An engine driven welder includes a generator configured to provide an electrical output, an engine coupled to the generator, an air compression system coupled to the engine, a first welding system coupled to the generator, and a second welding system. The engine is configured to drive the generator, and the air compression system is configured to provide a pneumatic output. The first welding system is configured to provide a first weld output, and the second welding system is configured to provide a second weld output. The second weld output is independent of the first weld output in an independent mode, and the second weld output is combined with the first weld output as a combined weld output in a parallel mode.

A method and apparatus for providing welding type power on one of at least two output terminals is disclosed. Input power is received and welding type power is derived and provided by a shared power circuit. The welding type power is provided across a shared terminal and only two process terminals in response to a desired process. The desired process can be set bu user input, feedback, or sensing working connections. The process terminal is selected by selectively opening and closing at least two controllable switches.

A method of projection welding hardware to a plated steel sheet for hot stamping, may include pressing hardware and a plated steel sheet in a state in which a welding projection on the hardware is in contact with the plated steel sheet, supplying a primary current to the hardware and the plated steel sheet in a state in which they are pressed, and supplying a secondary current to the hardware and the plated steel sheet.

A welding system includes a multi-process power supply, a TIG torch, and a TIG power pin for connecting the TIG torch to the multi-process power supply. The multi-process power supply has a power output connection for a MIG torch and a controller. The Controller is configured to command shielding gas and welding current to be provided to the power output connection, and the power output connection is configured to provide the shielding gas and the welding current to a MIG torch when the MIG torch is connected to the power output connection. The TIG power pin connects the TIG torch to the power output connection such that the power output connection is configured to provide the shielding gas and the welding current to the TIG torch. The controller is configured such that at least one of the shielding gas and the welding current is not provided to the TIG torch through the power output connection until a user engages a control member.

Multiple arc welding systems are provided, along with welding system controllers and control methods, in which a single user selected system setpoint value is used to derive individual machine setpoints for a plurality of welding machines in the multiple arc welding system.

The present application relates to a welding system comprising a main module provided with an outer casing identifying an input port for the connection to a source of external electrical power, an electric generator configured to adapt the electrical characteristics of said electrical power to a first type of welding, at least an output port for the connection to a welding torch, an electronic control unit configured to control the functionality of said electric generator. Said main module comprises a mechanical and electrical connection unit of a first type, said welding system comprising at least an auxiliary module provided with an outer casing identifying an electric generator configured to adapt the electrical characteristics of an electrical power to a second type of welding, at least a mechanical and electrical connection unit of a second type couplable to said mechanical and electrical connection unit of a first type.

A a multiple welding method having an improved starting process in which the control unit of the guide electrode starts welding-wire advancing of the guide electrode and sends a synchronization signal to the control unit of the trailing electrode when the guide electrode has moved a certain distance or for a certain time. The control unit of the trailing electrode starts welding-wire advancing of the trailing electrode in dependence on the received synchronization signal before the guide electrode touches the workpiece.

Submerged arc welding torches and systems to resistively preheat electrode wire are disclosed. A disclosed example submerged arc welding torch includes: a first contact tip configured to transfer weld current and preheating current to the wire; a second contact tip configured to conduct the preheating current to the wire; an air-cooled first conductive body portion configured to receive the weld current and to conduct the weld current and the preheating current to the first contact tip; an air-cooled second conductive body portion configured to receive the preheating current and to conduct the preheating current to the second contact tip; and an insulator coupled between the first and second conductive body portions.

A simulator facilitates simulated welding activity of simulated weld joints. The simulator may include a logic processor based system operable to execute coded instructions for generating an interactive welding environment in which a welding activity is simulated, the welding activity occurring at an interface of a first simulated work piece and a second simulated work piece that defines a simulated weld joint. The simulator is capable of simulating the simultaneous welding of multiple users on the simulated weld joint in real time.

Disclosed herein are continuous welding systems and methods for changing electrodes in continuous welding operations. The continuous welding system may include a first and a second welding assembly. A controller may engage with each welding assembly and may individually energize either one of the welding assemblies or both welding assemblies to perform a continuous welding operation. Electrodes from one welding assembly may be removed and replaced without interrupting the operation of at least one other welding assembly. A method of changing electrodes in a continuous welding operation may include performing a welder swap sequence to replace one electrode from a first welding assembly without interrupting the operation of at least one other welding assembly.