The present invention comprises an arrangement and process for the fluxless manufacture of an integrated circuit component, comprising the steps of loading a solder ball and chip arrangement, solder ball side up or down, onto a first or a second donor chuck respectively; monitoring the solder ball and chip arrangement by a computer-controlled camera; removing the solder ball and chip arrangement from the donor chuck by a computer-controlled gripper mechanism; moving the solder ball and chip arrangement via the gripper mechanism onto a computer-controlled gang carrier, the monitored by a second computer controlled camera; flipping the gang carrier about a horizontal axis so as to arrange the solder ball and chip arrangement into an inverted, solder ball side down orientation over a receiver chuck substrate, monitored and positionally controlled by a third computer-controlled camera; and compressing the solder ball side down solder ball and chip arrangement onto the receiver chuck substrate by a computer-controlled compression rod so as to bond the solder ball side down solder ball and chip arrangement onto the receiver chuck substrate so as to form an integrated circuit assembly.

A production system includes: a substrate counter configured to count the number of substrates existing in a production line including a mounting device; a mark pattern acquisition unit configured to acquire a mark pattern indicating a pattern of a mark that is provided to each of the plurality of substrates counted by the substrate counter; a determination unit configured to determine whether the respective mark patterns of the plurality of substrates acquired by the mark pattern acquisition unit are the same as each other; and a detection controller configured to control a detection process of the mark pattern by the mounting device based upon a determination result of the determination unit.

A device (150) for supplying components (197) for a placement machine (100) is described, wherein the components (197) are provided in the form of a continuous material (295). The device (150) has (a) a chassis (252); (b) a transport device (260) attached to the chassis (252) for transporting the continuous material (295) along a transport track towards a pick-up position; and (c) a cutting device (270) which is configured to cut off a section (296) at a leading end of the continuous material (295), wherein the cut-off section (296) represents a supplied component (197). Also described is a placement system (BS) having such a component supplying device (150), and a method for supplying components (197) cut off from a continuous material (295) to a placement machine.

A component mounting device includes a control device configured to execute a recognition data creation process and a pickup process. In the recognition data creation process, the control device creates the recognition data by obtaining the angle information of the component, causing the imaging device to operate so as to image the component, and rotating the captured image so obtained to the reference angle based on the angle information. In the pickup process, the control device causes the head to operate so as to pick up the component after the supply state of the component is determined based on the captured image obtained by causing the imaging device to operate so as to image the component, the recognition data created in the recognition data creation process, and the angle information.

A three-dimensional molding machine includes a three-dimensional molding device configured to mold a three-dimensional molded object on a molding pallet, a circuit forming device configured to form a circuit pattern on the molded object during or after molding, a component mounting device configured to mount an electronic component on the circuit pattern formed on the molded object, a pallet conveyance device configured to convey the molded object together with the molding pallet between the three-dimensional molding device, the circuit forming device, and the component mounting device, and a component conveyance device configured to the electronic components into the component mounting device from an outside of the machine.

A component mounting system that includes a unit exchange device configured to automatically exchange the component supply unit and a processing section configured to determine whether the attachment and detachment of the component supply unit is performed according to the attachment and detachment instruction based on the attachment and detachment record acquired by an acquisition section and the instruction list, and when it is determined that the attachment and detachment is performed according to the attachment and detachment instruction, to perform an update process to update the instruction list by deleting the corresponding attachment and detachment instruction.

A three-dimensional molding machine for manufacturing a three-dimensional molded object comprising an electronic circuit includes multiple modules disposed adjacent to each other, a work unit provided in each of the multiple modules and configured to share a manufacturing operation for manufacturing the three-dimensional molded object on a pallet, and a pallet conveyance section provided in each of the multiple modules and configured to convey the pallet into and out of a module and to transfer the pallet between the module and another adjacent module of the multiple modules.

Provided is a method for the throughput-optimised production of printed circuit boards on least two assembly lines, wherein: the printed circuit boards are divided into clusters; each cluster is produced using a set-up system that is carried out by changeover tables that can be attached to the assembly line, each changeover table having at least one feed device for keeping ready stocks of components; and a changeover table set and an empty changeover table set comprises changeover tables with feed devices that are empty.

A positioning device that has a support table, two pairs of sliding blocks slidably mounted in the support table, a positioning plate extending vertically at the top of each sliding block, a base on which the support table is supported, a cylinder in the base, a ball in the cylinder, a piston rod slidably mounted in the cylinder and pushing the ball to move upward in a vertical direction, so that the ball drives the two pairs of sliding blocks to move away from each other in the first horizontal direction and the second horizontal direction, respectively, until the positioning plates of the two pairs of sliding blocks abut against four inner walls of the opening of the circuit board, respectively, to allow the electronic device to be received in a positioning slot defined by the positioning plates, and a release mechanism that drives the piston rod to move downward in the vertical direction to allow the two pairs of sliding blocks to be moved toward each other in the first horizontal direction and the second horizontal direction, so that the positioning plates drive the electronic device in the positioning slot to move toward a center of the opening.

A component mounter includes a mounting tool to receive the electronic component in a component supply position and release the electronic component at a predetermined position on the board; an accommodation section accommodating mounting tools of multiple types; a head configured to detachably mount thereon a single mounting tool selected from the mounting tools of the multiple types in the accommodation section; a moving mechanism to move the head between the component supply position and the predetermined position on the board; an abnormality detecting section to detect an abnormality in relation to the mounting tool; and a selection section to select the mounting tool to be mounted on the head, and select a mounting tool of a second type, which differs from the mounting tool of a first type which is being mounted on the head, when the abnormality is detected by the abnormality detecting section.