Lewis Scott scite author profile

Spiral jet mills are ubiquitous in the pharmaceutical industry. Breakage and classification in spiral jet mills occur due to complex interactions between the fluid and the solid phases. The study of these interactions requires the use of computational fluid dynamics (CFD) for the fluid phase coupled with discrete element models (DEM) for the particle phase. In this study, we investigate particle dynamics in a 50-mm spiral jet mill through coupled CFD-DEM simulations. The simulations showed that the fluid was significantly decelerated by the presence of the particles in the milling chamber. Furthermore, we study the particle dynamics and collision statistics at two different operating conditions and three different particle loadings. As expected, the particle velocity was affected by both the particle loading and operating pressure. The particles moved slower at low pressures and high loadings. We also found that particle–particle collisions outnumbered particle–wall collisions.

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Effect of grinding nozzles pressure on particle and fluid flow patterns in a spiral jet mill

Scott

Borissova

Burns

et al. 2021

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Application of coarse-graining for large scale simulation of fluid and particle motion in spiral jet mill by CFD-DEM

Scott

Borissova²,

Renzo³

et al. 2022

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Analysis of hold-up and grinding pressure in a spiral jet mill using CFD-DEM

et al. 2021

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A spiral jet mill was simulated using Discrete Element Method modelling and Computational Fluid Dynamics. The particle behaviour and fluid motion were analysed as a function of hold-up and grinding pressure. Particle collision energy was predicted to be prevalent along the bed surface and in front of the grinding jets, as shown through the collision data recorded. The bed itself affects the fluid flow field, as momentum is transferred to the particles. Increasing the grinding pressure does not result in a proportional increase in the kinetic energy of the particle system, as the high pressure jets begin to penetrate the bed with greater ease. The particle bed moves as ‘plug-flow’, with the layers of the bed closest to chamber wall.

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Lewis Scott

Influence of holdup on gas and particle flow patterns in a spiral jet mill

Numerical Simulation of Particle Dynamics in a Spiral Jet Mill via Coupled CFD-DEM

Effect of grinding nozzles pressure on particle and fluid flow patterns in a spiral jet mill

Application of coarse-graining for large scale simulation of fluid and particle motion in spiral jet mill by CFD-DEM

Analysis of hold-up and grinding pressure in a spiral jet mill using CFD-DEM

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