Abstract: The present invention provides a cooling medium flow path for improving cooling efficiency of a cooling medium used for liquid-cooling systems for motors, radiators and the like. The cooling medium flow path according to the present invention is capable of increasing cooling efficiency of a cooling medium by providing magnetic members for generating a magnetic force in a direction substantially perpendicular to the flow direction of the cooling medium so that clusters of a liquid, such as cooling water, antifreeze liquid or the like flowing through the flow path may be finely divided or activated.

Abstract: The present invention provides a magnetic sink strainer with at least one magnet securely attached to the strainer, to create a magnetic field. The invention also provides a magnetic sink strainer made of a magnetized material to provide a magnetic field. The magnetic sink strainer is firmly placed over a standard sink drain and functions to capture and retain objects that are attracted by a force as a result of being subjected to the magnetic field. This prevents such objects from accidentally being discarded into the sink drain. The magnetic sink strainer also includes at least one slit to enable fluids and other non-magnetic substances to easily and rapidly flow down to the sink drain.

Abstract: The present invention provides inexpensive, safe and reliable methods and systems for enhancing the effectiveness of aqueous or non-aqueous, concentrated or non-concentrated, cleaning compositions, such as concentrated cleaning liquids, by “energizing” all, or a portion, of the water that is employed in the compositions, and/or in diluted aqueous or non-aqueous compositions, and/or of the compositions, and to enhanced cleaning compositions that are safe for use by human beings.

Abstract: Apparatus and method for manipulating particles on a micro- or nano-scale. An embodiment of the present invention includes a magnetic micro-manipulation technique that utilizes micro-coils and soft magnetic microscopic wires for localized manipulation of particles. Another embodiment of the present invention uses magneto-static interaction between two magnetic microscopic wires to mechanically manipulate particles. Yet another embodiment of the present invention combines a magnetic particle with a magnetic manipulator or other device for generating magnetic fields to operate as a micro-fluidic micro-motor. Other embodiments of the present invention employ a magnetic separation system employing porous membranes partially filled with magnetic wires.

Abstract: A magnetic filter device for filtering ferromagnetic material from a fluid in which said material is suspended, has a pair of annular plates (5, 6) attached to either side of an annular magnet (2) of smaller diameter. Pairs of pole pieces (11, 12) radially disposed on the plates (5, 6) are aligned so as to generate fields of magnetic flux which promote the collection and retention of ferromagnetic material between the pairs of pole pieces (11, 12).

Abstract: A method and a device for treating water using an electromagnetic field. The method comprising the steps of subjecting the water to the electromagnetic field generated utilizing an inductor coil; and varying a frequency of a driving signal for the inductor coil such that the generated electromagnetic field has a varying frequency.

Abstract: A magnetic knife block is provided for temporary installation along a hydraulic flow conduit of a cutting system, in lieu of a conventional hydraulic water knife fixture, for collecting metal debris attributable to construction and/or maintenance activity. The magnetic knife block includes at least one and preferably multiple magnets for collecting metal debris upon initial water flow through the cutting system. The magnetic water knife block is then removable from the hydraulic flow conduit and replaced by the conventional water knife fixture for normal cutting operation, such as cutting a succession of raw potatoes into elongated French fry strips.

Abstract: A method and apparatus for removing soluble and insoluble contaminants from highly purified and ultra-pure liquids having a bulk resistivity in excess of one megohm-centimeter by establishing laminar flow of the liquid in a cylindrical chamber through an electromagnetic field transverse to the direction of flow, to induce mobility of the constituents. The wall of the chamber forms a cathode and a central rod forms an anode in the chamber. The mobilized constituents are transported either to the anode or the cathode, where the material will adhere and agglomerate with other constituents. Systems are provided utilizing the method and apparatus for purifying and analytically evaluating highly purified and ultra-pure water.

Abstract: The invention relates to a method which uses magnetic ionic liquids for the liquid-liquid, liquid-solid, or liquid-gas extraction, wherein the partition of the phases occurs in a magnetic field.

