A filter for removing ferrous particles from a fluid. The filter has an outer filter housing and a non-ferrous liner inside the housing. A plurality of magnets are longitudinally extended at intervals outside the liner. An insert inside the liner imparting a directional flow to the fluid inside the filter whereby ferrous particles in the fluid are trapped by the magnets and held against the non-ferrous line.

A particle separator including a rotor disposed inside a housing. The rotor has a plurality of magnetic sections that are arranged with alternating poles. A drive rotates the rotor to generate a changing magnetic field. Magnetic particles and non-magnetic conductive particles are removed from a liquid that flows through the particle separator. The magnetic particles attach to the rotor and the non-magnetic conductive particles are repelled away from the rotor by the changing magnetic field.

A magnet cleaner cooperates with one or more permanent magnets positioned over a conveyer carrying pieces of metal in non-ferrous material so as to remove the metal from the non-ferrous material. The magnet cleaner includes a frame and a capture sheet mounted to the frame and positioned on the frame so as to be substantially flush with the permanent magnets when they are in their lowered positioned. The magnets are spaced by an attenuation distance from the capture sheet when they are in their raised position. The permanent magnets, which may be mounted in a housing, are positionably mounted on the frame so as to be selectively elevatable between their lowered and raised positions upon actuation of an actuator. The actuator is positioned so as to cooperate with the permanent magnets and the frame so as to raise or lower the magnets relative to the capture sheet.

Weld balls disposed in solutions in full immersion tanks of a phosphate system are collected by magnets attached to at least some of the hangers that carry skids through stages of the phosphate system. The magnet attached to a hanger is immersed in the solutions when the hanger is immersed in the solutions and magnetically attracts the weld balls.

The invention relates to a magneto-centrifugal flotation cell for ore concentration which reduces water consumption. A disadvantage of conventional flotation cells is the use of a large amount of water, some flotation cells requiring at least 60% water. The present invention uses ore pulp with increased density and viscosity, owing to the application of an axial magnetic field, wherein the Lorentz force, which is the force exerted by an electromagnetic field that receives a charged particle or an electrical current, can be used. The solution is a cell which, in addition to the forces that usually act on conventional flotation cells, uses external forces which, in principle, produce synergy in the separation of ore particles that have different gravitational and magnetic properties.

An automatic purification system using magnetic particles comprises: 1) a first container module; and 2) a system controller module. The first container module comprises a first container and a first magnetic field supply device disposed outside the first container. A first container liquid inlet is formed in the upper portion of the first container, and a first container liquid outlet is formed in the bottom of the first container. The system controller module can generate a variable magnetic field in the first container by controlling the first magnetic field supply device. A method for purifying a target component from a biological sample comprises a step for allowing a biological sample containing a target component to be in contact with magnetic particles capable of specifically binding the target component, in the first container in the automatic purification system. The automatic purification system and method help to efficiently separate a target product from a biological sample, and helps to reduce process costs and time at the same time.

The invention relates to a system, comprising: a) a sample processing unit, comprising an input port and an output port coupled to a rotating container having at least one sample chamber, the sample processing unit configured provide a first processing step to a sample or to rotate the container so as to apply a centrifugal force to a sample deposited in the chamber and separate at least a first component and a second component of the deposited sample; and b) a sample separation unit coupled to the output port of the sample processing unit, the cell separation unit comprising separation column holder (42), a pump (64) and a plurality of valves (1-11) configured to at least partially control fluid flow through a fluid circuitry and a separation column (40) positioned in the holder, the separation column configured to separate labeled and unlabeled components of sample flowed through the column.

A basket strainer insert having a body with one or more magnets disposed therein. The basket strainer insert includes a baffle that is removable. The movement of withdrawing the baffle from the body allows magnetic debris to be removed. A baffle may be disposed at the center of the elongate intermediate portion of the body. The baffle may comprise a collar and two or more symmetrical lobes, each lobe comprising an upper portion and a lower portion. Alternatively, the baffle may be a hollow shape with a plurality of apertures.

A solenoid valve may include a magnetic force generating coil applied with power to generate an electromagnetic force, a valve spool disposed to reciprocate depending on the electromagnetic force generated from the magnetic force generating coil, a holder including a hollow into which the valve spool inserted, the holder forming a plurality of ports to be opened and closed depending on the reciprocating of the valve spool, and a permanent magnet disposed to enclose the hollow of the holder.

A blood purification device or the like capable of confirming that magnetic particles have been separated and removed from blood. A blood purification device includes a main flow channel configured to allow blood flows; a magnetic extraction unit (magnetic extraction means) to collect magnetic particles with a magnetic force, the magnetic particles being contained in blood; and one or more magnetic sensor configured to be capable of detecting a presence of the magnetic particles in blood. Each of the magnetic particles has, on at least a part of its outer circumferential portion, a modified part being modified with a separation-target capturing material which is capable of capturing a specific substance to be separated in the blood.