A shield for shielding a portion of an electronic component from undesirable emissions from neighboring components. The shield comprises a metal body configured to be attached to a substrate, and solder selectively applied to a lower portion of the metal body in manner that allows for both location and volume of the solder to be controlled. A bond is created between the solder and the metal body. The bond may be a metallurgical bond created by proximity of the solder to the at least one leg and sufficient heat and time to bring the solder to a melting temperature of the solder; or a diffusion bond created by heat and pressure. A method of attaching the shield to the substrate is also described.

A welding quality processing method and device, and a circuit board. The method includes: obtaining warpage data of each circuit board layer in a multi-layer circuit board under a preset welding temperature change curve; performing simulation according to a stacked state of the multi-layer circuit board and the warpage data to generate a warpage level of each region in the multi-layer circuit board in the stacked state; and processing the multi-layer circuit board according to the warpage level.

A heat-bonding apparatus and method of manufacturing a heat-bonded product without overheating during cooling thereof after the completion of the heat-bonding, where the object can be cooled in a shorter time than the conventional when the heat-bonding is performed in a vacuum. A heat-bonding apparatus having a vacuum chamber for housing an object to be heat-bonded and a buffer part, a heater for applying heat to the buffer part placed into contact with the object, an object temperature sensor for detecting a temperature of the object heated through the buffer part, a buffer temperature sensor for detecting a temperature of the buffer part, a vacuum breaker for breaking the vacuum, and a controller for operating the vacuum breaker to break the vacuum when a temperature difference between a temperature detected by the object temperature sensor and a temperature detected by the buffer temperature sensor falls within a range of specified temperature difference.

A pane, includes a substrate, an electrically conductive structure on a region of the substrate, a layer of a solder material on a region of the electrically conductive structure, and at least two soldering points of the at least one electrical connection element on the solder material, wherein the at least two soldering points form at least one contact surface between the at least one electrical connection element and the electrically conductive structure, and a shape of the at least one contact surface has at least one segment of an oval, an ellipse, or a circle with a central angle α of at least 90°.

A laser soldering technique prevents generation of scorching of a substrate or heat-susceptible components in the surroundings, residues, etc. A method includes adjusting a height of the laser soldering device 1 to a position at which laser light has a preset irradiation diameter D1 larger than a diameter of a solder droplet S, irradiating the solder droplet S with the laser light to heat the solder droplet S to a temperature at which a flux solvent component volatilizes and a solder powder does not melt; adjusting the height of the laser soldering device to a position at which the laser light has a preset irradiation diameter D2 smaller than the diameter of the solder droplet S, and irradiating the solder droplet S with the laser light to heat the solder droplet S to a temperature at which the solder powder melts, and performing soldering.

A soldered product manufacturing device 1 includes a stage 13 on which a substrate W is placed, solder being arranged on the substrate W; a cover 16 configured to cover at least an upper part of the substrate W placed on the stage 13 at a predetermined distance therefrom; a chamber 11 configured to house the stage 13 and the cover 16; a heater 15 configured to heat the substrate W on the stage 13; and a reducing gas supply device 19 configured to supply a reducing gas F. A method for manufacturing a soldered product includes, by using the soldered product manufacturing device 1, placing the substrate W on the stage 13; covering the substrate W placed on the stage 13 with the cover 16; heating the substrate W; and supplying the reducing gas F into the chamber 11.

An electronic component mounting system is disclosed. An elapsed time acquiring section acquires an elapsed time from printing onto circuit board by solder printer. A raising and lowering operation changing section changes raising and lowering operation of component holding tool based on the elapsed time from printing acquired by the elapsed time acquiring section. A mounter mounts an electronic component on the solder printed on circuit board by performing raising and lowering of the component holding tool at the raising and lowering operation changed by the raising and lowering operation changing section.

Soldering is performed with a high yield ratio even when extremely-thin wires are joined at an extremely-narrow pitch. Moreover, a bridge between conductive joint portions is reduced. A core wire 41 is placed on a preliminarily-soldered conductive joint portion 2. Then, the conductive joint portions 2 and the core wires 41 are covered with an optically-transparent sheet 30. Thus, the state in which the core wire 41 is placed on the conductive joint portion 2 is held. In this state, the optically-transparent sheet 30 is irradiated with light. A preliminary solder 3 is heated and melted to join the core wire 41 and the conductive joint portion 2 together.

A tool and a method of reflow are provided. In various embodiments, the tool includes a chamber unit, a wafer lifting system, a heater, and an exhausting unit. The wafer lifting system is disposed in the chamber unit. The heater is coupled to the chamber unit, and configured to heat the wafer. The exhausting unit coupled to the chamber unit, and configured to exhaust gas in the chamber unit. The wafer lifting system is configured to receive and move the wafer in the chamber unit, and to provide a vertical distance between the heater and the wafer in the chamber unit.

An electronic component mounting device, includes a stage in which a plurality of stage portions are defined, a first heater provided in the plurality of stage portions respectively, and the first heater which can be controlled independently, a mounting head arranged over the stage, and a second heater provided in the mounting head.