A method of identifying and selecting welding electrodes and welding output parameters on a welding power source is provided. The method includes identifying electrodes and/or electrode packaging with distinct colors and/or patterns which correspond to properties of the electrode. The method also may include employing distinguishable identifying markings on a power supply which correspond to the electrodes to be used to allow for easy setting of output parameters.

A method of identifying and selecting welding electrodes and welding output parameters on a welding power source is provided. The method includes identifying electrodes and/or electrode packaging with distinct colors and/or patterns which correspond to properties of the electrode. The method also may include employing distinguishable identifying markings on a power supply which correspond to the electrodes to be used to allow for easy setting of output parameters.

A welding system and a method of control. The welding system may include a weld gun that may have an induction coil and a guide sleeve. The induction coil may heat a welding electrode in the weld gun. The guide sleeve may inhibit the welding electrode from engaging the induction coil.

A welding wire feeder having a multiple motor drive standard is provided. The welding wire feeder may be coupled to one of a plurality of electric motor assemblies, and a user may select the electric motor assembly to be used from a menu of electric motor assemblies on a user interface or may enter customized configuration parameters for the electric motor assembly on the user interface. The control circuitry of the welding wire feeder may then be properly configured backed upon which electric motor assembly is selected or based upon the customized configuration parameters entered.

A feed assist unit (1) includes a base portion (2) having a plurality of ribs (16a-d) on a lower surface (18) thereof. A dome portion (4) is connected to the base portion (2), and a rotating conduit portion (6) has a curved shape and is coupled to the dome portion (4). Each of the ribs (16a-d) has a first end (20) adjacent to the dome portion (4) and a second end (22) adjacent an associated side (14) of the base portion (2). The feed assist unit (1) has first and second central axes (A-A, B-B) oriented perpendicular to each other. First and third of the ribs (16a, 16c) are oriented parallel to the second central axis (B-B) and the second and fourth of the ribs (16b, 16d) can be oriented parallel to the first central axis (A-A). The first and third ribs (16a, 16c) are offset from the second central axis (B-B) by an offset length (OL) and the second and fourth ribs (16b, 16d) are offset from the first central axis (A-A) the offset length (OL).

A fabrication and monitoring device for micro probe ball tips includes a magnetic field generator, a 3-dimensional displacement adjusting mechanism, a wire supplier and an image monitoring system. The magnetic field generator includes a U-shaped electromagnet. The 3-dimensional displacement adjusting mechanism includes a 2-dimensional moving platform, a 1-dimensional moving platform, a guiding tube, and a sparking plug. The wire supplier includes a transmission wheel, a pressing roller, a wire feeding roller and a tungsten wire material supplier. The image monitoring system includes a micro objective, a third-generation infinite beam structure lens and a supporting frame. The present invention overcomes an eccentric problem of a tungsten ball and a tungsten rod, and also overcomes a sphericity problem caused by gravity, so as to improve sphericity, eccentric accuracy and enable monitoring of dynamic manufacturing process of the probe ball tips.

Apparatuses, systems, and/or methods for securing and unsecuring a wire feeder in an automatic welding system without using tools are disclosed. The welding system can include, for example, a robotic arm with a welding torch, an adaptor, and a wire feeder. The adaptor can include, for example, a quick-disconnect member located on the robotic arm. The wire feeder that can be removed from the adaptor after the quick-disconnect member has been actuated. The wire feeder can be installed and secured with tools by placing the wire feeder in the actuator and actuating the quick-disconnect member of the actuator.

Apparatuses, systems, and/or methods for securing and unsecuring a wire feeder in an automatic welding system without using tools are disclosed. The welding system can include, for example, a robotic arm with a welding torch, an adaptor, and a wire feeder. The adaptor can include, for example, a quick-disconnect member located on the robotic arm. The wire feeder that can be removed from the adaptor after the quick-disconnect member has been actuated. The wire feeder can be installed and secured with tools by placing the wire feeder in the actuator and actuating the quick-disconnect member of the actuator.

A gas tungsten arc welding torch includes a handle and a nozzle located distal of the handle and having a central bore. First and second tungsten electrodes are located partially within the central bore of the nozzle. The torch includes at least one filler wire channel that terminates radially inward of the first tungsten electrode and the second tungsten electrode. The torch includes a torch trigger. Operation of the torch trigger controls delivery of a first filler wire and a second filler wire through the at least one filler wire channel. The torch includes a wire feed speed control. Operation of the wire feed speed control adjusts a wire feed speed of both of the first filler wire and the second filler wire.

A device for feeding a welding wire to a welding device is disclosed, having a carriage guide, having a carriage that is supported on a carriage guide so that it is able to move along a carriage axis, particularly in a linear fashion, having an advancing drive, which has an advancing device that is provided on the carriage and driven to induce an advancing motion of the welding wire, and having a carriage drive, which includes a drive unit, an eccentric that is driven by the drive unit, and an eccentric rod that is eccentrically mounted on the eccentric and is mechanically coupled to the carriage to induce a reciprocating motion to the carriage, said carriage drive having means for adjusting the stroke of the reciprocating motion of the carriage.