Abstract: The present invention discloses a system for separating minerals in drilling fluid based primarily on density. The separator creates and maintains a slurry with a controllable density for separating minerals from drill cuttings. The density if controlled through the use of an electrode array. The separator comprises a primary separation chamber containing the dense shiny, and a multiple number of secondary separation chambers used to separate cuttings from the drilling fluid. The invention also contains inlet hardware allowing the mixed mineral suspension to enter the first separation chamber, and hardware allowing the three outlet (separated) streams to exit the device. One of the three outlet streams carries the minerals that have a density greater than the user selectable density set point, while the second carries the minerals that have a density less than the density set point, and the third carries clean drilling fluid.

Abstract: Self-assembly of magnetic microparticles in AC magnetic fields. Excitation of the system by an AC magnetic field provides a variety of patterns that can be controlled by adjusting the frequency and the amplitude of the field. At low particle densities the low-frequency magnetic excitation favors cluster phase formation, while high frequency excitation favors chains and netlike structures. For denser configurations, an abrupt transition to the network phase was obtained.

Abstract: The present invention relates to an automatic refining apparatus for separating target materials from a plurality of biological sample solutions by using magnetic particles to which the magnetic particles are to be reversibly coupled, and to a multi-well plate kit for use in the automatic refining apparatus. Further, the present invention relates to a method for extracting nucleic acids from biological samples by using the above-described automatic refining apparatus. The present invention can be used in the automatic separation of nucleic acid, protein, and the like from biological samples.

Abstract: A technique for inhibiting biofouling caused by biofilms grown on a material surface of a water system where microorganisms exist such as the membrane surface of a membrane bioreactor (MBR) for advanced wastewater treatment is disclosed. Specifically, a magnetic carrier comprising an enzyme for quenching quorum sensing that inhibits biofilm formation, a membrane bioreactor system that can be stably operated without inactivation and loss of enzymes and a method for inhibiting biofilm formation are described.

Abstract: The present invention provides an apparatus and method of producing transformed water without contact between the original transformed water and the water to be transformed. This is accomplished by organizing the original transformed water into a geometric contained arrangement such that a central cavity is created that substantially surrounds the water that is to be transformed. The water to be transformed is placed into a confined vessel such as a cylindrical container or a pipe inside the central cavity for about sixty seconds. This water then becomes transformed in the same likeness of the molecular clustering of the original transformed water.

Abstract: An assembly (1) for preparing mineral water in situ, including a container (2) filled with a mineral concentrate (4) and a dosing device (6) connected to the holder for dispensing the concentrate from the container in a dosed manner, the dosing device being provided with a housing (15) including an inlet (16), an outlet (18), a liquid flow path (20), a pump (22), and a magnetizable or magnetic operating element (24). The operating element is being included in the housing for carrying out a predetermined movement relative to the housing with the aid of a changing magnetic field and the operating element is mechanically connected to the pump for driving the pump when the operating element carries out the predetermined movement. The operating element is manufactured, from corrosion resistant steel, or the operating element is provided with a corrosion resistant coating such as gold, silver or Teflon or the operating element is manufactured, from a magnetizable and/or magnetic ceramic material.

Abstract: Described are a device and a method for the manipulation of a liquid sample material in which magnetic microparticles are suspended whereby the microparticles have a functionalized surface and an analyte is bound to the surface. The sample material is introduced into a device with a liquid system through an injection device (50) and in a first mobile phase the sample material is carried to an extractor (90). In a section (97) of the extractor (90) the microparticles are immobilized by means of a magnetic field of a controllable means (96) and separated from the remaining sample material. By switching over of a switching unit (110) a second mobile phase (75) is carried to the extractor (90) and the second mobile phase (75) detaches the adsorbed analyte from the surface of the microparticles. The second mobile phase (75) with the dissolved analyte(s) can be analyzed by way of chromatographic separation (130) and subsequent detection (140).

Abstract: The present invention relates to a device and a method for treating liquids with magnetic particles, wherein at least one further central element which ensures collection and homogenization of the particles is additionally provided.

Abstract: A device for washing and isolating magnetic particles from a continuous fluid flow in at least one fluidic channel having an inlet at one end and an outlet at another end, said device comprising at least one magnetic source carrier arranged proximate to the at least one fluidic channel. The at least one magnetic source carrier is moveable between a first position and a second position. The at least one magnetic source carrier comprises at least one first magnetic source, wherein a movement of the at least one magnetic source carrier to the first position places the at least one first magnetic source at a first spatial location along the at least one fluidic channel such that said at least one first magnetic source generates a maxima magnetic field at said first spatial location that attracts the magnetic particles from the continuous fluid flow and assembles said magnetic particles at said first spatial location.

