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Granular flow: physical experiments and their implications for microstructural theories

Published online by Cambridge University Press:  26 April 2006

Thomas G. Drake
Affiliation:
Department of Earth and Space Sciences, University of California, Los Angeles, CA 90024–1567, USA Present address: Center for Coastal Studies, Scripps Institution of Oceanography, University of California, La Jolla, CA, 92093-0209, USA.

Abstract

Positions, velocities and rotations of individual particles obtained from high-speed motion pictures of essentially two-dimensional flows of plastic spheres in an inclined glass-walled chute were used to test critical assumptions of microstructural theories for the flow of granular materials. The measurements provide a well-defined set of observations for refining and validating computer simulations of granular flows, and point out some important limitations of physical experiments. Two nearly steady, uniform, collisional flows of 6-mm-diameter plastic spheres over a fixed bed of similar spheres inclined at 42.75° were analysed in detail. Particle fluxes were about 2230 particles s−1 and 1280 particles s−1. The nominal depth in both flows was about 18 particle diameters. Profiles of mean downstream velocity and mean rotations, translational temperature and rotational temperature, and bulk density in the flows show slip at the bed of 17 and 26% of the mean flow velocity for the high- and low-flux flows, respectively; mean rotation rates $\overline{\omega}_x$ and $\overline{\omega}_y$ less than 9% of $\overline{\omega}_z$ ($\hat{e}_x$ parallel to the bed, $\hat{e}_x$ normal to the sidewall); translational temperature nearly independent of distance from the bed; rotational temperature decreasing with distance from the bed; and density decreasing almost linearly with distance from the bed. The continuum hypothesis (i.e. small gradients in mean-flow properties) is satisfied throughout the flow except near the fixed bed, where large gradients in the mean rotation $\overline{\omega}_z$ and downstream velocity occur over a few particle diameters. The distributions of velocities and rotations are approximately Maxwellian, except near the fixed bed. Testing microstructural theories with physical experiments is severely hampered by limitations on material properties of particles, flow lengthscale and the spatial and temporal resolution of observations. Only a small volume of the parameter space for collision-dominated flows can reasonably be explored by physical experiment. Extraneous forces due to air drag, sidewall friction and electrical effects are not included in theories but must be addressed in physical experiments. Properly designed experiments are the essential link between computer simulations and theory, because they focus attention on particular features critical to testing the simulations, which in turn provide detailed particle-scale information needed to test theories.

