An apparatus includes a fin pack of parallel plates that protrude from a base, a lid attachable to the fin pack opposite the base, and a brazing material painted onto the lid only in a plurality of wettable regions. The lid is positioned against the fin pack, opposite the base, with portions of the plurality of regions contacting edges of the parallel plates. The lid is brazed to the fin pack without intrusion of the brazing material between the parallel plates. This is accomplished by obtaining a lid to be attached to a fin pack of parallel plates that protrude from a base, painting the lid with the brazing material only in a plurality of wettable regions, positioning the lid against the fin pack, opposite the base, with portions of the plurality of regions contacting edges of the parallel plates, and brazing the lid to the fin pack.

Micro solder joint and stencil design. In one embodiment, a stencil for depositing solder on a printed circuit board (PCB) includes a plurality of stencil apertures, a first stencil aperture of the plurality of apertures having an aperture wall defining an aperture perimeter. The aperture wall is configured to not extend beyond an outer edge of a PCB pad provided on the printed circuit board, the aperture wall is also configured to not extend beyond an outer edge of a terminal of a surface mount component, and the first stencil aperture is configured to receive solder paste to form a non-convex solder joint between the PCB pad and the terminal.

Method for operating a soldering device and soldering device, wherein a graphic representation of at least part of the soldering device is captured, wherein an instantaneous operating state of the soldering device is determined by means of automated processing of the graphic representation dependent on information about the soldering device from the graphic representation, characterized in that the information about the soldering device is determined dependent on a reference representation of at least part of the soldering device, wherein the reference representation is captured as a graphic representation or wherein the reference representation is read as a graphic representation from a memory, and in that the reference representation characterizes a degree of oxidation of solder (122) when the solder (122) flows out over at least part of a surface (124) of a soldering nozzle (116).

A stencil printer is configured to print an assembly material on an electronic substrate. The stencil printer includes a frame, a stencil coupled to the frame, a support assembly coupled to the frame, and a print head gantry coupled to the frame. The print head gantry includes an elongate beam that rides along rails provided on the frame and a print head assembly supported by the print head gantry in such a manner that the print head assembly is configured to traverse the stencil during print strokes. The print head assembly includes a print head having a squeegee blade assembly configured to roll solder paste along the stencil. The stencil printer further includes a solder paste bead recovery system configured to remove a bead of solder paste from a top surface of the stencil and to deposit the bead of solder paste onto a new replacement stencil.

A jet soldering apparatus has a first housing; a first supply port provided on the first housing and configured to provide molten solder; a second housing; and a second supply port provided on the second housing and configured to provide the molten solder. The molten solder supplied from the first supply port and the molten solder supplied from the second supply port are mixed. The mixed molten solder is not separated from a substrate conveyed by a conveyance unit between the first supply port and the second supply port.

The invention relates to a method for operating a soldering system for selective wave soldering comprising at least one solder crucible, the solder crucible comprising a solder reservoir, a solder nozzle and a solder pump, the solder pump being designed to guide the liquid solder out from the solder reservoir through the solder nozzle for generating a standing wave from liquid solder. The invention relates, in particular, to a method for cleaning a solder nozzle comprising the following steps: conveying solder from the solder reservoir at a first pump capacity which is adjusted in such a way that a standing wave of liquid solder is generated at a solder level which is below an upper edge of the nozzle outlet of the solder nozzle; introducing a cleaning agent into the nozzle outlet of the solder nozzle; increasing the pumping capacity of the solder pump to a second pump capacity such that the cleaning agent flows over the upper edge of the nozzle such that the cleaning agent is guided to an outer side of the solder nozzle.

Provided is an apparatus for attaching semiconductor parts. The apparatus includes a substrate loading unit, at least one semiconductor part loader, a first vision examination unit, at least one semiconductor part picker, at least one adhesive hardening unit, and a substrate unloading unit, wherein the substrate loading unit supplies a substrate on which semiconductor units are arranged, the at least one semiconductor part loader supplies semiconductor parts, the first vision examination unit examines arrangement states of the semiconductor units, the at least one semiconductor part picker mounts semiconductor parts in the semiconductor units, the at least one adhesive hardening unit hardens and attaches adhesives interposed between the semiconductor units and the semiconductor parts, and the substrate unloading unit releases the substrate on which semiconductor parts are mounted. The adhesive hardening units restrictively transmit a heat source only to at least one semiconductor unit, which is to be hardened.

A wire automatic soldering system includes a carrier adapted to load an electrical product to be soldered, a robot adapted to grip and move the carrier on which the electrical product is loaded, a solder paste container containing a solder paste, and a heater configured to heat the solder paste and melt the solder paste into a liquid. The robot moves a plurality of wires of the electrical product into the solder paste container to solder the wires together with the solder paste.

A jet solder bath for performing soldering by jetting molten solder to bring the molten solder into contact with a substrate is provided with a primary jet nozzle that jets the molten solder by a first jet pump, as a first jet nozzle, and a secondary jet nozzle, as a second jet nozzle, which is arranged at a downstream side of the primary jet nozzle along a carrying direction of the substrate and jets the molten solder by a second jet pump. The primary jet nozzle includes a first nozzle body, and a first solder-flow-forming plate that is provided at an upper end of the first nozzle body and has a plurality of jet holes, and the secondary jet nozzle includes a second nozzle body and a second solder-flow-forming plate that is provided at an upper end of the second nozzle body and has a plurality of jet holes.

A device for applying fluid having a pasty consistency is provided. The present invention relates to a device for applying brazing paste manually or by means of a robotic arm, having an elastically deformable conduit and a drive spindle.