A method of manufacturing an electronic module includes supplying paste to an electronic component and/or a wiring board. The paste includes solder powder and first resin. The method includes supplying second resin to the electronic component and/or the wiring board. The method includes placing one of the electronic component and the wiring board on another. The method includes curing the second resin to form a second resin portion. The method includes heating the paste to a temperature equal to or higher than a solder melting point after the second resin portion is formed. The method includes solidifying molten solder at a temperature lower than the solder melting point to form a solder portion that bonds the electronic component and the wiring board. The method includes curing the first resin after the solder portion is formed, to form a first resin portion.

A substrate work machine for repeatedly performing substrate work, the substrate work machine including a data storing section configured to store component data used in the substrate work, the component data including shape data related to a shape of an electronic component to be mounted on a substrate, a reference value and a tolerance; a data determining section configured to determine whether a difference between measurement data acquired by measuring the electronic component during the substrate work and the reference value of the component data is within a range of the tolerance; a quality information acquiring section configured to acquire work quality information related to a performance condition of a second substrate work machine; and a data correcting section configured to correct at least one of the reference value and the tolerance in accordance with the work quality information.

A component supply device including an accommodation body installation unit in which one or more accommodation bodies each accommodating components are installable, the component supply device sequentially operates the one or more accommodation bodies to supply each of the components to a predetermined component supply position. The component supply device comprises a supply state detector which detects a supply state of components in total accommodated in the one or more accommodation bodies installed on the accommodation body installation unit, a determination unit which determines, based on the supply state, a state of the accommodation body installation unit among (i) an installation disabled state, (ii) an installation enabled state, and (iii) an installation required state, and a notifier which notifies a worker of the state of the accommodation body installation unit determined by the determination unit.

A carrier tape holding electrical components to a reel around which the carrier tape is wound is provided. Furthermore, the present disclosure is related to a pick-and-place apparatus for receiving this carrier tape and for picking and placing the electrical components arranged in the carrier tape. The carrier tape according to an aspect of the present disclosure includes an adhesive film that forms a bottom wall of the cavities in which a plurality of electrical components is arranged. The adhesive of the adhesive film is configured to substantially release the attachment of the electrical component as a result of heating the adhesive and/or as a result of irradiating the adhesive using light, such as visible light, infrared light, or ultraviolet light, for the purpose of allowing the electrical component to be removed from the cavity using a pick-and-place apparatus.

A mounting device comprises a substrate stage, a mounting head, an elevating unit, a recognition mechanism, and a control unit. The recognition mechanism acquires position information about a chip recognition mark and a substrate recognition mark using an imaging unit. The control unit calculates an amount of positional deviation between a chip component and a substrate from the position information about the chip recognition mark and the substrate recognition mark, and performs alignment by driving the mounting head and/or the substrate stage according to the amount of the positional deviation. The chip component and the substrate are brought closer with each other and the alignment is performed in a state in which the imaging unit simultaneously images the chip recognition mark and the substrate recognition mark within a depth of field, after which the chip component and the substrate are brought into close contact with each other.

A mounting device comprises a substrate stage, a mounting head, an elevating unit, a recognition mechanism, and a control unit. The recognition mechanism acquires position information about a chip recognition mark and a substrate recognition mark using an imaging unit. The control unit calculates an amount of positional deviation between a chip component and a substrate from the position information about the chip recognition mark and the substrate recognition mark, and performs alignment by driving the mounting head and/or the substrate stage according to the amount of the positional deviation. The chip component and the substrate are brought closer with each other and the alignment is performed in a state in which the imaging unit simultaneously images the chip recognition mark and the substrate recognition mark within a depth of field, after which the chip component and the substrate are brought into close contact with each other.

A method of manufacturing a display device includes providing a display layer including a light-emitting element, providing a base resin on the display layer, providing a chassis part by using a chassis providing unit including an electromagnet, providing a resin part by transforming a shape of the base resin, and separating the chassis providing unit from the display layer.

A method of manufacturing a display device includes providing a display layer including a light-emitting element, providing a base resin on the display layer, providing a chassis part by using a chassis providing unit including an electromagnet, providing a resin part by transforming a shape of the base resin, and separating the chassis providing unit from the display layer.

A rack-mountable computer system enables an airflow that cools components in an upstream portion of the computer system interior to be cooled through mixing with a bypass airflow downstream of the components in the upstream portion. The mixed airflow can cool components in a downstream portion of the interior. The bypass airflow is directed by a bypass plenum that is unencompassed by the separate plenum that directs the airflow to cool the upstream portion components. The bypass plenum can be at least partially established by an external surface the computer system and one or more external structures, including an external surface of an adjacently mounted computer system. Relative flow rates through the separate plenums can be adjusted, via flow control elements, to separately control heat removal from components upstream and downstream of the air mixing, based at least in part upon air temperatures in the separate interior portions.

A rack-mountable computer system enables an airflow that cools components in an upstream portion of the computer system interior to be cooled through mixing with a bypass airflow downstream of the components in the upstream portion. The mixed airflow can cool components in a downstream portion of the interior. The bypass airflow is directed by a bypass plenum that is unencompassed by the separate plenum that directs the airflow to cool the upstream portion components. The bypass plenum can be at least partially established by an external surface the computer system and one or more external structures, including an external surface of an adjacently mounted computer system. Relative flow rates through the separate plenums can be adjusted, via flow control elements, to separately control heat removal from components upstream and downstream of the air mixing, based at least in part upon air temperatures in the separate interior portions.