Abstract: The invention relates to a composition for producing magnetic or magnetizable moldings, comprising from 95.5 to 98.95% by weight of a powder made of a magnetic or magnetizable material, from 1.0 to 4% by weight of a mixture made of at least one epoxy-novolak resin, and also of at least one hardener, and comprising from 0.05 to 0.5% by weight of at least one additive, based in each case on the total weight of the composition. The mixture made of the at least one epoxy-novolak resin and of the at least one hardener comprises from 85 to 95% by weight of the epoxy-novolak resin and from 5 to 15% by weight of hardener. The hardener has been selected from (cyclo)aliphatic amines and their adducts, polyamides, Mannich bases, amidoamines, phenolic resins, imidazoles, and imidazole derivatives, dicyandiamide, and BF3-monoethanolamine. The invention further relates to a process for producing the composition, and also to a process for producing a molding made of the composition.

Abstract: The invention relates to a single or multiple-layer plastic skin as the surface covering of coated objects. Regions are disposed in the plastic skin which are made up of a mixture of the plastic material of the plastic skin and a conducting material.

Abstract: There is provided herein an intermediate transfer member. The intermediate transfer member includes conductive particles having thereon a shell comprising polyhedral oligomeric silsequioxane dispersed in a polymer. A method of manufacturing and intermediate transfer member is also disclosed.

Abstract: Polymeric microstructures and nanostructures can be prepared with use of a tip to pattern a surface. A tip can be used to pattern a structure which can initiate polymerization. The structure can be then exposed to monomer to induce polymerization at the structure. Alternatively, a tip can be used to pattern a surface with a monomer in which the surface is treated with polymerization catalyst so that polymerization occurs at the patterning site. Ring-opening metathesis polymerization can be carried out with use of the tip to control the polymerization. The tip can be a sharp tip as used in for example an atomic force microscope tip. Norbornene types of monomers can be used. Biological macromolecules can be also prepared.

Abstract: An electric motor that includes a rotor; a coil that is wound around the rotor; and a carbon brush that supplies power to the coil, wherein the brush is formed by using a raw material in which artificial graphite whose crystallites are flaky in shape is mixed with natural graphite whose crystallites are squamous or scaly in shape.

Abstract: Disclosed are a multi-layer substrate and a manufacturing method of the multi-layer substrate. By employing a carrier to alternately form dielectric layers and metal structure layers thereon. Each dielectric layer adheres with the adjacent dielectric layer to embed the metal structure layers in the dielectric layers corresponding thereto. Comparing with prior arts, which have to use prepregs when hot pressing and adhering different layers of different materials, the present invention takes fewer processes, thus, fewer kinds of materials without using prepregs. Therefore, the present invention can promote the entire quality and yield of manufacturing the multi-layer substrate to satisfy mechanical characteristic matching of the multi-layer substrate and to reduce cost of the whole manufacturing process.

Abstract: The present teachings provide an intermediate transfer member. The intermediate transfer member includes a polyimide polymer having the formula: wherein R is alkyl or aryl and the like and mixtures thereof; and n and m are the mole percent of the repeating unit.

Abstract: An in-mould molding touch module includes a plastic film, a touch circuit and a molding rind. The plastic film includes an inner surface and an outer surface for handling and touching. At least one region of the inner surface and a corresponding region of the outer surface define a touch area. The touch circuit is arranged on the inner surface in the touch area. The molding rind is integrated on the inner surface by an in-mould injecting mode to contain the touch circuit for forming a one-piece body. In addition, the invention also provides a method for manufacturing an in-mould molding touch module.

Abstract: One aspect relates to a method for producing an electrical bushing for an implantable device, a corresponding electrical bushing, and a corresponding implantable device. The method according to one embodiment is characterized in that a green blank is produced and sintered from an electrically insulating base body green blank made of a ceramic slurry or powder and at least one electrically conductive bushing body green blank made of a cermet material. The at least one bushing body green blank is inserted into a bushing opening of the base body green blank to form a composite green blank, a shape of the at least one bushing body green blank and a shape of the at least one bushing opening are complementary to each other at least in sections thereof and prevent slippage of the bushing body green blank through the bushing opening. The composite green blank is sintered while applying a force that keeps the bodies together.

