Hopper flows of dense suspensions: a 2D microfluidic model system

Abstract: Flows of particles through bottlenecks are ubiquitous in nature and industry, involving both dry granular materials and suspensions. However, practical limitations of conventional experimental setups hinder the full understanding of these flows in confined geometries. Here, we present a microfluidic setup to investigate experimentally the flow of dense suspensions in a two-dimensional hopper channel. Particles with controlled properties are in-situ fabricated with a photolithographic projection method and compacted at the channel constriction using a Quake valve. The setup is characterized by examining the flow of a dense suspension of hard, monodisperse disks through constrictions of varying widths. We demonstrate that the microfluidic hopper discharges particles at constant rate, resulting from the channel resistance being dominated by the presence of densely packed particles within the tapered section of the hopper. Under imposed flow rate the discharge remains independent of particle and orifice sizes, whereas it exhibits a Beverloo-like scaling under pressure-imposed conditions. Additionally, we show that the statistics of clog formation in our microfluidic hopper follow the same stochastic laws as reported in other systems. Finally, we show how the versatility of our microfluidic model system can be used to investigate the outflow and clogging of suspensions of more complex particles.