A circuit board tape includes substrate units each including a sprocket-hole region, a layout region and a joining mark. There are odd and more than three sprocket holes on the sprocket-hole region. An imaginary line extended from the joining mark is extended to between a first layout and a second layout located on the layout region. The amount of the sprocket holes between the imaginary lines of the adjacent substrate units is odd. The circuit board tape is cut along the imaginary lines of the different substrate units so as to remove the defective substrate unit from the circuit board tape and divide the circuit board tape into a front tape and a rear tape. After joining the front and rear tapes, the region where a first layout on the front tape and a second layout on the rear tape are located is defined as a combined layout region.

A carrier assembly configured to facilitate manufacture of a printed circuit board assembly includes a bottom frame defining a generally rectangular configuration and having a length and a width. The bottom frame is adjustable to vary at least one of the length or the width thereof. The assembly further includes a core releasably positionable on the bottom frame and configured to support a circuit board thereon. A carrier assembly system includes the bottom frame and a plurality of cores. Methods of manufacturing printed circuit board assemblies utilizing carrier assemblies are also provided.

A temporary storage and reflow frame substrate system includes a substrate frame, a substrate loading and unloading station, a first conveying unit, and a second conveying unit. The substrate frame is suitable for loading the substrate. The substrate loading and unloading station includes a robotic arm, a feeding and discharging unit and a returning unit, the substrate frame is suitable for connecting to the feeding and discharging unit and the returning unit, the robotic arm is suitable to place the substrate into or remove the substrate from the substrate frame. The first conveying unit is connected to the feeding and discharging unit and is suitable for conveying the substrate frame. The second conveying unit is connected between the first conveying unit and the returning unit, in order to return the substrate frame to the returning unit, thereby loading and unloading the substrate at the substrate loading and unloading station.

A component mounting machine includes a board conveyance device, a component supply device, a component transfer device which includes a mounting head and a head driving mechanism, and a mounting order control device. The component mounting machine partitions a long printed circuit board of a length exceeding a mounting station into a plurality of mounting areas, sequentially positions each mounting area in the mounting station, and mounts the electronic components. The mounting order control device performs control to change the mounting order of the electronic components.

In embodiments, a PCB reflow process may be carried out by the components of an automated system working together to separate PCBs from reflow carriers and transport the reflow carriers back to a previous station of the PCB reflow system. The automated reflow carrier recycling system that is described herein may include a clip unlocking mechanism, a PCB pickup mechanism, a shifter, one or more lifters, and one or more overhead conveyors.

A lower surface of a board arranged at a working position is supported by a board supporter, and heights of a plurality of portions of the lower surface of the board are measured by a plurality of height measuring instruments attached to the board supporter. A component is installed on the board by control of a height of the installation of the component by an installation head and with respect to the board, which has the lower surface supported by the board supporter, being performed based on the height of the plurality of portions of the lower surface of the board measured by the plurality of height measuring instruments.

A method for equipping printed circuit boards on an equipping machine, the printed circuit boards being of a first length, and the equipping machine being realized to equip printed circuit boards of a second length, the second length being more than twice as great as the first length. The equipping machine has an input section (1) and an equipping section (2), the equipping section (2) being disposed after the input section (1) in a direction of conveyance (F) of the printed circuit boards, disposed after the input section (1) in a direction of conveyance of the printed circuit boards, the printed circuit boards of the first length and the printed circuit boards of the second length being transportable, in their longitudinal direction, from the input section (1) into the equipping station (2).

There is provided technology which is a component mounting machine which mounts electronic components onto a circuit substrate and is capable of displaying a movable region of an inner portion of the component mounting machine within a same image. The component mounting machine is provided with a fixed camera which monitors the inner portion of the component mounting machine and a display section which is capable of displaying a captured image of the fixed camera. The fixed camera is capable of imaging a range from a pickup position at which the suction nozzle picks up the electronic component which is supplied from the component feeder to a mounting position at which the electronic component is mounted onto the circuit substrate within the same image.

A system that may include a apertured structure that is configured to support a substrate and a vacuum supply unit that is configured to (i) prevent a supply of vacuum to a first area of the substrate during a first processing period during which the first area is processed and a second area of the substrate is not processed; (ii) provide vacuum to the second area during the first processing period; (iii) prevent the supply of vacuum to the second area during a second processing period during which the second area is processed and the first area is not processed; and (iv) provide vacuum to the first area during the second processing period.

A movable table system comprising two identical tables on a common rail arrangement having a linear rail region underneath a detection unit and a processing unit, and therefore the tables can be alternatingly moved in a straight line along the common rail arrangement, in the same table-movement direction, fully underneath the detection unit and processing unit, and can be independently controlled by a computer unit. The movable table system provides a new option for processing planar workpieces, in which a particularly high throughput rate and improved precision can be achieved using merely one processing unit.