Multi-scale analysis on the pulverized coal flow behaviors under high pressure dense-phase pneumatic conveying

To deeply knowledge of the flow behaviors of pulverized coal particles in dense gas-solid two-phase flow, a multi-scale analysis method based on electrostatic sensor array is applied for the multi-scale characterization of flow behaviors of dense gas-solid flow. The experimental results indicate that: for steady flow, with the increment of conveying pressure difference, the individual particles increase and the particle clusters decrease, the individual particle distribution is always inhomogeneous but the particle cluster distribution tends to be more homogeneous over the cross-section of pipe, while the average flow behavior of pulverized coal particles is always in the relatively static state. For unsteady flow, the average flow behavior of pulverized coal particles is dynamic, and the flow behaviors of the multi-scale flow structures over the cross-section of pipe are all significantly inhomogeneous. Moreover, the effect of particle size on flow behavior of pulverized coal is also investigated and validated. (c) 2021 Chinese Society of Particuology and Institute of Process Engineering, Chinese Academy of Sciences. Published by Elsevier B.V. All rights reserved.

Automated summary

A multi-scale analysis method based on electrostatic sensor array is used to investigate the flow behaviors of pulverized coal particles in dense gas-solid two-phase flow. The experimental results indicate that under steady flow, the individual particles increase and the particle clusters decrease with increasing conveying pressure difference. The particle distribution remains inhomogeneous while the particle cluster distribution tends to be more homogeneous over the cross-section of the pipe. Under unsteady flow, the average flow behavior of pulverized coal particles is dynamic, and the flow behaviors of multi-scale flow structures over the cross-section of the pipe are significantly inhomogeneous. The effect of particle size on flow behavior is also explored and confirmed.