A component mounting apparatus including a component supply device which includes a carrier tape that accommodates a component to be mounted on a board in which a plurality of feeders having carrier tapes loaded are respectively mounted at a plurality of mounting positions, which automatically discharges a carrier tape to a tape insertion port of the feeder based on a component discharge instruction, and which automatically conveys an inserted carrier tape to a suction position at which a component is suctioned when the carrier tape is inserted into the tape insertion port; and control device which instructs discharge or supply of a component.

Methods for attachment and devices produced using such methods are disclosed. In certain examples, the method comprises disposing a capped nanomaterial on a substrate, disposing a die on the disposed capped nanomaterial, drying the disposed capped nanomaterial and the disposed die, and sintering the dried disposed die and the dried capped nanomaterial at a temperature of 300° C. or less to attach the die to the substrate. Devices produced using the methods are also described.

A method can include coupling a semiconductor chip and an electrode with a substrate. Bottom and top mold die can be use, where the top mold die define a first space and a second space that is separated from the first space. The method can include injecting encapsulation material to form an encapsulation member coupled to and covering at least a portion of the substrate. The encapsulation member can include a housing unit housing the electrode. The electrode can have a conductive sidewall exposed to, and not in contact with the encapsulation member, such that there is open space between the conductive sidewall of the electrode and the encapsulation member from an uppermost surface to a bottommost surface of the encapsulation member, the substrate can having a portion exposed within the open space, and the encapsulation member can have an open cross-section perpendicular to an upper surface of the substrate.

A method is disclosed for manufacturing an electronic component carrier. The method comprises positioning a header of a frame between opposing attachment arms extending outwardly for attaching an electronic component for seating within the frame. Further, latching members of a latching mechanism of the frame are positioned at a distal end of each of the attachment arms for releaseably seating the electronic component. The attachment arms are resiliently flexible such that the latching members bend to a release position and resiliently return to a grasping position for releasing and grasping the electronic component. Handling levers are positioned for removably mating the electronic component to a connector on a circuit board. The handling levers extend upwardly through an outer casing housing the circuit board when in an open position, and the handling levers are substantially parallel with a top surface of the header when in a closed position.

A modular light emitting diode (LED) mounting configuration is provided including a light source module having a plurality of pre-packaged LEDs arranged in a serial array. The module includes a heat conductive body portion adapted to conduct heat generated by the LEDs to an adjacent heat sink. As a result, the LEDs are able to be operated with a higher current than normally allowed. Thus, brightness and performance of the LEDs is increased without decreasing the life expectancy of the LEDs. The LED modules can be used in a variety of illumination applications employing one or more modules.

A method of manufacturing an ink jet print head capable of bonding the printing element substrate to the support surface with high precision in a reduced period of time is provided. For this purpose, raised flat portions are formed in the support surface of the supporting member to provide in an adhesive layer between the printing element substrate and the supporting member a portion of the thermosetting adhesive that is thinner than others. After the relative positions of the printing element substrate and the supporting member are adjusted, the thin portions of the adhesive layer are hardened. This enables the printing element substrate to be bonded to the supporting member in a relatively short period of time. As a result, if there are undulations on the support surface, the printing element substrate can be bonded to the supporting member with high precision, improving the mass productivity of the print head.

A work head unit that detects the rotational position of suction nozzle with first Q-axis encoder positioned facing component holding section that holds a component. With the work head unit, it is desirable to detect the orientation of component holding section at two locations: suction nozzle and syringe member.

A work machine including: a tape feeder with taped lead components having multiple leads to supply the lead components in a state of being detached from the taped components extended to a supply position; a mounting head to mount the lead components supplied by the tape feeder onto a board; an imaging device; and a control device having an imaging section to image an identification object, the identification object being on the taped components and capable of identifying the polarity of each of the multiple leads, and a determination section to determine whether an actual polarity disposition, which is the polarity disposition of each of the multiple leads, and a set polarity disposition, which is the polarity disposition of each of the multiple leads set in advance, match each other based on image data obtained by imaging with the imaging section.

Disclosed are methods and systems of controlling the placement of micro-objects on the surface of a micro-assembler. Control patterns may be used to cause phototransistors or electrodes of the micro-assembler to generate dielectrophoretic (DEP) and electrophoretic (EP) forces which may be used to manipulate, move, position, or orient one or more micro-objects on the surface of the micro-assembler. A set of micro-object may be analyzed. Geometric properties of the set of micro-objects may be identified. The set of micro-objects may be divided into multiple sub-sets of micro-objects based on the one or more geometric properties and one or more control patterns.

An assembly machine includes a plurality of track modules, each track module including a section of track, the plurality of track modules connectable to form a continuous circuitous track, the continuous circuitous track configured to receive a dispensing head, the dispensing head configured to rotate about the continuous circuitous track and at least partially assemble an unfinished product. The machine includes a first feeder module attached to a first length of the continuous circuitous track configured to feed a component to the dispensing head, and a first placement module attached to a second length of the continuous circuitous track configured to receive the unfinished product. The dispensing head is configured to place the component on the unfinished product. The assembly machine is reconfigurable by attaching or removing one or more of the plurality of track modules, the first feeder module and the first placement module.