Abstract: A continuously operating magnetic particle separating machine includes an inlet for receiving a material having magnetic particles mixed therein, an outlet for discharging the material after the magnetic particles have been separated therefrom, a first flow path extending between the inlet and the outlet, a first magnetic element positionable in the first flow path, a second flow path extending between the inlet and the outlet, and a second magnetic element positionable in the second flow path. The separating machine includes a control system including a diverter valve switchable between a first position for directing the material through the first flow path and a second position for directing the material through the second flow path, whereby the switching frequency of the diverter valve is responsive to a concentration of the magnetic particles in the material.

Abstract: A reusable magnetic device for the extraction of ferrous particles from a body of fluid, wherein the device comprises a plurality of magnets and soft ferrous metal spacers arranged in an alternating sequence to form a stack, adjacent magnets being arranged with like poles facing, a non-magnetic and non-ferrous end piece terminally disposed at a first end of the stack, and a non-magnetic housing that contains the magnets, the spacers and the end piece. The magnetic device can be installed in a vessel to provide a fluid filtering assembly.

Abstract: Techniques for fabricating magnetic nanoparticles are provided. In one embodiment, a method performed under the control of at least one apparatus for fabricating magnetic nanoparticles includes preparing a substrate that defines at least one cavity through a portion thereof, soaking the substrate with a solution, the solution including a multiple number of magnetic nanoparticles, and applying a magnetic field so as to collect at least a portion of the magnetic nanoparticles into the at least one cavity.

Abstract: A rod assembly for the extraction of magnetizable particles from solutions is described. The rod assembly includes at least one guide element. A rod element is insertable into the at least one guide element and moveable in a direction substantially parallel to the at least one guide element. A magnet element is moveable to a distal magnet element position; wherein the distal magnet element position is located on a distal end section of the at least one guide element; wherein the at least one guide element includes an opening at a distal end. A method for the extraction of magnetizable particles from solutions is also described, as well as a magnet element for the extraction of magnetizable particles from solutions.

Abstract: A device facilitating mixing of a fluid containing magnetic or magnetizable particles, including a support for a container for the fluid and particles, a first magnet adjacent one side of the support, a second magnet adjacent the other side, and a drive for moving the second magnet between a first position near the container top and a second position near the container bottom. The first magnet is supported in a third position on the one side near the container bottom. A related tray and method for mixing magnetic particles are also disclosed.

Abstract: An apparatus for separating magnetic particles from a liquid which contains said particles, said liquid being contained in an elongated vessel (11) having a length axis (12), said vessel being arranged in a vessel holder (13) with its length axis (12) in a substantially vertical position, said vessel (11) having a bottom and a tapered cross-section that diminishes towards the bottom of the vessel and a side wall (14) which has an outer surface which forms an angle with the length axis (12) of said vessel (11).

Abstract: A system for enumeration of cells in fluids by image cytometry is described for assessment of target populations such as leukocyte subsets in different bodily fluids or bacterial contamination in environmental samples, food products and bodily fluids. Briefly, fluorescently labeled target cells are linked to magnetic particles or beads. In one embodiment, a small, permanent magnet is inserted directly into the chamber containing the labeled cells. The magnets are coated with PDMS silicone rubber to provide a smooth and even surface which allows imaging on a single focal plane. The magnet is removed from the sample and illuminated with fluorescent light emitted by the target cells captured by a CCD camera. In another embodiment, a floater having a permanent magnet allows the target cells to line up along a single imaging plane within the sample solution.

Abstract: A magnet drum mechanism of a magnet separator includes a cylindrical drum, a magnet provided inside of the drum and forming a magnetic field region configured to adsorb magnetic particles in a circumferentially partial range of an outer peripheral surface of the drum, and a scraper provided in a nonmagnetic field region of the drum, the scraper being configured to guide the magnetic particles adsorbed onto the outer peripheral surface of the drum to an outside of the separator main body in the nonmagnetic field region. The scraper includes a front end portion which faces the outer peripheral surface of the drum in a contactless manner along an axial direction of the drum, and a small gap is formed between the front end portion and the outer peripheral surface of the drum.

