Fluids containing polymers are frequently utilized in
the chemical
industry and exhibit shear-thinning characteristics. The flow distribution
of non-Newtonian fluids in parallelized microchannels is a key issue
to be solved during numbering-up. Numbering-up means increasing the
number of parallelized microchannels. In this study, a high-speed
camera is used to explore the distribution of fluid flow as well as
the uniformity and stability of droplets in conceptual asymmetrical
parallelized microchannels. Cyclohexane and carboxymethylcellulose
sodium (CMC) aqueous solutions are used as the continuous phase and
dispersed phase, respectively. The effects of fluctuation of pressure
difference around the T-junction, the hydrodynamic resistance in microchannels,
and the shear-thinning property of fluids on flow distribution and
droplet formation are revealed. The uniformity and stability of droplets
in microdevices with various cavity settings are compared, and an
optimal configuration is proposed. Finally, prediction models for
the flow distribution of shear-thinning fluids in asymmetrical parallelized
microchannels are established.
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