What question did this study set out to answer?

The research aims to understand how granular flow transitions occur in a hopper based on filling height and grain numbers.

March 21, 2026

Filling height dependence of dense granular flow in a hopper: Transition from fluid‐like flow to Beverloo flow

Key Points

The research aims to understand how granular flow transitions occur in a hopper based on filling height and grain numbers.
Utilized a fixed-grain-number discrete element method to simulate granular flow.
Identified fluid-like and Beverloo flow regimes based on flow rates and filling heights.
Analyzed the impact of outlet size on the transition grain number.
Fluid-like flow is observed at low grain numbers, with flow rate linked to filling height.
Beverloo flow occurs at high grain numbers, leading to flow rate independence from filling height.
Dynamic force arches and the Janssen effect contribute to flow behavior and contact forces along the axis.

Abstract

ABSTRACT Gravity‐driven dense granular flow in a hopper is investigated using a fixed‐grain‐number discrete element method. Two flow regimes are identified: a fluid‐like flow at low grain numbers, with a flow rate governed by filling height, and a Beverloo flow at high grain numbers, where the flow rate becomes independent of filling height. The transition grain number increases with outlet size. In the Beverloo regime, a dynamic force arch forms above the outlet, accompanied by a dynamic Janssen effect at the sidewalls, which causes contact forces along the central axis to saturate. These findings provide a micromechanical explanation for the constant flow rate and advance the understanding of granular flow transitions.

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Filling height dependence of dense granular flow in a hopper: Transition from fluid‐like flow to Beverloo flow

Key Points

Abstract

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