Type
Research Article
Copyright
© 1991 Cambridge University Press

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References

Ahn, H.: 1989 Experimental and analytical investigations of granular materials: shear flow and convective heat transfer. PhD dissertation, California Institute of Technology, Division of Engineering and Applied Science Report E200.28, Pasadena, California, USA.
Araki, S. & Tremaine, S., 1986 The dynamics of dense particle disks. Icarus 65, 83109.Google Scholar
Batchelor, G. K.: 1967 An Introduction to Fluid Dynamics. Cambridge University Press.
Brooks, C., Hart, S. R. & Wendt, I., 1972 Realistic use of two-error regression treatments as applied to rubidium-strontium data. Rev. Geophys. Space Phys. 10, 551577.Google Scholar
Campbell, C. S. & Brennen, C. E., 1985 Computer simulation of granular shear flows. J. Fluid Mech. 151, 167188.Google Scholar
Cartwright, P., Singh, S. & Bailey, A. G., 1985 Electrostatic charging characteristics of polyethylene powder during pneumatic conveying. IEEE Trans. Indust. Applic. 11, 541546.Google Scholar
Dahler, J. S. & Theodosopulu, M., 1975 The kinetic theory of dense polyatomic fluids. Adv. Chem. Phys. 31, 155229.Google Scholar
Drake, T. G.: 1988 Experimental flows of granular material. PhD dissertation, University of California, Los Angeles, California, USA.
Drake, T. G.: 1990 Structural features in granular flows. J. Geophys. Res. 95, 86818696.Google Scholar
Drake, T. G. & Shreve, R. L., 1986 High-speed motion pictures of nearly steady, uniform, twodimensional inertial flows of granular material. J. Rheol. 30, 1981993.Google Scholar
Gutt, G.: 1987 A continuum theory of granular flow including spin. Caltech Brown Bag series, BB-59.Google Scholar
Gutt, G. & Haff, P. K., 1988 Boundary conditions on continuum theories of granular flow. Caltech Brown Bag series, BB-70.Google Scholar
Haff, P. K.: 1983 Grain flow as a fluid-mechanical phenomenon. J. Fluid Mech. 134, 401430.Google Scholar
Jenkins, J. T. & Richman, M. W., 1985a Grad's 13-moment system for a dense gas of inelastic spheres. Arch. Rat. Mech. Anal. 87, 355377.Google Scholar
Jenkins, J. T. & Richman, M. W., 1985b Kinetic theory for plane flows of a dense gas of identical, rough, inelastic, circular disks. Phys. Fluids 28, 34853494.Google Scholar
Jenkins, J. T. & Richman, M. W., 1986 Boundary conditions for plane flows of smooth, nearly elastic, circular disks. J. Fluid Mech. 171, 5369.Google Scholar
Jenkins, J. T. & Richman, M. W., 1988 Plane simple shear of smooth, inelastic, circular disks: the anisotropy of the second moment in the dilute and dense limits. J. Fluid Mech. 192, 313328.Google Scholar
Jenkins, J. T. & Savage, S. B., 1983 A theory for the rapid flow of identical, smooth, nearly elastic, spherical particles. J. Fluid Mech. 130, 187202.Google Scholar
Johnson, P. C., Nott, P. & Jackson, R., 1990 Frictional-collisional equations of motion for particulate flows and their application to chutes. J. Fluid Mech. 210, 501535.Google Scholar
Johnson, K. L.: 1985 Contact Mechanics. Cambridge University Press.
Lun, C. K. K. & Savage, S. B. 1987 A simple kinetic theory for granular flow of rough, inelastic, spherical particles. J. Appl. Mech. 54, 4753.Google Scholar
Lun, C. K. K., Savage, S. B., Jeffery, D. J. & Chepurniy, N., 1984 Kinetic theories for granular flow — inelastic particles in a Couette flow and slightly inelastic particles in a general flow field. J. Fluid Mech. 140, 223256.Google Scholar
Mindlin, R. D. & Deresiewicz, H., 1953 Elastic spheres under varying oblique forces. J. Appl. Mech. 21, 237244.Google Scholar
Pasquarell, G. C. & Babic, M., 1988 On the form of the velocity distribution for collisional constitutive relations. In Abstracts for the Seventh Engineering Mechanics Specialty Conference, p. 12. ASCE, 23–25 May 1988, Blacksburg, Virginia.
Richman, M. W. & Chou, C. S., 1989 Boundary effects on granular shear flows. Z. angew Math. Phys., in press.Google Scholar
Savage, S. B.: 1982 Granular flows down rough inclines — review and extension. In Proc. US—Japan seminar on new models and constitutive relations in the mechanics of granular materials (ed. J. T. Jenkins & M. Satake), pp. 232281. Elsevier.
Savage, S. B.: 1983 Granular flows at high shear rates. In Theory of Dispersed Multiphase Flow (ed. R. E. Meyer), pp. 339358. Academic Press.
Savage, S. B.: 1984 The mechanics of rapid granular flows. In Advances in Applied Mechanics, vol. 24 (ed. J. Hutchinson & T. Y. Wu), pp. 289366. Academic Press.
Savage, S. B. & Lun, C. K. K. 1988 Particle size segregation in inclined chute flow of dry cohesionless granular solids. J. Fluid Mech. 189, 311335.Google Scholar
Savage, S. B., Nbdderman, R. M., Tüzün, U. & Houlsby, G. T. 1982 The flow of granular materials, 3. Rapid shear flows. Chem. Engng Sci. 38, 189195.Google Scholar
Savage, S. B. & Sayed, M., 1984 Stresses developed by dry cohesionless granular materials sheared in an annular shear cell. J. Fluid Mech. 142, 391430.Google Scholar
Soga, N. & Anderson, O. L., 1967 Elastic properties of tektites measured by resonant sphere technique. J. Geophys. Res. 72, 17331739.Google Scholar
Stringham, G. E., Simons, D. B. & Guy, H. P., 1969 The behavior of large particles falling in quiescent liquids. US Geol. Survey Professional Paper 562-C.Google Scholar
Walton, O.: 1983 Particle-dynamics calculations of shear flow. In Proc. US—Japan seminar on new models and constitutive relations in the mechanics of granular materials (ed. J. T. Jenkins & M. Satake), pp. 327338. Elsevier.
Walton, O. R. & Braun, R. L., 1986a Viscosity, granular-temperature and stress calculations for shearing assemblies of inelastic, frictional disks. J. Rheol. 30, 949980.Google Scholar
Walton, O. R. & Braun, R. L., 1986b Stress calculations for assemblies of inelastic spheres in uniform shear. Acta Mech. 63, 4560.Google Scholar
Walton, O. R. & Drake, T. G., 1988 Granular flow in a two-dimensional channel: a comparison of measurements and numerical simulations. In Abstracts for the Seventh Engineering Mechanics Specialty Conference, p. 4. ASCE, 23–25 May 1988, Blacksburg, Virginia.
Werner, B. T. & Haff, P. K., 1986 A simulation study of the low energy ejecta resulting from single impacts in eolian saltation. In Advancements in Aerodynamics, Fluid Mechanics and hydraulics (ed. R. E. A. Arndt), pp. 337345. ASCE.