An innovative compact high efficiency hydraulic particle separator is disclosed. Featured embodiments of the innovative separator comprise a cylindrical main body having an upper chamber and a lower chamber separated by a partition. A liquid fluid flow upwelling through the partition from the lower chamber is caused to mix with tangential jet of fluid flowing introduced above the partition in the upper chamber produces a spiral flow within the upper chamber and flows upward to the top of the apparatus. Particle mixtures containing low density and high specific gravity particles and other solids are introduced into the upper chamber are immediately contacted by the upward spiral flow, where low-density particles are immediately entrained in the spiral flow and separated from the high-density particles, swept upward and exit the apparatus. High-density particles may be forced outward and collect along the wall of the apparatus, falling through the partition to the lower chamber and settle in a collection vessel.

A screen sorting device for cleaning a fibrous stock suspension includes: an inlet for the fibrous stock suspension; a first sorting stage, which includes a first accepts discharge; at least one second sorting stage, which includes a second accepts discharge; and a fill level detection way, which is configured for detecting an accumulation height in the at least one second sorting stage and is assigned to the at least one second sorting stage.

A screen sorting device for cleaning a fibrous stock suspension includes: an inlet for the fibrous stock suspension; a first sorting stage, which includes a first accepts discharge; at least one second sorting stage, which includes a second accepts discharge; and a fill level detection way, which is configured for detecting an accumulation height in the at least one second sorting stage and is assigned to the at least one second sorting stage.

Separating target particles from discard particles in an aggregate using tailored frequencies in a mineral separation table is described. The separation table comprises a planar surface angled in a z direction along the +x axis at an angle and in the z direction along the +y axis at an angle . A motor is responsive to a first or second vibration wave train received by a controller. The motor vibrates the table with the vibration wave train thereby separating target from discard particles by differences in specific gravity. The first vibration wave train is a plurality of primary half sine waves each followed by a pause. The second vibration wave train is the plurality of the primary half sine waves and a plurality of high frequency sine waves having a frequency that is higher than the primary half sine wave.

Separating target particles from discard particles in an aggregate using tailored frequencies in a mineral separation table is described. The separation table comprises a planar surface angled in a z direction along the +x axis at an angle and in the z direction along the +y axis at an angle . A motor is responsive to a first or second vibration wave train received by a controller. The motor vibrates the table with the vibration wave train thereby separating target from discard particles by differences in specific gravity. The first vibration wave train is a plurality of primary half sine waves each followed by a pause. The second vibration wave train is the plurality of the primary half sine waves and a plurality of high frequency sine waves having a frequency that is higher than the primary half sine wave.