics (CFD)
model based on the Eulerian approach was developed to simulate multiphase cavitat ing flow. Using the simulated flow, population balance model (PBM) with appropriate
breakage kernels was solved to simulate droplet breakage in a vortex-based HC
device. The device showed an excellent drop breakage efficiency (nearly 1% which is
much higher than other commercial devices such as rotor–stators or sonolators) and
was able to reduce mean drop size from 66 to ~15 μm in a single pass. The CFD and
PBM models were able to simulate DSD. The presented models and results will be
useful for researchers and engineers interested in developing compact devices for
producing emulsions of desired DSD.