Abstract: A method and apparatus provide fluid treatment utilizing an electrical power supply providing at least one distinct programmable output of electrical energy wherein one or more of the voltage, current, repetition rate, amplitude or wavelength of the programmable output establish at least one distinct electrical signal generating concentrated magnetic in a plurality of distinct areas.

Abstract: The present disclosure relates to a magnetising portion for providing a high-gradient magnetic field in a magnetic separation device. The magnetising portion comprises at least one magnetic assembly. The at least one magnetic assembly comprises: a plurality of magnets whereby each magnet has a north pole, south pole and a magnet axis extending between the north and south poles, and the plurality of magnets are arranged one above the other in a direction at least substantially perpendicular to the axis of each magnet in such a manner that the north and south poles of adjacent magnets are arranged alternately and a space is provide between adjacent magnets; and at least one non-magnetic spacing means arranged in the space between adjacent magnets. The present disclosure also relates to magnetic separation devices comprising at least one of the said magnetising portions and to a method of isolating magnetically labelled particles using the magnetic separation devices.

Abstract: The application provides sample preparation devices and analyses. The devices and analyzes allow for the rapid preparation and analysis of samples using a variety of techniques, including PCR, by even unskilled users.

Abstract: An apparatus for retaining magnetic particles in self-assembled magnetic particle structures in a liquid flow, comprises a micro-channel (5) and magnets (1,2) for generating a substantially static magnetic field across the micro-channel (5) such that magnetic particles (12) suspended in a liquid in the micro-channel (5) form magnetic particle structures (15). The micro-channel (5) has along its length transverse large sections (8) alternating with narrow sections (9). The large sections (8) are periodically distributed along and on either side of the narrow sections (9) so that in use magnetic particle structures (15) form across the large sections (8) of the micro-channel (5), the magnetic particle structures being retained by engagement of end parts (18) of the magnetic particle structures in the large sections (8) of the cell or channel (5).

Abstract: A separator system with a separator column and a method of fractionating magnetic particles, preferably using field-flow fractionation is proposed, which allows for more effective fractionation of magnetic particles with respect to their dynamic magnetic response in a wide frequency and amplitude range of an applied magnetic field, in particular relevant for magnetic particle imaging (MPI).

Abstract: In forming magnetic blocks, a first permanent magnet may be lowered to the bottom of an upwardly open vessel, the vessel may be already filled or may be then filled with liquid and, while forcefully maintaining the first permanent magnet in that position, further permanent magnets are gradually inserted into the vessel in a direction perpendicular to their resulting joint contact surfaces, where the adjacent surfaces of the superimposed permanent magnets have an opposite polarity, while during insertion of a further permanent magnet, the liquid is drained from the space in the vessel under that inserted magnet, whereby the motion speed of the inserted magnet is controlled as it bears down on the permanent magnet lying beneath it.

Abstract: The present invention relates to a magnetic separation apparatus for continuous separating and recovering magnetic solid particles from a solid-liquid mixture. The apparatus includes at least one magnetic separation unit and each unit includes: an outer cylindrical vessel having a material inlet, a first outlet, and a second outlet; an inner cylindrical vessel, at least part of which extends along the axis inside the first cylindrical vessel without contacting with the inner surface of the outer cylindrical vessel; and a magnet, rendering the bottom of the inner cylindrical vessel magnetism during the first period and making the part of the surface lose its magnetism during a second period. When the solid-liquid mixture flows through the magnetic surface of the inner cylindrical vessel in the passage, the magnetic solids are absorbed and separated from the mixture.

Abstract: Magnetic handling structure (1a) comprising a retractable magnet (4) and a probe (3) for the manipulation of magnetic particles in biological samples and methods of handling magnetic particles in biological samples.

Abstract: The invention provides an apparatus for moving magnetic particles in a liquid medium, a system comprising an apparatus, a method for moving magnetic particles and a method for moving and for fixing the magnetic particles. The apparatus comprises a first magnetic means generating a first magnetic field, the apparatus further comprising a second magnetic means generating a second magnetic field, the first magnetic field having a first main axis, the second magnetic field having a second main axis, wherein the first and second main axes are inclined relative to each other by an acute angle of inclination.

