This invention is for an innovative magnetic air separator (MAS) for delivering oxygen-enriched air or near-pure oxygen to for advanced combustion, coal gasification, industrial processes, and medical applications. In the MAS of the subject invention, input air is drawn into a large array of microchannels immersed in a strong, spatially varying magnetic field. Magnetic forces accelerate the paramagnetic O2 molecules within the microchannel flow and in a direction perpendicular to it, thus forming enriched and depleted streams. Such streams are then physically separated and subsequently combined according to their level of O2 enrichment or depletion. Highly enriched streams are repeatedly subjected to the magnetic separation process until the targeted level of O2 concentration is reached in selected streams. Partially enriched streams are recycled and fed back into the process feedstock air, while depleted streams are vented from the process.

This invention is for an innovative magnetic air separator (MAS) for delivering oxygen-enriched air or near-pure oxygen to for advanced combustion, coal gasification, industrial processes, and medical applications. In the MAS of the subject invention, input air is drawn into a large array of microchannels immersed in a strong, spatially varying magnetic field. Magnetic forces accelerate the paramagnetic O2 molecules within the microchannel flow and in a direction perpendicular to it, thus forming enriched and depleted streams. Such streams are then physically separated and subsequently combined according to their level of O2 enrichment or depletion. Highly enriched streams are repeatedly subjected to the magnetic separation process until the targeted level of O2 concentration is reached in selected streams. Partially enriched streams are recycled and fed back into the process feedstock air, while depleted streams are vented from the process.

A magnetic cleaning device includes a handle unit, a main unit, and a deforming mechanism. The main unit includes a housing and a magnetic member. The deforming mechanism is connected between the handle unit and the main unit. The housing defines an accommodating space extending along an axis. The magnetic member is disposed in the accommodating space, and is movable along the axis between an attraction position, where the magnetic member is adjacent to an end of the housing, and a non-attraction position, where the magnetic member is away from the end of the housing. The main unit is movable relative to the handle unit via operation of the deforming mechanism.

A waste management system for plastic or other material floating on the surface and in the subsurface of a body of water. A shredding device will reduce the size of the particles of waste. Ocean water is removed by a drying device. The dried waste material is frozen to a temperature at or below minus fifty degrees Fahrenheit, using liquid nitrogen or other suitable means. The frozen waste material is then pulverized and ground into a powder. The powder may then be sprayed into a gas-filled chamber and heated. Temperature, pressure and humidity are maintained within the chamber for more than one minute. Microwave or other radiation and catalysts may be used to enhance the process of extraction. The processed material is then removed from the chamber. Carbon may be recycled or used as fuel by the ship. Water may be used by the ship or returned to the ocean.

A foreign substance capturing apparatus according to an embodiment of the present invention may comprise: a capturing body unit having an inlet port for introducing the air including magnetic foreign substances and an outlet port for discharging the air from which the magnetic foreign substances have been removed; and a magnetic isolation unit connected to the capturing body unit, including a magnetic member for isolating, by an attractive force, the magnetic foreign substances from the air flowing in the capturing body unit, and provided with a non-magnetic member surrounding the magnetic member.

A ferromagnetic material sequestering device for separating metals from a waste stream generated by a vacuum includes a shell, which has a bottom and a top. The bottom is open and a hole is positioned in the shell proximate to the top. A connector is engaged to the shell proximate to the hole engages a hose that is operationally engaged to a vacuum generator so that the vacuum generator is in fluidic communication with the shell. The vacuum generator is positioned to suction a mixture of objects through the shell. A magnet is engaged to the shell and magnetically engages ferromagnetic materials in the mixture of objects. The ferromagnetic materials thus are sequestered within the shell and can be reclaimed.

The invention provides an electrostatic precipitator, including: a gas inlet, supplied with gas containing dust that is a magnetic substance; a charging part, charging the dust; a collecting part, capturing the charged dust; a cleaning device, including at least one of a charging part cleaning device and a collecting part cleaning device; a magnet filter, provided downstream of the collecting part; an ozone removing filter, provided downstream of the magnet filter and removing ozone from the gas; and a gas outlet, discharging the gas in which the dust and the ozone are removed. In the magnet filter, multiple magnet plates are arranged at a predetermined interval. A downstream side of each magnet plate provided on an upper side with respect to a center is inclined downward. A downstream side of each magnet plate provided on a lower side with respect to the center is inclined upward.

A magnetic separation device has a membrane having a plurality of pores, a magnetically soft material layer disposed on the membrane, and a passivation layer disposed on the magnetically soft material layer. The magnetic separation device may be part of a microfluidic device having a lateral flow channel and a vertical flow magnetic separation filter. The magnetic separation device may be used to separate magnetically tagged particles, such as cells.

A magnetic separation device has a membrane having a plurality of pores, a magnetically soft material layer disposed on the membrane, and a passivation layer disposed on the magnetically soft material layer. The magnetic separation device may be part of a microfluidic device having a lateral flow channel and a vertical flow magnetic separation filter. The magnetic separation device may be used to separate magnetically tagged particles, such as cells.

A printer is described that comprises a print chamber and an electromagnet moveable within the print chamber. The electromagnet has an on state and an off state. The electromagnet is to collect magnetic powder within the print chamber when in the on state, and to deposit magnetic powder when in the off state.