Abstract: A touch-screen interface for a dishwasher door comprises a user interface, a touch sensitive component and a holder. The user interface includes a graphics film defining a plurality of transparent portions. The user interface is configured to facilitate touch communication therethrough. The graphics film is secured to the user interface to prevent moisture therebetween. The touch sensitive component is configured to receive touch communication through the user interface. The touch sensitive component senses a position of a user's finger on the user interface. The holder is releasably connected to the user interface and is configured to releasable secure the touch sensitive component to the user interface. The holder is releasably coupled to a dishwasher door. The releasable connection between the components of the touch-screen interface allows for ease of disassembly and repair or replacement of the components.

Abstract: In the formation of a fiber reinforced composite material component produced by a resin transfer infusion process such as to have an electrically conductive surface layer for lightning strike protection wherein the component is to be drilled and countersunk to receive an electrically conductive fastener, a localized part of the electrically conductive mesh is deformed so as to be relocated in the countersunk recess thus to ensure electrical contact with the fastener when inserted and to eliminate any gap between the mesh and the fastener, thus determining the electrical conductive integrity of the mesh to avoid arcing in the event of lightning strike attachment.

Abstract: As a piezoelectric ceramic having an alkaline-containing niobic acid-perovskite structure contains [K1-xNax]1-yLi[Nb1-z-wTazSbw]O3 (x, y, z, and w each indicate a molar ratio, and 0?x<1, 0?y<1, 0?z<1, and 0?w<1 hold) as a primary phase and K3Nb3O6Si2O7 as a subphase.

Abstract: A measuring sensor has a hollow body through which a fluid is able to flow. Two sections of a wall of the hollow body form electrodes for a capacitive and/or a resistive measurement and the electrodes are made of a conductive plastic. The measuring sensor may be used in a fuel feed line. A method for manufacturing is also described.

Abstract: The present disclosure relates to a method for producing an insulated electrode comprising a conductive material coated with an electrically insulating material.

Abstract: A formed body having a curved surface, a method of producing the formed body, a front cover for a vehicle lighting device, and a method of producing the front cover. A front cover (10) for a vehicle lighting device, mounted to a front opening in a vehicle lighting device (16) having a lamp body (12) and a light source (14) which is provided in the lamp body (12), wherein a heat generating body (20) is provided in a substantially rectangular region of that surface of the front cover which faces the light source (14). The heat generating body (20) maintains the relationship of Ra=(2 R0), where R0 is the electric resistance value (initial value) of the heat generating body (20) before the heat generating body is elongated and Ra is the electric resistance value of the heat generating body (20) after the heat generating body is elongated 5%.

Abstract: Provided is an organic-inorganic hybrid nanofiber including an inorganic semiconductor material in a nanoparticle or nanocrystal state, and a conductive polymer including the inorganic semiconductor material and having a lower thermal conductivity than the inorganic semiconductor material. The inorganic semiconductor material and the conductive polymer are arranged in a composite material type to have a thermoelectric property. Thus, the organic-inorganic hybrid nanofiber can be applied to a low-priced thermoelectric device having relatively high thermoelectric conversion efficiency.

Abstract: According to one embodiment, a manufacturing method includes performing lithography processes for manufacturing a semiconductor device that includes a three-dimensional stacked device. The stacked device includes layers stacked above a substrate. Each of the layers includes a device circuit. The lithography processes include a lithography process for forming a lower layer of the layers by using a first original plate that has quality not less than a certain level. The first original plate is selected from original plates. Each of the original plates includes a pattern corresponding to the device circuit. The original plates are ranked according to quality based on defect. The lithography processes further include a lithography process for forming a higher layer of the layers by using a second original plate that has quality lower than the certain level. The second original plate is selected from the original plates.

Abstract: An electrically conductive composite material includes metallic nanostrands distributed throughout a matrix constructed of a polymer, ceramic, or elastomer. The nanostrands may have an average diameter under four microns and an average aspect ratio over ten-to-one. Larger fibers may also be included to enhance electrical conductivity or other properties. The nanostrands and/or fibers may be magnetically oriented to enhance electrical conductivity along one direction. A pressure sensor may be formed by utilizing an elastomer for the matrix. Electrical conductivity through the composite material varies in proportion to deflection of the elastomer. A composite material may be applied to a surface as an electrically conductive paint. Composite materials may be made by cutting a blank of the nanostrands to the desired shape, inserting the matrix, and curing the matrix. Alternatively, a suspension agent may first be used to dispose powdered nanostrands in the desired shape.

