Abstract
This work deals with a non-conventional use of a drum-type electrostatic separator. Indeed, the electrostatic separation process is used as a tool to evaluate the efficiency of different formulations of insulating coatings surrounding coarse and irregular conducting mineral particles. Our analysis is based on the change of the particle’s distribution in the conductive and the non-conductive pans after the electrostatic separation process. Different coating formulations were tested and we found that only hydrophobic components have to be used and that a composite formulation must be considered to sufficiently increase the coating thickness. Viscous hydrophobic oil combined with talc is a particularly relevant coating formulation for insulating hematite or ilmenite particles. The viscosity of the binder plays a crucial role as it guarantees the necessary cohesion of the coating itself. To evaluate the required thickness to obtain efficient insulating capabilities for the coating surrounding coarse and irregular mineral particles, we linked the experimental volume ratio between the coating and the particles and the theoretical ratio. The experimental volume ratio is calculated using the weights of all the materials used and their respective densities. Whereas, the theoretical one is calculated using the volume the mineral particles would have, considering them all identical, spherical, with a smooth surface and the volume of the coating being uniform with the same thickness on each mineral particle. We found that an efficient insulating coating for hematite particles means a thickness of 9.5% of the average mineral radius, ranging from 125 μm to 1250 μm, resulting in an equivalent insulating thickness of about 48 μm for particles of around 1 mm in diameter. Interestingly, all results originate from the analysis of the change occurring in the particle’s distribution in the different collecting pans of an electrostatic separator.
Highlights
Electrostatic separation can be challenging as numerous parameters can affect the efficiency of the separation
We identified the thickness required to completely insulate a conductive mineral particle by covering it with a mix of talc and viscous oil
The required thickness is proportional to the average radius of the mineral particles and depends on the size of the talc
Summary
Electrostatic separation can be challenging as numerous parameters can affect the efficiency of the separation. Three important factors have major impacts on the final result of a separation process conducted with a drum type electrostatic separator. The parameters of the separator itself, such as the roll speed and the filament and electrode positions [4] play a role in the separation results. Some external parameters such as the relative humidity have an important impact. Modifying the electrical properties of the particles can lead to improvements of the separation quality. As electrostatic properties depend on the surface conductivity of the particles, surface modifications can create an obvious change in improving separation. Surface resistivity can be modified by immersing particles in water and by adjusting the pH [7]
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