A method for performing a magnetic separation procedure that includes transporting a receptacle containing a fluid medium to a first location of a system, where the fluid medium contains both a sample material and a suspension of magnetically-responsive solid supports. At the first location, the fluid medium is exposed to a first magnetic field for a first dwell period, thereby isolating the solid supports within the receptacle, where no portion of the fluid medium is removed from the receptacle at the first location. The receptacle is then transported from the first location to a second location of the system, where the fluid medium is exposed to a second magnetic field for a second dwell period. Following the second dwell period, at least a portion of the fluid medium is removed from the receptacle. A suspension fluid is then dispensed into the receptacle, and the contents of the receptacle are agitated to suspend the solid supports within the suspension fluid.

A method for performing a magnetic separation procedure that includes transporting a receptacle containing a fluid medium to a first location of a system, where the fluid medium contains both a sample material and a suspension of magnetically-responsive solid supports. At the first location, the fluid medium is exposed to a first magnetic field for a first dwell period, thereby isolating the solid supports within the receptacle, where no portion of the fluid medium is removed from the receptacle at the first location. The receptacle is then transported from the first location to a second location of the system, where the fluid medium is exposed to a second magnetic field for a second dwell period. Following the second dwell period, at least a portion of the fluid medium is removed from the receptacle. A suspension fluid is then dispensed into the receptacle, and the contents of the receptacle are agitated to suspend the solid supports within the suspension fluid.

A drum type separation apparatus includes a liquid passage that allows a liquid mixed with a magnetic body to pass therethrough, a rotary drum that is disposed such that a part of the rotary drum is exposed above a liquid surface in the liquid passage, and transports the magnetic body adsorbed on an outer peripheral surface as the rotary drum rotates, and a magnet that is disposed on an inner side of the rotary drum, in which a magnetic force on a side lower than the liquid surface from an intersection position where the rotary drum and the liquid surface intersect each other is larger than a magnetic force on a side higher than the liquid surface from the intersection position.

The invention relates to a method for operating a fluidized bed boiler (6), comprising the steps of: a) providing fresh ilmenite particles having a shape factor of 0.8 or lower as bed material to the fluidized bed boiler (6); b) carrying out a fluidized bed combustion process; c) removing at least one ash stream comprising ilmenite particles from the fluidized bed boiler; d) separating ilmenite particles from the at least one ash stream, wherein the separation includes a step of using a magnetic separator (12) comprising a field strength of 2,000 Gauss or more; e) recirculating separated ilmenite particles into the bed of the fluidized bed boiler; wherein the average residence time of ilmenite particles in the fluidized bed is 100 h or more.

The invention relates to a method for operating a fluidized bed boiler (6), comprising the steps of: a) providing fresh ilmenite particles having a shape factor of 0.8 or lower as bed material to the fluidized bed boiler (6); b) carrying out a fluidized bed combustion process; c) removing at least one ash stream comprising ilmenite particles from the fluidized bed boiler; d) separating ilmenite particles from the at least one ash stream, wherein the separation includes a step of using a magnetic separator (12) comprising a field strength of 2,000 Gauss or more; e) recirculating separated ilmenite particles into the bed of the fluidized bed boiler; wherein the average residence time of ilmenite particles in the fluidized bed is 100 h or more.

An operation pipe and a device equipped with the operation pipe, which use a gel to perform operations such as separation, extraction, purification, elution, recovery, analysis and the like of target components that are biological components such as nucleic acids. More specifically, an operation pipe and a device, with which it is possible to perform operations such as separation, extraction, purification, elution, recovery, analysis and the like of target components in a sealable pipe by operating magnetic particles in the pipe under a magnetic field from outside of the pipe.

An operation pipe and a device equipped with the operation pipe, which use a gel to perform operations such as separation, extraction, purification, elution, recovery, analysis and the like of target components that are biological components such as nucleic acids. More specifically, an operation pipe and a device, with which it is possible to perform operations such as separation, extraction, purification, elution, recovery, analysis and the like of target components in a sealable pipe by operating magnetic particles in the pipe under a magnetic field from outside of the pipe.

A magnetic separating conveyor output roll including a first plurality of magnetic rings, each of such magnetic rings having radially inner and radially outer ends, each such magnetic ring having annular north and south poles respectively positioned at its radially inner and radially outer ends; and including a second plurality of magnetic rings having radially inner and radially outer ends, each such magnetic ring having annular north and south poles respectively positioned at its radially outer and radially inner ends; wherein the first and second pluralities of magnetic rings are stacked in an alternating series along a rotation axis; wherein each magnetic ring's radial cross section is rectangular; wherein each magnetic ring includes a circumferential array of radially extending seams, the roll incorporating a plurality of adhesive bonds residing within such seams; the roll further incorporating magnetic armature effect resisting gaps between adjacent pairs of the magnetic rings.

A tailings recovery process comprises: feeding ore pulp into a concentration barrel of a concentrating machine; driving the concentration barrel to rotate around its own central axis while the ore pulp flows, so as to enable the ore pulp to be continuously stirred and turn over in inner cavity of the concentration barrel; applying a magnetic field to the ore pulp by means of a magnetic field generation device; accurately sorting the ore pulp by means of a classifier, so as to enable selected minerals in the ore pulp to be exposed under the action of the magnetic field in processes of rising and dropping, thus attaching to an inner wall of the concentration barrel and moving upwards until reaching a collecting area; by making the selected minerals fall into a material receiving trough of the concentrating machine in the collecting area, enabling other materials in the ore pulp except the selected minerals to enter into a tailings trough of the concentrating machine at the bottom of the inner cavity of the concentration barrel and then into a tailings conveying system.

A tailings recovery process comprises: feeding ore pulp into a concentration barrel of a concentrating machine; driving the concentration barrel to rotate around its own central axis while the ore pulp flows, so as to enable the ore pulp to be continuously stirred and turn over in inner cavity of the concentration barrel; applying a magnetic field to the ore pulp by means of a magnetic field generation device; accurately sorting the ore pulp by means of a classifier, so as to enable selected minerals in the ore pulp to be exposed under the action of the magnetic field in processes of rising and dropping, thus attaching to an inner wall of the concentration barrel and moving upwards until reaching a collecting area; by making the selected minerals fall into a material receiving trough of the concentrating machine in the collecting area, enabling other materials in the ore pulp except the selected minerals to enter into a tailings trough of the concentrating machine at the bottom of the inner cavity of the concentration barrel and then into a tailings conveying system.