The present invention relates to a magnetic cleaning tool (100) for removing ferrous debris from within a BOP, riser or wellbore, the tool comprising: a tool body having a longitudinal axis, and one or more magnets (104) configured to rotate around an axis substantially parallel to the longitudinal axis from a first position to a second position. In the first position the one or more magnets attract ferrous debris to a debris gathering surface, and in the second position the one or more magnets do not attract ferrous debris to the debris gathering surface.

A magnetic separator incorporating a rigid frame having left and right rails having longitudinal and oppositely longitudinal ends; longitudinal and oppositely longitudinal rollers respectively mounted at the left and right rails' longitudinal and oppositely longitudinal ends, the longitudinal roller having an interior cylindrical space; a multiplicity of magnets within the interior cylindrical space; a continuous loop belt mounted over the longitudinal and oppositely longitudinal rollers, the belt having a longitudinally movable upper flight, a longitudinal end, and a simultaneously oppositely longitudinally movable lower flight having a longitudinal end; a plenum mounted beneath the lower flight, the plenum having an air input port and having an air output port, the plenum's air output port being positioned for directing a flow of air toward the lower flight's longitudinal end; and an air impeller operatively mounted in communication with the plenum's air input port.

A system for eliminating unexploded ordnance from a mixture. The system includes a separation plant, including a crusher, a magnetic separation station, and a screen plant. The crusher reduces the size of pieces in the mixture, the magnetic separator separates pieces containing a significant amount of ferrous metal, and the screen separates small pieces from larger pieces. The fine output of the screen is composed of pieces that are sufficiently small to pose little hazard; they may be further subjected to heat treatment. Large pieces containing ferrous metal, or large pieces containing nonferrous metal, may be explosive and are transported, using an unmanned machine, to an inspection plant where they are sorted and where any unexploded ordnance is identified and disposed of. The separation plant is sufficiently distant from the inspection plant that an explosion at the separation plant does not pose a hazard to personnel at the inspection plant.

A magnetic drawer separator incorporating at least a first permanent magnet series having a longitudinal, oppositely longitudinal, and outer ends, each permanent magnet having an opening; a longitudinally extending hollow bore within the at least first permanent magnet series, the bore being formed by the permanent magnets' openings; at least a first shaft having longitudinal and oppositely longitudinal ends, the longitudinal end of the at least first shaft engaging the at least first permanent magnet series within the bore; at least a first wiper engaging the outer end of the at least first permanent magnet series; and a frame having longitudinal and oppositely longitudinal ends, wherein the at least first wiper is fixedly attached to the frame's longitudinal end, and wherein the at least first shaft is fixedly attached to the frame's oppositely longitudinal end.

The present application relates to a concentration process of iron minerals from ultrafine tailings (slimes) from iron ore processing through reverse flotation with pH between 8.5 and 10.5 with the addition of amide-amine type collector, or further a mixture thereof with traditional cationic collectors (amines), in the absence of any depressant, alternatively including a step of high field magnetic concentration, which allows to obtain a concentrate with iron content higher than 66% and contents of SiO2+Al2O3 below 4%.

Method for separating first type particles from a mixture of at least first type particles and second type particles, the method comprising contacting in a dispersion medium first type particles and second type particles with magnet type particles, so that in the dispersion medium first type particles agglomerate to magnet type particles to obtain magnetic agglomerates, separating magnetic agglomerates from second type particles by applying a magnetic field; wherein during step an amount of energy is transferred into a mixture of the dispersion medium, first type particles, second type particles and magnet type particles.

A centrifugal liquid separating system broadly comprises an insert cartridge including a housing, an inlet, one or more flow guides, a stator, a compression nozzle, an expansion nozzle, and an outlet. The flow guides guide liquid flowing into the inlet past the stator into the compression nozzle. The stator induces a rotational vortex into the liquid flow. Liquid with heavier particles in the liquid flow is urged to the outside of the rotational vortex. Liquid with lighter particles and cleaner liquid is urged to the inside of the rotational vortex. The compression nozzle and the expansion nozzle are aligned to cooperatively form an annular liquid channel. The liquid with the heavier particles flows through the annular liquid channel and the liquid with the lighter particles and the cleaner liquid flows to the expansion nozzle to the outlet.

A magnet apparatus for generating a high gradient and/or high strength magnetic field, comprises: two permanent magnets (2, 4) located side-by-side with oppositely oriented magnetic field polarities and end surfaces of opposite polarities next to one another, wherein the magnetic anisotropy of the magnets exceeds the magnetic induction of the material of the magnets; and a mask (6) or masks (6) on a first end of each of the adjacent permanent magnets (2, 4), the mask(s) 6 comprising a non-retentive material covering adjacent end surfaces of the two permanent magnets (2, 4) with a gap (8) along a joining line between the two permanent magnets (2, 4) to form a zone of high-gradient magnetic field above the joining line; wherein the mask(s) (6) are embedded within the magnets (2, 4) and/or have a varying thickness and wherein the mask(s) (6) each have a maximum thickness greater than a tenth of the thickness of the respective magnet (2, 4).

The subject of the present invention is a method for processing electrical and electronic components in order to recover valuable materials, such as the metals contained in printed circuit boards. According to this method, the electrical and electronic components are pre-shredded mechanically and then mixed with a liquid before they undergo wet milling (5).

Methods of reducing copper metal content of shredded scrap steel are provided. The method includes continuously separating a first scrap steel fraction from an amount of scrap steel concurrently with separating a second fraction from the amount of scrap steel; continuously separating the second fraction and providing a nonmagnetic fraction and, concurrently, a third scrap steel fraction; grinding the nonmagnetic fraction followed by magnetic separation to provide a fourth scrap steel fraction and, concurrently, an enriched nonmagnetic fraction; continuously combining the first scrap steel fraction, the third scrap steel fraction, and the fourth scrap steel fraction to obtain a combined scrap steel product comprising scrap steel with reduced copper metal content; and introducing the combined scrap steel product to an electric arc furnace. Systems of reducing copper metal content of shredded scrap steel are also provided.