Abstract: A component mounting apparatus includes a nozzle that sucks a component supplied from a feeder, conveys the component to a predetermined position on a substrate, and mounts the component in the predetermined position. The component mounting apparatus controls an XY-robot to perform repeatedly the component mounting operation while performing a thermal correction from a start of the component mounting operation as a result of a power supply being turned on until an amount of positional deviation due to heat from the XY-robot reaches a steady state. After the steady state is achieved, the component mounting apparatus controls the XY-robot to perform repeatedly the component mounting operation while performing a steady state correction using a correction amount resulting immediately after the steady state is achieved without performing the thermal correction and controls the XY-robot to perform a dummy operation for maintaining the steady state during a standby period.

Abstract: Provided are a method of manufacturing a shear and normal force sensor including fabricating raised and sunken polymers having a plurality of bent parts of bent shapes, forming an electrode pattern on one surface of a piezoelectric element, and embedding the piezoelectric element between the raised and sunken polymers, and a shear and normal force sensor including raised and sunken polymers having a plurality of bent parts of bent shapes, a piezoelectric element embedded between the raised and sunken polymers and having an electrode pattern on one surface, and a flexible printed circuit board (FPCB) embedded between the sunken polymer and the piezoelectric element and electrically connected to the electrode pattern.

Abstract: A system is provided for wire processing. The wire processing system may include a wire transport, a processing station that may provide wire to the wire transport, a processing station that may move an electrical component threaded onto the wire, and a processing station that may move the electrical component to a position on the wire for further processing.

Abstract: A method of making an electrical structure having a foam housing is set forth. The foam housing includes an interior surface forming a conductive cavity adapted to carry energized waveforms therethrough. An electrical component of the electrical structure is integrally formed with the interior surface as the foam housing of the structure is assembled. The method includes the steps of depositing a plating material into a mold, pouring a foam polymer into the mold and removing the plated foam structure from the mold without etching the section from the mold. The method further includes steps of forming a metallic form into a planar structure, filling the open pores of the foam with a material such as photo-resist, machining a cavity from the foam, electroplating the cavity in the foam then removing the photo-resist material.

Abstract: A mother substrate that enables winding cores to be obtained in a manner in which the mother substrate is divided along x-direction division lines and y-direction division lines is prepared. Subsequently, x-direction division grooves are formed along the x-direction division lines on a first main surface of the mother substrate, y-direction division grooves are formed along the y-direction division lines on the first main surface, and shallow bottom surface exposure grooves, for exposing surfaces that are to be core portion bottom surfaces, are formed on the first main surface. The mother substrate is divided by performing a flattening process on a second main surface of the mother substrate that is opposite the first main surface until the second main surface reaches the x-direction division grooves and the y-direction division grooves to obtain the winding cores that are separated from each other.

Abstract: An electronic device assembling apparatus has a cable holder and a lock member operator. The cable holder holds a cable and inserts the cable into a connector. After the cable is inserted into the connector by the cable holder, the lock member operator operates a lock member to lock the cable to the connector. The lock member operator starts an operation with respect to the lock member in a state where the cable inserted into the connector is held by the cable holder.

Abstract: A method of making an inductor includes forming a plurality of first metal layers on a substrate and an ILD. The method includes patterning a plurality of trenches in the ILD, depositing a magnetic material, and depositing another layer of ILD. The method further includes patterning a plurality of vias adjacent to the trenches filled with the magnetic material, and patterning trenches in the another layer of ILD. The trenches in the another layer of ILD include first portions arranged over, adjacent to and substantially parallel the plurality of first metal layers, and the second portions arranged substantially perpendicular to the first portions, extending from both ends of the first portions, and oriented in opposite directions such that the second portions are continuous with the plurality of vias. The method includes depositing a metal in the plurality of vias and the trenches in the another layer of ILD.

Abstract: A manufacturing method of a liquid supply component in which a liquid supply path is formed between a first constituent component and a second constituent component that are joined with molten resin. The method includes a first step of preparing these constituent components, a second step of causing the constituent components to face each other and forming an orifice portion and a reservoir portion between a mold and a surface of either of the constituent components, and a third step of pouring the molten resin between the constituent components so that it flows into the reservoir portion through the orifice portion.

Abstract: A system for applying thermal interface materials to components includes a supply of thermal interface material and a die. The die is operable for pushing against and/or removing a portion of the thermal interface material that is between the die and a corresponding one of the components. The portion of the thermal interface material is removed from the supply and applied to the corresponding one of the components.

Abstract: A multi-layer piezoelectric microactuator assembly has at least one poled and active piezoelectric layer and one poled but inactive piezoelectric layer. The poled but inactive layer acts as a constraining layer in resisting expansion or contract of the first piezoelectric layer.