Abstract: A method for forming a case of an electronic device with a wireless communication function includes: (a) providing a pair of outer prepreg layers, each containing a fiber that permits permeation of an electromagnetic wave; (b) providing a plurality of inner prepreg layers, each of which includes: a first prepreg sheet that contains a first fiber, which permits permeation of an electromagnetic wave; and a second prepreg sheet containing a second fiber that prevents permeation of an electromagnetic wave and that has a strength higher than that of the first fiber; (c) stacking and pressing the inner prepreg layers to obtain an inner laminate; (d) disposing the inner laminate between the outer prepreg layers; and (e) forming the outer prepreg layers and the inner laminate in a mold. A case for an electronic device with a wireless communication function is also disclosed.

Abstract: A method for forming organic layers of electronic devices by contact printing is disclosed, which comprises: (A) providing a substrate, which has an electrode formed thereon; (B) coating an organic material ink onto a mold; (C) applying the ink-coated mold onto the substrate, to transfer the organic material ink onto the electrode of the substrate and then to form an organic layer; and (D) forming another electrode on the organic layer. In addition, after the step (C) is completed, the steps (B) to (C) can be repeated once or several times to form series of organic layers, if needed.

Abstract: There is provided a method for manufacturing a substrate for a display panel including a rib and a flat surface (hereinafter referred to as “substrate surface”) formed on one surface, the substrate surface being the region other than the rib in the substrate and including an electrode provided thereon, the substrate having a convex/concave shape (hereinafter referred to as “a substrate convex/concave shape”) composed of the rib and the substrate surface, comprising: a step 1 for positioning a mold having a convex/concave shape (hereinafter referred to as “a mold convex/concave shape) that is reversed to the substrate convex/concave shape so that the mold convex/concave shape and the substrate convex/concave shape are fitted to each other, the mold being provided with a flat surface (hereinafter referred to as “a mold convex surface”) facing to the substrate surface at a convex portion of the mold convex/concave shape, and with a surface (hereinafter referred to as “a mold concave bottom surface”) facing to a

Abstract: A method of making an article of a semiconducting material involves withdrawing from a melt of molten semiconducting material a solid mold having already formed on an external surface of the mold a solid layer of the semiconducting material. During the act of withdrawal, one or more of a temperature, a force, and a relative rate of withdrawal are controlled in order to achieve one or more desired attributes in a solid overlayer of semiconductor material that is formed over the solid layer during the withdrawal.

Abstract: An electric power plug comprises blades, a bridge and a plug body. The bridge includes sleeves for covering the roots of the blades and a core for holding the lower ends of the blades. The blades and the core are integrally molded. The plug body is molded so that the plug body embeds the bridge except the upper portions of the sleeves. The core may embed the lower portions of the blades, cords, a caulking portion for connecting the lower ends of blades and wire conductors of the cords. A cavity may be formed at the central portion of the core. The plug body may be molded so that the plug body embeds the bridge and the cords except the upper portions of the sleeves.

Abstract: In one aspect, an LED lighting apparatus includes an electronic circuit board having a peripheral portion and a central portion that is radially inward of said peripheral portion, said electronic circuit board having an exterior side for optically interfacing with ambient environment during operation and an interior side opposite the exterior side. At least one LED is mounted on the exterior side of the electronic circuit board central portion and a thermally conductive housing encloses said electronic circuit board, said thermally conductive housing formed of a moldable thermally conductive material. The thermally conductive housing defines a first cavity adjacent the central portion of the electronic circuit board exterior side and a second cavity adjacent the central portion of the electronic circuit board interior side, wherein a portion of said thermally conductive housing being overmolded onto said peripheral portion. In a further aspect, a method of manufacturing an LED lighting apparatus is provided.

