Abstract: A manufacturing method of a coil component including the steps of: holding a plurality of semi-finished products, each of which includes a base and a coil before forming the coil component, with a jig having a holding portion; setting the plurality of semi-finished products held by the jig to the setting positions of the jig in a mold; and sealing at least a portion within the base and the coil with resin by filling the resin into a cavity of the mold.

Abstract: A component feeder includes a feeding mechanism which feeds taped components in which components with leads having a plurality of leads are held on a carrier tape by the plurality of leads, and a positioning mechanism which positions each of the plurality of leads included in the component at the supply position. The positioning mechanism includes a clamp which is configured to include a first member and a second member that are operated relative to each other, and a guide section which guides each of the plurality of leads to a defined position in a feeding direction of the taped component when the plurality of leads are pinched by the clamp. The component feeder includes a clamp closed position checking mechanism for checking whether or not a closed position which is an operation position of the clamp in a state where the clamp is closed is an appropriate position.

Abstract: Implementations of methods of forming capacitors may include depositing a first metal layer over a substrate, forming a photoresist layer over the first metal layer, patterning the photoresist layer, patterning the first metal layer using the pattern of the photoresist layer, depositing a dielectric layer over the first metal layer, and depositing a second metal layer over the dielectric layer to form a metal-insulator-metal capacitor.

Abstract: Methods, systems, and apparatus, including computer programs encoded on a computer storage medium, for producing meander-line polarizers. In some implementations, a meander-line polarizer includes a dielectric substrate made of a polyester polymer material and meander-line arrays formed on a surface of the dielectric substrate. Each meander-line array includes a sequence of alternating perpendicular conductive traces that are formed the surface of the dielectric substrate by applying conductive ink to the surface of the dielectric substrate using a template that defines a location and dimensions of each conductive trace of each meander-line array.

Abstract: A method for fabricating electrodes sized and dimensioned to record, measure, and/or stimulate very fine nerve structures (e.g., microscale or less) is described herein. The method can include securing a tip of an electrode, comprising a conductor substantially encased by an insulator, to a proximal portion of an inserter. The electrode can be wound around a proximal portion of the inserter and a portion of the electrode can be secured to a distal portion of the inserter. A tension in the electrode can be maintained during the winding to keep the electrode in place during the winding.

Abstract: A production management system of a component mounting line that includes component mounters that identify a board ID of a circuit board conveyed during production, send the board ID to a production management computer of the production management system, measure actual data for early-stage-discovery of a mounting defect at a specified interval during production, and send the measurement results to the production management computer. The production management computer saves the board IDs sent from each of the component mounters with a time stamp, monitors whether there is a possibility of a mounting defect based on the measurement result, extracts board IDs of circuit boards on which components were mounted at the component mounters since the previous time measurement was performed if there is the possibility of a mounting defect, and displays a list of the circuit boards with a possible mounting defect.

Abstract: A method of making a slow wave inductive structure includes forming a first conductive winding over a first substrate. The method further includes bonding a second substrate to the first substrate, wherein the second substrate has a thickness ranging from about 50 nanometers (nm) to about 150 nm, wherein a distance between the first conductive winding and the second substrate ranges from about 1 micron (?m) to about 2 ?m.

Abstract: Method for providing cooling of a power electronics system which is integrated in a battery module, in which method the battery module has a battery housing, containing a large number of energy storage units and the power electronics system which is integrated adjacent thereto and includes a printed circuit board which is populated with power semiconductor switches, and a thermally conductive element which creates thermal contact between the respective energy storage units and the power electronics system. Cooling of the power electronics system is achieved by the thermally conductive element which renders possible transfer of thermal energy from the power electronics system to the energy storage units. At least one side of the battery housing is coupled to a cooling system. A surface area of the thermally conductive element is connected to a respective energy storage unit and is contacted by way of a respective curved portion.

Abstract: A method of manufacturing a packaged board includes the steps of blanketing a wiring board with devices disposed thereon in a molding die and supplying the molding resin to the molding die, provisionally sintering the molding resin at a relatively low provisional sintering temperature below a final sintering temperature, detaching the wiring board from the molding die, and thereafter, placing the wiring board on a first base having a first flat surface, pressing the wiring board with a second base having a second flat surface parallel to the first flat surface, and heating the wiring board at the final sintering temperature to finally sinter the provisionally sintered molding resin while keeping its thickness uniform.

Abstract: An apparatus for manufacturing a belt-like electrode including: a pair of press rolls configured to press a belt-like current collector foil with an electrode mixture layer along a longitudinal direction in a thickness direction of the electrode mixture layer; and a stretching roll configured to stretch a non-forming part which is the current collector foil without the electrode mixture layer in respective ends in a width direction is provided. The stretching roll includes: a first roll opposed to the electrode mixture layer formed in the current collector foil; and a pair of second rolls arranged in respective ends of the first roll in an axial direction and opposed to the non-forming part, and a central axis of the first roll is deviated with respect to a central axis of the pair of second rolls in a direction away from the stretched current collector foil.

Abstract: A device for transferring chips from a wafer to a placement head of an automatic placement machine. The device includes a removal tool rotatable about a first axis of rotation (i) for the removing of singulated chips from the wafer, (ii) for turning the chips to provide them as FCOB chips at a first collection position, and (iii) for transferring, at a common transfer position, the chips to a turning tool rotatable about a second axis of rotation; and the rotatable turning tool (i) for receiving of chips from the removal tool, and (ii) for again turning the received chips, in order to provide them as COB chips at a second collection position. The removal tool has a plurality of first grippers, which are arranged protruding radially from the first axis of rotation in a first plane. The turning tool has a plurality of second grippers, which are arranged radially protruding from the second axis of rotation in a second plane.

