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.

A component placement device for picking up a component and placing a component on a substrate device comprises a holder which is movable at least in a main direction, as well as a nozzle for picking up a component. The nozzle is movable at least in a direction opposite the main direction relative to the holder. The component placement device comprises a fluid flow channel which opens or closes upon movement of the nozzle in the direction opposite the main direction relative to the holder, detection means for detecting the opening or closing of the fluid flow channel as well as means for controlling the movement of the holder in at least the main direction on the basis of a signal delivered by the detection means concerning the opening or closing of the fluid flow channel.

In a board work machine that performs board work with reference to a reference mark provided on a board, in a case of performing board work with respect to a board provided with overall reference mark and local area reference mark that acts as a reference for a local area as reference marks, when recognizing the reference marks by imaging, checking is performed as to whether a recognized reference mark is recognized correctly. For this checking, when checking whether the position deviation amount from a normal position and the relative position deviation amount of an imaging target identified as a reference mark is within the range of a set tolerance, set tolerances for a local area reference mark are smaller than set tolerances for an overall reference mark.

An electronic component mounting device, includes a stage in which a plurality of stage portions are defined, a first heater provided in the plurality of stage portions respectively, and the first heater which can be controlled independently, a mounting head arranged over the stage, and a second heater provided in the mounting head.

An apparatus including a carrier substrate configured to move a microelectronic device. The apparatus further includes a rotatable body configured to receive the microelectronic device. Additionally, the apparatus includes a second substrate configured to receive the microelectronic device from the rotatable body.

A support pin arrangement determination assisting apparatus including a display unit which displays an image including a board image, the board image indicating a shape and an arrangement of a component on the board, a position input unit through which an arrangement position of the support pin is input, a display processing unit which causes the display unit to display a figure to be superimposed on the board image, the figure corresponding to the support pin of which the arrangement position is input, a storage unit which stores three-dimensional shape data of an electronic component and three-dimensional shape data of the support pin, an interference judging unit which judges whether or not one or some of the support pins of which arrangement positions input interfere an already mounted component, and an alarm unit which announces occurrence of interference if the interference judging unit judges the occurrence of interference.

A mechanism comprising a base having a top surface and including a groove extending along the top surface and a frame flexibly coupled to the base. The frame includes a right side attached to a left side. The right side has a substantially “L-shaped” cross-section and includes a knife portion and a creasing portion. The left side includes a substantially “L-shaped” cross-section and is rigidly coupled to the right side such that the frame has a substantially “U-shaped” cross-section that is sized to receive at least a portion of the base. A first spring is positioned proximate the knife portion and is arranged to control a compressive force between the knife portion and the base and a second spring is positioned proximate the creasing portion and is arranged to control a compressive force between the creasing portion and the base.

An apparatus for executing a direct transfer of a semiconductor device die from a first substrate to a second substrate. The apparatus includes a first substrate conveyance mechanism movable in two axes. A micro-adjustment mechanism is coupled with the first substrate conveyance mechanism and is configured to hold the first substrate and to make positional adjustments on a scale smaller than positional adjustments caused by the first substrate conveyance mechanism. The micro-adjustment mechanism includes a micro-adjustment actuator having a distal end and a first substrate holder frame that is movable via contact with the distal end of the micro-adjustment actuator. A second frame is configured to secure the second substrate such that a transfer surface is disposed facing the semiconductor device die disposed on a surface of the first substrate. A transfer mechanism is configured to press the semiconductor device die into contact with the transfer surface of the substrate.

Semiconductor packages are described which increase the density of electronic components within. The semiconductor package may incorporate interposers with cavities formed into the top and/or bottom. The cavities may then be used as locations for the electronic components. Alternatively, narrow spacer interposers may be used to space apart standard more laterally elongated interposers to form the indentations used to house the electronic components. The semiconductor package designs described herein may be used to reduce footprint, reduce profile and increase electronic component and transistor density for semiconductor products.

An assembly machine comprising a continuous circuitous track; a dispensing head system configured to at least partially assemble products, wherein the dispensing head system includes one or more dispensing heads movable around the continuous circuitous track; a product conveyance system extending between a first location of the continuous circuitous track and a second location of the continuous circuitous track and a placement module, the placement module including a first positioning system configured to move along a first axis that intersects with the product conveyance system, wherein the first positioning system is configured to receive a first of the products from the product conveyance system and move the first of the products from the product conveyance system to a first placement location; and a second positioning system configured to move along a second axis that intersects with the product conveyance system, wherein the second positioning system is configured to receive a second of the products from the product conveyance system and move the second of the products from the product conveyance system to a second placement location.