Abstract: An electrochemical cell includes a fuel electrode configured to operate as an anode to oxidize a fuel when connected to a load. An electrode holder includes a cavity for holding the fuel electrode, at least one inlet connected to the cavity on one side of the cavity and configured to supply an ionically conductive medium to the cavity, and at least one outlet connected to the cavity on an opposite side of the cavity and configured to allow the ionically conductive medium to flow out of the cavity. A plurality of spacers extend across the fuel electrode and the cavity in a spaced relation from each other to define a plurality of flow lanes in the cavity.

Abstract: The present invention provides a negative active material for a rechargeable lithium battery, including an inner layer including a material being capable of doping and dedoping lithium, a carbon layer outside the inner layer, and an outer layer disposed on the carbon layer and including a material being capable of doping and dedoping lithium. The materials being capable of doping and dedoping lithium included in the inner layer and in the outer layer may be the same or different from each other.

Abstract: The present invention provides a method for manufacturing a conductive structure having high electrical conductivity, and a method for manufacturing a dimensionally accurate separator for a fuel cell having high electrical conductivity. In the present invention, the cavity surface temperature of a mold is kept equal to or higher than the crystal melting temperature (Tm) of composite material until the shaping of the composite material melted in the mold is completed, and after the completion of the shaping process, the cavity surface temperature of the mold is controlled to be equal to or higher than a temperature 20° C. lower than the crystallization temperature (Tc) of the composite material but equal to or lower than a temperature 20° C. higher than the crystallization temperature of the composite material to harden the composite material.

Abstract: An electromagnetic-wave shielding film of a display panel and a plasma display device are manufactured by transcribing a conductive ink material onto a substrate by an off-set process, and firing the conductive ink material to form a conductive material.

Abstract: An electrode active material layer includes an electrode active material and a sulfide solid state electrolyte material which is fused to a surface of the electrode active material and is substantially free of bridging sulfur.

Abstract: The electrode film of the present invention includes electrode material particles having an average particle diameter of Da, solid particles having an average particle diameter of Db, and an ionic liquid, wherein Da and Db satisfy a formula Db/Da?1.0×10?1. This electrode film is fabricated into an electrode in which the electrode film is stacked on a current collector. The electrode film is produced by a method including a step of dispersing electrode material particles having an average particle diameter of Da, solid particles having an average particle diameter of Db, and an ionic liquid in a liquid medium to obtain a dispersion liquid, a step of applying the dispersion liquid onto a support to form a dispersion liquid film, a step of removing the liquid medium from the dispersion liquid film to form an electrode film on the support, and a step of removing the support to isolate the electrode film. If a current collector is used as the support, an electrode is produced.

Abstract: A method of producing sharp tips useful for scanning probe microscopy and related applications is described. The tips are formed by deposition into a mold(s) formed in a sacrificial crystalline semiconductor substrate with an exposed {311} surface which has been etched with a crystallographic etchant to form a 3-sided, trihedral or trigonal pyramidal mold(s) or indentation(s). The resultant tips, when released from the sacrificial mold material or substrate, are typically formed in the shape of a trigonal pyramid or a tetrahedron. Another embodiment involves starting with a {100} surface and the formation of two tips on opposite ends of a wedge at trigonal or trihedral points of the wedge. These tips are less susceptible to the tip wedge effect typical of tips formed using known methods.

Abstract: A manufacturing method for a solid electrolyte sheet includes applying slurry, which contains sulfide-based solid electrolyte powder, a sulfur-containing compound and a solvent, onto a base; and forming the slurry into a sheet.

Abstract: To manufacture by a simple method a reinforced electrolyte membrane obtained by directly impregnating a molten electrolyte resin into a porous reinforced membrane. Further, to easily manufacture a membrane electrode assembly including the reinforced electrolyte membrane by slightly changing the method of manufacturing a reinforced electrolyte membrane. A heated and molten electrolyte resin p is extruded from a resin discharge port 3 of a die 2, and the extruded molten electrolyte resin p is supplied into a porous reinforced membrane 6. The porous reinforced membrane 6 supplied by two heated rotating rolls 4 arranged opposite to each other is embedded into the molten electrolyte resin p, and the molten electrolyte resin p is impregnated into the porous reinforced membrane 6, so that a reinforced electrolyte membrane 20 is formed.

