Silo Collapse under Granular Discharge

Gutiérrez, Gustavo; Colonnello, Claudia; Boltenhagen, Philippe; Darias, J. R.; Peralta–Fabi, R.; Brau, Fabian; Clément, Éric

doi:10.1103/physrevlett.114.018001

Cited by 29 publications

(21 citation statements)

References 41 publications

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“…These findings are of particular importance when designing operational protocols for filling and emptying silos, since the stress on walls can be largely affected and the system can keep memory of the history of the filling procedures even after significant manipulation. The larger the forces at the wall, the larger their wear and possible collapse [31]. Since it is generally simpler and more affordable to reinforce the base of a silo, a distributed filling protocol -which showed the higher M app -should be considered of preference over a concentric filling.…”

Section: Discussionmentioning

confidence: 99%

Apparent mass during silo discharge: Nonlinear effects related to filling protocols

Peralta

Aguirre

Géminard³

et al. 2017

Powder Technology

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We study the evolution of the force exerted by a granular column on the bottom surface of a silo during its discharge. Previous to the discharge, we prepare the system using different filling procedures: distributed, i.e. a homogeneous rain of grains across the cross-section of the silo; concentric, a granular jet along the silo axis; and a combination of both, i.e. filling half of the silo using one procedure and the second half using the other. We observe that each filling protocol leads to distinctive evolutions of the apparent mass (i.e., the effective weight sensed at the base) during the discharge. Interestingly, the use of combined filling protocols may lead to a reduced apparent mass, smaller than any other achieved with a simple filling. We propose a model based on the Janssen rationale that quantitatively accounts for the

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Section: Discussionmentioning

confidence: 99%

Apparent mass during silo discharge: Nonlinear effects related to filling protocols

Peralta

Aguirre

Géminard³

et al. 2017

Powder Technology

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“…For the semi‐mass flow, it can be explained as a transition state between mass flow and funnel flow 4 . The funnel flow results some industrial problems, like arching, collapsing, and ratholes 5–7 …”

Section: Introductionmentioning

confidence: 99%

Investigation of wet coal flow characteristics in silos by experiments and simulations

Yuan

Guan

et al. 2021

Asia-Pacific J Chem Eng

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The investigation of the wet coal flow characteristics is carried out in a three‐dimensional silo system by experiments and simulations. The effect of the moisture content on the flow characteristics is firstly investigated by experiments, which is in terms of bulk density, angle of repose, and flow rate at outlet. When moisture content is below 9%, the coal particles act as the easy flow mode. When moisture content exceeds 9.8%, the flow pattern turns to be cohesive. For the further understanding of the influence of the moisture content, we develop the continuum method with the effect of moisture content being considered in the mathematic model. The simulation results of the discharge rate and the ash content at outlet have good agreements with a maximum deviation of 7.3%. It is found that the Mixing Index decreases with the moisture content increasing because the moisture strengthens mixing among particles. And the velocity difference between particles in the central axis and ones near the wall grows accordingly. Particles with higher moisture content are easier to get the funnel flow mode. For particles with good flowability, the mass flow mode appears in the silo.

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“…Granular materials are ubiquitous in the food industry, agriculture, pharmacy, chemistry, construction, and so forth . In the chemical industry, granular materials are widely encountered in particulate reaction engineering, design of powders, storage of grain flows, separation, and granulation .…”

Section: Introductionmentioning

confidence: 99%

Gravitational discharge of fine dry powders with asperities from a conical hopper

Zhong

Cao

et al. 2017

AIChE Journal

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The effects of particle properties, especially the surface roughness and particle type, on the gravity discharge rate and flow behavior of fine dry powders from a conical hopper are studied in detail. The van der Waals force is considered to dominate the discharge of small particles, while the empty annulus effect dominates the discharge of large particles. To predict the van der Waals force between two rough spherical particles, a model based on Rumpf theory is adopted. The effect of surface roughness can be reflected by Bond number Bo g which is correlated with discharge rate. By modifying the powder bed porosity and Beverloo constant, the discharge rates of fine dry powders can be well predicted by an empirical correlation. Finally, not only the ratio of hopper outlet size to particle size D 0 /d p but also the Bond number Bo g is found to be an important indicator to determine the powder flowability.

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Silo Collapse under Granular Discharge

Cited by 29 publications

References 41 publications

Apparent mass during silo discharge: Nonlinear effects related to filling protocols

Apparent mass during silo discharge: Nonlinear effects related to filling protocols

Investigation of wet coal flow characteristics in silos by experiments and simulations

Gravitational discharge of fine dry powders with asperities from a conical hopper

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