IMA Conference on Dense Granular Flows

Date: Monday 5 – Friday 9 January 2009
Location: Issac Newton Institute, Cambridge

Videos of the talks are available at http://sms.cam.ac.uk/collection/521697.

Flows involving solid particulates are ubiquitous in nature and industry alike. Such flows are found in pharmaceutical production, the chemical industry, the food and agricultural industries, energy production and the environment. Many unsolved problems remain, however. For example, the rejection rate by US pharmaceutical manufacturers is around 5% with the cost of losing a single batch of medication ranging from £50,000 to £500,000. In order to be able to solve such problems, granular flows need to be understood so that their behaviour can be controlled and predicted.

To date, we are able to describe rapid granular flows, where the particles are highly agitated and there has been some success describing static systems. The intermediate regime, where these two phases meet and coexist, is not as well understood and yet is the most commonly observed behaviour of granular flow. The objective of this meeting will be to interface the two ends of the particulate flow spectrum – those working to understand the fundamentals of granular flows and those attempting to control particulate flows in an industrial setting – to develop solutions to the complex problems presented by dense granular flows.

Organising Committee

Ricky Wildman, Loughborough University (Chair)
Nico Gray, University of Manchester
Jonathon Huntley, Loughborough University
Jim McElwaine, University of Cambridge
Christine Hrenya, University of Colorado, USA

Invited Speakers

Bob Behringer, Duke University, North Carolina, USA
Statistics of Dense Granular Materials
Abstract: Dense granular materials present a number of interesting challenges. They are many-body systems with dissipative interactions. As suggested by Edwards et al., one would like to have a statistical approach analogous to Boltzmann statistics for energy-conserving systems. But the dissipative character of dense granular materials challenges conventional notions. New approaches require a careful examination, and suggest a number of experiments. This talk will focus on recent experiments that seek to characterize the statistics of dense granular systems and to test recent models. In particular, we have carried out experiments to determine the microscopic distributions of contact forces, the nature of jamming, the effect of stress anisotropy, the role of affine and non-affine motion in sheared granular systems, the effect of particle rotation, and the importance of particle shape. Many of these experiments use photoelastic particles. This allows the tracking of particle motion, and perhaps most importantly, the determination of the contact forces by the solution of a nonlinear inverse problem.

Our results are consistent with predictions from the force ensemble approach, but much more needs to be done.

Thomas C. Halsey,  ExxonMobil Upstream Research, Houston, Texas
Motion of frictional grain packings

Jim Jenkins, Cornell University, USA
Dense Granular Flows Down Inclines
Abstract: We’ll show how kinetic theory, slightly extended to include an additional length scale in the rate of collisional dissipation that is associated with clusters and/or correlated collisions, can predict the observed features of inclined flows of inelastic, frictional spheres over a rigid bumpy base in the absence of side walls and over the surface of a heap when side walls are present.

Biography: James T. Jenkins is the Walter S. Carpenter, Jr. Professor of Engineering in the Department of Theoretical and Applied Mechanics at Cornell University. His recent research has focused on the formulation of constitutive relations for dense, dissipative, collisional flows; analytical descriptions of debris flows; and the modeling of wind-blown sand.

Raffaella Ocone, Department of Chemical Engineering, Heriot-Watt University
Investigating the Intermediate Granular Flow Regime
Biography: Raffaella Ocone is Professor of Chemical Engineering at Heriot-Watt University, Edinburgh, UK. She received her MEng in Chemical Engineering from the University of Naples, Italy, and MA and PhD from Princeton University, USA. She was elected Fellow of the Royal Society of Edinburgh in 2006 and Cavaliere of the Order of Merit of the Italian Republic in 2007. She is a Chartered Engineer, a Chartered Scientist and a Fellow of the Institution of Chemical Engineers. Her research interests are in modelling complex systems, spanning from the hydrodynamics of solid/gas suspensions, to complex reaction networks. Recent work includes the modelling of biological systems.

Dr Philippe Rogueda FRSC CChem CSci EurIng, Novartis UK
Multiphase flow enigmas in inhalation delivery
Biography: Philippe Rogueda is a world expert on formulation science, especially on the formulation of medicinal aerosols. His expert lies in the field of colloid and physical chemistry, in relation to particle engineering and non aqueous formulations.

Professor Jonathan Seville, School of Engineering, University of Warwick
Granular Flows at the Single Particle Level
Biography: Jonathan Seville is Dean of Engineering at the University of Warwick, UK. He holds degrees in Chemical Engineering from the Universities of Cambridge and Surrey and has held visiting appointments at the University of British Columbia and the Technical University of Denmark. He is a Chartered Engineer, a Fellow of the Institution of Chemical Engineers and a Fellow of the Royal Academy of Engineering. His research includes a wide range of solids processing activities, including particle formation, agglomeration, compaction and coating; fluidisation and reactor design; positron emission particle tracking; discrete element method modelling; and supercritical fluid processes.

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