Abstract: An endoscopic instrument has a shaft designed in a flexible manner along its longitudinal axis in at least one section. The flexible section of the shaft has a tube-shaped wall made of an electroactive polymer with a plurality of control electrodes and reference electrodes respectively embedded therein. As seen in the axial direction, the control electrodes and reference electrodes are respectively arranged alternately and separated from one another. The control electrodes and reference electrodes alternating in the axial direction respectively have a rigid design and are respectively interconnected in an electrically conducting manner in the axial direction by elastic webs arranged on the outer or inner circumference. A method is also provided for producing a flexible section of such an endoscopic instrument.

Abstract: Two catalyst electrode layers (CEL) are separately formed on two surfaces of a proton exchange membrane (PEM). The structure and processes are simple in the present invention for obtaining a membrane exchange assembly (MEA) with its thickness controllable. The MEA obtained can have a structure of CEL+PEM+CEL?. If a gas diffusion layer (GDL) is added before obtaining the CEL, a MEA having a structure of GDL+CEL+PEM+CEL?+GDL? is obtained.

Abstract: A method of producing all or a portion of an air electrode for a metal-air battery includes forming at least a portion of the air electrode using a process selected from the group consisting of an injection molding process and a screw extrusion process. This process may be used to form a gas diffusion layer of the air electrode, and active layer of the air electrode, or both. The air electrode may use polyethylene and/or polypropylene as a binder material in all or a portion of the air electrode.

Abstract: Manufactured articles and methods of producing such articles are disclosed where the article has a thermoplastic polymer component and a curable polymer component. The curable polymer may be moisture-curable polymer, or microwave, dielectric or radio frequency curable polymer. The articles may be manufactured by a variety of polymer processing methods including extrusion, co-extrusion, co-molding, injection molding and calendering. A variety of articles and shapes may be made by the method including electric wire and cable, and weatherstripping.

Abstract: The method is for fabricating a transparent or semi-transparent element, such as a glass (1), with capacitive touch keys, for a portable electronic instrument. This method includes the steps of placing an insulating film (3), on which are formed electrodes (2), acting as capacitive touch keys, conductive paths (4), each connected to a respective electrode, and external contact terminals (6), each connected via the conductive paths to the corresponding electrodes, in a transparent or semi-transparent plastic substance (5) in liquid form inside a mould. This liquid substance is then solidified inside the mould, to coat at least part of the film that includes the electrodes, the conductive paths and at least part of the external contact terminals of said film. Upon removal from the mould, a glass is obtained with capacitive touch keys integrated within said solidified plastic substance of the glass.

Abstract: Automotive housings are formed of a conductive loaded resin-based material. The conductive loaded resin-based material comprises micron conductive powder(s), conductive fiber(s), or a combination of conductive powder and conductive fibers in a base resin host. The percentage by weight of the conductive powder(s), conductive fiber(s), or a combination thereof is between about 20% and 50% of the weight of the conductive loaded resin-based material. The micron conductive powders are metals or conductive non-metals or metal plated non-metals. The micron conductive fibers may be metal fiber or metal plated fiber. Further, the metal plated fiber may be formed by plating metal onto a metal fiber or by plating metal onto a non-metal fiber. Any platable fiber may be used as the core for a non-metal fiber. Superconductor metals may also be used as micron conductive fibers and/or as metal plating onto fibers in the present invention.

Abstract: Single pellets of a thermoplastic resin containing long glass fibers and a conductive filler are set forth that enable molded articles made from these pellets to exhibit conductivity and, at the same time, high mechanical properties. These pellets have mechanical properties that are substantially equivalent to non-conductive pellets of a thermoplastic resin containing same loading of long glass and provide conductivity that is substantially equivalent to articles obtained by blending two kinds of pellets, one pellet having a conductive filler and the other pellet one containing long glass fibers. The pellets include a thermoplastic resin, a long fiber reinforcing filler and a conductive additive dispersed in the pellet.