Abstract: A device is provided to separate magnetic or magnetizable particles from a liquid by using a magnetic field. The device includes two limbs made of a soft-magnetic material. An air gap is provided between be two poles of the limbs. The air gap can receive one or more liquid containers. A head piece is arranged in a fixed or detachable manner on one of the two poles. One or more magnetizable bars are disposed in a fixed or movable manner on the head piece, in the vertical direction. One or more permanent magnets are arranged in a movable manner on at least one point of the device, such that a magnetic field can be produced between the two poles and the magnetic field can be activated or deactivated by moving the magnet(s). The region of the device where the movable magnet(s) are arranged is at least partially surrounded by a material that screens the magnetic field.

Abstract: A molecular arrangement magnetic treatment apparatus and method includes an apparatus including a material passageway configured for having material flow therethrough and at least one pair of magnets oriented such that material in the material passageway passes through a magnetic field effect produced by the at least one pair of magnets. Further, each magnet of the at least one pair of magnets is allowed to move independent of each other such that the magnetic field effect at least partially influences relative placement of each magnet of the at least one pair of magnets.

Abstract: A magnetic fuel conditioner according to the present invention includes an inner pipe, an outer pipe surrounding the inner pipe with sufficient clearance that fuel can pass between the inner pipe and the outer pipe, a plurality of magnets placed inside the inner pipe with like magnetic poles facing each other, and a plurality of mild steel disks placed between each pair of magnets. In a preferred form, the inner pipe and the outer pipe are made of stainless steel. An outer sleeve of mild steel surrounds the outer pipe. In a preferred arrangement, each of the plurality of magnets is cylindrically shaped to tightly fit into the inner pipe and is in the range of from about 9000 gauss to about 10,000 gauss. Typically, the plurality of magnets comprise neodymium. In such an arrangement, each disk of mild steel is approximately one quarter inch thick and approximately the same diameter as the magnets in the plurality of magnets.

Abstract: The invention is an electromagnetic probe used in conjunction with a ferrofluid containng M particles. The electromagnetic probe is used to steer M-particles to a desired location, or use the M particles for mixing the ferrofluid. The probe can be used in conjunction with a microscope, a micromanipulator, a catheter or endoscope.

Abstract: A magnetic separation device, comprising: a separator, including a top base and a bottom base; at least a groove set, each composed of two arc-like grooves having curvatures opposite to each other; at least a magnetic member, being movably fitted inside the two arc-like grooves of the at least one groove set; and at least a test tube slot, each being formed at the outer rim of a base selected from the group consisting of the top and the bottom base of the separator; wherein the top and the bottom bases are assembled by means of a pivotal axis piecing through about at the center of the top and the bottom bases for enabling the two bases to rotate relative to each other; and one of the two arc-like groove is formed on the top base at a surface thereof facing toward the bottom base while forming another arc-like groove on the bottom base at a surface thereof facing toward the top base.

Abstract: A method for continuously eliminating foreign matter, may have the following steps: a) through-flow of a reactor with waste water in a flow direction, b) adding of magnetic or magnetizable particles to a feeding point in the reactor, wherein at least one foreign matter is attached to the particles, c) separating of particles charged with foreign matter to another spot in the reactor, located opposite the feeding point in the downward flow direction by applying a magnetic field to the water flow for the transport of particles into a collecting area connected fluidic with the reactor and d) separating of the particles and the foreign matter connected to the particles from each other. A device may have a reactor receiving waste water polluted with pollutants, a collecting area for polluted magnetic or magnetizable particles, and may produce a magnetic field, transporting the particles into the collecting area.

Abstract: Magnetic treatment units are comprised of a body (21) having a central aperture, and having a pair of recesses (28) on opposite sides of the central aperture for inserting and retaining magnets (22) when covered by sleeve (23). The magnets (22) are flat magnets that have their poles on their flat sides, and are inserted into the recesses (28) such that the north pole of one magnet faces the south pole of the other magnet in the opposite recess. The invention also provides for a magnetic treatment assembly (10) for insertion into a pipe (11) or open channel comprising baffle plate (14) having a plurality of apertures (18) of which some have magnetic treatment units (15) attached to them such that the magnetic treatment units (15) are regularly spaced about baffle plate, and orientated so that north and south poles of magnets (22) in adjacent magnetic treatment units (15) are aligned.

