Garment comprising a module with a removable electronic display, fastened to the garment through supple magnetic means The garment comprises a supple-sheet support (100) including a cut-out (102) formed in an apparent region. The electronic module (200) is a flat module arranged on the inner side of the support, which comprises a flexible circuit supporting electronic components and a display (206). The support (100) comprises, around the cut-out and the surface thereof opposite to the panel, a peripheral band carrying a first magnetization pattern with ranges magnetized alternatively with a given magnetic polarity and with a reverse magnetic polarity. The module (200) includes at the periphery (204) thereof a frame of similar dimensions carrying a second reverse magnetization pattern, conjugated with respect to the first magnetization pattern, when the module and the support are arranged opposite to each other in the overlapping peripheral region.

A method and a system for continuously in-line annealing a forwarding ferromagnetic amorphous alloy ribbon in a curved shape to improve its magnetic properties without causing the ribbon to become brittle and which operates at significant high ribbon feeding rates. The amorphous alloy ribbon is fed forward, tensioned and guided along a path at a preset feeding rate and is heated at a point along the path at a rate greater than 10.sup.3 C./sec to a temperature to initiate a thermal treatment. Then the ribbon is initially cooled at a rate greater than 10.sup.3 C./sec until the thermal treatment ends. During the thermal treatment, a series of mechanical constraints is applied on the ribbon until the amorphous alloy ribbon adopts a specific shape at rest after the thermal treatment is ended. After the initial cooling, the amorphous alloy ribbon is subsequently cooled at a sufficient rate to a temperature that will preserve the specific shape.

A magnetic band that is made of elastomeric resin material with magnets deposed therein is disclosed. The magnetic band optionally contains wires and also optionally contains holes at each end that may have grommets inserted into the holes. The magnetic band is used for a plurality of purposes including its ability to hold metallic magnetic items.

Provided is a method for a magnetic encoder having a magnetic body comprised of a magnetic rubber molded article, comprising a mixing step of mixing and then kneading a nitrile rubber (A), a ferrite magnetic powder (B) and a vulcanizing agent (C) to provide a magnetic rubber composition; and a molding step of molding and vulcanizing the magnetic rubber composition in a mold to which a magnetic field is applied to provide the magnetic rubber molded article, wherein a content of the ferrite magnetic powder (B) is 700 to 1500 parts by mass based on 100 parts by mass of the nitrile rubber (A); and a compressed density of the ferrite magnetic powder (B) is 3.5 g/cm.sup.3 or more. According to this method, a magnetic encoder having a magnetic body with high coercivity and residual magnetic flux density can be produced by vulcanizing a magnetic rubber composition having favorable moldability.

Apparatus, including a ferromagnetic sheet and at least one radiator, mounted in proximity to the ferromagnetic sheet and configured to radiate a magnetic field into a region in proximity thereto. The apparatus further includes a solid sheet of thermal insulation, mounted between the ferromagnetic sheet and the at least one radiator so as to prevent transfer of thermal energy from the at least one radiator to the ferromagnetic sheet.

A structural body includes: a three-dimensional net shaped body including a plurality of net lines that form a three-dimensional net shape; and a plurality of objects respectively present in two or more of a plurality of spaces partitioned by the plurality of net lines. The plurality of objects are each a mobile object that moves within one of the plurality of spaces or moves over two or more of the plurality of spaces.

The magnetic encoder is constituted by integrally bonding a magnet portion obtainable by forming a magnetic material containing a magnetic powder and a binder for the magnetic powder in a circular ring shape to a slinger. The binder contains at least a thermoplastic resin and an impact resistance-improving agent.

There is provided a magnetic rubber composition comprising a rubber (A), a thermosetting resin (B) and a magnetic powder (C), wherein a mass ratio (A/B) of the rubber (A) to the thermosetting resin (B) is 0.2 to 5, and a mass ratio [C/(A+B)] of the magnetic powder (C) to the total mass of the rubber (A) and the thermosetting resin (B) is 0.5 to 20. It gives a magnetic rubber molded article excellent in flexibility and abrasion resistance, and a magnetic encoder produced therewith.

This application relates to devices in which magnets are arranged so that an intensity of a magnetic field emitted by the magnets is substantially the same at a position of interest for at least two discrete positions of the magnets. The application describes how this can be achieved even when the discrete positions are different distances from the position of interest by identifying locations at which magnetic material can be added to balance the field intensity for both discrete locations. In some embodiments, this type of configuration can be helpful in accommodating movement of magnets between two common positions. When the magnetic field intensity for the position of interest is set near zero a magnetically sensitive component can be positioned at the point of interest with little or no effect from the magnetic field when the magnets are in any of the discrete positions.

Magnetic structure production may relate, by way of example but not limitation, to methods, systems, etc. for producing magnetic structures by printing magnetic pixels (aka maxels) into a magnetizable material. Disclosed herein is production of magnetic structures having, for example: maxels of varying shapes, maxels with different positioning, individual maxels with different properties, maxel patterns having different magnetic field characteristics, combinations thereof, and so forth. In certain example implementations disclosed herein, a second maxel may be printed such that it partially overwrites a first maxel to produce a magnetic structure having overlapping maxels. In certain example implementations disclosed herein, a magnetic printer may include a print head comprising multiple parts and having various properties. In certain example implementations disclosed herein, various techniques for using a magnetic printer may be employed to produce different magnetic structures. Furthermore, description of additional magnet-related technology and example implementations thereof is included herein.