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Transition from clogging to continuous flow in constricted particle suspensions

Mathieu Souzy, Iker Zuriguel, Alvaro Marin

2020Physical review. E61 citationsDOIOpen Access PDF

Abstract

When suspended particles are pushed by liquid flow through a constricted channel, they might either pass the bottleneck without trouble or encounter a permanent clog that will stop them forever. However, they may also flow intermittently with great sensitivity to the neck-to-particle size ratio D/d. In this Rapid Communication, we experimentally explore the limits of the intermittent regime for a dense suspension through a single bottleneck as a function of this parameter. To this end, we make use of high time- and space-resolution experiments to obtain the distributions of arrest times (T) between successive bursts, which display power-law tails (∝T^{-α}) with characteristic exponents. These exponents compare well with the ones found for as disparate situations as the evacuation of pedestrians from a room, the entry of a flock of sheep into a shed, or the discharge of particles from a silo. Nevertheless, the intrinsic properties of our system (i.e., channel geometry, driving and interaction forces, particle size distribution) seem to introduce a sharp transition from a clogged state (α≤2) to a continuous flow, where clogs do not develop at all. This contrasts with the results obtained in other systems where intermittent flow, with power-law exponents above two, were obtained.

Topics & Concepts

SiloBottleneckMechanicsCloggingFlow (mathematics)Suspension (topology)Channel (broadcasting)Particle (ecology)Power lawSimulationPhysicsStatistical physicsMathematicsComputer scienceEngineeringGeologyTelecommunicationsMechanical engineeringStatisticsGeographyHomotopyArchaeologyEmbedded systemOceanographyPure mathematicsEvacuation and Crowd DynamicsLattice Boltzmann Simulation StudiesGranular flow and fluidized beds
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