A method and system is used to process slag material to yield by-products including a finished iron rich product and a finished low iron fines product. The by-products may include a finished high iron product and a finished medium iron product. The method and system include size classifying the material into a plurality of sized groups prior to using magnetic separation to separate at least one of the sized groups into two portions having differing magnetic susceptibilities. The method and system may include more than one phase of size classifying the material into a plurality of sized groups and using magnetic separation to separate at least one of the sized groups into portions, where the average size of the material remaining after one phase is reduced prior to the subsequent phase.

A method and system is used to process slag material to yield by-products including a finished iron rich product and a finished low iron fines product. The by-products may include a finished high iron product and a finished medium iron product. The method and system include size classifying the material into a plurality of sized groups prior to using magnetic separation to separate at least one of the sized groups into two portions having differing magnetic susceptibilities. The method and system may include more than one phase of size classifying the material into a plurality of sized groups and using magnetic separation to separate at least one of the sized groups into portions, where the average size of the material remaining after one phase is reduced prior to the subsequent phase.

Provided is a method of restoring arsenic-contaminated soil. In the present invention, arsenic may be easily separated from soil particles by washing the arsenic-contaminated soil by using a basic solution and simultaneously irradiating the soil with ultrasonic waves. Also, since iron oxide and manganese oxide are exposed to the basic solution by dissolving a portion of the surface of a silicate mineral using the basic solution, a residual form of arsenic may be removed.

Provided is a method of restoring arsenic-contaminated soil. In the present invention, arsenic may be easily separated from soil particles by washing the arsenic-contaminated soil by using a basic solution and simultaneously irradiating the soil with ultrasonic waves. Also, since iron oxide and manganese oxide are exposed to the basic solution by dissolving a portion of the surface of a silicate mineral using the basic solution, a residual form of arsenic may be removed.

The present invention provides a method for filtration of CTCs directly out of patient blood and returning the blood after filtration to the patient. CTCs are an important factor for diagnosis and prognosis of cancer patients and can cause cancer metastasis. By eliminating CTCs from the bloodstream the chances for metastasis reduction decrease.

The present invention provides a method for filtration of CTCs directly out of patient blood and returning the blood after filtration to the patient. CTCs are an important factor for diagnosis and prognosis of cancer patients and can cause cancer metastasis. By eliminating CTCs from the bloodstream the chances for metastasis reduction decrease.

A magnetic device includes a holder; a plurality of conduits mounted on the holder; a plurality of magnetic assemblies, each magnetic assembly including a soft magnetic center pole having a bottom end and a tapered tip end; first and second soft magnetic side poles disposed on opposite sides of the soft magnetic center pole and respectively having first and second top ends that are bent towards the soft magnetic center pole; and a magnetic flux source generating a magnetic flux in the soft magnetic center pole and the first and second soft magnetic side poles, the magnetic flux being concentrated from the bottom end to the tapered tip end of the soft magnetic center pole and divided between the first and second top ends. Each conduit is disposed in a gap formed between the tapered tip end and the first and second top ends of a respective magnetic assembly.

A magnetic device includes a holder; a plurality of conduits mounted on the holder; a plurality of magnetic assemblies, each magnetic assembly including a soft magnetic center pole having a bottom end and a tapered tip end; first and second soft magnetic side poles disposed on opposite sides of the soft magnetic center pole and respectively having first and second top ends that are bent towards the soft magnetic center pole; and a magnetic flux source generating a magnetic flux in the soft magnetic center pole and the first and second soft magnetic side poles, the magnetic flux being concentrated from the bottom end to the tapered tip end of the soft magnetic center pole and divided between the first and second top ends. Each conduit is disposed in a gap formed between the tapered tip end and the first and second top ends of a respective magnetic assembly.

A method and system for separating valuable material, such as precious metals and rare earth elements, from a raw material, such as coal, is disclosed. The system may include a crusher or pulverizer for producing finely crushed material. This crushed material may be made into a slurry and placed into an econosizer for separating material by its specific gravity. High specific gravity material may be further refined using magnets, separators, or centrifuges, among other disclosed components of the system.

A method and system for separating valuable material, such as precious metals and rare earth elements, from a raw material, such as coal, is disclosed. The system may include a crusher or pulverizer for producing finely crushed material. This crushed material may be made into a slurry and placed into an econosizer for separating material by its specific gravity. High specific gravity material may be further refined using magnets, separators, or centrifuges, among other disclosed components of the system.