Flour, coal, polymer, and other dust explosions in industrial plants led to tremendeous financial losses, injuries, and even fatalities. These catastrophic explosions were often caused by electrostatic discharges. Moreover, electrostatic charge causes dust to deposit on component surfaces, increasing the facility's resources and energy demand. However, to date, it is impossible to predict the rate at which powder charges during processing.
The PowFEct project develops an open-source simulation tool that couples fluid mechanics, surface science, and electrostatics to reveal the distinct mechanisms determining the charging rate of powder flow. To formulate a model for the charging of individual particles when contacting surfaces, we conduct single-particle experiments of extremely low scatter. Since no method is currently available to validate these simulations, we develop a new experimental technology to resolve powder flow charging in space. Unlike conventional measurement devices that only show the average charge, this new technology can find dangerous local charge peaks; thus, it can identify hidden threats to powder flow safety.
The PowFEct project will significantly enhance our understanding of powder flow charging and deliver experimental and theoretical methodologies to support safe and clean powder processing in a variety of industrial applications.