A method for electromagnetic stirring of liquid metal in a continuous charge electric arc furnace, in which there are positioned a first electromagnetic field along a first axis of electromagnetic stirring and a second electromagnetic field along a second axis of electromagnetic stirring.

Apparatus and methods for stirring a molten metal are provided. The apparatus comprising: an electromagnetic stirrer, the electromagnetic stirrer including a core, the core being provided with two or more teeth, the core being provided with two or more electrically conducting coils; connections for applying a current to the electrically conducting coils; wherein the two or more teeth have an end proximal the core and an end distal the core, the end distal the core defining a tooth end face, the tooth end face for at least one of the teeth not being aligned with the tooth end face for at least one of the other teeth. In this way the air gap between the teeth and the container in which molten metal is to be stirrer can be kept small, even with curved walls or bases to the container.

Apparatus and methods for stirring a molten metal are provided. The apparatus comprising: an electromagnetic stirrer, the electromagnetic stirrer including a core, the core being provided with two or more teeth, the core being provided with two or more electrically conducting coils; connections for applying a current to the electrically conducting coils; wherein the two or more teeth have an end proximal the core and an end distal the core, the end distal the core defining a tooth end face, the tooth end face for at least one of the teeth not being aligned with the tooth end face for at least one of the other teeth. In this way the air gap between the teeth and the container in which molten metal is to be stirrer can be kept small, even with curved walls or bases to the container.

The present invention relates to a particle manipulation method to disperse magnetic particles 70 in a liquid 35 filling up a tube container 10, wherein a circumferential direction moving step to move the magnetic particles 70 along the circumferential direction of the container 10 in the liquid 35 and in a radial direction moving step to move the magnetic particles 70 as crossing the radial direction of the container 10 in the liquid 35 are implemented repeatedly. Such manipulations can be achieved by combining rotation of the container and gravity force and magnetic field manipulations.

There is provided a method and apparatus for indirect magnetic treatment of fluids/gases, where a magnetic or electromagnetic field having a certain dimension, geometry and flux density is, in a first step, applied to a working fluid/gas to obtain the directly magnetized fluid/gas. Then the directly magnetized fluid/gas is used in a second step as a magnetizer or a magnetic treating agent for magnetizing indirectly the normal non-magnetized fluid/gas by mixing the directly magnetized fluid/gas and normal non-magnetized fluid/gas in accordance with a predetermined mixing ratio and mixing method between the directly magnetized fluid/gas and normal non-magnetized working fluid/gas. Afterwards, the resultant mixed or indirectly-magnetized fluid/gas is used in the proper application directly or stored in a storage tank for later use. Possible applications for the invention include, but not limited to, all previous applications of the direct magnetic treatment of fluid/gas such as water treatment, hydrocarbon fuel treatment.

Provided is an ultrafine bubble generation device. A device 10 includes a rotary blower 31a, a rotary mixer 11, and a bubble shear filter 21. The rotary mixer 11 includes a hollow part 13 including a vertex X inside, an inflow hole 12 for introducing a fluid and a discharge hole 16. In an inner wall surface of the hollow part 13, a groove 14 having a spiral shape for the fluid introduced from the inflow hole 12 is provided, and the discharge hole 16 is provided away from the vertex X of the spiral shape on an axis of the spiral shape. The bubble shear filter 21 is provided with a hollow part inside, and includes an inflow hole 24 for introducing the fluid into the hollow part, and a discharge hole 26 for discharging the fluid. The hollow part is tubular, a plurality of plate-like thin plates 22 and 23 are arranged perpendicularly to a central axis of the hollow part such that the central axis passes through a center point of each circular plate, adjacent thin plates are provided with a plurality of openings and a plurality of pointed end portions, and a pointed end portion 25a and an opening 25b of the adjacent thin plates are arranged to face each other.

A system and a method for determining/predicting a tapping time for a metal melt in an electric arc furnace (EAF), at least one electrode is provided for melting the metal melt until it reach a target tapping temperature, the EAF further includes a slag and smoke layer on the surface of the metal melt, wherein an electromagnetic stirrer is provided for stirring the metal melt.

Apparatus and methods for stirring a molten metal are provided. The apparatus comprising: an electromagnetic stirrer, the electromagnetic stirrer including a core, the core being provided with two or more teeth, the core being provided with two or more electrically conducting coils; connections for applying a current to the electrically conducting coils; wherein the two or more teeth have an end proximal the core and an end distal the core, the end distal the core defining a tooth end face, the tooth end face for at least one of the teeth not being aligned with the tooth end face for at least one of the other teeth. In this way the air gap between the teeth and the container in which molten metal is to be stirrer can be kept small, even with curved walls or bases to the container.

Apparatus and methods for stirring a molten metal are provided. The apparatus comprising: an electromagnetic stirrer, the electromagnetic stirrer including a core, the core being provided with two or more teeth, the core being provided with two or more electrically conducting coils; connections for applying a current to the electrically conducting coils; wherein the two or more teeth have an end proximal the core and an end distal the core, the end distal the core defining a tooth end face, the tooth end face for at least one of the teeth not being aligned with the tooth end face for at least one of the other teeth. In this way the air gap between the teeth and the container in which molten metal is to be stirrer can be kept small, even with curved walls or bases to the container.

In one embodiment, a treatment system for removing dissolved contaminants (e.g., arsenic) from a contaminated fluid (e.g., water) utilizes in-situ generation of adsorption filtration media or reactive components. Corrosion materials (e.g., iron oxide complexes) that serve as the adsorption filtration media or reactive components are generated by supplying a flow of contaminated fluid, and injecting air, into a generator vessel containing pieces of an oxidizable source (e.g., zero-valent iron spheres). The pieces of the oxidizable source are agitated to release particulates of corrosion materials from their surface into solution with the contaminated fluid. Simultaneous to the ongoing generation of corrosion materials, dissolved contaminants in the contaminated fluid are adsorbed on the corrosion materials. New particulate compounds generated by adsorption of the dissolved contaminants on the corrosion materials precipitate from the solution, and are filtered out, thereby removing the contaminants, and yielding treated fluid (e.g., potable water).