An apparatus includes a hopper configured to receive a plurality of solder microspheres, and a moveable singulation device positioned proximate to and below the hopper. The moveable singulation device is configured to receive the plurality of solder microspheres from the hopper as the plurality of microspheres exit the hopper. The movable singulation device includes a plurality of holes, with each of the plurality of holes configured to receive a single solder microsphere of the plurality of solder micro spheres. The apparatus further includes a piezoelectric vibration device configured to provide ultrasonic vibrations to the singulation device, thereby preventing agglomeration of the plurality of solder microspheres in the hopper.

A method for filling a through hole with solder includes mounting a substrate having a through hole formed therein on a permeable barrier layer having pores that enable gas to flow through the permeable barrier. A solder source is positioned over the through hole. Molten solder is delivered in the through hole with a positive pressure from the solder source such that gas in the through holes passes the permeable barrier while the molten solder remains in the through hole.

A working machine for a board including a working device that selectively performs work for mounting conductive balls on a circuit board by a ball holder and work for transferring viscous fluid onto the circuit board by transfer pins, and a tray in which the viscous fluid is stored, when the conductive balls are to be mounted on the circuit board, the viscous fluid being transferred onto the circuit board by the transfer pins and the conductive balls having been immersed in the viscous fluid are mounted on the transferred viscous fluid. Accordingly, the conductive balls can be fixed onto the circuit board by the viscous fluid, which is transferred onto the circuit board by the transfer pins, and the viscous fluid that adheres to the conductive balls due to the immersion of the conductive balls in the viscous fluid.

A method for controlling an ejector is disclosed, wherein the ejector comprises an actuator arrangement configured to eject a droplet of viscous medium onto a substrate, and wherein the droplet forms part of a sequence of a plurality of droplets. The method comprises obtaining a control parameter for controlling the operation of the actuator arrangement, and operating the actuator arrangement, using the control parameter, in order to eject the droplet. The obtained control parameter is based on at least one of: a time period between the droplet and a previous droplet in the sequence, a difference in target size of the droplet and a size of the previous droplet in the sequence, and the droplets position in the sequence.

In a solder processing device (A) which includes: a substantially tubular iron tip (5) that can be heated and that is extended vertically; and a solder piece supply portion (2, 6) that supplies a solder piece (Wh) from above into the iron tip (5), and in which the heat of the iron tip (5) is used to melt the solder piece (Wh) such that the molten solder is supplied downward, the supplied solder piece (Wh) is forcefully brought into contact with the inner wall of the iron tip (5). In this way, it is possible to more reliably heat and melt the solder piece (Wh) by use of the heat of the iron tip (5).

In a solder processing device (A) which includes: a substantially tubular iron tip (5) that can be heated and that is extended vertically; and a solder piece supply portion (2, 6) that supplies a solder piece (Wh) from above into the iron tip (5), and in which the heat of the iron tip (5) is used to melt the solder piece (Wh) such that the molten solder is supplied downward, the supplied solder piece (Wh) is forcefully brought into contact with the inner wall of the iron tip (5). In this way, it is possible to more reliably heat and melt the solder piece (Wh) by use of the heat of the iron tip (5).

The invention relates to a laser brazing system, comprising a braze tool having a laser configured to emit a laser beam along a radiation path, and a braze wire tool being configured to guide a braze wire along a wire path intersecting the laser beam. The system comprises a jig comprising a first alignment surface and a first blocking surface, wherein the first alignment surface is configured to be in contact with the braze wire while the first blocking surface blocks at least a first part of the emitted laser beam, and a detector arranged in the radiation path and configured to detect the emitted light of the laser beam passing the jig.

A bonding apparatus has a bonding tool for bonding a wire to a bonding surface, a bonding tool retainer configured to releasably retain the bonding tool, a bonding tool holder configured to hold at least one bonding tool, a bonding tool manipulator configured to transfer said bonding tool between said bonding tool holder and said bonding tool retainer, and a bonding tool guide configured to guide said bonding tool to be received by said bonding tool retainer during transfer by said bonding tool manipulator.

A soldering device includes a laser head for outputting a laser beam and a solder feeder for feeding a thread solder to a path of the laser beam. The soldering device includes a solder receiving member for receiving solder melted by the laser beam and a pouring member for pouring molten solder into a workpiece. The solder receiving member includes a recess part having a shape for retaining the molten solder. The pouring member has a groove part communicating with the recess part and allowing the solder to flow therein.

Assembly for placing solder from solder balls on a substrate, comprising a reservoir with a plurality of solder balls, an exit opening for releasing one single solder ball, a feeding channel between the reservoir and the exit opening with a feeding channel width larger than the diameter of one solder ball and smaller than the diameter of two solder balls, and a suction channel with end opening into the feeding channel which end is smaller than the diameter of one solder ball. A pressure difference is generated between the feeding channel and the suction channel and is controlled whereby pressure in the suction channel is smaller than in the feeding channel. A solder ball present in the feeding channel can be sucked to and held to the end of the suction channel at a first pressure difference to block feeding of solder balls and is released at a second pressure difference.