An experimental scaling law for particle-size segregation in dense granular flows

A depth-weakening wall friction coefficient, µw, has been reported from three-dimensional numerical simulations of steady and transient dense granular flows. To understand the degradation mechanisms, a scaling law for µw/ f and χ has been proposed where f is the intrinsic particle-wall friction and χ is the ratio of slip velocity to square root of granular temperature (Artoni & Richard, Phys. Rev. Lett., vol. 115 (15), 2015, 158001). Independently, a friction degradation model has been derived which describes a monotonically diminishing friction depends on a ratio of grain angular and slip velocities, Ω (Yang & Huang, Granular Matter, vol. 18 (4), 2016, 77). In search of experimental evidence for how these two parameters degrade the µw, an annular shear cell experiment was performed to estimate the bulk granular temperature, angular and slip velocities at sidewall through image-processing. Meanwhile, µw was measured by a force sensor to confirm the weakening towards the creep zone. The measured µw/ f − χ and µw/ f − Ω were both well-fitted to the corresponding models showing that both granular temperature and angular velocity are significant mechanisms to degrade the µw which broadens the research perspective on modeling the boundary condition of dense granular flows.

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Shock Waves and Particle Size Segregation in Shallow Granular Flows

Solid Mechanics and Its Applications - IUTAM Symposium on Segregation in Granular Flows ◽

10.1007/978-94-015-9498-1_25 ◽

2000 ◽

pp. 269-276 ◽

Cited By ~ 1

Author(s):

J. M. N. T. Gray ◽

Y. C. Tai ◽

K. Hutter

Keyword(s):

Particle Size ◽

Shock Waves ◽

Granular Flows ◽

Size Segregation

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Effect of Flow Rate and Particle Size on Heat Transfer to Dense Granular Flows

Volume 1: Biofuels, Hydrogen, Syngas, and Alternate Fuels; CHP and Hybrid Power and Energy Systems; Concentrating Solar Power; Energy Storage; Environmental, Economic, and Policy Considerations of Advanced Energy Systems; Geothermal, Ocean, and Emerging Energy Technologies; Photovoltaics; Posters; Solar Chemistry; Sustainable Building Energy Systems; Sustainable Infrastructure and Transportation; Thermodynamic Analysis of Energy Systems; Wind Energy Systems and Technologies ◽

10.1115/es2016-59258 ◽

2016 ◽

Author(s):

Megan F. Watkins ◽

Richard D. Gould

Keyword(s):

Heat Transfer ◽

Particle Size ◽

Heat Transfer Coefficient ◽

Transfer Coefficient ◽

Flow Rate ◽

Granular Flows ◽

Heat Transfer Fluid ◽

Storage Medium ◽

Flow Rates ◽

Dense Granular Flows

The increasing demand for renewable energy sources necessitates the development of more efficient technologies. Concentrated solar power (CSP) towers exhibit promising qualities, as temperatures greater than 1000°C are possible. The heat transfer fluid implemented to capture the sun’s energy significantly impacts the overall performance of a CSP system. Current fluids, such as molten nitrate salts and steam, have limitations; molten salts are limited by their small operational temperature range while steam requires high pressures and is unable to act as an effective storage medium. As a result, a new heat transfer fluid composed of ceramic particles is being investigated, as ceramic particles demonstrate no practical limit on operation temperature and have the ability to act as a storage medium. This study sought to further investigate the use of dense granular flows as a new heat transfer fluid. Previous work validated the use of such flows as a heat transfer fluid; the present work examined the effect of flow rate, as well as the particle size and type on the heat transfer to the particle fluid. Three different types of particles were tested, along with two different diameter particles. Of the three materials tested, the particle type did not appear to effect the heat transfer. Particle diameter, however, did effect the heat transfer, as a smaller diameter particle yielded slightly higher heat transfer to the fluid. Flow rates ranging from 30 to 200 kg/m2-s were tested. Initially, the heat transfer to the flow, characterized by the convective heat transfer coefficient, decreased with increasing flow rate. However, at approximately 80 kg/m2-s, the heat transfer coefficient began to increase with increasing flow rate. These results indicate that a dense granular flow consisting of small diameter particles and traveling at very slow or fast flow rates yields the best wall to “fluid” heat transfer.

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Self-diffusion scalings in dense granular flows

Soft Matter ◽

10.1039/d0sm01846e ◽

2021 ◽

Author(s):

Riccardo Artoni ◽

Michele Larcher ◽

James T. Jenkins ◽

Patrick Richard

Keyword(s):

Shear Rate ◽

Solid Fraction ◽

Granular Flows ◽

The Self ◽

Granular Temperature ◽

Restitution Coefficient ◽

Self Diffusion ◽

Diffusivity Tensor ◽

Dense Granular Flows

The self-diffusivity tensor in homogeneously sheared dense granular flows is anisotropic. We show how its components depend on solid fraction, restitution coefficient, shear rate, and granular temperature.

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