An automatic soldering processing system is disclosed and includes a soldering-point information obtaining unit, a soldering-parameter generating unit, a solder feeding unit, an iron tip, a motion control unit, and a temperature control unit. The soldering-point information obtaining unit obtains an image of at least one soldering-point of an electronic product, the soldering-parameter generating unit generates soldering parameters such as solder feeding speed, solder feeding amount, moving speed, moving path, heating temperature and heating time for the at least one soldering-point correspondingly according to the image. The solder feeding unit feeds solder based on the solder feeding speed and the solder feeding amount, the iron tip performs a soldering action by using the solder, and the motion control unit and the temperature control unit control the iron tip according to the moving speed, the moving path, the heating temperature, and the heating time.

In wire processing systems and methods, a wire channel receives a wire. One or more fluid guides flow the fluid into the wire channel to move, along the wire, a component (e.g. a solder sleeve) positioned at least partially in the wire channel and coupled to the wire. Other features are also provided.

A wire dispenser for a laser metal wire deposition machine comprises a longitudinal duct for guiding a wire from a proximal end to a distal end of the duct. A nozzle unit is connected to the distal end of the duct and has a through bore for receiving the wire from the distal end of the duct and for discharging the wire adjacent to a laser metal wire deposition site. The nozzle unit includes a cooling circuit for a cooling liquid.

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 wire bonding includes a capillary that extrudes a wire; a wire clamp assembly disposed on the capillary; a support disposed on the wire clamp assembly; a wire contact member; and a slide rail that provides a slide hole. The wire clamp assembly includes: a first member; a second member spaced apart from the first member; a first contact member coupled to the first member; and a second contact member coupled to the second member and spaced apart from the first contact member. The first member includes a first body that extends in a first direction and a first tilting member that extends at an acute angle relative to the first direction. The second member includes a second body that extends in the first direction and is spaced apart from the first body in a second direction a second tilting member.

A welding system comprises a welding module and a moving module adapted to move the welding module to a predetermined welding position. The welding module includes a guiding device and a welding tool. The guiding device has a plurality of tubular guiding heads arranged in a row, ends of the plurality of tubular guiding heads are disposed close to joints of a plurality of cables so as to guide a plurality of welding wires to the joints of the plurality of cables. The welding tool has a plurality of tooth-shaped welding heads arranged in a row, ends of the plurality of tooth-shaped welding heads are disposed close to the joints of the plurality of cables and configured to simultaneously heat the plurality of welding wires guided to the joints of the plurality of cables, so as to simultaneously weld the joints of the plurality of cables onto a circuit board.

The control device includes a brazing controller configured to control a brazing material moving mechanism so as to retract a tip of a brazing material from a heating position to interrupt the brazing, during execution of the brazing, and a movement controller configured to, when the brazing is interrupted, control a movement machine so as to retract a heating device or a base material in a direction opposite to a movement direction during the execution of the brazing, and subsequently advance the heating device or the base material in the movement direction again. The brazing controller resumes the brazing by controlling the brazing material moving mechanism so as to cause the tip of the brazing material to reach the heating position at the same time when the heating device or the base material advanced by the movement controller reaches an interruption position at which the brazing is interrupted.

A method of forming a rod feedstock for titanium stir friction welding additive manufacturing may comprise: mixing a plurality of powdered metals comprising titanium, iron, vanadium, and aluminum to produce a powder blend; at least one of die pressing the powder blend to form a die pressed powder or continuously powder rolling the powder blend to form a die pressed powder; and sintering the powder blend to form a rod feedstock having a cross-sectional profile.

Disclosed are ball jumping apparatuses and ball absorption methods using the same. The ball jumping apparatus comprises a fixing part, a moving part spaced apart from the fixing part, and a resilient member that connects the fixing part and the moving part to each other. The resilient member extends upwardly from the fixing part and has a connection with the moving part. The fixing part includes a fixing plate that spreads in a horizontal direction. The moving part includes an oscillating vessel that has a ball receiving space in which a ball is received, and an oscillator coupled to the oscillating vessel. A bottom surface of the oscillating vessel is upwardly spaced apart from a top surface of the fixing plate.

Welding-apparatus configured to weld base-material through wire-material melted by welding-laser, includes: laser-applicator configured to apply welding-laser to welding-area; wire-feeder configured to feed wire-material to welding-area; detector provided on wire-feeder and configured to detect feed-amount of wire-material or reaction-force from wire-material; moving-unit configured to move welding-area or wire-material; controller configured to respectively control laser-applicator, wire-feeder, and moving-unit. Controller is configured to perform: controlling wire-feeder to stop feeding wire-material to welding-area; then controlling laser-applicator to stop applying welding-laser to welding-area; then controlling moving-unit so that welding-area and wire-material are separated from each other; determining whether wire-material has been welded to base-material based on feed-amount of wire-material or reaction-force from wire-material detected by detector; and controlling laser-applicator to apply cutting-laser when it is determined that wire-material has been welded to base-material.