Abstract: Display particles for an image display apparatus, wherein the image display apparatus comprises two substrates at least one of which is transparent, with the display particles being sealed between the substrates in a powder state, so that by generating an electric field between the substrates, the display particles are moved to display an image, wherein the display particles are formed through processes in which at least a binder resin and a colorant are kneaded and pulverized to give core particles, resin fine particles are fixed and fused on surfaces of the core particles, and then the core particles on which the resin fine particles are fixed and fused are sphered to give an average degree of roundness of 0.960 or more, and wherein a ratio of use of the resin fine particles is set in the range from 100 to 300% in the rate of the total projection area of the resin fine particles relative to the total surface area of the core particles, as well as an image display apparatus loaded with the display particles.

Abstract: Described herein are printable structures and methods for making, assembling and arranging electronic devices. A number of the methods described herein are useful for assembling electronic devices where one or more device components are embedded in a polymer which is patterned during the embedding process with trenches for electrical interconnects between device components. Some methods described herein are useful for assembling electronic devices by printing methods, such as by dry transfer contact printing methods. Also described herein are GaN light emitting diodes and methods for making and arranging GaN light emitting diodes, for example for display or lighting systems.

Abstract: Dielectric oxide materials prepared by producing a sol from a mixture of a metal oxide precursor, a solvent, and an epoxide, and preparing a metal oxide material from the sol. In various versions, the mixture can also include a cosolvent, one or more additional metal oxide precursors, water, or a precursor to a glassforming oxide, or any combination thereof. The prepared dielectric oxide materials can be in the form of thin films having high ? values, low electrical leakage, and low dielectric loss tangent values.

Abstract: An LED-based light can include a highly thermally conductive base having multiple radially outward projecting nodes. The nodes can be spaced apart in an axial and circumferential directions of the base. An electrical connector and at least one LED can be attached to the base, and a light transmitting bulb can be attached to the base and can cover the at least one LED. The geometry of the base can promote heat dissipation, which can allow the at least one LED to use enough power to produce an amount of luminosity that allows the LED-based light to replicate, for example, an incandescent light without overheating.

Abstract: The present invention provides a method for the fabrication of high performance densified nanocrystalline bulk thermoelectric material, comprising: (1) preparing a thermoelectric alloy nanopowders by a ball milling process to achieve an average crystal size of 5-30 nm, and (2) preparing the nanocrystalline bulk thermoelectric material by high pressure sintering at a temperature of 0.25-0.8 Tm under a pressure of 0.8-6.0 GPa for 10-120 minutes, to achieve a relative density of 90-100% and an average grain size of 10-50 nm. The method is easy to operate and allows the production of a thermoelectric material with a ZT value higher than 2. In addition, the method can ensure both good thermoelectric properties and high density, and therefore have important applications for energy industry.

Abstract: The invention relates to methods of making articles of semiconducting material on a mold comprising semiconducting material and semiconducting material articles formed thereby, such as articles of semiconducting material that may be useful in making photovoltaic cells.

Abstract: The invention relates to methods of making articles of semiconducting material and semiconducting material articles formed thereby, such as articles of semiconducting material that may be useful in making photovoltaic cells.

Abstract: Method for manufacturing a rigid power module with a layer that is electrically insulating and conducts well thermally and has been deposited as a coating, the structure having sprayed-on particles that are fused to each other, of at least one material that is electrically insulating and conducts well thermally, having the following steps: manufacturing a one-piece lead frame; populating the lead frame with semiconductor devices, possible passive components, and bonding corresponding connections, inserting the thus populated lead frame into a compression mould so that accessibility of part areas of the lead frame is ensured, pressing a thermosetting compression moulding compound into the mould while enclosing the populated lead frame, coating the underside of the thus populated lead frame by thermal spraying in at least the electrically conducting areas and overlapping also the predominant areas of the spaces, filled with mold compound.

Abstract: A cold-shrinkable type rubber insulation sleeve includes a reinforced insulation sleeve, a semiconductive stress-relief cone, an internal semiconductive layer, and an external semiconductive layer. The reinforced insulation sleeve, the semiconductive stress-relief cone, and the internal semiconductive layer are formed by molding, and the external semiconductive layer is formed by coating.

Abstract: A three-dimensional circuit substrate comprises one or more electrically conductive tracks. The substrate is formed from a unitary moulding over the one or more electrically conductive tracks and thereby provides structural support therefor.