Versatile reconfigurable glass capillary microfluidic devices with Lego® inspired blocks for drop generation and micromixing.

Novel cost effective, versatile, reconfigurable, reusable and easy to assemble glass capillary microfluidic devices were developed and used to generate micro/nano-materials with controlled size and morphology. The devices are composed of coaxial assemblies of glass capillaries held between two interchangeable plastic blocks fabricated from chemically inert polyoxymethylene copolymer using computer numerical control (CNC) machining. Three different blocks were combined and locked together using Lego® inspired stud-and-hole coupling system to achieve different flow configurations.

Prediction and control of drop formation modes in microfluidic generation of double emulsions by single-step emulsification.

Hypothesis: Predicting formation mode of double emulsion drops in microfluidic emulsification is crucial for controlling the drop size and morphology.

Experiments And Modelling: A three-phase Volume of Fluid-Continuum Surface Force (VOF-CSF) model was developed, validated with analytical solutions, and used to investigate drop formation in different regimes. Experimental investigations were done using a glue-free demountable glass capillary device with a true axisymmetric geometry, capable of readjusting the distance between the two inner capillaries during operation.