Abstract: A suction nozzle 65 of a reversing head device 22 has a distal end surface 65a with a suction hole 65b opened therein, and a suction passage 65c communicated with the suction hole 65b at one end thereof. A portion of the distal end surface 65a outside of the suction hole 65b abuts against bumps 39 of an electronic component 12. The suction hole 65b is opposed with a gap to a portion of a mounting side surface 12a where no bumps 39 are present. A vacuum pump 65 creates an air flow that flows from the gap between the suction hole 65b and mounting side surface 12a into the suction passage 65c through the suction hole 65b. The electronic component 12 is held at the distal end surface 65a by a negative pressure generated by the air flow.

Abstract: In slack removal processing for removing slack generated on a wafer sheet by heating blow, a wafer feeding plate is positioned at a height position between a first height position and a second height position. This makes it possible to decrease a gap between an upper end portion of an expanding ring and a lower face of the wafer sheet and allows efficient and uniform processing. Moreover, setting the height position so as to avoid the contact between the wafer sheet and the upper end portion of the expanding ring at least when the slack removal processing is completed reliably prevents shrinking operation of the wafer sheet from being disturbed by the contact between the wafer sheet and the upper end portion.

Abstract: After detection of contact between respective solder bumps of an electronic component, sucked and held by a suction nozzle of a head tool, and respective solder portions of a circuit board, the solder bumps and the solder portions are melted by heating. Releasing of the electronic component from suction and holding by the suction nozzle of the head tool is performed, not at a time during solder melting, but at a time after the solder is melted, cooled and solidified. Thus, an electronic component mounting method and apparatus capable of mounting high-end electronic components having narrow-pitched bumps are provided.

Abstract: In a receiver for component feed plates for housing, in multi-stage stacks, a plurality of component feed plates with a plurality of components placed thereon, identification mark portions are formed so as to be placed at end portions or their proximities of support guide portions in a plate feed direction so that each of paired sets of support guide portions out of individual support guide portions can be distinguished from the other paired sets of support guide portions and moreover visually discerned in the plate feed direction.

Abstract: A component-mounted substrate moved to a specified substrate position by a substrate holding-and-moving device is delivered from a top of the substrate holding-and-moving device to a substrate discharge holder, and then while the substrate discharge holder is not moved, the substrate holding-and-moving device is moved to another substrate position, where a new substrate is received. Consequently, a later-executed movement operation for moving the new substrate to a substrate mounting region by the substrate holding-and-moving device, and a transfer operation for transferring the component-mounted substrate to an unloader unit by the substrate discharge holder, may be performed in parallel with each other without being influenced by each other's operation.

Abstract: A method and an apparatus for mounting electronic components that enables precise mounting of electronic components, such as deformation-prone thin IC chips or fine-pitch and high-pin-count IC chips, on a substrate. Thin IC chips, which conventionally tend to lose flatness because of warping that occurs during production or deformation that occurs when picked up with a suction nozzle, are pressed against a substrate (4) with a preset load using a suction nozzle with a flat suction surface (11b) so as to correct deformation; the suction nozzle (11) is controlled to move up to make up for a decrease in the distance between the oppositely spaced IC chip and the substrate (4) that is caused by thermal expansion due to the heating for melting solder bumps (1a) on the electrodes; and the suction nozzle (11) is controlled to move down to mitigate the effect of a pulling-apart force applied to the molten parts as the thermally expanded parts cool down and contract.

Abstract: In component mounting process for a plurality of components to be mounted onto a board, a plurality of bump electrode portions formed on mounting-side surfaces of the components to be mounted onto the board are brought into contact with a bonding-assistant agent so that the bonding-assistant agent is supplied thereto to allow the bonding-assistant agent-supplied components to be mounted onto the board, the component mounting process includes, supplying the bonding-assistant agent to a first component among the plurality of components, and starting the supply of the bonding-assistant agent to a second component among the plurality of components before completion of the mounting of the bonding-assistant agent-supplied first component onto the board.

Abstract: An electronic component mounting apparatus which employs a first air feed device connected to an air passage at one end part of a spline shaft, and a second air feed device connected to the air passage in the vicinity of the other end of the spline shaft. The first and second air feeds function to supply air to the air passage to return an interior thereof to atmospheric pressure. The time required to return the vacuum pressure in the air passage to atmospheric pressure can be shortened by the use of the two separate air feeds.

Abstract: A component mounting system includes first to third (pickup, transfer, and placement) stations. A component supplied at a component supply is picked up by a transport head at the pickup station and then transferred to a placement head at the transfer station. The placement head carries the component to the placement station where the component is placed and mounted onto a substrate such as a circuit board. The component, when held by the placement head, is recognized by an imaging device at or in the vicinity of the transfer station.

Abstract: According to the type of the plate placed in a plate placing device of a component feeder, appropriate holding operation and expanding operation are performed selectively and automatically according to the type of the plate by regulating the lowered position of a plate pressurizing member for the tray feeding plate to securely hold the plate and performing wafer expanding while securely holding the wafer feeding plate by releasing the regulation of the lowered position for the wafer feeding plate.

Abstract: A component-mounted substrate moved to a specified substrate position by a substrate holding-and-moving device is delivered from the top of the substrate holding-and-moving device to a substrate discharge holder, and then while the substrate discharge holder is not moved, the substrate holding-and-moving device is moved to another substrate position, where a new substrate is received. Consequently, a later-executed movement operation for moving the new substrate to a substrate mounting region by the substrate holding-and-moving device and a transfer operation for transferring the component-mounted substrate to an unloader unit by the substrate discharge holder may be performed in parallel with each other without being influenced from each other's operation.

Abstract: A component mounting system includes first to third (pickup, transfer, and placement) stations. A component supplied at a component supply is picked up by a transport head at the pickup station and then transferred to a placement head at the transfer station. The placement head carries the component to the placement station where the component is placed and mounted onto a substrate such as a circuit board. The component, when held by the placement head, is recognized by an imaging device at or in the vicinity of the transfer station.

Abstract: An electronic component mounting apparatus which employs a first air feed device connected to an air passage at one end part of a spline shaft, and a second air feed device connected to the air passage in the vicinity of the other end of the spline shaft. The first and second air feeds function to supply air to the air passage to return an interior thereof to atmospheric pressure. The time required to return the vacuum pressure in the air passage to atmospheric pressure can be shortened by the use of the two separate air feeds.

Abstract: By arranging bonding members formed of a gold nanopaste between chip-electrodes and board-electrodes, making the chip-electrodes are brought in contact with the respective board-electrodes via the bonding members and applying ultrasonic vibrations to the bonding members in the contact state, the bonding members are bonded to the board-electrodes and the chip-electrodes.

Abstract: An electronic component mounting apparatus which employs a first air feed device connected to an air passage at one end part of a spline shaft, and a second air feed device connected to the air passage in the vicinity of the other end of the spline shaft. The first and second air feeds function to supply air to the air passage to return an interior thereof to atmospheric pressure. The time required to return the vacuum pressure in the air passage to atmospheric pressure can be shortened by the use of the two separate air feeds.

Abstract: After detection of contact between respective solder bumps of an electronic component, sucked and held by a suction nozzle of a head tool, and respective solder portions of a circuit board, the solder bumps and the solder portions are melted by heating. Releasing of the electronic component from suction and holding by the suction nozzle of the head tool is performed, not at a time during solder melting, but at a time after the solder is melted, cooled and solidified. Thus, an electronic component mounting method and apparatus capable of mounting high-end electronic components having narrow-pitched bumps are provided.