Abstract: A method for manufacturing a rotor core includes detecting a height of a projecting portion formed on a lower die by a height detecting unit, and placing onto the lower die a core body in which a magnet insertion hole is formed such that the projecting portion is positioned in the magnet insertion hole when the height detecting unit has determined that the height of the projecting portion is within a set range. Additionally, the method includes bringing a permanent magnet in the magnet insertion hole into contact with an upper end of the projecting portion, and placing onto the core body a holding member after bringing the permanent magnet into contact with the upper end of the projecting portion. Melted resin is injected into the magnet insertion hole in which the permanent magnet has been inserted after placing the holding member onto the core body.

Abstract: A stator of a rotary electrical machine has a stator body formed by a stack of metal sheets. The stator body is delimited by inner and outer radial surfaces. Notches in the stator body extend axially. Each notch has a notch base and a notch opening, and the notch opening is on the side of the inner radial surface. A stator winding is supported by the stator body, and the winding has a plurality of winding parts. Each part is accommodated in one of the notches. Each of the notches at the notch opening has a closure element. Each winding par in a notch is retained between the notch base and the closure element. The closure elements are formed by offsetting at least one of the metal sheets of an adjacent notch in the direction of the notch.

Abstract: A component supply device supplies components stored in a component storage tape to a component extracting position. The component supply device includes a component exposing unit that exposes the components in the component storage tape fed by a tape feeding unit, the component storage tape traveling on a travel path formed from a tape travel path forming unit. The component exposing unit includes an insertion member that is inserted between a cover tape and a carrier tape and includes a base part and a tip part continuous with an upstream end in a tape feeding direction of the base part. The tip part is inclined toward the cover tape away from the carrier tape with respect to the base part in a state where the insertion member is inserted between the cover tape and the carrier tape.

Abstract: A crimping tool is disclosed. The crimping tool comprises a first handle, a second handle, a crimping member, a first mechanism link and a second mechanism link. The first handle comprises a hole and a first shaft portion, wherein the first shaft portion is adjacent to a top end of the first handle. The second handle comprises a second shaft portion, wherein the first shaft portion and the second shaft portion are connected by a shaft member. The crimping member is disposed on the first handle. The first and the second mechanism links are respectively connected with the first handle, the second handle and the crimping member such that when the first handle and the second tool are rotated with respect to each other, the crimping member is pushed to move from a first position to a second position.

Abstract: A positioning device may be used to peripherally position copper rods about a center axis that defines an axial direction. Each of the copper rods may be generally U-shaped and may have a first leg portion and a second leg portion. The positioning device may include a positioning body, a rotary body, locking means, and a rotary drive. Grooves of an outer peripheral surface of the positioning body may receive the first leg portions of the copper rods, which can be locked in place by the locking means. The rotary body may be rotatable about the positioning body and may include guide channels that receive the second leg portions of the copper rods. The rotary drive can cause the rotary body and the positioning body to rotate relative to one another, to pivot the second leg portions inwardly into the grooves of the positioning body.

Abstract: The present disclosure relates to a feeder arm for a surface mount technology (SMT) machine. In an embodiment, the feeder arm includes a support body that is fastened to an SMT machine. The feeder arm includes a reel loading body that supports a reel of electrical components to allow the reel to be prepared for installation on the SMT machine. The feeder arm includes preparation circuitry configured to electrically connect the reel to allow the reel to be prepared. The feeder arm includes an articulating joint between the reel loading body and the support body. The articulating joint may articulate the second body between a first position and a second position.

Abstract: A method of forming an electrode array is disclosed, the method comprising: forming an elongate comb structure comprising a plurality of longitudinally-spaced electrode contacts extending from and supported by a spine; electrically connecting each of a plurality of electrically conductive pathways to a respective one of the plurality of electrode contacts; placing the conductive pathways adjacent the contacts; placing silicone over the conductive pathways and contacts; curing the silicone so as to substantially retain the longitudinal spacing between neighboring contacts; and severing the spine from the plurality of electrode contacts.

Abstract: An electric machine includes a stator core defining slots and a first hairpin assembly installed in the stator core. The first hairpin assembly includes first and second same hairpins, each having first and second ends and separately coated to have first and second outer coating surfaces, respectively. The hairpin assembly is in first and second ones of the slots such that the first and second outer surfaces are touching. A weld material joins the first ends and another weld material joins the second ends.

Abstract: Methods and systems are disclosed for scalable antenna arrays that may be built up using pluggable tiles that have low distortion, flat band high gain, and structured to channelize the signals into narrow bands that may be 40 MHz or even smaller bandwidth apart. Antenna array tiles may employ traveling wave tube (TWT) components and wafer scale arrays. H-topology, equal length, feed networks connect the signals to antenna elements. The fractal-like, recursively repeating at different size scales, structure for the H-tree feed networks, implemented using pluggable tiles, facilitates the scalability of the high gain waveguide antenna array. System integration across the 75-115 GHz spectral band implements scalable aperture architecture with emphasis on addressing considerations of the TX power requirement, feed network, channelizing signals at different frequency bands using specially designed diplexers and combiners, cooling, component placement, and isolation.