A system for flux residue detection is provided. The system includes a flux heater, where the flux heater controls a temperature of a flux spray applied to a printed circuit board, and an infrared camera, wherein the infrared camera provides a thermal image of the flux on the printed circuit board. A method, a computer system, and a computer program product for flux residue detection is provided, including setting flux application parameters, applying flux to a printed circuit board, and capturing an infrared image of the flux applied to the printed circuit board. A method, a computer system, and a computer program product for flux residue detection is provided, including setting flux application parameters, applying flux to a printed circuit board, capturing an infrared image of the flux applied to the printed circuit board, and determining there is excess flux residue on the printed circuit board.

The three-dimensional mounting device includes a supporting section capable of fixing a processing target, an application section for applying a viscous fluid to the processing target, a mounting section for arranging a component on the processing target, an imaging section for imaging the processing target, and a control section for controlling the processing section including the supporting section, the application section, the mounting section, and the imaging section. One or more of the supporting section, the application section, the mounting section, and the imaging section has multiple tilt axes and is capable of tilting the processing target and/or the processing section in multiple directions. The control section performs coordinate correction using the circuit pattern on the forming surface as a reference position, and arranges the component on the mounting section.

An inspection apparatus includes an imaging unit that captures an image of a board having a land on which a solder piece has been printed, an image of the board having a component mounted on the solder piece, or an image of the board having the component soldered to the land, a land determination unit that determines a position of an element on the board other than the land from the image of the board captured by the imaging unit, and determines a position of the land in the image based on the determined position of the element, and an inspection unit that inspects the solder piece or component on the land using the position of the land determined by the land determination unit as a reference.

A substrate inspection apparatus according to an embodiment of the present invention comprises a projection unit, an illumination unit, an image acquisition unit and a processing unit. The projection unit irradiates an inspection target with light for obtaining three-dimensional shape information of the inspection target. The illumination unit irradiates the inspection target with at least two lights having different colors. The image acquisition unit acquires a first image by receiving light irradiated by the projection unit and reflected from the inspection target, and a second image by receiving the lights irradiated by the illumination unit and reflected from the inspection target. The processing unit acquires brightness information and color information from the first image and the second image, respectively, which are acquired by the image acquisition unit, and acquires at least a portion of a boundary by using the bright information and the color information. Therefore, the accuracy and reliability of the inspection can be improved.

A component mounting system includes: a component mounting machine that mounts an electronic component having a predetermined electrode portion on a solder printed on a substrate, the electronic component being fixed to the substrate with a thermosetting adhesive; and an adhesive inspection device. The component mounting machine: sets, with regard to the electronic component to be fixed with the adhesive that cures at a temperature lower than a melting temperature of the solder, a target mounting height along a height direction perpendicular to a face of the substrate on which the adhesive is applied; and mounts the electronic component at the target mounting height. The target mounting height is: an ideal mounting height based on design data; or a height lower than the ideal mounting height by a value that corresponds to a sinking of the electronic component as a result of melting of the solder.

A three-dimensional measurement apparatus measures measurement targets placed in a target measurement area on a measurement object. The apparatus includes: a measurement module that: is positioned with respect to the target measurement area, and includes: a first irradiator that irradiates the target measurement area with predetermined light for height measurement; a second irradiator that irradiates the target measurement area with predetermined patterned light for three-dimensional measurement; and an imaging device that takes an image of the target measurement area; and a control device that moves the measurement module in a height direction and successively positions the measurement module at a predetermined height position determined by mapping, and performs, based on image data taken by irradiating the target measurement area with predetermined patterned light, three-dimensional measurement to the measurement targets at the predetermined height position.

A mounting device includes: an application part applying paste on a substrate to form an application body; a bonding part forming a mounted body by mounting a chip component on the substrate via the application body; a first imaging part imaging the application body after application processing and before mounting processing to acquire first image information; a second imaging part imaging the mounted body after the mounting processing to acquire second image information; and a control part controlling the application part, the bonding part, and the first and second imaging parts, and obtains a 3D application body shape (first shape) from the first image information as a first shape and calculates a 3D mounted body shape (second shape) from the second image information. The control part evaluates the application processing or the mounting processing based on the first and the second shapes.

A substrate inspection device that is placed on an upstream side of a component mounting machine that mounts an electronic component on solder that is printed on a substrate by a solder printing machine, and that inspects the solder and a thermosetting adhesive applied on the substrate, the substrate inspection device including: an irradiator that irradiates the solder and the adhesive with light; an imaging device that takes an image of the irradiated solder and the irradiated adhesive; and a processor that: generates actual solder position information of a solder group that the electronic component is mounted on based on the image, wherein the solder group includes two or more solders; generates, based on design data or manufacturing data, ideal solder inspection reference information indicating a reference inspection position and/or a reference inspection range of the solder included in the solder group.

An apparatus that communicates with a screen printer and a solder inspection device is disclosed. The apparatus according to the present disclosure may include a process that is configured to: obtain first information associated with each of a plurality of pads on the substrate; obtain second information associated with each piece of the solder paste applied to each of the plurality of pads from the solder inspection device; determine a position correction value for the stencil mask with respect to the substrate based on the first information and the second information; and deliver the position correction value to the screen printer.

A system for determining a degree of contamination of production units of a production line for the printing, equipping and reflow soldering of printed circuit boards, and evaluation unit.