Abstract: A flat coil, a manufacturing method thereof and an electronic apparatus are disclosed. The manufacturing method comprises: rolling a metal foil lamination onto a carrier roller to form a foil rod, wherein the metal foil lamination includes at least one layer of metal foil; sliding the foil rod from the carrier roller; slicing the foil rod into thin disks; and processing the thin disks to form at least one flat coil, wherein a pressing roller is pressed against the carrier roller via the metal foil lamination with a controlled pressing force as the metal foil lamination is rolled.

Abstract: A method for manufacturing a surge absorbing device is provided. The method includes providing an elongate ceramic tube having a hollow space defined therein and having open and opposite first and second end; forming a first plating layer and a second plating layer on the first end and the second end, respectively; placing a surge absorbing element within the hollow space within the ceramic tube; disposing first and second brazing rings on the first plating layer and the second plating layer, respectively; disposing first and second sealing electrodes on the first and second brazing rings respectively; and melting the first and second brazing rings in an inert gas atmosphere to attach the first and second sealing electrodes onto the first plating layer and the second plating layer, respectively.

Abstract: Methods for manufacturing a microfluidic delivery device comprising a semiconductor structure, such as silicon, are provided. In particular, the structure for delivering fluid may be formed from polycrystalline silicon, also called polysilicon, or epitaxial silicon. The microfluidic delivery device that predominantly uses semiconductor material, such as silicon, to form the structures that are in contact with the dispensed fluid results in a device that is compatible with a wide set of fluids and applications.

Abstract: A method for forming an inductor device. The method comprises forming a trench within a central core region of a conductive coil formed within a dielectric material. The method further comprises forming a composite region within the trench. The composite region including a polymer matrix having a plurality of particles with magnetic properties dispersed therein with the central core region to reduce eddy current loss and increase energy storage.

Abstract: An electronic component removal device comprising a cutting wire routed through a cutting region configured to receive an electronic component coupled to a substrate. The electronic component removal device can also include a leading actuator coupled to a leading end of the cutting wire to cause movement of the cutting wire in a cutting direction at a cutting speed. The electronic component removal device can further include a trailing resistance device coupled to a trailing end of the cutting wire to resist movement of the cutting wire in the cutting direction with a variable resistance. In addition, the electronic component removal device can include a leading tension sensor to sense a leading tension in the cutting wire between the cutting region and the leading actuator. The trailing resistance device can resist movement of the cutting wire with a resistance that varies based on the leading tension in the cutting wire.

Abstract: A method for producing a laminate that includes at least the following: providing a first intermediate laminate comprising a carrier substrate including a support therein and a peelable metal layer formed on at least one surface of the carrier substrate; forming, in a section not serving as a product of the first intermediate laminate, a first hole reaching at least the support in the carrier substrate from a surface of the first intermediate laminate, to prepare a second intermediate laminate with the first hole; stacking and disposing on the surface where the first hole is formed of the second intermediate laminate, an insulating material and a metal foil in this order when viewed from the surface; and pressurizing the second intermediate laminate, the insulating material and the metal foil in the stacking direction thereof with heating, to prepare a third intermediate laminate where the first hole is filled with the insulating material; and performing treatment with a chemical agent on the third intermedia

Abstract: A bonding layer 3 is formed over a piezoelectric material substrate, and the bonding layer is made of one or more materials selected from the group consisting of silicon nitride, aluminum nitride, alumina, tantalum pentoxide, mullite, niobium pentoxide and titanium oxide. A neutralized beam is irradiated onto a surface of the bonding layer and a surface of a supporting body to activate the surface of the bonding layer and the surface of the supporting body. The surface of the bonding layer and the surface of the supporting body are bonded by direct bonding.

Abstract: A method of manufacturing a dielectric device includes epitaxially growing a metal film on a substrate, forming a dielectric film on the metal film such that the dielectric film has a preferentially oriented structure, forming a first electrode film having a non-oriented or amorphous structure on the dielectric film, removing the substrate and the metal film from the dielectric film or removing the substrate from the metal film, and forming a second electrode film having a non-oriented or amorphous structure on the dielectric film or the metal film.

Abstract: A component mounting device includes a heater unit which heats along a range which is narrower than a movement range of a head and which is a partial length of a board, in which the head is controlled to mount components onto the board using a heating range of the heater as a mounting range, the board is conveyed to shift the mounting range every time mounting of components in the mounting range is completed such that an unmounted range in which components are not mounted on the board becomes the mounting range, and components are mounted in a new mounting range.

Abstract: An MRIS gradient coil sub-assembly comprising a first coil layer comprising a first conducting coil portion, a second coil layer comprising a second conductive coil portion electrically connected with the first conductive coil portion so that the first and second conductive coil portions act together as one coil, and a B-stage material consolidation layer sandwiched between the first and second coil layers. A method including laminating a first punched sheet metal conductive saddle coil portion and a second punched sheet metal conductive saddle coil portion together by bonding the first and second punched sheet metal conductive saddle coil portions on opposing sides of a B-stage material insulation layer, and electrically connecting the first punched sheet metal conductive saddle coil portion to the second punched sheet metal conductive saddle coil portion in parallel so that the first and second conductive saddle coil portions act together as one saddle coil.