Abstract: A method for controlling pore size of a membrane that includes providing a porous magnetic architecture and magnetizing the porous magnetic architecture. The porous magnetic architecture changes pore size when magnetized. A method for inhibiting the mobility of a solute through a membrane includes magnetizing a porous magnetic architecture in a flow stream that includes a solute. A membrane system for a solute includes a porous magnetic architecture disposed within a flow stream that also includes a solute, and a magnetic source disposed such that the nonuniform porous magnetic architecture is selectively magnetized.

Abstract: A vessel for magnetically treating a fluid is generally cylindrical, having an open end and a bottom end closed by a wall; and a magnet disposed at the bottom wall of the vessel. The fluid may be a beverage in a container such as a bottle or a can which fits into the open top end of the vessel. Or, the vessel may hold the fluid. The vessel may be formed of plastic or neoprene. The magnet may be a neodymium magnet in the form of a disc. The magnet may be disposed in the vessel with its north pole facing up, may be removable so that its orientation can be changed, may be disposed on an interior or exterior surface of a bottom wall of the vessel, and may be embedded in the bottom wall. The vessel may function as a bottle holder, a cup holder, or a cup.

Abstract: A control unit includes a plurality of electronic components; and at least two metal busbars disposed along each other. Each of the at least two metal busbars establishes an electrical connection between the electronic components and includes a magnetic-material portion. The at least two metal busbars are arranged to cause the magnetic-material portion of one of the at least two metal busbars to have magnetic poles generating a magnetic force substantially in the same direction as that of the magnetic-material portion of another of the at least two metal busbars which is adjacent to the magnetic-material portion of the one of the at least two metal busbars.

Abstract: Three magnet casings are adjustably and removably attached to one another such that the device may snuggly fit about fluid conduits of differing diameters. An outer casing wall of ferrous content stainless steel confines the magnetic field. An inner magnet holder frame attached to the outer casing wall holds a magnet to the conduit and is fabricated of non-ferrous stainless steel to allow maximum trans mission of the magnetic field to the fluid in the non-ferrous section of the conduit around which the casings are attached together.

Abstract: A pipeline filter includes: a pipeline mounting structure for mounting the pipeline filter in a pipeline, a screen support connected to the mounting structure and formed for releasably securing a screen filter to the pipeline filter and a magnetic filter support through which a magnetic filtering device is securable to the mounting structure.

Abstract: A process of conditioning a fluid includes passing the fluid through a magnetic field. A fluid conditioning system includes a conduit adapted to allow fluid to pass from a pre-conditioned volume to a post-conditioned volume, and a magnet assembly including at least one magnet disposed such that magnetic field produced by the at least one magnet penetrates the conduit. The conduit is formed from a material that allows the magnetic field produced by the at least one magnet to have a magnetic effect on molecules of the fluid as the fluid passes through the conduit.

Abstract: A magnetic separation device separating magnetic material from a working fluid of a container is disclosed. The magnetic separation device includes a first element, a second element and a magnetic assembly structure including a plurality of magnetic units. The first element includes a first body, a plurality of first main positioning portions disposed on the first body, and a plurality of first sub-positioning portions disposed on the first body and next to the first main positioning portions to receive the container. The second element includes a second body, a plurality of second main positioning portions disposed on the second body, and a plurality of second sub-positioning portions disposed on the second body and next to the second main positioning portions to receive the container. The magnetic units disposed on the first main positioning portions and the second main positioning portions absorb magnetic material from the working fluid.

Abstract: An embodiment of an apparatus for removing deposits from a petroleum flow line may include a pipe capable of being attached to a petroleum flow line. The pipe may have a pipe axis that defines a direction for fluid flow in the petroleum flow line. The apparatus may also include a first and a second field winding circumferentially disposed around the pipe, and an electric wave generator adapted to electrically communicate an electric wave to the first field winding and the second field winding. In response to the electric wave, the first field winding is adapted to produce a first magnetic field having a first magnetic axis and the second field winding is adapted to produce a second magnetic field having a second magnetic axis. The first magnetic axis may be noncollinear with respect to the second magnetic axis, and at least the first magnetic axis may be noncollinear with respect to the pipe axis.